Chemicals/Pesticides
Maternity protection - Reproduction & Work
(C) Copyright Wim Van Hooste, MD.
Website with information on reproduction, pregnancy and work.
http://maternityprotection-reproductionwork.blogspot.com/2007_02_01_archive.html
This report contains the collective views of an international group of experts and does not necessarily represent the decisions or the stated policy of the United Nations Environment Programme, the International Labour Organization or the World Health Organization.
Environmental Health Criteria 225
Initial drafts prepared by Dr P. Foster, Research Triangle Park, NC, USA; Dr W. Foster, Los Angeles, CA, USA; Dr C. Hughes, Los Angeles, CA, USA; Dr C. Kimmel, Washington, DC, USA; Dr S. Selevan, Washington, DC, USA; Dr N. Skakkebaek, Copenhagen, Denmark; Dr F. Sullivan, Brighton, England; Dr S. Tabacova, Sofia, Bulgaria; Dr J. Toppari, Turku, Finland; and Dr B. Ulbrich, Berlin, Germany
Published under the joint sponsorship of the United Nations Environment Programme, the International Labour Organization and the World Health Organization, and produced within the framework of the Inter-Organization Programme for the Sound Management of Chemicals.
World Health Organization Geneva, 2001
The International Programme on Chemical Safety (IPCS), established in 1980, is a joint venture of the United Nations Environment Programme (UNEP), the International Labour Organization (ILO) and the World Health Organization (WHO). The overall objectives of the IPCS are to establish the scientific basis for assessment of the risk to human health and the environment from exposure to chemicals, through international peer review processes, as a prerequisite for the promotion of chemical safety, and to provide technical assistance in strengthening national capacities for the sound management of chemicals. The Inter-Organization Programme for the Sound Management of Chemicals (IOMC) was established in 1995 by UNEP, ILO, the Food and Agriculture Organization of the United Nations, WHO, the United Nations Industrial Development Organization, the United Nations Institute for Training and Research and the Organisation for Economic Co-operation and Development (Participating Organizations), following recommendations made by the 1992 UN Conference on Environment and Development to strengthen cooperation and increase coordination in the field of chemical safety. The purpose of the IOMC is to promote coordination of the policies and activities pursued by the Participating Organizations, jointly or separately, to achieve the sound management of chemicals in relation to human health and the environment. WHO Library Cataloguing-in-Publication Data
Principles for evaluating health risks to reproduction associated with exposure to chemicals.
1. Reproduction – physiology
2.Reproduction – drug effects
3.Fertility – drug effects
4.Fetal development – drug effects
5.Environmental exposure
6.Risk assessment
I. International Programme for Chemical Safety
II.Series
ISBN 92 4 157225 6
(NLM classification: QZ 59)
ISSN 0250-863X
The World Health Organization welcomes requests for permission to reproduce or translate its publications, in part or in full. Applications and enquiries should be addressed to the Office of Publications, World Health Organization, Geneva, Switzerland, which will be glad to provide the latest information on any changes made to the text, plans for new editions, and reprints and translations already available. © World Health Organization 2001
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The designations employed and the presentation of the material in this publication do not imply the expression of any opinion whatsoever on the part of the Secretariat of the World Health Organization concerning the legal status of any country, territory, city or area or of its authorities, or concerning the delimitation of its frontiers or boundaries.
The mention of specific companies or of certain manufacturers’ products does not imply that they are endorsed or recommended by the World Health Organization in preference to others of a similar nature that are not mentioned. Errors and omissions excepted, the names of proprietary products are distinguished by initial capital letters.
NOTE TO READERS OF THE CRITERIA MONOGRAPHSEvery effort has been made to present information in the criteria monographs as accurately as possible without unduly delaying their publication. In the interest of all users of the Environmental Health Criteria monographs, readers are requested to communicate any errors that may have occurred to the Director of the International Programme on Chemical Safety, World Health Organization, Geneva, Switzerland, in order that they may be included in corrigenda.
* * *
A detailed data profile and a legal file can be obtained from the International Register of Potentially Toxic Chemicals, Case postale 356, 1219 Châtelaine, Geneva, Switzerland (telephone no. + 41 22 – 9799111, fax no. + 41 22 – 7973460, E-mail irptc@unep.ch).
Environmental Health Criteria
PREAMBLE
Objectives
In 1973, the WHO Environmental Health Criteria Programme was initiated with the following objectives:
(i)
to assess information on the relationship between exposure to environmental pollutants and human health, and to provide guidelines for setting exposure limits;
(ii)
to identify new or potential pollutants;
(iii)
to identify gaps in knowledge concerning the health effects of pollutants;
(iv)
to promote the harmonization of toxicological and epidemiological methods in order to have internationally comparable results.
The first Environmental Health Criteria (EHC) monograph, on mercury, was published in 1976, and since that time an ever-increasing number of assessments of chemicals and of physical effects have been produced. In addition, many EHC monographs have been devoted to evaluating toxicological methodology, e.g., for genetic, neurotoxic, teratogenic and nephrotoxic effects. Other publications have been concerned with epidemiological guidelines, evaluation of short-term tests for carcinogens, biomarkers, effects on the elderly and so forth.
Since its inauguration, the EHC Programme has widened its scope, and the importance of environmental effects, in addition to health effects, has been increasingly emphasized in the total evaluation of chemicals.
The original impetus for the Programme came from World Health Assembly resolutions and the recommendations of the 1972 UN Conference on the Human Environment. Subsequently, the work became an integral part of the International Programme on Chemical
Safety (IPCS), a cooperative programme of UNEP, ILO and WHO. In this manner, with the strong support of the new partners, the importance of occupational health and environmental effects was fully recognized. The EHC monographs have become widely established, used and recognized throughout the world.
The recommendations of the 1992 UN Conference on Environment and Development and the subsequent establishment of the Intergovernmental Forum on Chemical Safety with the priorities for action in the six programme areas of Chapter 19, Agenda 21, all lend further weight to the need for EHC assessments of the risks of chemicals.
Scope
The criteria monographs are intended to provide critical reviews on the effects on human health and the environment of chemicals and of combinations of chemicals and physical and biological agents. As such, they include and review studies that are of direct relevance for the evaluation. However, they do not describe every study carried out. Worldwide data are used and are quoted from original studies, not from abstracts or reviews. Both published and unpublished reports are considered, and it is incumbent on the authors to assess all the articles cited in the references. Preference is always given to published data. Unpublished data are used only when relevant published data are absent or when they are pivotal to the risk assessment. A detailed policy statement is available that describes the procedures used for unpublished proprietary data so that this information can be used in the evaluation without compromising its confidential nature (WHO (1990) Revised Guidelines for the Preparation of Environmental Health Criteria Monographs. PCS/90.69, Geneva, World Health Organization).
In the evaluation of human health risks, sound human data, whenever available, are preferred to animal data. Animal and in vitro studies provide support and are used mainly to supply evidence missing from human studies. It is mandatory that research on human subjects is conducted in full accord with ethical principles, including the provisions of the Helsinki Declaration.
The EHC monographs are intended to assist national and international authorities in making risk assessments and subsequent risk management decisions. They represent a thorough evaluation of risks and are not, in any sense, recommendations for regulation or standard setting. These latter are the exclusive purview of national and regional governments.
Content
The layout of EHC monographs for chemicals is outlined below.
• Summary — a review of the salient facts and the risk evaluation of the chemical
• Identity — physical and chemical properties, analytical methods
• Sources of exposure
• Environmental transport, distribution and transformation
• Environmental levels and human exposure
• Kinetics and metabolism in laboratory animals and humans
• Effects on laboratory mammals and in vitro test systems
• Effects on humans
• Effects on other organisms in the laboratory and field
• Evaluation of human health risks and effects on the environment
• Conclusions and recommendations for protection of human health and the environment
• Further research
• Previous evaluations by international bodies, e.g., IARC, JECFA, JMPR
Selection of chemicals
Since the inception of the EHC Programme, the IPCS has organized meetings of scientists to establish lists of priority chemicals for subsequent evaluation. Such meetings have been held in: Ispra, Italy, 1980; Oxford, United Kingdom, 1984; Berlin, Germany, 1987; and North Carolina, USA, 1995. The selection of chemicals has been
based on the following criteria: the existence of scientific evidence that the substance presents a hazard to human health and/or the environment; the possible use, persistence, accumulation or degradation of the substance shows that there may be significant human or environmental exposure; the size and nature of populations at risk (both human and other species) and risks for the environment; international concern, i.e., the substance is of major interest to several countries; adequate data on the hazards are available.
If an EHC monograph is proposed for a chemical not on the priority list, the IPCS Secretariat consults with the cooperating organizations and all the Participating Institutions before embarking on the preparation of the monograph.
Procedures
The order of procedures that result in the publication of an EHC monograph is shown in the flow chart on the next page. A designated staff member of IPCS, responsible for the scientific quality of the document, serves as Responsible Officer (RO). The IPCS Editor is responsible for layout and language. The first draft, prepared by consultants or, more usually, staff from an IPCS Participating Institution, is based initially on data provided from the International Register of Potentially Toxic Chemicals and from reference databases such as Medline and Toxline.
The draft document, when received by the RO, may require an initial review by a small panel of experts to determine its scientific quality and objectivity. Once the RO finds the document acceptable as a first draft, it is distributed, in its unedited form, to well over 150 EHC contact points throughout the world who are asked to comment on its completeness and accuracy and, where necessary, provide additional material. The contact points, usually designated by governments, may be Participating Institutions, IPCS Focal Points or individual scientists known for their particular expertise. Generally, some four months are allowed before the comments are considered by the RO and author(s). A second draft incorporating comments received and approved by the Director, IPCS, is then distributed to Task Group members, who carry out the peer review, at least six weeks before their meeting.
The Task Group members serve as individual scientists, not as representatives of any organization, government or industry. Their function is to evaluate the accuracy, significance and relevance of the information in the document and to assess the health and environmental risks from exposure to the chemical. A summary and recommendations for further research and improved safety aspects are also required. The composition of the Task Group is dictated by the range of expertise required for the subject of the meeting and by the need for a balanced geographical distribution.
The three cooperating organizations of the IPCS recognize the important role played by nongovernmental organizations. Representatives from relevant national and international associations may be invited to join the Task Group as observers. While observers may provide a valuable contribution to the process, they can speak only at the invitation of the Chairperson. Observers do not participate in the final evaluation of the chemical; this is the sole responsibility of the Task Group members. When the Task Group considers it to be appropriate, it may meet in camera.
All individuals who as authors, consultants or advisers participate in the preparation of the EHC monograph must, in addition to serving in their personal capacity as scientists, inform the RO if at any time a conflict of interest, whether actual or potential, could be perceived in their work. They are required to sign a conflict of interest statement. Such a procedure ensures the transparency and probity of the process.
When the Task Group has completed its review and the RO is satisfied as to the scientific correctness and completeness of the document, the document then goes for language editing, reference checking and preparation of camera-ready copy. After approval by the Director, IPCS, the monograph is submitted to the WHO Office of Publications for printing. At this time, a copy of the final draft is sent to the Chairperson and Rapporteur of the Task Group to check for any errors.
It is accepted that the following criteria should initiate the updating of an EHC monograph: new data are available that would substantially change the evaluation; there is public concern for health or environmental effects of the agent because of greater exposure; an appreciable time period has elapsed since the last evaluation.
All Participating Institutions are informed, through the EHC progress report, of the authors and institutions proposed for the drafting of the documents. A comprehensive file of all comments received on drafts of each EHC monograph is maintained and is available on request. The Chairpersons of Task Groups are briefed before each meeting on their role and responsibility in ensuring that these rules are followed.
WHO TASK GROUP ON ENVIRONMENTAL HEALTH CRITERIA FOR PRINCIPLES FOR EVALUATING HEALTH RISKS TO REPRODUCTION ASSOCIATED WITH EXPOSURE TO CHEMICALS
Members
Dr D. Anderson, TNO BIBRA Toxicology International Ltd., Surrey, United Kingdom
Prof. Dr E. Bustos-Obregón, University of Chile Medical School, Santiago, Chile
Prof. Dr I. Chahoud, Institut für Klinische Pharmakologie und Toxicologie, Berlin, Germany
Dr G. Daston, Procter & Gamble, Cincinnati, Ohio, USA
Dr P. Foster, Chemical Industry Institute of Toxicology, Research Triangle Park, North Carolina, USA
Dr W. Foster, Cedars-Sinai Medical Center, Los Angeles, California, USA
Dr U. Hass (representing Organisation for Economic Co-operation and Development), Soborg, Denmark
Dr C. Kimmel, US Environmental Protection Agency, Washington, DC, USA
Dr R. Little, National Institute of Environmental Health Sciences, Research Triangle Park, North Carolina, USA
Dr S. Selevan, US Environmental Protection Agency, Washington, DC, USA
Dr S. Tabacova, National Centre of Hygiene, Medical Ecology and Hygiene, Sofia, Bulgaria
Dr J. Toppari, University of Turku, Turku, Finland
Dr B. Ulbrich, Institute for Drugs and Medical Devices, Berlin, Germany
Dr M. Yasuda, Hiroshima School of Medicine, Hiroshima, Japan
Secretariat
Dr B.-H. Chen, Shanghai, China
Dr T. Damstra, World Health Organization, IPCS/Interregional Research Unit (IRRU), USA
PREFACE
The International Programme on Chemical Safety (IPCS) was initiated in 1980 as a collaborative programme of the United Nations Environment Programme (UNEP), the International Labour Organization (ILO) and the World Health Organization (WHO). One of the major objectives of the IPCS is to develop and evaluate principles and methodologies for assessing the effects of chemicals on human health and the environment. Since its inception, IPCS has been particularly concerned with assessing risk to the human reproductive system from exposure to chemicals and has given a high priority to improving methodologies and strategies in this area.
