Vol. 1 - Pages 9.1-9.30 (Printed Version)
Reproductive System
STRUCTURE OF THE FEMALE
REPRODUCTIVE SYSTEM AND TARGET ORGAN
VULNERABILITY
Donald R. Mattison
The female reproductive system is controlled by
components of the central nervous system, including the hypothalamus and
pituitary. It consists of the ovaries, the fallopian tubes, the uterus and the
vagina (Figure 9.4 [REP04FE]). The ovaries, the female gonads, are the source of
oocytes and also synthesize and secrete oestrogens and progestogens, the major
female sex hormones. The fallopian tubes transport oocytes to and sperm from
the uterus. The uterus is a pear-shaped muscular organ, the upper part of which
communicates through the fallopian tubes to the abdominal cavity, while the
lower part is contiguous through the narrow canal of the cervix with the
vagina, which passes to the exterior. Table 9.3 [REP03TE] summarizes compounds,
clinical manifestations, site and mechanisms of action of potential
reproductive toxicants.
The Hypothalamus and Pituitary
The hypothalamus is located in the diencephalon, which
sits on top of the brainstem and is surrounded by the cerebral hemispheres. The
hypothalamus is the principal intermediary between the nervous and the
endocrine systems, the two major control systems of the body. The hypothalamus
regulates the pituitary gland and hormone production.
The mechanisms by which a chemical might disrupt the
reproductive function of the hypothalamus generally include any event that
could modify the pulsatile release of gonadotrophin releasing hormone (GnRH).
This may involve an alteration in either the frequency or the amplitude of GnRH
pulses. The processes susceptible to chemical injury are those involved in the
synthesis and secretion of GnRH—more specifically, transcription or
translation, packaging or axonal transport, and secretory mechanisms. These
processes represent sites where direct-acting chemically reactive compounds
might interfere with hypothalmic synthesis or release of GnRH. An altered
frequency or amplitude of GnRH pulses could result from disruptions in
stimulatory or inhibitory pathways that regulate the release of GnRH.
Investigations of the regulation of the GnRH pulse generator have shown that
catecholamines, dopamine, serotonin, g-aminobutyric acid, and endorphins all have some
potential for altering the release of GnRH. Therefore, xenobiotics that are
agonists or antagonists of these compounds could modify GnRH release, thus
interfering with communication with the pituitary.
Prolactin, follicle-stimulating hormone (FSH) and
luteinizing hormone (LH) are three protein hormones secreted by the anterior
pituitary that are essential for reproduction. These play a critical role in
maintaining the ovarian cycle, governing follicle recruitment and maturation,
steroidogenesis, completion of ova maturation, ovulation and luteinization.
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The precise, finely tuned control of the reproductive
system is accomplished by the anterior pituitary in response to positive and
negative feedback signals from the gonads. The appropriate release of FSH and
LH during the ovarian cycle controls normal follicular development, and the
absence of these hormones is followed by amenorrhoea and gonadal atrophy. The
gonadotrophins play a critical role in initiating changes in the morphology of
ovarian follicles and in their steroidal microenvironments through the
stimulation of steroid production and the induction of receptor populations.
Timely and adequate release of these gonadotrophins is also essential for
ovulatory events and a functional luteal phase. Because gonadotrophins are
essential for ovarian function, altered synthesis, storage or secretion may
seriously disrupt reproductive capacity. Interference with gene
expression—whether in transcription or translation, post-translational events
or packaging, or secretory mechanisms—may modify the level of gonadotrophins
reaching the gonads. Chemicals that act by means of structural similarity or
altered endocrine homeostasis might produce effects by interference with normal
feedback mechanisms. Steroid-receptor agonists and antagonists might initiate
an inappropriate release of gonadotrophins from the pituitary, thereby inducing
steroid-metabolizing enzymes, reducing steroid half-life and subsequently the
circulating level of steroids reaching the pituitary.
The Ovary
The ovary in primates is responsible for the control
of reproduction through its principal products, oocytes and steroid and protein
hormones. Folliculogenesis, which involves both intraovarian and extraovarian
regulatory mechanisms, is the process by which oocytes and hormones are
produced. The ovary itself has three functional subunits: the follicle, the
oocyte and the corpus luteum. During the normal menstrual cycle, these
components, under the influence of FSH and LH, function in concert to produce a
viable ovum for fertilization and a suitable environment for implantation and
subsequent gestation.
During the preovulatory period of the menstrual cycle,
follicle recruitment and development occur under the influence of FSH and LH.
The latter stimulates the production of androgens by thecal cells, whereas the
former stimulates the aromatization of androgens into oestrogens by the
granulosa cells and the production of inhibin, a protein hormone. Inhibin acts
at the anterior pituitary to decrease the release of FSH. This prevents excess
stimulation of follicular development and allows continuing development of the
dominant follicle—the follicle destined to ovulate. Oestrogen production
increases, stimulating both the LH surge (resulting in ovulation) and the
cellular and secretory changes in the vagina, cervix, uterus and oviduct that
enhance spermatozoa viability and transport.
