Reproductive Aging PDF

Summary

This chapter examines reproductive aging in women and men, focusing on menopause and related changes. It describes the timing of menopause, discusses common symptoms, and explores various aspects of reproductive aging.

Full Transcript

C H A P T E R

7
Reproductive Aging

INTRODUCTION lifetime, and therefore their reproductive life span is not
limited by availability of oocytes. Although other mam-
The reproductive capacity of a woman varies greatly mals have a limited oocyte supply at birth, they typically
over her lifetime, peaking in her twenties, then dimin- remain fertile throughout their adult lives, although
ishing over several years, and finally coming to an end at sometimes at a gradually diminishing rate. Thus, most
menopause. Over a million US women enter menopause other animals continue to reproduce as long as they
each year. Because the average life span of humans has live. Only human females (and perhaps females of a few
increased, especially in the past one hundred years, other large mammalian species) live a significant portion
more women will live a larger proportion of their lives of their lives post-reproductively. Not only do women
post-reproductively. Male fertility often continues differ in this way from other animals, their reproductive
through adult life, although it also diminishes with age. aging contrasts with that of human males. There is some
This chapter examines the aging of the reproductive sys- overall decline in reproductive function in certain older
tem, comparing the two sexes in this regard. We discuss men (see discussion later), but men have been known to
the patterns and consequences of endocrine changes at father children well into their nineties!
menopause and during reproductive aging in men, and
look at the pros and cons of therapeutically replacing
diminishing reproductive hormones in older adults. TIMING OF MENOPAUSE

Menopause is the permanent end of menstrual cycling
MENOPAUSE associated with the loss of ovarian follicular activity.
A woman is diagnosed in retrospect as having entered
Most women who survive to the age of 50 can expect menopause after she has not had a menstrual cycle for a
to live 20, 30, or even 40 more years in reasonably good full year. In the United States, the average age of the last
health. A typical 50-year-old woman’s heart vigorously menstrual period is 51, with a normal range of 45–55.
continues to pump blood, other internal organs such as The factors influencing the age at which a woman enters
her kidneys and liver are properly functioning, and her menopause, when her ovaries are depleted of follicles,
brain is active. In contrast, her ovaries undergo a dra- are mostly unknown. Possibly different women’s ova-
matic decline, resulting in their complete loss of func- ries contain a variable number of oocytes at birth, or the
tion. Her follicles deteriorate and her egg supply is lost, rate of follicular atresia differs among women. We know
rendering her infertile. Levels of ovarian hormones that women who smoke cigarettes enter menopause one
drop, affecting steroid-responsive tissues, especially the to two years earlier than nonsmokers. Some studies sug-
uterus, vagina, and breast tissue. Loss of ovarian ste- gest that the number of ovulatory cycles experienced by
roids causes menstrual cycles to cease. Thus, a woman’s a woman over her reproductive lifetime influences the
reproductive system ages prematurely in comparison to timing of menopause. Women with a greater number
the rest of her body. This period of reproductive decline of total ovulations may enter menopause earlier. For
is called menopause. example, nulliparous women and those with few chil-
Menopause is an unusual feature of human life his- dren tend to have earlier menopause than women who
tory; it is not typical of other animals. Ectothermic verte- have had several full-term pregnancies. Some evidence
brate females (fishes, amphibians, and reptiles) generally suggests that use of oral contraceptives (which inhibit
have the ability to form new oocytes throughout their ovulation) tends to delay menopause. Thus, there seems