As part of this effort, IPCS publishes a series of monographs called Environmental Health Criteria (EHC). Past publications include two EHCs on aspects of risk assessment for reproductive health: EHC 30, "Principles for Evaluating Health Risks to Progeny Associated with Exposure to Chemicals during Pregnancy" (IPCS, 1984), and EHC 59, "Principles for Evaluating Health Risks from Chemicals during Infancy and Early Childhood: The Need for a Special Approach" (IPCS, 1986a). EHC 30 focused on the use of short-term tests and in vivo animal tests to assess prenatal toxicity and postnatal alterations in reproduction, development and behaviour following chemical exposure during gestation, and EHC 59 focused on methods to detect impaired reproductive and neurobehavioural development in infants and children who were exposed during the prenatal and early postnatal periods.
Many data and numerous new methods have emerged since these monographs were published in the 1980s, and the ability to assess the risk to reproductive health from chemical exposure has significantly improved. A number of urgent requests have been made by agencies in many different countries, particularly developing countries, for up-to-date information on principles and approaches to assessing reproductive health risk. In response to these requests, IPCS has produced another monograph on these issues. The present monograph focuses on approaches to assessing reproductive toxicity in males and females, including sexual dysfunction and infertility, and many aspects of developmental toxicity (following both prenatal and postnatal exposure), from conception to sexual maturation. It is an overview of the major scientific principles underlying hazard identification, testing methods and risk assessment strategies in human reproductive toxicity. It also discusses the evaluation of reproductive toxicity data in the context of the extensive risk assessment methodology that has emerged over the past 10–15 years.
IPCS is producing this monograph as a tool for use by public health officials, research and regulatory scientists and risk managers. It is intended to complement the monographs, reviews and test guidelines on reproductive and developmental toxicity currently available. However, this document does not provide specific guidelines or protocols for the application of risk assessment strategies or the conduct of specific tests. Specific testing guidelines for assessing reproductive toxicity from exposure to chemicals have been developed by the Organisation for Economic Co-operation and Development (OECD) and national governments.
Several meetings took place to discuss and evaluate the structure and content of this document. Initial drafts of the document were prepared by a group of authors (listed on the title page) and coordinated by the IPCS Secretariat, Dr B.-H. Chen and Dr T. Damstra. IPCS is grateful to these authors and acknowledges the time and expertise that they so generously gave to this project.
A preliminary draft was circulated for review to 52 experts in reproductive toxicology and IPCS contact points. Many reviewers provided substantive comments and text, and their contributions are gratefully acknowledged.
A Task Group meeting was held in Carshalton, United Kingdom, on 16–18 October 2000, to review a revised draft. Dr T. Damstra, IPCS, was responsible for the preparation of the final document and for its overall scientific content.
The efforts of all who helped in the preparation and finalization of the monograph are gratefully acknowledged. Special thanks are due to the US Environmental Protection Agency (EPA) and the Federal Ministry for the Environment, Nature Conservation and Nuclear Safety, Germany, for their financial support for the planning and review group meetings.
ACRONYMS AND ABBREVIATIONS
ABP
androgen binding protein
ACTH
adrenocorticotrophin hormone
ADI
allowable daily intake
ATPase
adenosine triphosphatase
AUC
area under the curve
bFGF
basic fibroblast growth factor
BMC
benchmark concentration
BMD
benchmark dose
BMP
bone morphogenetic protein
cAMP
cyclic adenosine monophosphate
Cmax
maximum plasma concentration
CNS
central nervous system
DDE
dichlorodiphenyldichloroethylene
DDT
dichlorodiphenyltrichloroethane
DES
diethylstilbestrol
DHEA
dehydroepiandrosterone
DHEAS
dehydroepiandrosterone sulfate
DHT
dihydrotestosterone
DNA
deoxyribonucleic acid
DSP
daily sperm production
EC
European Commission
ECETOC
European Centre for Ecotoxicology and Toxicology of Chemicals
EDC
endocrine disrupting chemical
EGF
epidermal growth factor
Egr
early growth response
EHC
Environmental Health Criteria
EPA
Environmental Protection Agency (USA)
FAO
Food and Agriculture Organization of the United Nations
FDA
Food and Drug Administration (USA)
FGF
fibroblast growth factor
FSH
follicle stimulating hormone
GDF
growth differentiation factor
GnRH
gonadotrophin releasing hormone
HCB
hexachlorobenzene
hCG
human chorionic gonadotrophin
H-P-G axis
hypothalamic–pituitary–gonadal axis
hPL
human placental lactogen
HSD
hydroxysteroid dehydrogenase
IARC
International Agency for Research on Cancer
IC50
median inhibitory concentration
ICM
inner cell mass
IGF
insulin-like growth factor
ILO
International Labour Organization
ILSI
International Life Sciences Institute
IPCS
International Programme on Chemical Safety
JECFA
Joint FAO/WHO Expert Committee on Food Additives
JMPR
Joint FAO/WHO Meeting on Pesticide Residues
Ki
inhibition rate constant
LDL
low-density lipoprotein
LH
luteinizing hormone
LOAEL
lowest-observed-adverse-effect level
MIS
Müllerian inhibiting substance
MOE
margin of exposure
NGF
nerve growth factor
NOAEL
no-observed-adverse-effect level
NTP
National Toxicology Program (USA)
OECD
Organisation for Economic Co-operation and Development
PAH
polycyclic aromatic hydrocarbon
PBB
polybrominated biphenyl
PCB
polychlorinated biphenyl
pKa
negative log of the acid dissociation constant
QSAR
quantitative structure–activity relationship
RfC
reference concentration
RfD
reference dose
RNA
ribonucleic acid
SBR
standardized birth ratio
TDI
tolerable daily intake
TGF-alpha
transforming growth factor alpha
TGF-beta
transforming growth factor beta
UN
United Nations
UNEP
United Nations Environment Programme
VEGF
vascular endothelial growth factor
WHO
World Health Organization
1. SUMMARY AND RECOMMENDATIONS
1.1 Summary
Since the publication of the IPCS Environmental Health Criteria documents dealing with aspects of reproductive toxicity risk assessment in the early 1980s, new scientific data and methodologies have significantly improved the ability to assess how environmental chemicals may adversely affect the reproductive system. This progress is reflected in the availability of a number of national and international (e.g., Organisation for Economic Co-operation and Development) reproductive and developmental toxicity test guidelines, risk assessment guidelines and guidance documents, as well as some international test method validation studies. However, the potential for human exposure to environmental contaminants (via a variety of routes) to affect the function of the reproductive system and normal development remains an area of global concern.
Normal human reproduction is regulated by a finely tuned system of coordinated signals that direct the activity of multiple interdependent target cells, leading to the formation of gametes, their transport, release, fertilization, implantation and gestation, and, ultimately, the development of offspring that is eventually capable of successfully repeating the entire process under similar or different environmental conditions.
Throughout the entire life cycle, all aspects of reproductive function are dependent on various endocrine communicating systems that employ a wide variety of protein/peptide and steroid hormones, growth factors and other signalling molecules that affect target cell gene expression and/or protein synthesis. In particular, development and gametogenesis are regulated by a myriad of signals delivered in appropriate strength at precisely defined times. Although recent animal studies demonstrate that the developing fetus may be more sensitive to the effects of exposure to environmental chemicals than the adult system, effects may not be manifest until adulthood. Further characterization of the molecular mechanisms regulating the various aspects of normal reproduction and development is critical to our understanding of the variety of mechanisms through which exogenous chemicals may disrupt normal reproduction and development.
Sexual function and fertility reflect a wide variety of functions that are necessary for reproduction and may be affected by exposure to environmental factors. Any disturbance in the integrity of the reproductive system may affect these functions. Patterns of reported infertility vary around the world, but approximately 10% of all couples experience infertility at some time during their reproductive years. Human studies on altered sexual function/fertility provide the most direct means of assessing risk, but data are often unavailable. For many environmental chemicals, it is still necessary to rely on information derived from experimental animal models and laboratory studies.
In vivo animal studies for reproductive toxicity risk assessment typically utilize standard laboratory rodents. Fertility assessments in male animals have limited sensitivity as measures of reproductive injury, because, unlike humans, males of most test species produce sperm in numbers that greatly exceed the minimum requirements for fertility. Histopathological data on reproductive tissues play an important role in male reproductive toxicity risk assessment. Chemicals with estrogenic or antiandrogenic activity have been identified that are capable of causing reproductive effects in males. While sensitivity may differ, it is likely that mechanisms of action for these endocrine disrupting agents will be consistent or similar across mammalian species. For females, all functions of the reproductive system are under endocrine control and can be susceptible to disruption by effects on the reproductive endocrine system. However, single measurements of hormonal changes may be insensitive indicators of any damage because of large normal variability in females.
A variety of in vitro test systems, including isolated perfused testis/ovary, primary cultures of gonadal cells, investigation of subcellular fractions of different organs and cell types and in vitro fertilization techniques, are available that can be used in supplementary investigational studies of different aspects of the reproductive system. In vitro testing systems are especially useful for screening for toxicity potential and for identifying potential mechanisms of action of potential toxicants. However, these tests are limited in their ability to assess complex, integrative reproductive functions.
Developmental toxicity, defined in its widest sense to include any adverse effect on normal development either before or after birth, has become of increasing concern in recent years. Developmental toxicity can result from exposure of either parent prior to conception, from exposure of the embryo or fetus in utero or from exposure of the progeny after birth. Adverse developmental effects may be detected at any point in the life span of the organism. In addition to structural abnormalities, examples of manifestations of developmental toxicity include fetal loss, altered growth, functional defects, latent onset of adult disease, early reproductive senescence and shortened life span.
In vivo studies on pregnant experimental animals and their progeny have been widely used in developmental toxicity assessment. The aim of the maternal observations is to assess the relative contribution of maternal toxicity to any observed embryo/fetal toxicity. Observations on progeny include early and late embryonic deaths (resorptions), fetal weight, external malformations, visceral and skeletal anomalies and sex determination. Background information and historical records on abnormal development of the experimental animals are important for adequate interpretation of such toxicity studies. Functions that can be evaluated postnatally include neurological development, simple and complex behaviours, reproduction, endocrine function, immune competence, xenobiotic metabolism and physiological function of different organ systems. Latent manifestations of toxicity may include transplacental carcinogenicity (neoplasia in the progeny resulting from maternal exposure to chemical agents during pregnancy) and shortened life span. A wide range of in vitro systems, ranging from whole embryo culture through organ and tissue culture to a variety of non-mammalian systems, has also been developed for the study of developmental toxicity. In vitro tests are useful in investigation of mechanisms of normal and abnormal development to obtain information on dose–response relationships and specific organ toxicity, and perhaps as screening systems for selection or prioritization of chemicals for further in vivo studies.
The most feasible end-points for evaluating developmental toxicity in humans are vital status at birth (including embryo/fetal loss), readily identifiable congenital anomalies, gestational length, birth weight and sex ratio. Measurable postnatal developmental effects include changes in growth, behaviour and organ or system function, as well as cancer. Both prenatal and postnatal effects may not be apparent until well after birth, and some may not appear until adulthood. For example, some congenital anomalies are not immediately apparent, and the long-term sequelae of intrauterine growth retardation are just now being appreciated. Chemical exposure during development may also affect the later reproductive function of the offspring. For example, chemicals could damage female germ cells in utero and affect the mature female’s fertility; similarly, male stem cells or Sertoli cells could be depleted, potentially affecting sperm production.
Many countries have developed risk assessment processes for reproductive and developmental toxicity in order to set standards and regulate exposures. These processes typically include components of hazard identification, dose–response relationships, exposure assessment and risk characterization. Experimental testing protocols are largely based on identifying structural anomalies and/or functional deficits following chemical exposure during critical windows of the reproductive cycle. All available sources of animal and human data should be considered to assess specific reproductive and developmental toxic effects. Approaches for evaluating and summarizing reproductive toxicity data have improved. Nevertheless, assumptions must often be made in the risk assessment process because of gaps in knowledge about underlying biological processes and species differences. Risk assessment test methods and strategies need to be continually refined as new data and technologies become available.
1.2 Recommendations
In order to employ effective control and intervention strategies to prevent reproductive and developmental toxicity, an adequate knowledge base must be developed. The following recommendations are made to improve this knowledge base:
1.