In the postovulatory phase, thecal and granulosa cells
remaining in the follicular cavity of the ovulated ovum, form the corpus luteum
and secrete progesterone. This hormone stimulates the uterus to provide a
proper environment for implantation of the embryo if fertilization occurs.
Unlike the male gonad, the female gonad has a finite number of germ cells at
birth and is therefore uniquely sensitive to reproductive toxicants. Such
exposure of the female can lead to decreased fecundity, increased pregnancy
wastage, early menopause or infertility.
As the basic reproductive unit of the ovary, the
follicle maintains the delicate hormonal environment necessary to support the
growth and maturation of an oocyte. As previously noted, this complex process
is known as folliculogenesis and involves both intraovarian and extraovarian
regulation. Numerous morphological and biochemical changes occur as a
primordial follicle progresses to a pre-ovulatory follicle (which contains a
developing oocyte), and each stage of follicular growth exhibits unique
patterns of gonadotrophin sensitivity, steroid production and feedback pathways.
These characteristics suggest that a number of sites are available for
xenobiotic interaction. Also, there are different follicle populations within
the ovary, which further complicates the situation by allowing for differential
follicle toxicity. This creates a situation in which the patterns of
infertility induced by a chemical agent would depend on the follicle type
affected. For example, toxicity to primordial follicles would not produce
immediate signs of infertility but would ultimately shorten the reproductive
lifespan. On the other hand, toxicity to antral or preovulatory follicles would
result in an immediate loss of reproductive function. The follicle complex is
composed of three basic components: granulosa cells, thecal cells and the oocyte.
Each of these components has characteristics that may make it uniquely
susceptible to chemical injury.
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Several investigators have explored methodology for
screening xenobiotics for granulosa cell toxicity by measuring the effects on
progesterone production by granulosa cells in culture. Oestradiol suppression
of progesterone production by granulosa cells has been utilized to verify
granulosa cell responsiveness. The pesticide p,p¢-DDT and its o,p¢-DDT isomer
produce suppression of progesterone production apparently with potencies equal
to that of oestradiol. By contrast, the pesticides malathion, parathion and
dieldrin and the fungicide hexachlorobenzene are without effect. Further
detailed analysis of isolated granulosa cell responses to xenobiotics is needed
to define the utility of this assay system. The attractiveness of isolated
systems such as this is economy and ease of use; however, it is important to
remember that granulosa cells represent only one component of the reproductive
system.
Thecal cells provide precursors for steroids
synthesized by granulosa cells. Thecal cells are believed to be recruited from
ovarian stroma cells during follicle formation and growth. Recruitment may
involve stromal cellular proliferation as well as migration to regions around
the follicle. Xenobiotics that impair cell proliferation, migration and
communication will impact on thecal cell function. Xenobiotics that alter
thecal androgen production may also impair follicle function. For example, the
androgens metabolized to oestrogens by granulosa cells are provided by thecal
cells. Alterations in thecal cell androgen production, either increases or
decreases, are expected to have a significant effect on follicle function. For
example, it is believed that excess production of androgens by thecal cells
will lead to follicle atresia. In addition, impaired production of androgens by
thecal cells may lead to decreased oestrogen production by granulosa cells.
Either circumstance will clearly impact on reproductive performance. At
present, little is known about thecal cell vulnerability to xenobiotics.
Although there is a paucity of information defining
the vulnerability of ovarian cells to xenobiotics, there are data clearly
demonstrating that oocytes can be damaged or destroyed by such agents.
Alkylating agents destroy oocytes in humans and experimental animals. Lead
produces ovarian toxicity. Mercury and cadmium also produce ovarian damage that
may be mediated through oocyte toxicity.
Fertilization to Implantation
Gametogenesis, release and union of male and female
germ cells are all preliminary events leading to a zygote. Sperm cells
deposited in the vagina must enter the cervix and move through the uterus and
into the fallopian tube to meet the ovum. Penetration of ovum by sperm and the
merging of their respective DNA comprise the process of fertilization. After
fertilization cell division is initiated and continues during the next three or
four days, forming a solid mass of cells called a morula. The cells of the
morula continue to divide, and by the time the developing embryo reaches the
uterus it is a hollow ball called a blastocyst.
Following fertilization, the developing embryo
migrates through the fallopian tube into the uterus. The blastocyst enters the
uterus and implants in the endometrium approximately seven days after
ovulation. At this time the endometrium is in the postovulatory phase.
Implantation enables the blastocyst to absorb nutrients or toxicants from the
glands and blood vessels of the endometrium.
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