Human Reproductive Biology, Fourth Edition. 119 Copyright © 2014 Elsevier Inc. All rights reserved.
http://dx.doi.org/10.1016/B978-0-12-382184-3.00007-6
120 7. REPRODUCTIVE AGING

to be an effect of the number of lifetime ovulations on or indirectly by changes in circulating hormones, espe-
the timing of menopause. Does each woman have a cially the drop in circulating estrogen. The symptoms
limited number of ovulations after which her ovaries may end within a year or they may last for several years.
are exhausted? If so, one would predict that girls who The most common symptom of menopause, experienced
entered menarche early would also experience a rela- by over 75% of menopausal women in the United States,
tively early menopause, but studies have not supported is the occurrence of hot flashes (or hot flushes). These are
this hypothesis. Age at menopause is unrelated to birth sudden, intense feelings of heat experienced in the chest
weight, but having a low relative adult weight or being and face, sometimes spreading over the body. They may
on a weight-reduction diet may be associated with ear- be accompanied by profuse sweating. Hot flashes may
lier menopause. occur at any time of the day or night, as often as every
10 min or less frequently, and they may last for 30 s to
several minutes. For most women, hot flash symptoms
PERIMENOPAUSE last for more than a year, and many postmenopausal
women continue to suffer hot flashes for five years or
Although the average age of menopause for ­American more. Some women experience hot flashes as only a
women is 51, a woman can begin to experience pre- minor nuisance; for other women, they cause major dis-
menopausal symptoms in her forties (average age, 47.5) turbances in sleep patterns and interfere with normal
or even late thirties. The first indication of perimeno- daily activities.
pause is a change in menstrual cycles. Menstruation Other physical symptoms of menopause include
may occur more often or less frequently than before, slight shrinking of the external genitalia, breasts, and
the menstrual flow may be heavier or lighter, and some uterus. The vagina can decrease in size, and its internal
periods may be missed. Other symptoms can include lining becomes thinner and drier. For some women, loss
hot flashes, sleep irregularities, mood changes, and of vaginal lubrication can lead to pain during sexual
vaginal dryness. This stage preceding true menopause intercourse. An increased pH of vaginal fluids can make
is called perimenopause and lasts an average of four the vagina more prone to infection (vaginitis; see Chapter
years. Women who are smokers tend to have an ear- 17). Lower urinary tract disorders such as urinary tract
lier and shorter perimenopause. Although a woman’s infections and incontinence are common. Other physical
periods can be irregular during perimenopause, and changes, such as abdominal weight gain, deepening of
there may be shorter cycles, she is usually still ovulat- the voice, and the appearance of hair on the chin and
ing and should use contraceptives to avoid pregnancy upper lip, may occur during and after menopause.
during this time. In fact, women using the combination The phrase female climacteric is used to refer to all of
birth control pill (Chapter 13) likely will not experience the changes (psychological and emotional as well as hor-
as many perimenopausal symptoms. Women who are monal and physical) of menopause. Menopause can be
seeking to become pregnant will be less likely to achieve a period of psychological adjustment for some women.
a successful pregnancy as perimenopause advances. Behavioral symptoms that can occur include irritability,
insomnia, and fatigue. Whether these symptoms are a
direct result of hormonal changes is not clear. Many of
PREMATURE MENOPAUSE the psychological responses to menopause may result
from physiological changes during this time. Hot flashes
About one in 100 women enters menopause unusu- that can waken a woman repeatedly during the night
ally early, before age 40. This condition, called premature may be a major cause of insomnia, fatigue, and mood
ovarian failure, most often has a genetic cause. Premature swings. The psychological effects of a woman’s loss of
menopause can also be caused by surgical removal of the fertility, which may represent an important aspect of her
ovaries, the chemotherapy and radiation used to treat feminine identity, can affect her emotional state nega-
cancers, or by autoimmune disorders in which the body tively at this time. One positive note for most women is
destroys its own tissues. A woman who experiences pre- the end of the monthly menstrual flow and, for some, the
mature ovarian failure will have the same menopausal PMS associated with menstrual cycling (see Chapter 3).
symptoms as those who enter menopause at a later time. A study of 2500 women reported that 70% had positive
or at least neutral feelings about end of their periods. It
must be emphasized that menopause is a normal phase
SYMPTOMS OF MENOPAUSE of the human life cycle, and most women adjust to this
change in a healthy and comfortable way. Later in this
Before and after reaching menopause, at least 85% of chapter we learn that older men can also experience a
women have symptoms, the occurrence and intensity of more gradual decline in sex hormones, with associated
which vary among individuals. These are caused directly symptoms (andropause).