Establish and develop better (molecular) markers of effects on reproduction and development. Those that may have a human and animal congruence would be particularly useful and would aid in the evaluation and use of animal data in human risk assessment.
2.
Examine the utility of newer technologies related to gene expression (e.g., gene arrays, proteomics, laser capture microscopy) to aid in the understanding and elucidation of the underlying mechanisms of normal and abnormal reproductive function and development.
3.
Strengthen and refine methods to assess both the critical windows of exposure through the entire spectrum of development and stages of development most vulnerable to manifestations of adverse effects.
4.
Increase basic knowledge of the mechanisms of male reproductive physiology to a level comparable to the current level of knowledge on mechanisms of female reproductive physiology.
5.
Promote the application of cellular and molecular understanding of gonadal and gamete functions to extend the understanding of toxicological effects on these tissues.
6.
Search for and validate animal models to analyse toxicological aspects of reproductive biology to develop appropriate systems that are reproducible, low cost and easier to extrapolate to human disease.
7.
Improve and validate in vitro methods for assessing mechanisms of potential reproductive toxicity.
8.
Develop more accurate and efficient methods of measuring human exposure to environmental chemicals with potential reproductive toxicity.
9.
Improve the surveillance, collection and harmonization of data on the frequency and geographical distribution of birth defects and developmental disorders, with special attention to establishment of complete registries.
10.
Promote research efforts to better identify subpopulations potentially vulnerable to the effects of agents responsible for reproductive toxicity and to characterize the factors contributing to increased vulnerability.
11.
In view of the sensitivity of the developing organism, place more emphasis on toxicity studies involving gestational and perinatal exposure to a chemical or mixture of chemicals.
12.
Utilize previously studied birth cohorts to investigate the incidence of latent adverse reproductive outcomes later in life (cohorts with pregnancy exposure data are extremely important).
13.
Establish an international harmonized system for terminology and definitions for reproductive and developmental toxicity.
2. INTRODUCTION A growing body of scientific evidence indicates that exposure to a wide range of environmental contaminants causes adverse reproductive effects in humans and other species. These issues are a prominent public health concern of scientists, decision-makers and the general public. Many disorders of reproduction have been described in both males and females. Examples include reduced fertility, menstrual disorders, impaired spermatogenesis, cryptorchidism and hypospadias, pregnancy loss, low birth weight, structural and functional birth defects, postnatal developmental defects and various genetic diseases affecting the reproductive system and offspring. It has been estimated that the incidence of easily recognized birth defects is 2–3% of live births and that the incidence of less easily recognized birth defects and developmental disorders is 5–10% of live births from all causes (ICH, 1993). The magnitude of reproductive problems in the general population is becoming widely recognized, and the possible role of environmental agents in causing these disorders has renewed worldwide interest in reproductive and developmental toxicology. Recently, the US National Toxicology Program (NTP) established the Center to Evaluate Risks to Human Reproduction, the purpose of which is to conduct risk assessment on agents with potential to cause reproductive and developmental toxicity. This monograph summarizes current scientific knowledge on hazard identification and risk assessment for reproductive toxicity. For the purposes of this document, reproductive toxicity includes adverse effects on sexual function and fertility in males and females as well as developmental toxicity. This monograph builds on previously published Environmental Health Criteria monographs (EHCs) and scientific reviews (e.g., IPCS, 1984, 1986a; Moore, 1995; Moore et al., 1995; ILSI, 1999; US NRC, 2000). The document is intended as a tool for use by public health officials, research and regulatory scientists and risk managers. It seeks to provide a scientific framework for the use and interpretation of reproductive toxicity data from human and animal studies. It also discusses emerging methodology and testing strategy in reproductive toxicity. Chapter 3 discusses basic reproductive physiology and the relative vulnerability of specific reproductive structures and processes and provides the scientific background for understanding specific methods and procedures used in reproductive toxicology. Chapter 4 focuses on methods for assessing and evaluating altered sexual function and fertility. Chapter 5 addresses methodologies for assessing developmental toxicity, defined as any effect interfering with normal development both before and after birth resulting from exposure of either parent prior to conception, exposure during prenatal development or exposure postnatally to the time of sexual maturation. Chapter 6 deals with the general principles of risk assessment for reproductive toxicity and identifies areas where research is needed. An appendix provides working definitions for the terminology used in the monograph. A particular area of concern in reproductive and development toxicity relates to the effects of chemicals that have the potential to disrupt or interfere with the endocrine system (i.e., potential endocrine disrupting chemicals, or EDCs). The potential adverse health consequences of exposure to EDCs have fuelled intense public debate and media attention, and a considerable amount of scientific research is being conducted on EDCs. The concern over EDCs extends to governments, international organizations, scientific societies, the chemical industry and public interest groups. Many research programmes, conferences, workshops and committees are trying to address EDC-related issues. Endocrine disruption is only one of a diverse number of mechanisms for potentially causing adverse reproductive and developmental effects. It is beyond the scope of this document to review the large body of data dealing with EDCs, and the reader is referred to recent comprehensive reviews (Colborn et al., 1996; US EPA, 1997b; Crisp et al., 1998; IUPAC, 1998; Olsson et al., 1998; US NRC, 1999). Also, at the request of international bodies, IPCS is preparing a "Global Assessment of the State-of-the-Science of Endocrine Disruptors" (in preparation) and has developed a Global Endocrine Disruptor Research Inventory. The US Environmental Protection Agency (EPA), Organisation for Economic Co-operation and Development (OECD) and a number of countries and industrial associations are implementing activities and collaborating on the development and validation of screening and testing methods to assess chemicals for their ability to disrupt the endocrine system (ECETOC, 1996; Ankley et al., 1998; US EPA, 1998d; OECD, 1999a, 1999b). These tests are referred to only briefly in this document. As described in the Preface, this monograph does not provide practical advice or specific guidance for the conduct of specific tests and studies. These have been developed and issued by international organizations and national governments and vary with the types of chemicals being assessed and according to national regulations and recommendations. For example, the OECD has developed internationally agreed upon test guidelines for the reproductive toxicity testing of pesticides and industrial chemicals. The OECD is an intergovernmental organization of 29 industrialized countries in North America, Europe and the Pacific, as well as the European Commission, which meet to coordinate and harmonize policies and work together to respond to international concerns, including the effects of chemicals on human health and the environment. Test guidelines specifically developed for reproductive toxicity testing in laboratory animals include Test Guideline 414 on prenatal developmental toxicity (OECD, 2001a), which was originally published as a guideline for teratogenicity studies (OECD, 1981a); Test Guideline 415 on one-generation reproductive toxicity (OECD, 1983a); Test Guideline 416 on two-generation reproductive toxicity (OECD, 1983b, 2001b); Test Guideline 421 on reproduction/developmental toxicity screening (OECD, 1995); and Test Guideline 422 on the combined repeated-dose toxicity study with reproduction/developmental toxicity screening (OECD, 1996b). An OECD guidance document on reproductive toxicity testing is also in preparation. Extensive risk assessment guidelines for reproductive toxicity testing have also been published by the US EPA (1996b, 1998b, 1998c) and the European Commission (EC, 1996). For pharmaceuticals and food additives, international bodies and national governments have also developed testing protocols (US FDA, 1982, 1993; IPCS, 1987). The harmonized guidelines for the safety testing of drugs are discussed briefly in chapter 5, since drug regulations are more advanced in their scientific development and reflect basic underlying principles similar to those for testing other types of chemicals (ICH, 1993). The reader should refer to these test guidelines for details and guidance on specific test protocols. The testing of chemicals for reproductive toxicity is a dynamic and evolving process. As the basic sciences of molecular biology, reproductive physiology and endocrinology advance, so do the requirements for safety and risk evaluation. It must be emphasized that the design and interpretation of reproductive tests and the conduct of risk assessment on reproductive toxicity from exposure to environmental chemicals are a highly specialized science. Therefore, it is essential that properly trained professional reproductive toxicologists and epidemiologists conduct and interpret the results of such studies. It is hoped that this monograph will be a useful tool in this process.
3. PHYSIOLOGY OF HUMAN REPRODUCTION 3.1 Introduction Human reproduction is regulated by a set of hormone signals that act in a finely tuned and coordinated manner. These hormones act upon multiple interdependent target cells, directing the development of germ line gametes as well as their transport, release, fertilization, implantation and gestation. This process produces offspring and continues indefinitely, maintaining the evolutionary survival of the species. As indicated in chapter 2, exposures to certain environmental contaminants can adversely influence reproduction and development through a variety of mechanisms. Therefore, it is important to improve our understanding of the impact of such exposures on human reproductive health. This chapter focuses on the endocrine organ communication system and its regulation of human reproduction and development and describes the major endocrine regulating elements and their anatomical and functional characteristics. Other molecular and cellular events and signalling pathways also play a major role, but are not discussed here. The critical developmental stages and the basic physiological processes of reproduction and fetal development are emphasized, with separate discussion of processes and elements important during adulthood and pre- and postnatal development. The principal elements important during adulthood (Figure 1) are gamete production and release, fertilization, zygote transport, growth and development, sexual maturation and reproductive senescence. During pre- and postnatal stages (Figure 1), the elements are implantation, embryogenesis, fetal development, parturition, lactation and postnatal development. The possible influences of environmental contaminants on human reproduction and development are discussed throughout the chapter. 3.2 Reproductive endocrinology 3.2.1 Gonadal function A central concept and mechanism in reproductive and developmental biology is hormonal communication. Small-molecule hormones communicate information from the endocrine glands to the cells of target tissues located throughout the body, thereby regulating fetal and postnatal development as well as production and release of gametes. It is essential for normal reproductive function and fetal development that appropriate hormone signals reach target tissues at the proper time. Hormones convey information to cells that are proximal or distal to the site of synthesis and secretion. When a hormone targets the cell from which it was secreted, it is termed autocrine hormone signalling; if the target is a different cell in the same tissue, it is termed paracrine hormone signalling. Peptide hormones recognize and activate membrane-bound receptors on the surface of the target cell; downstream events can involve one or more signalling cascades (i.e., activation of adenylate cyclase, higher cAMP level, increased enzyme activity). In contrast, steroid hormones are highly lipophilic and can cross cellular membranes into the cytoplasm or nucleus, where they recognize appropriate receptor molecules that can regulate transcription, translation or protein synthesis. The integration and coordination of the effects of peptide and steroid hormones require delicate and precise control. Together, these two types of hormones provide the mechanisms by which the endocrine system regulates complex cellular pathways, such as cell division, differentiation, protein and steroid synthesis and programmed cell death, as well as reproduction and development. Many steps in hormone action can affect reproductive function and fetal development; these steps include hormone production, release, transport, metabolism, receptor binding, postreceptor events and intracellular events such as DNA binding. The complete cellular and molecular details of the mechanisms directing these events are beyond the scope of the discussion in this chapter; however, the interested reader is referred to reports and reviews referenced throughout the text. The hypothalamus, pituitary and gonads (the hypothalamic–pituitary–gonadal, or H-P-G, axis) are the basic endocrine elements that regulate the reproductive system (Figure 2). Although anatomically discrete, these structures are functionally linked to each other. Regulation of the H-P-G axis and communication between its elements depend on hormone levels and sensitive feedback control mechanisms. Peptide and steroid hormones stimulate the gonads, which then produce steroid hormones that act locally on the gonad itself in an autocrine and paracrine manner. These hormones also function in a classical endocrine manner on accessory sex organs, such as the mammary gland and uterus in women and the epididymis and prostate in men. Gonadal hormones also effect negative feedback on the hypothalamus and pituitary and inhibit gene transcription, translation and synthesis of the decapeptide gonadotrophin releasing hormone (GnRH) and pituitary gonadotrophins luteinizing hormone (LH) and follicle stimulating hormone (FSH). In women, estradiol effects positive feedback on the hypothalamus and pituitary at ovulation, which elevates the circulating level of LH. The gonads produce steroid hormones, including progestins, androgens and estrogens. These steroid hormones play a significant role in regulating reproductive processes, including sexual development, production and release of gametes, fertilization, pregnancy, fetal development, parturition, the development of secondary sexual characteristics and lactation. Most of the enzymes that synthesize gonadal steroids are members of the cytochrome P-450 superfamily of oxidases and are located in the smooth endoplasmic reticulum of steroidogenic cells. However, conversion of cholesterol to pregnenolone by cytochrome P-450 side-chain cleavage occurs in mitochondria. Steroidogenesis follows two different pathways (Figure 3); the choice between the Delta4 or the Delta5 pathway depends on the availability of substrate and enzymes, as well as the tissue and the species. For example, unlike the gonads, the placenta is unable to convert cholesterol to progestins because it lacks the required enzymes. Also, the Delta4 pathway dominates in the testis in the rat, whereas the Delta5 pathway is the major route of testosterone synthesis in the rabbit. These differences must be considered when using animal models to predict effects in humans. The gonads also contain enzymes that carry out biotransformation and detoxification to protect the gonads from damage due to oxidative stress or exogenous chemicals. Cytochrome P-450 enzymes carry out phase I biotransformation reactions, producing water-soluble products that readily undergo phase II biotransformation reactions (Sipes & Gandolfi, 1991). Enzymes that protect the gonads from such damage (phase II detoxification enzymes) include glutathione peroxidase, glutathione reductase, superoxide dismutase and catalase. In animal experiments, these defence mechanisms can be overwhelmed by treatment with chemicals such as polychlorinated biphenyls (PCBs), 7,12-dimethylbenz[a]anthracene or hexachlorobenzene (HCB). In some cases, the effects of these chemicals include structural alteration of mitochondria of ovarian granulosa cells, uncoupling of oxidative phosphorylation and altered steroidogenesis. These experiments and other data suggest that environmental contaminants can reduce circulating steroid levels by decreasing the level of pituitary gonadotrophins (Müller et al., 1978; Foster, 1992; Jansen et al., 1993). In addition, direct effects on steroidogenic enzyme activity have been observed (Drew & Miners, 1984; Evenson & Jost, 1993). 3.2.2 Basic elements underlying normal development Embryonic development is arguably the most complicated of biological processes. It involves the formation of a new individual from a single cell, the fertilized zygote. A high rate of cell division is the most obvious of the events that must take place in order for development to occur, but it is far from the only one. Formation of the embryo from the mass of cells accumulating from repeated cell division involves the establishment of three germ layers of body axes (anterior–posterior, ventral–dorsal, left–right), the partitioning of groups of cells into organ primordia and the development of those primordia into discrete structures. A number of cellular and molecular mechanisms underlie these processes. These include intercellular communication, governed by paracrine and endocrine factors (hormones and growth factors); cell surface and extracellular matrix proteins that control migration and mutual induction between discrete groups of cells; selective expression and suppression of genes, leading to differentiation of cells; and a balance of cell proliferation and programmed cell death (apoptosis) to provide an ample number of cells for organ development and to establish form. While these events are going on, the embryo is also undergoing marked changes in intermediary metabolism, progressing from mostly glycolytic to mostly oxidative as the placenta and embryonic circulatory system become functional, and xenobiotic metabolism. All of these processes are essential for normal development, and any may be a target for exogenous insult that may lead to abnormal development. The literature on these processes and their role in normal and abnormal development is too large to review here, but is important for understanding normal and abnormal development. The reader is directed to a recent compendium on mechanisms of abnormal development (Kavlock & Daston, 1997). 3.3 Female reproductive physiology 3.3.1 Ovarian development and oogenesis The principal functions of the ovary are to produce ova, gonadal steroids (estrogens and progestin) and other hormones, such as inhibin and activin. Numerous other factors, such as cytokines, prostaglandins and growth factors, are also produced by the ovary to regulate follicular development (folliculogenesis), ovulation or luteal function in an autocrine or paracrine fashion. Cyclical ovarian function also regulates the menstrual cycle in women and the estrous cycle in female rats. The endocrine regulation of ovarian function, menstrual cycle and follicular development has been reviewed previously (Erickson, 1978; Goebelsmann, 1986; Ferin, 1996). Oogenesis is the process of ovum formation and maturation. During oogenesis, primordial germ cells are formed, which become oogonia and subsequently oocytes in the fetus. In the adult, oocytes mature into ova, which contain the nutrients that support the early embryo’s energy requirements (Wasserman, 1996; Wasserman & Albertini, 1996). In the female fetus, primordial germ cells are formed from stem cells in the yolk sac endoderm, and these cells are the sole source of germ cells in the adult. The primordial germ cells migrate to the genital ridges and subsequently into the cortex of the developing ovary, where, together with the superficial epithelium, they give rise to the cortical sex cords of the ovary. Once the developing ovary forms, the primordial germ cells are converted to oogonia, which divide mitotically until approximately 6–7 million oogonia are formed at approximately 20 weeks of gestation. At this time, the oogonia enter meiosis, and the number of oocytes is fixed (Baker, 1963). Oogonia are transformed into oocytes when the last mitotic division occurs in preparation for meiosis. Once oocytes enter the diplotene phase of meiosis, they become arrested, also called the dictyate stage, and remain in that stage until meiosis resumes at ovulation. The oocytes remain arrested in meiosis I until the preovulatory surge of LH (Baker, 1982). From the 20th week of gestation until puberty, the ovary is composed primarily of primordial follicles, each of which possesses an oocyte arrested in the first meiotic cell division surrounded by a single flattened layer of granulosa cells. A number of these follicles begin to develop spontaneously, becoming a primary follicle; in the absence of gonadotrophin, however, they undergo apoptosis. The number of primordial follicles continues to decline due to apoptosis from the 20th week of gestation until reproductive senescence or menopause. At the time of menarche or puberty, there may be only 300 000 – 400 000 oocytes in the ovaries. With the onset of puberty, a second layer begins to form from cuboidal granulosa cells; these cells arise from a small number of growing follicles that have an enlarged ooplasm and a zona pellucida. 3.3.2 Functional morphology of the ovary The ovary is the source of the female gametes and the reproductive hormones that regulate the female reproductive cycle. The adult ovary is made up of the cortex (containing ovarian follicles), the medulla and the hilum (the ovarian attachment area). The medulla consists of the ovarian stroma, which are mainly connective tissue, and the sex steroid-producing interstitial cells. A follicle progresses from an inactive primordial follicle to a preovulatory Graafian follicle in approximately 2 months. Only the last 2–3 weeks of this maturation process is responsive to and controlled by the pituitary gonadotrophins LH and FSH. Throughout the female reproductive life, maturing follicles undergo atresia at different stages. Structurally, the ovary is composed of germinal epithelium, ovarian follicles in different stages of development and stromal tissue. The functional unit of the ovary is the follicle, which is a single oocyte surrounded by granulosa cells, a basement membrane and a thin layer of thecal cells. During folliculogenesis, granulosa cells proliferate, an antrum develops containing granulosa cell secretions and the follicle enlarges. Following ovulation, the corpus luteum forms, which either persists during pregnancy or regresses to form a corpus albicans in the absence of fertilization. 3.3.2.1 Folliculogenesis As mentioned above, oocytes are arrested in the diplotene phase of the first meiotic division before sexual maturity is reached. Follicles begin maturing in the presence of low circulating levels of estradiol (Erickson, 1978; Goebelsmann, 1986), but gonadotrophin is not required. As a population of follicles begins to grow, a single follicle is selected to become the dominant follicle for ovulation. The oocyte enlarges and the granulosa cells become cuboidal and thicken to three or more layers. This is now called a secondary follicle. While the oocyte remains constant in size, the granulosa cells undergo rapid division, and a fluid-filled antrum forms. Such a Graafian or antral follicle is 5–6 times larger than the secondary follicle. The innermost layer of granulosa cells surrounding the oocyte (the corona radiata) becomes columnar, and these cells form specialized gap junctions with the oocyte plasma membrane that are important in regulation of oocyte development. The oocyte secretes a layer of glycoproteins to form the zona pellucida, which separates the oocyte from the surrounding corona radiata. The layer of cells and connective tissue that envelops and delineates the follicle from the surrounding ovarian stroma is the theca. The dominant follicle grows at a faster rate and produces a higher level of estradiol than the remainder of the growing pool of follicles. Serum FSH induces expression of LH receptors on the surface of thecal cells, which then produce pregnenolone, progesterone and, subsequently, androstenedione. Androstenedione is transported into granulosa cells, where it is converted first to testosterone by 17-hydroxysteroid dehydrogenase and then to estradiol via an irreversible reaction catalysed by the enzyme P-450 aromatase (Figure 4). While the remaining developing follicles become apoptotic, the granulosa cells of the dominant follicle continue to divide, eventually producing an antrum within the follicle. The rising level of estradiol that results from folliculogenesis leads to a mid-cycle surge in LH, which induces the dominant follicle to ovulate. In preparation for fertilization, meiosis is resumed, forming one daughter cell and one small polar body. The daughter cell enters the second meiotic division and arrests in the second metaphase until fertilization. The follicle becomes highly vascularized, the follicular wall forms a protrusion (macula pellucida) where rupture occurs and the oocyte and its surrounding granulosa cells are released. At ovulation, the oocyte is extruded onto the ovarian surface, where the cumulus mass can be retrieved by the fimbriated end of the fallopian tube. Once the oocyte has been extruded at ovulation, the nucleus progresses from the dictyate stage of the first meiotic division (2N) to metaphase II (1N), where it remains until fertilized. After ovulation, the walls of the follicular cavity in the ovary develop into the corpus luteum, which persists if fertilization occurs or disintegrates if fertilization does not occur. In addition to triggering ovulation, the mid-cycle surge in LH induces luteinization of the thecal and granulosa cells of the follicle wall. Normal luteal function depends upon both normal folliculogenesis and successful follicular rupture. Vascularization of the follicle wall with ovulation makes it possible for the luteinized thecal and granulosa cells to access low-density lipoprotein (LDL) cholesterol circulating in the blood; cholesterol is required for synthesis of progesterone. Inhibin is produced by granulosa cells and exerts negative feedback on the serum FSH level in the female. Inhibin is composed of a single a chain and two distinct b chains designated as bA and bB. Dimers containing bA or bB are called inhibin A and inhibin B, respectively. During the first half of the menstrual cycle, inhibin B is the dominant form in the serum; during the second half of the cycle, inhibin A is the dominant form. Thus, the appearance of inhibin A correlates well with the decline in the circulating level of FSH in the luteal phase of the cycle. The hormone activin is also produced by granulosa cells in the female and stimulates FSH, although autocrine action of the pituitary-derived activin may be more important. Activins are composed of two different subunits that form homodimers AA and BB or a heterodimer AB. These three forms are called activin A, activin B and activin AB, respectively. Like the inhibins, activins are widely produced in different tissues. Throughout postpubertal life, cohorts of follicles are recruited. Some of these mature to become Graafian follicles and ovulate; however, most follicles undergo atresia. Although approximately 1 million follicles are present in the ovaries at birth, essentially all are depleted by about the age of 50 years, resulting in menopause. Toxicants can have many adverse effects on ovarian function, including a decrease in the number of primordial follicles, death of follicles, disrupted steroidogenesis or delayed ovulation (see chapter 4). The mechanisms of action of ovarian toxicants are not well defined but may include hormone mimicry or increase in oxygen free radicals and uncoupling of oxidative phosphorylation (Foster et al., 1995). 3.3.2.2 Intraovarian signalling The principal extraovarian regulators of intraovarian processes are the pituitary gonadotrophins LH and FSH. Within the ovary, androgens, estrogens and progestins are important in situ regulators. Receptors for all three gonadal steroids are present in the ovary, suggesting that intraovarian signalling occurs via classical steroid hormone–receptor mechanisms. Androgens exert actions on the granulosa cells, are used to produce estrogen, induce aromatase activity and promote progestin synthesis (Armstrong & Dorrington, 1976; Lucky et al., 1977). Androgens also promote follicular atresia in the absence of gonadotrophins and generally oppose estrogen action. The thecal cells and the interstitial cells of the ovarian stroma produce androgens under the influence of LH. Circulating LDL cholesterol is converted to pregnenolone, then to progesterone. The 17alpha-hydroxylase/17,20-desmolase activity in the thecal/interstitial cells is responsible for converting pregnenolone and progesterone to dehydroepiandrosterone (DHEA) and androstenedione. The androgen produced is mainly androstenedione, which can go directly into the circulation, be converted to testosterone or be aromatized to estrogens in the granulosa cells by FSH-induced aromatase activity. This compartmentalized production of steroids (androgen substrate in thecal cells, estrogens in granulosa cells) should be kept in mind when considering results from in vitro cultures of granulosa or thecal cells. These cells have distinct gonadotrophin receptors (LH receptors in thecal cells; FSH receptors in granulosa cells) and enzyme activities, all of which are needed for estrogen production. In vivo, these cells function cooperatively. Estrogens promote cellular division in the granulosa cells, prevent follicular atresia, enhance antrum formation and inhibit ovarian androgen production. Because regulation of all ovarian processes cannot be explained adequately by gonadal steroids alone, it is likely that other intraovarian regulators exist. Such putative intraovarian regulators have to meet the following criteria: 1) be produced in the ovary; 2) have a receptor in the ovary; and 3) have a biological effect on the ovary. By these criteria, insulin-like growth factor-1 (IGF-1) is an intraovarian regulator. The ovary produces IGF-1, its receptor is found in the ovary and IGF-1 influences steroidogenesis in both granulosa and thecal cells (Adashi et al., 1989; Guthrie et al., 1995). Other putative intraovarian regulators are epidermal growth factor (EGF) and transforming growth factor-alpha (TGF-alpha), which share the same receptor and may have autocrine and paracrine activities in the ovary. One of the primary actions of FSH is to increase the expression of LH/human chorionic gonadotrophin (hCG) receptors, and this effect is inhibited by EGF (May & Schomberg, 1989). EGF also has mitogenic effects on granulosa cells and may be an important signal for granulosa cell proliferation. TGF-alpha is thought to act similarly to EGF. Another putative intraovarian regulator is transforming growth factor-beta 1 (TFG-beta 1), which increases steroidogenesis in granulosa cells (Knecht et al., 1989) and decreases steroidogenesis in thecal (Knecht et al., 1989) and Leydig cells (Lin et al., 1987). Acidic and basic fibroblast growth factor (bFGF) are related and act through the same receptor. bFGF may act during early embryogenesis to promote differentiation of ectoderm to mesoderm. bFGF may also promote development of follicles in preparation for ovulation before gonadotrophin dependence develops (Gospodarowicz, 1989). It also may mediate angiogenesis in follicular development (Koos, 1989). Other possible ovarian regulators include tumour necrosis factor-alpha, catecholaminergic input, luteinization inhibitor, gonadotrophin-binding inhibitors, oocyte maturation inhibitor and the ovarian renin–angiotensin system. Ovarian renin–angiotensin has been detected in follicular fluid (Lightman et al., 1989). Receptor sites for angiotensin II, the main active peptide of the renin–angiotensin system, have been found in the ovaries (Lightman et al., 1989). Ovarian renin–angiotensin may also have an autocrine role in angiogenesis, steroidogenesis and oocyte maturation. Inhibin is produced by the ovarian follicle and corpus luteum (Tsonis et al., 1987) and appears to have some autocrine action on thecal and granulosa cells involving steroidogenesis (Burger & Findlay, 1989). Evidence is growing that multiple other substances — i.e., vascular endothelial growth factor (VEGF) and growth differentiation factors (GDF) 9 and 9B — also influence intraovarian functions. Two other putative intraovarian regulators are Müllerian inhibiting substance (MIS) and oocyte maturation inhibitor. MIS is produced by the Sertoli cells of the fetal testis; its function is to regress the Müllerian duct in the male fetus. Thus, it is the first hormonal determinant of male gonadal differentiation. Granulosa cells also produce MIS; however, by the time the primordial germ cells are primary follicles in the female fetus, the Müllerian duct becomes resistant to MIS. Although not well characterized, oocyte maturation inhibitor may arrest oocytes in the dictyate stage in the first meiotic division and in metaphase in the second meiotic division (Tsafriri & Adashi, 1994). 3.3.3 Neuroendocrine regulation of ovarian function and reproductive cycling 3.3.3.1 Hypothalamus Beginning in fetal life, the release of GnRH from the hypothalamus stimulates production of LH and FSH by the pituitary. The mean peak plasma levels of LH and FSH during gestation are higher in the female than in the male fetus. The pulsatile release of LH and FSH is controlled by neurons in the arcuate nucleus of the hypothalamus, which secrete GnRH into the hypothalamic–hypophyseal portal system. Dopamine and serotonin are among the hypothalamic neurotransmitters important in this process. Estradiol provides both positive and negative feedback to control GnRH release. The peptidergic neurons in the hypothalamus produce GnRH, which is released in a pulsatile fashion (Knobil, 1980) into the hypothalamic–hypophyseal portal circulation and transported to the anterior pituitary, where it binds to high-affinity receptors on the surface of pituitary gonadotrophs. Change in the pulse frequency of GnRH is the mechanism by which GnRH regulates the synthesis and secretion of both LH and FSH. Both LH and FSH are secreted in a pulsatile fashion in response to GnRH and are released into the cavernous sinuses that surround the pituitary and drain into the general circulation for transport to the gonads. GnRH-containing neurons receive a variety of neural inputs that regulate GnRH release. Opioids, dopamine and serotonin decrease the pulse frequency of GnRH; in contrast, norepinephrine and, to a lesser extent, epinephrine increase GnRH pulse frequency. Disruption of the pulse generator system by factors that result in continuous GnRH release or repress secretion decrease pituitary gonadotrophin secretion and thus suppress gonadal function. 3.3.3.2 Pituitary The pituitary gland is composed of anterior and posterior lobes that are attached to the hypothalamus via the infundibulum or hypophyseal stalk, which includes the portal vessels. Processes from GnRH cells in the hypothalamus terminate on or in the vicinity of the portal vessels that convey blood to the anterior lobe of the pituitary. The anterior lobe of the pituitary is highly vascular and contains sinusoids, which are irregularly anastamosing terminal blood vessels consisting of a single layer of endothelial cells and a basement membrane. Primarily acidophilic, chromophobic and basophilic cells line the sinusoids. It is the latter cell type, the gonadotrophs, that are responsible for producing LH and FSH in response to stimulation by GnRH. These glycoprotein hormones are composed of two polypeptide chains designated alpha and beta. The alpha chain is common to both LH and FSH, whereas the beta chain differs and confers immunological and hormonal specificity. Experiments carried out with animal model systems indicate that environmental contaminants can alter pituitary function and the level of GnRH. For example, perfusion of pituitary glands in vitro with PCBs can influence synthesis and secretion of gonadotrophins (Jansen et al., 1993). 3.3.3.3 Patterns of ovarian response The balanced secretion of FSH and LH controls follicular growth, ovulation and maintenance of pregnancy. Both hormones interact with cell surface receptors on their target cells in the ovary. In addition, FSH stimulates aromatization of theca-derived androgens to estrogens by granulosa cells (Gore-Langton & Armstrong, 1994). The main endocrine action of FSH is to stimulate granulosa cells to produce progesterone. LH stimulation induces follicular thecal cells and stromal interstitial cells to produce androgens. LH is secreted at a basal level in prepubertal females with irregular pulsatile occurrences. In human cycling females, the ovarian hormonal profile is linked to the menstrual cycle, which is controlled by LH and FSH levels. There is an LH surge before ovulation that is temporally linked to the preceding rise of estradiol. After ovulation, the levels of progesterone and, to a lesser extent, estrogen accelerate until luteolysis, when progesterone and estrogen levels return to basal values (Greenwald, 1987). 3.3.4 Effects of hormones on reproductive tract and breast During pregnancy, progesterone, estrogen and prolactin stimulate proliferation of alveolar cells. Pulsatile secretion of gonadotrophins starts at puberty, and the subsequent increase in estrogen level stimulates growth of the rudimentary mammary gland. When progesterone is produced as part of an ovulatory cycle, it stimulates the alveolar buds within the mammary lobules. After puberty, the changing estrogen and progesterone levels in the cycling female affect breast tissue development, with maximal activity in the luteal phase. Since the levels of estrogen and progesterone in the cycling female are under the influence of the hypothalamo–pituitary axis, the neuroendocrine system indirectly influences breast development. The signal for the breast to start producing milk after delivery is probably the rapid decline in serum concentration of progesterone and estrogen that occurs after delivery. Growth hormone, adrenocorticotrophin hormone (ACTH) and thyroxine are involved in maintaining lactation, and the hypothalamus regulates their production by the pituitary and thyroid gland, respectively. 3.4 Male reproductive physiology 3.4.1 Testes The principal roles of the male gonads are to produce gonadal steroids and spermatozoa to fertilize the ovum. The gonadal steroid testosterone acts in a paracrine manner to stimulate spermatogenesis in the testis. From the early teen years until puberty in the male, the circulating level of gonadotrophin increases at night and induces the production of testosterone. In target tissues, testosterone is converted to dihydrotestosterone (DHT), which is a more potent androgen than testosterone and stimulates development of secondary sexual characteristics. Male accessory sex organs such as the prostate are incapable of synthesizing testosterone themselves. The testes are composed of the interstitium and the seminiferous tubule, which are histologically distinct compartments. The interstitium is composed of nests of Leydig cells, which surround the seminiferous tubule and produce testosterone. The seminiferous tubule is the site of spermatogenesis and constitutes approximately 90% of the testis volume. The seminiferous tubule contains male germ cells in different stages of development and Sertoli (nurse) cells. Columnar Sertoli cells extend from the basement membrane to the lumen of the tubule. These cells form tight junctions in the basal region of the cells and thus form the anatomical basis for the blood–testis barrier, which divides the tubule into basal and adluminal compartments. Spermatogonia are located in the basal compartment, and the developing spermatocytes and maturing spermatids are located in the adluminal compartment. The blood–testis barrier is an important structural element of the testis because it prevents large molecules, ions and steroid hormones from passing from the basal region into the adluminal compartment. The Sertoli cells are key structural elements in the seminiferous tubule and play a central role in spermatogenesis; they provide nutrients to the developing germ cells, translocate them to the lumen of the tubule and eliminate degenerating germ cells and their products. FSH plays a key role in spermatogenesis; it binds G-protein-coupled membrane-bound receptors on Sertoli cells and induces the Sertoli cells to proliferate during pre- and postnatal development. FSH also induces Sertoli cells to produce androgen binding protein (ABP), TGF-beta 1, MIS and other important signalling compounds. Sertoli cells also play an important role in spermiation and are the source of the seminiferous tubule fluid that provides nutrients to sperm cells as they travel from the testis to the epididymis. 3.4.2 Spermatogenesis Spermatogenesis is the process by which precursor cells form mature haploid spermatozoa within the seminiferous tubule. Spermatogonia multiply mitotically, but remain quiescent during most of the prepubertal period. After puberty, approximately 3 million spermatogonia begin to develop into spermatozoa each day (Johnson et al., 1983), and daily sperm production (DSP) is approximately 100 million. Spermatogenesis, which takes approximately 70 days and comprises the phases of spermatogonial proliferation, meiotic divisions of the spermatocytes and differentiation of spermatids (spermiogenesis) and spermatogenesis, has been reviewed previously (Sharpe, 1994; Matsumoto, 1996). During the proliferative phase of spermatogenesis, the spermatogonia that lie above the basement membrane but beneath the tight junctions at the basal region of Sertoli cells undergo a series of mitotic divisions. This renews the stem cell population and creates a group of germ cells that are committed to further cell division and differentiation. In humans, there are only two type A spermatogonia (dark and pale) and one generation of type B spermatogonia; in rodents, there are several generations of type A spermatogonia plus intermediate and type B spermatogonia. Spermatogonia divide mitotically. After division of type B spermatogonia, preleptotent spermatocytes emerge. These cells undergo DNA replication and the first prophase of meiosis, which take more than 3 weeks in humans. After the first meiotic division, the second division rapidly follows without another S-phase, generating haploid germ cells called spermatids. Round spermatids undergo a complex morphogenetic process (spermiogenesis), including nuclear elongation and condensation, acrosome formation and flagellar development. This process ends up with release of mature spermatids to seminiferous tubular lumen (spermiation). After spermiation, the germ cells, which are now called spermatozoa, pass into the rete testis and further to the seminal pathway (Bustos-Obregõn et al., 1975). During spermiogenesis, the third and last phase of spermatogenesis, spermatids become mature spermatozoa. The spermatids lose all excess cytoplasm, the nucleus loses fluid, the tail forms, the acrosome develops and the chromosomes condense. The nucleus moves to an eccentric position, and an acrosomal cap separates it from the cranial pole of the spermatozoa. The acrosome is closely attached to the spermatic cell membrane. The flagellum forms from centrioles at the caudal pole of the nucleus. The flagellum is divided into a middle, principal and end section. Mitochondria aggregate and form a spiral sheath around the middle of the flagellum. After the flagellum develops, the cytoplasm and its organelles reorganize, and the nucleus becomes condensed. Spermatids appear at the luminal surface of the seminiferous tubule and are released by a process called spermiation. The spermatozoa, which are still immature, are transported via the rete testis to the epididymis. On passage through the epididymis, the spermatozoa continue to mature. The mature spermatozoan is motile and can undergo the acrosome reaction. Factors that alter the level of testosterone, by decreasing synthesis, increasing metabolic clearance or blocking the androgen receptor, can adversely affect the amount or quality of semen. It has been reported that exposure to environmental chemicals may lead to reduced semen quality (see chapter 4). As discussed above, Sertoli cells play a central role in spermatogenesis. These cells also produce the regulatory molecules inhibin and activin, which are members of the TGF superfamily (see review by Vale et al., 1994). In males, activin and inhibin B coordinately regulate the level of serum FSH. Inhibin is a peptide hormone produced in response to FSH that exerts negative feedback on the pituitary gland to reduce serum FSH. Inhibin B is produced to a small extent in other tissues, but the level of inhibin B and the inhibin/FSH ratio can be useful indicators of Sertoli cell function. Activins are similar to inhibin, but they stimulate release of FSH from the pituitary. However, activin produced locally in the pituitary gland is more important in stimulating FSH secretion than activin secreted by the testes. 3.4.3 Intratesticular signalling The main autocrine hormones in the testes are androgens, the most important of which is testosterone. As mentioned above, testosterone is converted to the more potent DHT in peripheral tissues. Testicular androgens produced by Leydig cells act locally to control spermatogenesis. Leydig cells store cholesterol in lipid droplets in their cytoplasm and use the cholesterol to form androgens. Estrogens are also produced by Leydig cells and are able to inhibit spermatogenesis. In adult male rats, administration of estrogens suppresses spermatogenesis (Handelsman et al., 2000). This may result from estrogen-mediated suppression of LH, which decreases secretion of testosterone by Leydig cells, or it may indicate an intratesticular role for estradiol. It is likely that many of the factors involved in intraovarian signalling are involved in intratesticular signalling; for example, IGF-1 may regulate spermatogenesis (Antich et al., 1995). In the young rat, Sertoli cells can also convert androgens to estrogens (Sharpe et al., 1995). Since FSH and LH are involved in spermatogenesis, hypothalamic control of their release by the pituitary is important for testicular function. Both FSH and LH are secreted in a pulsatile fashion from the pituitary. Inhibin B produced by Sertoli cells has the most important negative feedback effect on FSH secretion, while testosterone exerts negative feedback effects on secretion of GnRH by the hypothalamus, thus regulating secretion of LH and, to a lesser extent, FSH. 3.5 Mating behaviour In human males and females, androgen increases libido. Women treated with androgens frequently experience increased libido, whereas women treated with antiandrogens experience reduced libido. Sexual activity may occur when testosterone levels are relatively low, although an interval of testosterone priming may be necessary. In all male primates, androgens increase sexual drive. When exposed to receptive females, male macaques increase their production of testosterone; in contrast, social subordination, and the stress associated with it, can reduce testosterone production (Rose et al., 1978). Stress reduces plasma testosterone in males and females via the hypothalamic–gonadal axis and also reduces, or even eliminates, mating behaviour. Environmental exposures can influence reproductive function and mating behaviour. In some cases, these effects are mediated through visual or olfactory cues. For example, circadian rhythms influence the timing of the periovulatory surge of LH and the rate of ovulation. The LH surge tends to occur at night and in the morning (Seibel et al., 1982; Testart et al., 1982). The best evidence of seasonal variation in human reproduction is from studies in Alaskan Inuit, which show that seasonal changes in birth rates correspond to peaks in June and January (Ehrenkranz, 1983). Humans do not reproduce in a rigidly seasonal manner, possibly because they are less sensitive than other species to environmental cues or because they live in civilized or urbanized environments in which the impacts of environmental influences are attenuated (Van Vugt, 1990). Macaques breed seasonally in temperate environments but ovulate year-round when environmental conditions are maintained in a non-seasonal manner (Vandenbergh & Vessey, 1968; Van Vugt, 1990). However, macaques that are reared indoors and exposed to varying photoperiods still ovulate year-round. This suggests that humans no longer mate in a seasonal manner that reflects annual variation in photoperiods because of ontogenic and possibly evolutionary experience. Hormonal control of mating behaviour is well documented in animals. In rats, estrogen and, to a lesser extent, progesterone control lordosis behaviour via the central nervous system (CNS). In female non-human primates, attractiveness and proceptivity change during the menstrual cycle or as a result of sex steroid administration. The effects of hormones on receptivity are unclear. It is assumed that steroid hormones influence behaviour in humans as they do in animals; however, it is difficult to differentiate the effects of social and other environmental factors from the effects of sex steroids on mating behaviour in humans. Male mating behaviour has been studied predominantly in rodents as well as in other mammalian species. The male mating repertoire involves precopulatory behaviour, mounting, intromission, ejaculation and postejaculatory behaviour. The preoptic anterior hypothalamic area controls important aspects of male mating behaviour. Rhesus monkeys with bilateral lesions in this area do not attempt to copulate but can masturbate and achieve erections, indicating a deficit in mating behaviour towards the female, but no obvious neuroendocrine physiological compromise (Eisenberg, 1981). 3.6 Gamete transport In most mammals, spermatozoa become motile while in the proximal cauda epididymis. The epididymis is also a reservoir for sperm. In addition, maturation of the spermatic plasma membrane in the epididymis involves physical and chemical alterations in the membrane lipids. Seminal and prostatic fluids are added to the semen during its passage through the male reproductive tract. Human semen is deposited in the anterior vagina during coitus. There are usually between 20 and 120 million sperm per millilitre in human ejaculate (WHO, 1999). For fertilization to occur, sperm deposited in the vagina must travel to the fallopian tubes, and the ovum must be released from the ovary and transported within the fallopian tubes. Vaginal mucus protects the spermatozoa in the acidic vaginal environment from being ingested by macrophages. Spermatic movement through the cervix may continue for days, and most spermatozoa die during this manoeuvre. Prostaglandins in the semen stimulate uterine contractions that facilitate movement of spermatozoa through the uterus. Only a small proportion of deposited spermatozoa reach the site of fertilization in the mid-fallopian tube. Before ovulation, the vaginal mucus is thin and watery, allowing spermatozoa to pass more readily than the thicker mucus that forms after ovulation. Spermatozoan motility is necessary for movement up the female reproductive tract to the oviduct. Immotile spermatozoa are an easily detected cause of infertility in males. Another common cause of male infertility is spermatozoa that cannot penetrate the cervical mucus; this problem can be assessed to some extent in vitro (Eggert-Kruse et al., 1989). Capacitation is the physiological change that makes spermatozoa capable of fertilization. While the sperm are in the male reproductive tract, capacitation is blocked by a decapacitation factor, but this factor is no longer active on sperm that have been deposited in the female reproductive tract. After capacitation, spermatozoa can demonstrate hyperactivated motility, undergo the acrosome reaction and bind with the zona pellucida of an unfertilized egg (Yanagimachi, 1970). Capacitation begins when spermatozoa are in the cervical mucus and continues until sequestration in the isthmus. Capacitation involves changes in intracellular ion concentrations (e.g., K+, Na+ and Ca2+), increased metabolism, stabilization of disulfide bonds in nuclear proteins and removal of decapacitation factors from the plasma membrane. At ovulation, the ovum, surrounded by the cumulus oophorus, is released from the ovary and moves down the fallopian tubes. As described above, ovulation follows a surge in LH, which causes luteinization of the granulosa cells of the follicle destined for ovulation. During ovulation, the oocyte enters the tubal lumen and is eventually moved to the site of fertilization. Since mating can occur at any time in the cycle in humans, the spermatozoa may be at the fallopian tubes at the time of ovulation, or the ovum may be at the fallopian tubes awaiting the arrival of the spermatozoa. After fertilization, in the isthmus of the fallopian tubes, the zygote moves to the uterus for implantation. Prostaglandins, catecholamines, estrogen and progesterone stimulate contractions of the smooth muscle in the walls of the fallopian tubes, which move the zygote to the uterus. 3.7 Fertilization Fertilization is the fusion of the sperm and ovum. The sperm head binds to the plasma membrane of the egg (oolemma), and the entire spermatozoon enters the cytoplasm of the ovum. Only capacitated spermatozoa with intact acrosomes can enter and pass through the cumulus oophorus. The acrosome is a membrane-bound, cap-like structure covering the anterior portion of the sperm nucleus. The acrosomal reaction is the release of materials that lyse the glycoprotein coat (zona pellucida) surrounding the ovum. This is necessary for fertilization to take place. Before undergoing the acrosomal reaction, sperm go through a type of hypermotility called hyperactivation. The hypermotility involves vigorous, whiplash beating of the tail and linear dashing movements. Hyperactivity appears to begin in the isthmus of the fallopian tubes and is thought to facilitate movement in the fluid of the oviduct (fallopian tubes) and to provide the power necessary to penetrate the cumulus oophorus and zona pellucida. The acrosome reaction is the loss of the acrosomal and plasma membranes in the acrosome region and the release of acrosin, hyaluronidase and other enzymes that disperse the cumulus complex and allow the sperm to penetrate the zona pellucida. After capacitation and the acrosome reaction, sperm penetrate the extracellular cumulus matrix and bind with zona protein 3, a heavily glycosylated protein of the zona pellucida. The first segment of the sperm to make contact with the oolemma is usually the inner acrosomal membrane, followed by the postacrosomal region. The plasma membrane of the sperm attaches to microvilli on the oolemma. Sperm–egg fusion is apparent from reduced movement of the sperm tail (Yanagimachi, 1970, 1988; Takano et al., 1993). Once a sperm fuses with the egg membrane, the zona pellucida undergoes structural changes that form a physical barrier preventing additional sperm from entering the egg. After fusion with the sperm, the egg resumes meiosis, the second polar body is extruded and the male and female pronuclei fuse. Once the pronuclear envelopes of the sperm and egg have fused, the chromatin condenses, and the first mitotic division begins with the first cleavage. This first cleavage is the beginning of blastogenesis. 3.8 In utero development 3.8.1 Blastogenesis Preimplantation development commences with a single cell and concludes with implantation of a late blastocyst. Preimplantation development has been well characterized and described in detail (Moore, 1988). The single-cell zygote progresses through two-, four- and eight-cell stages, during which the blastomeres are loosely attached to each other. Late in the eight-cell stage, the blastomeres become compact, and tight junctions form. The next cell division forms the 16-cell morula, characterized by inner cells that are surrounded by other blastomeres. By the 64-cell stage, the inner cells form the inner cell mass (ICM). The ICM forms the fetus, and the trophectoderm forms a connection with the uterus. Secretions from trophoblast cells form a blastocoele, and the ICM becomes located at one end of the cavity; the overlying cells are termed polar trophectoderm, and the rest are termed mural trophectoderm. All cell divisions up to this point are cleavage or reductive in nature. Because of this fact, the size of the embryo does not increase up to this point. In mammalian species, these cleavage events occur in the fallopian tube as the embryo is transported to the uterus, which takes approximately 7 days in humans and variable amounts of time in other mammals. By the 8th day after fertilization, the trophectodermal cells are organized into two layers, an inner layer of mononucleated cells (cytotrophoblast) and an outer layer of larger, multinucleated cells that form the implantation syncytium (syncytiotrophoblast). The inner, mononucleated cells continue to form giant cells that are pushed progressively to the outer layers. The cells that make up the inner layer form the embryo, aggregate at one pole of the blastocyst and divide to form the bilaminar germ disc, with a layer of small cuboidal cells (hypoblasts) and a layer of high columnar cells (epiblasts). 3.8.2 Implantation When the embryo arrives in the uterine cavity, the trophectoderm infiltrates the uterine epithelium by a poorly characterized mechanism. Several maternal and embryonic factors are crucial to implantation. These factors include colony stimulating factor, leukaemia inhibitory factor, interleukin-6 and several proteolytic enzymes. Before the placenta develops, the implanted embryo is nourished by histotrophic material from degradation of endometrial cells during implantation. The embryo is also nourished by secretions from endometrial glands and by the yolk sac; the latter persists for different time periods and plays different roles in different species. The blastocyst implants into the maternal endometrial wall on about the 7th day of embryonic life. Trophoblastic cells attach to the uterine mucosa by apposition and adhesion. Under the influence of progesterone and estrogen, the uterine lumen closes, which brings the blastocyst into close contact with the endometrium. Adhesion of the trophoblast to the uterine epithelium occurs with increasing apposition and involves cell surface glycoproteins. The uterine epithelium is penetrated by syncytial growths on the trophoblast into the adjacent uterine epithelial cells. Subsequently, the trophoblastic membranes share junctional complexes and desmosomes with the uterine epithelial cells. The syncytial trophoblastic processes penetrate the basal lamina of endometrial blood vessels. Decidualization of the endometrium occurs as a response to implantation. The decidualized endometrium is thickened due to proliferation of endometrial stromal cells, infiltration of inflammatory cells, increased vascular permeability, engorgement of blood vessels and oedema. Sustained exposure of the endometrium to both progesterone and estrogen is necessary for decidualization. Antiprogestins or high doses of estrogen disturb the estrogen/progesterone balance and inhibit decidualization and implantation. 3.8.3 Placentation The placenta is a temporary organ that forms from the trophectoderm of the embryo and maternal cells. The fetal portion of the placenta develops from the chorionic sac, while the maternal portion arises from the endometrium. The placenta carries out a number of important functions, which include anchoring the developing fetus to the uterine wall, providing nutrients for the fetus and removing waste products. In addition, hormones are synthesized in the placenta, which maintain pregnancy and promote development of the fetus. Apart from its role in maternal–fetal interchange, the placenta is involved in metabolism and endocrine secretion. The placenta synthesizes glycogen, cholesterol and fatty acids early in gestation and produces large quantities of progestins and estrogens. The placental syncytioblast secretes hCG and human placental lactogen (hPL). Gases, nutrients, hormones, electrolytes, antibodies and waste products are transported across the placenta. Many drugs and infectious agents can also cross the placenta. Maternal transfer of steroid hormones across the placenta is limited. When natural or synthetic steroid hormones do cross the placenta, developmental toxicity can result. Furthermore, hormones produced by the fetal placenta also play an important role in parturition. In mammals, two distinct placentas, the yolk sac placenta and the chorioallantoic placenta, which develops during the first 40 days of development, are present early in development. Placentation involves complex vascular remodelling in both maternal and fetal circulation. Vasculogenesis is regulated by several gene products, including vascular endothelial growth factors and the angiopoietins and their receptors (see Smith et al., 2000). The expression of these genes is regulated in a temporally and spatially ordered manner in the maternal–fetal interface, and they are principal mediators in the development of the normal placenta. Disruption of their function causes disturbances of implantation and vasculogenesis of the placenta. 3.8.3.1 Yolk sac placenta In rodents, the yolk sac transports materials that are absorbed from the chorion and chorionic cavity before the allantoic (embryochorionic, fetoplacental) circulation is established. In humans, the yolk sac placenta functions in haematopoiesis, protein secretion and formation of the primordial germ cells. After the first trimester, the yolk sac becomes vestigial; by day 40 of gestation, the yolk sac is in the developing umbilical cord. The yolk sac provides nutrients to the developing fetus for approximately 92 days in the hamster, 10 days in mice, 12 days in the rat and 1 month in humans. In the rat and rabbit, the yolk sac nourishes the fetus until late in pregnancy, when it is separated from the gut. In rodents, the yolk sac placenta is the principal organ providing postimplantation nutrition to the embryo, and the chorioallantoic placenta is the site of attachment to the uterus. It is not until day 12 of gestation that the chorioallantoic placenta provides nutrients in the rodent. 3.8.3.2 Chorioallantoic placenta The chorioallantoic placenta is the principal placenta in mammals, but the number of layers separating the maternal and fetal circulations and the shape of the layers vary. The fundamental unit of the mature placenta is the cotyledon, which is formed by a single placental disc in humans, rabbits and rats, but by two placental discs in monkeys. In humans, the villous tree transports materials between the maternal and fetal circulation. The villous tree is composed of fetal capillaries, associated endothelium, stromal cells and the macrophages known as Hofbauer cells. The trophoblast cells include the cytotrophoblast stem cells in one layer and a second layer of syncytiotrophoblast cells that secrete hCG and steroids early in pregnancy. Later in pregnancy, the syncytiotrophoblast produces large quantities of hPL. Extravillous trophoblast produces hPL early in gestation and proteolytic enzymes, resulting in the invasion of trophoblastic cells into the myometrium, replacing the endothelium in maternal blood vessels. Invasion and attachment of the trophectoderm are followed by the flow of blood in both the maternal and fetal circulations. The maternal blood is not in direct contact with the villous tissue until 10 weeks of gestation. In humans, embryochorionic circulation begins around 28–30 days of gestation. There is a gap of approximately 14 days between the establishment of the maternochorionic and embryochorionic circulation. The placenta is essential for exchange of substances between the mother and the fetus. The fetal placenta develops from the chorionic sac, and the maternal placenta develops from the endometrium. By the end of the 3rd week, the primary chorionic villi develop, begin to branch and become surrounded by secondary chorionic villi. Blood vessels differentiate from spaces within the villi and become tertiary chorionic villi. Vessels in the chorion are connected to vessels in the embryo and to the heart primordia. By the beginning of the embryonic period, oxygen and nutrients in the maternal blood diffuse through the walls of the villi into fetal vessels, and carbon dioxide and waste products diffuse from the fetal capillaries into the vessels of the maternal endometrium. During this period, the villi extend over the entire amniotic cavity. By the end of the embryonic period, maternal blood enters the vessels in the villi from endometrial arteries, while blood is carried away from the villi by endometrial veins. Fetal membranes form a barrier between fetal and maternal compartments. The fetal placenta is attached to the maternal placenta by the cytotrophoblastic shell, which is an extension of the cytotrophoblast through the syncytiotrophoblast. The villi from the cytotrophoblastic shell anchor the placenta to the endometrium. The villi from the syncytiotrophoblast are the main sites of exchange between maternal and fetal blood. By the 15th week, the decidua forms septa that project into the villi vessels. Syncytial cells cover the surfaces of the septa such that the maternal blood does not directly contact fetal tissue. The formation of septa compartmentalizes the placenta into cotyledons. In humans, the thin separation between maternal and fetal blood is called the haemochorial placentation. 3.8.3.3 Placental steroidogenesis Both the cytotrophoblast and the syncytiotrophoblast synthesize peptide hormones, but only the syncytiotrophoblast produces steroid hormones. The placenta lacks certain steroidogenic enzymes and can not use acetate and cholesterol to produce progestins, androgens or estradiol. Therefore, the fetus converts androgens from the maternal circulation and fetal sources. The placental enzyme sulfatase removes the sulfate moiety from dehydroepiandrosterone sulfate (DHEAS) to form DHEA, which is then converted by 3beta-hydroxysteroid dehydrogenase (3beta-HSD) to the androgen androstenedione. Interconversion between androgens and estrogens is driven by 17beta-HSDs. There are seven types of beta-HSDs that differ in their substrate specificity and activity. Estriol is also produced by another pathway in the syncytiotrophoblast cells of the placenta; DHEAS from fetal adrenal is converted to 16alpha-hydroxydehydroepiandrosterone sulfate in the fetal liver, followed by removal of the sulfated chain to produce 16alpha-hydroxydehydroepiandrosterone, which is then aromatized to estriol. Estriol is the predominant estrogen produced during pregnancy, and almost all of the estriol and estradiol produced by the placental syncytiotrophoblast enters the maternal circulation. By the 7th week of gestation, the placenta produces the majority of the estrogen in the maternal circulation. In the placenta, there are 17beta-HSDs that reduce androstenedione to testosterone (in rodents) and estrone to estradiol (in rodents and humans) and 17beta-HSDs that promote the opposite activity, possibly protecting the fetus from highly active hormones (Peltoketo et al., 1999). 3.9 Embryogenesis Detailed reviews of embryogenesis of all organ systems can be found elsewhere (Brown, 1994). Embryogenesis (and indeed all of development) is particularly sensitive to exogenous insult because it involves dynamic interactions between cells (or groups of cells) and products of gene expression that occur within a very limited window of time (termed a "critical period"). If the scheduled developmental events fail to happen during this critical period, an irreversible abnormality almost invariably results. Some of the deleterious effects that can occur during embryogenesis are spontaneous abortion, developmental abnormalities or latent changes that are not detected until later stages of development. A classic example of the latter situation occurred in pregnant women whose children were adversely affected when the drug diethylstilbestrol (DES) was given during pregnancy (Herbst et al., 1971; Arai et al., 1983). The human embryo develops a bilaminar disc at about the 2nd week; a small cavity develops among the epiblastic cells and enlarges to become the amniotic cavity. The amnion is the fluid-filled membranous sac immediately surrounding the embryo/fetus. The epiblastic cells are the primordial forms for fetal mesoderm, endoderm and ectoderm. The yolk sac arises from cells of the cytotrophoblast that form a continuous membrane with the hypoblasts of the bilaminar germ disc and surround the initial blastocyst cavity, now called the exocoelomic cavity. The trophoblast gives rise to a layer of cells loosely arranged as the extraembryonic mesoderm around the amnion. Spaces in the syncytiotrophoblast are filled with a mixture of maternal blood from ruptured, engorged endometrial capillaries and secretions from eroded endometrial glands. The spaces in the syncytiotrophoblast fuse to form networks that are the primordial version of the intervillous spaces of the placenta. Maternal blood seeps into and out of the spaces, beginning the formation of the uteroplacental circulation. The cytotrophoblast produces extensions called the primary chorionic villi that penetrate the syncytiotrophoblast. The extraembryonic coelom divides the extraembryonic mesoderm into two layers. The extraembryonic mesoderm lines the trophoblast and covers the amnion. The extraembryonic somatic mesoderm and the trophoblast next to it are the chorion, and the extraembryonic cavity is now the chorionic cavity. The first indication of cranial differentiation occurs when the hypoblasts at the junction of the amnion and yolk sac form the prochordal plate. The next series of embryonic events includes gastrulation, neurulation and formation of the major organ systems. The primitive streak appears in the bilaminar disc; from it, mesenchymal cells form the mesodermal layer between the epiblast and hypoblast, giving rise to the trilaminar embryo. The notochord develops from mesenchymal cells and moves to an area of the prochordal plate. Cells from the primitive streak migrate cranially to form the oropharyngeal membrane and the primitive cardiogenic area. The embryonic ectoderm, which is the epiblast of the bilaminar stage, surrounds the developing notochord to form the neural plate. The ectoderm of the neural plate (ultimately to form the brain and spinal cord) grows cranially until it reaches the oropharyngeal membrane. The neural plate invaginates along its central axis and forms the neural tube. The neural tube completely separates from the surface ectoderm, which gives rise to the epidermis of the skin. Some ectodermal cells of the neural tube migrate to each side of the neural tube and form irregular, flattened masses called neural crests. The neural crests give rise to the sensory ganglia of the spinal and cranial nerves (Stykova et al., 1998). Because elements that will later form the CNS appear earlier than most other systems in the developmental process, disturbances of neurulation may result in severe abnormalities of the brain and spinal cord. Other ectodermal thickenings, the otic placode and lens placode, develop into the inner ear and lens, respectively. A series of mesodermal blocks called somites form around the neural tube, and these somites give rise to the axial skeleton. The intraembryonic coelom appears in the lateral mesoderm and later divides into the pericardial, pleural and peritoneal cavities. The intermediate mesoderm forms the nephrogenic cord, which later becomes the kidneys. Kidney development provides a useful example of the kinds of events that occur in the development of an organ. The kidney is formed through reciprocally inductive interactions between two tissues of different embryonic origin, the epithelial ureteric bud and the mesenchymal metanephric blastema. The ureteric bud arises from the distal region of the mesonephric (Wolffian) duct and grows into an area of mesenchyme of the nephrogenic cord, the metanephric blastema, that is committed to form the kidney. The metanephric mesenchyme consists of paired masses of cells, about 5000 cells in each, at the level of the hindlimb buds. The ureteric bud must grow 200–300 µm to contact the blastema. Contact between bud and blastema occurs on day 11 in the mouse, on day 12 in the rat and at the end of the 4th week in the human. On contacting the metanephric blastema, the ureteric bud induces the mesenchyme to condense around the tip of the bud. The condensed mesenchyme epithelializes and forms a nephron. At the same time, the mesenchyme induces the ureteric bud to branch and stimulates further outgrowth. The new branches of the ureteric bud contact more of the blastema, inducing new condensation and nephron formation. This reciprocal induction occurs over and over, eventually forming all of the nephrons of the kidney. The ureteric bud develops into the ureter, and the swelling at its end becomes the renal pelvis. The repeated branching of the ureteric bud results in the formation of the major and minor calyces (the large ducts that empty into the renal pelvis) and the system of collecting tubules. The two major calyces form from the first branching of the ureteric bud, around the end of the 6th week. Studies using transgenic mice show that lack of the gene for the bone morphogenetic protein BMP-7 also results in the failure of the collecting duct tree to develop. However, BMP-7 is produced by the ureteric bud and metanephric mesenchyme, so it may be that the failure of the ureteric bud derivatives to develop is secondary to effects on other aspects of kidney development. The C-ros gene, responsible for the production of a tyrosine kinase, is also expressed in the ureteric bud and appears to be important for ureteric bud elongation and branching. C-ros appears to recognize a membrane-bound ligand, so it requires contact with the blastema to be activated. Branching can be inhibited in vitro by heparin, activin and TGF-beta 1. It is not known whether these are active in vivo. A number of substances have been shown to induce the metanephric mesenchyme to differentiate. One obvious candidate signalling molecule is nerve growth factor (NGF). The NGF receptor is present transiently on the mesenchyme before and during nephrogenesis, and the treatment of ureteric bud/metanephric mesenchyme cultures with antisense oligonucleotides to NGF receptor blocks the induction (Sariola & Sainio, 1998). However, adding NGF to metanephric mesenchyme cultured alone does not induce differentiation, so the selectivity of the oligonucleotide treatment has been questioned. One line of evidence suggesting that NGF is important is the presence of nerve cells in the ureteric bud. The nerve cells appear to play an integral role in the induction process, as antibodies to ganglioside G3, a cell surface antigen on the nerve cells, blocks induction in vitro. How these interactions alert the genome of the mesenchyme to start transcribing the elements necessary for differentiation into nephrons is not known. However, the early events involve the expression of WT1, a transcription factor critical for early kidney development. WT1 was discovered in Wilms tumour, a relatively common paediatric tumour, affecting 1 in 10 000. Wilms tumour is characterized by uncontrolled proliferation of metanephric mesenchymal stem cells, along with incomplete or inappropriate differentiation of these cells. WT1 has four zinc fingers and four alternative splice forms that appear to be localized differently within the nucleus. WT1 is present in the metanephric mesenchyme before induction and is upregulated during induction. Blocking induction stops the production of WT1. WT1 is expressed at high levels during the condensation of the mesenchyme and its transition to epithelium. Its expression diminishes thereafter, except in the podocyte layer of Bowman’s capsule. WT1 knockout mice do not develop kidneys. The metanephric mesenchyme from these mice cannot be induced by wild-type inducers. WT1 is also expressed in other tissues in the embryo that undergo the unusual mesenchyme-to-epithelium transition, the mesothelium and the primary sex cords. Knockout of WT1 also results in agenesis of the gonads. Thus, one possible function of WT1 is to initiate this transition. WT1 regulates the expression of IGF-II, the IGF-I receptor, platelet-derived growth factor A chain and the early growth response gene Egr-1. All four genes appear to play a role in nephrogenesis. IGF-II levels are very high in Wilms tumour. The roles of the other genes have not been worked out fully, but it is possible that IGF and Egr-1 are involved in an autoregulatory loop with WT1. PAX-2 is a pattern formation gene expressed during early nephrogenesis. PAX-2 appears to maintain the proliferative state and is downregulated by WT1. PAX-2 knockouts have renal agenesis, also indicating an important role for this gene; however, its specific function has yet to be determined. One possibility is that PAX-2 may stimulate the upregulation of WT1 in the induced mesenchyme and in early condensates. A number of small proteins, such as BMP-7, Wingless-Int (WNT) and fibroblast growth factor (FGF-2), are candidate molecules for metanephric mesenchyme induction. BMP-7 is produced in the right place, BMP-7 knockout leads to renal agenesis and antibodies to BMP-7 block nephrogenesis in vitro. However, it is produced by tissues that cannot induce nephrogenesis in a co-culture. This suggests that BMP-7 is necessary for most, but perhaps not the earliest, events in nephrogenesis. FGF-2 is produced by the ureteric bud and induces nephrogenesis in rat, but not mouse, mesenchyme. Another argument against it being the inducer is that it is produced by tissues that cannot produce nephrogenesis, including previously induced nephrons. Cells transfected with WNT-1 can induce nephrogenesis, but neither WNT-1 nor any other known WNT protein has been identified in the right tissues at the right time of development. More work is needed to sort out the contributions of these and other factors in mesenchymal induction. It is worth mentioning the homeobox HOX gene family as having involvement in kidney development. A number of HOX genes are expressed in a graded pattern in the nephron, suggesting that they may play a role in establishing proximal–distal polarity. Knockout of both the HOX a11 and d11 genes results in complete or almost complete renal agenesis. However, loss of either gene by itself has little adverse effect, suggesting some redundancy of function. The precise role of HOX genes in kidney development has yet to be determined. After induction, two events occur: condensation of the mesenchyme around the ureteric bud, and transformation of the mesenchyme into epithelium. In order for condensation into a comma-shaped mass to occur, there has to be induction of a critical mass of cells, not all of which appear to be in contact with the ureteric bud. There appears to be some short-range signalling in the mesenchyme involving the secreted glycoprotein WNT-4. Mice lacking WNT-4 fail to form pretubular aggregates (as do PAX-2 knockouts). There also appears to be migration of induced cells away from direct contact with the ureteric bud, often several cell diameters distant. This may permit uninduced cells to contact the ureteric bud. Condensation appears to result from changes in the extracellular matrix, particularly the synthesis of syndecan, a glycoprotein. Condensation can be blocked in vitro by heparin or heparan sulfate, and over a 48-h culture period these glycans decrease nephrogenesis by over 90%. However, neither chondroitin sulfate nor hyaluronic acid had any effect on condensation, even though the latter is similar to heparan sulfate. Mice null for the gene for heparan sulfate 2-sulfotransferase are born without kidneys. Ureteric bud outgrowth and expression of early markers of differentiation in the mesenchyme are not affected by this mutation. However, condensation of the differentiating mesenchyme fails to take place, and subsequent renal development is blocked. The transition from mesenchyme to epithelium involves biochemical changes in the cells and the extracellular matrix. N-CAM expression on cell surfaces disappears, replaced by L-CAM (uvomorulin). Vimentin, a characteristic cytoskeletal component of mesenchyme, disappears, and cytokeratin, characteristic of epithelia, appears. There is a decrease in collagen I extracellularly and an increase in the basement membrane components laminin and collagen IV. The metanephric mesenchyme has an extremely high rate of proliferation. The metanephros doubles in size every 8 h during the first 5 days. In the prospective renal cortex, the expression of PCNA, a marker for S-phase, occurs in a majority of cells. The proliferation rate is slowed significantly in BMP-7 knockouts (described above) and BF-2 knockouts. BF-2 is a transcription factor in the medullary stroma. It is likely that it controls the synthesis of a soluble growth factor that stimulates mesenchyme proliferation, but the identity of that factor is unknown. Despite the high rate of proliferation, there is also significant apoptosis in the kidney. Apoptosis is associated with three processes of kidney development. The first is during early nephron formation, perhaps as a way to get rid of cells that did not undergo the mesenchyme–epithelial transition. The second phase of apoptosis sculpts the glomeruli, and the third phase occurs later in the medulla and renal pelvis. Mice that overexpress p53 have excessive cell death and develop kidneys that are smaller than normal. Mice that are null for the bcl-2 gene have excessive apoptosis early in renal development, followed by hyperproliferation. This leads to the development of cystic kidneys. Prior to the 3rd week, embryonic nutrition occurs by diffusion of maternal blood. At that point, development of the primitive blood and blood vessels begins in the extraembryonic mesoderm of the yolk sac. These cells differentiate into angioblasts that form cords and clusters, which in turn canalize. Cells in the periphery become flat and form the endothelium, whereas the inner cells give rise to the primitive blood cells. By fusion and continuous budding, the extraembryonic vessels that have contact with maternal circulation establish contact with vessels arising from the embryo proper. The mesenchymal cells surrounding the primitive endothelial cells differentiate to form the muscular and connective tissues of the vessel wall. The primitive heart is formed from mesenchymal cells in the cardiogenic area, similarly to the formation of the blood vessels. The gastrointestinal tract is formed from the endodermal germ layer. The embryo folds cephalo-caudally and laterally to incorporate the endodermal layer into the body cavity. At the cephalic end, the buccopharyngeal membrane is the boundary of the foregut. The hindgut terminates at the cloacal membrane. By the end of the 8th week, tissues and organ systems have developed, and the major features of the external body form have developed. The ectodermal layer has given rise to primordial forms of the central and peripheral nervous systems and the sensory epithelium of the ear, nose, eye and epidermis. The ectodermal layer also gives rise to the mammary and pituitary glands and the enamel of the teeth. The mesoderm gives rise to the kidneys, cartilage, bone, connective tissue, muscle, heart, blood, lymph cells, gonads (ovaries and testes), genital ducts, serous membrane lining the body cavities (pericardial, pleural and peritoneal), spleen and cortex of the adrenal gland. The endoderm gives rise to the gastrointestinal and respiratory tracts, tonsils, thyroid, parathyroid, thymus, liver, pancreas and epithelial linings throughout the body. The connection between the placenta and the embryo is maintained by the umbilical cord. A tubular extension of the embryonic hindgut called the allantois contains blood vessels that become the umbilical vein and arteries. The allantois itself extends from the umbilicus to the urinary bladder; as the fetus develops, it involutes, leaving a residual thick tube called the urachus, which persists throughout life as the median umbilical ligament. The umbilical cord develops from the connecting stalk of the allantois and the yolk sac stalk. The two are pushed together by the developing amniotic cavity as it obliterates the chorionic cavity. Two important aspects of early development of the reproductive tract are that the fetal gonad is structurally indifferent in male and female embyros and that the fetal reproductive system can therefore develop as male or female. Thus, the first major step in development of the reproductive system is establishing gonadal sex. Sex of the embryo depends on whether the spermatozoon carries an X or Y chromosome, and sexual differentiation of the indifferent structures in the gonad is necessary to form the male or female reproductive tract. The SRY gene on the Y chromosome is needed for testicular differentiation. The primitive gonad differentiates around the 7th week of gestation. Other genes implicated in normal differentiation of the male reproductive tract include, but are not limited to, WT1, steroidogenic factor 1 (Parker et al., 1996), DAX-1, SOX-9 and a variety of homeobox genes (Lindsey & Wilkinson, 1996; Pellegrini et al., 1997). In the fetal gonad, the development of the Sertoli cells results in synthesis of MIS, which initiates the removal of female structures (Behringer, 1995). The Sertoli cells also control the normal development of the Leydig cells, resulting in testosterone synthesis and the development of the vas deferens, epididymis and seminal vesicles. In rodents, most of these events take place in the second half of pregnancy, whereas in the human fetus, most events occur during the first trimester of pregnancy. 3.10 Fetal development The fetal period in humans extends from the 9th week of gestation until birth. The fetus grows rapidly, and many of the organ systems formed during embryogenesis mature and develop. At the beginning of the fetal period, the head is half as long as the whole fetus. As growth of the body proceeds rapidly, the relative length of the head diminishes. Primary ossification centres appear in the skeleton by 12 weeks, and the limbs develop further. The external genitalia of males and females appear similar until the 9th week, but are different by the 12th week. Urine starts to form between the 9th and 12th weeks. In early stages, the eyes have a lateral orientation, but by 16 weeks, the eyes come closer together. By the 17th week, growth slows, and by the 20th week, the fetus is covered in fine, downy lanugo hair. From weeks 21 to 25, the respiratory system develops rapidly. By 26 weeks, the eyes open, hair on the head and body is well developed and toenails appear. The quantity of body fat increases, and subcutaneous deposition makes the skin less wrinkled. The site of erythropoiesis shifts from the spleen to the bone marrow. At 36 weeks, the girth of the torso increases, and growth slows. In this interval, the male fetus grows more rapidly than the female, resulting in a greater weight at birth for males. In the male fetus, full descent of the testes into the scrotum should occur by the 38th week. Male and female gonadal development is discussed in section 3.12.2. Kidney development can be used again here to illustrate the kinds of events that occur during organ maturation, which takes place during fetal and postnatal development. While the induction of the organ and formation of its basic structure are initiated in the embryonic period, differentiation of the nephrons is not complete until term in humans, and not until the 2nd week postnatally in rodents. Nephrons form as generations of ureteric bud branches contact increasingly more distal regions of the metanephric blastema. The loose mesenchyme of the blastema condenses (i.e., the cells come together, leaving very little extracellular space) around the tip of the bud. The condensed mesenchyme becomes comma-shaped, with the tail of the comma always pointing away from the adjacent duct of the ureteric bud. It is at this comma-shaped stage that the condensed mesenchyme changes into epithelium. Blood vessels invade the indentation between the tail and body of the comma; these vessels will develop into the glomerulus. The comma begins to grow another tail at the end closest to the ureteric bud, thus becoming S-shaped. The new tail will become the distal tubule of the nephron and fuse with the ureteric bud/collecting duct. The distal part of the S-shaped tubule differentiates into the loop of Henle, proximal tubule and Bowman’s capsule. The tubule elongates as development proceeds. The podocyte layer of Bowman’s capsule forms around the blood vessels of the glomerulus as they develop. Induction and differentiation of nephrons occur continuously through the 38th week of gestation in humans and for 10–12 days postnatally in rats and mice. There are approximately 1.5 million nephrons per kidney in humans, and 1000–2000 in mice. After epithelialization and the formation of the S-shaped tubule, there is still much that needs to occur in order for the nephron to function. Cells destined to form the podocyte layer of the glomerulus flatten out and lose some of the markers that characterized their earlier transition to epithelium, including c-MYC, HOX-c9, LFB-1 and LFB-3, while keeping a high level of WT1. Expression of more classical mesenchymal markers such as vimentin takes place, but the cells also keep a number of epithelial proteins such as desmosomal components. The result is a tissue that is more organized than most connective tissue but leakier than most epithelium, the optimum design for urine filtration. The rest of the S-shaped tubule retains its epithelial character and segments into proximal tubule, loop of Henle and distal tubule. The cells lose expression of WT1, PAX-2 and n-MYC. Capillaries grow into the cleft in Bowman’s capsule. These apparently arise from blood vessels in response to angiogenic factors from the nephron. One such factor is VEGF, known to be secreted by early nephrons. The kidney begins to function as soon as there are functional nephrons at the corticomedullary junction. Nephron development continues during this time in the periphery of the cortex. Production of urine starts at about the end of the 3rd month in humans and by gestation day 17 or 18 in rats. Urine production is not necessary for waste excretion from the fetus, as this is taken care of by the placenta. Urine production is necessary to maintain proper amniotic fluid volume. Fetuses without kidneys or with insufficient urine production have oligohydramnios, too little amniotic fluid. Oligohydramnios can lead to abnormal development by physically confining the fetus, sometimes resulting in amputation or deformation of limbs in utero. Fetal urine is rich in serum proteins, as glomerular filtration begins before the podocyte layer of the glomerulus is mature. Although the proximal tubules have tight junctions and are capable of some endocytosis, there is insufficient capacity to resorb all of the filtered protein. The glomerular filtration barrier and proximal tubule resorption mature about 7 days after birth in the rat. The ability to produce a concentrated urine also matures over time. In the rat, this function is not mature until 2–3 weeks after birth. This is due to the lengthening of the loops of Henle and to maturation of ion transport function. Sodium influx from the renal tubular lumen stimulates proximal tubule growth and upregulates the expression of Na+K+-ATPase, the major transporter of sodium in the kidney, in the basolateral membranes of the epithelium. Fetal and postnatal maturation of the nervous system need special mention, because the nervous system is the organ system that requires the longest time to mature. Outgrowth of neuronal processes, formation and deletion of synaptic contacts and myelination take place over an extended period of time in humans and laboratory animals. This extended maturation makes the brain susceptible to environmental insult for a long period. For example, adverse neurobehavioural outcomes can occur from maternal alcoholism during the embryonic or fetal period. Endemic cretinism results from hypothyroid conditions (attributable to dietary iodine deficiency) during the fetal and early postnatal periods. 3.11 Gestation Maintenance of pregnancy depends on a functi