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Endocrine Changes during Menopause 121
ENDOCRINE CHANGES DURING the follicular phase and speeding up cycles. The cycle
MENOPAUSE length, however, can be quite variable, with some cycles
longer and others shorter than normal.
During perimenopause, one of the first changes in a During perimenopause a woman has an increasing
woman’s endocrine status is a decline in the release of number of cycles that are anovulatory. In fact, female
small glycoprotein hormones from her ovaries ­(Figure fertility declines beginning around age 27 and continues
7.1). The ovaries stop producing a glycoprotein called to decline through perimenopause (Figure 7.2). During
anti-müllerian hormone (AMH). In Chapter 5 we this period of decreased fertility, it is common to have
learned that this hormone is released by Sertoli cells missed periods. After a woman’s cycles have ended and
in the developing testis and causes degeneration of she is in true menopause, the ovaries cease to respond
the ­müllerian ducts in males. Although AMH does not to FSH and LH. Most of a woman’s stock of ovarian fol-
appear to be present in the ovary during sex differen- licles is gone by this stage; only a few hundred remain at
tiation, starting around the time of birth it is produced menopause. The depletion of ovarian follicles results in a
and secreted by granulosa cells of primary, secondary, decrease in the production of estradiol to very low levels
and early tertiary follicles. Because it is produced by (Figure 7.1). Because estradiol levels are so low, there is
growing, but not primordial follicles, AMH reflects little if any negative feedback on gonadotropin secretion.
the entrance of resting follicles into the pool available Thus, in the absence of estrogen feedback, levels of FSH
for selection and ovulation each cycle. This hormone continue to rise. Secretion of LH also rises during meno-
continues to be produced throughout a woman’s repro- pause (Figure 7.1). In fact, the pituitary gland secretes
ductive life but begins to decline several years before 10 times as much FSH and four times as much LH as
menopause, and by menopause it is not detectable in in younger women. When these gonadotropins are
the blood. extracted from the urine of postmenopausal women, the
In the years leading up to menopause, the ovaries extract is called human menopausal gonadotropin. GnRH
also gradually stop producing inhibins. Inhibin-B is levels in the hypothalamus are low, and some studies
a glycoprotein that selectively suppresses the release have demonstrated a decrease in GnRH pulse frequency.
of FSH from the anterior pituitary. When the pituitary Androgen levels fall gradually as women age, but this
is released from this inhibition, the secretion of FSH decrease is thought to be unrelated to menopause. How-
rises. Higher levels of FSH can be detected in the blood ever, the adrenal glands and ovaries of postmenopausal
of women in their forties who are still menstruating women continue to secrete androgens. Sex hormone
regularly and showing no overt signs of menopause
­ binding globulin levels decrease, causing free androgen
(Figure 7.1). A woman usually continues to menstruate levels to rise. These hormones, in the absence of estro-
during perimenopause, although her cycles may become gens, cause some menopausal symptoms such as voice
irregular. This may be because the higher levels of FSH deepening, enlargement of the clitoris, and appearance
increase the rate of follicular maturation, thus shortening of facial hair.

FSH
Circulating hormone levels

LH

Inhibin-B
Estrone

E2
AMH
–8 –6 –4 –2 0 2 4 6 8
Number of years around menopause

FIGURE 7.1 Circulating levels of FSH, LH, estradiol (E2), estrone, AMH, and inhibin-B in women before, during, and after menopause. The
y axis is unitless. Note that declines in AMH and inhibin-B precede the reduction in estradiol levels. The increase in circulating gonadotropins,
especially FSH, seen during perimenopause remains elevated for years after menopause.

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
122 7. REPRODUCTIVE AGING

Because of the dramatic drop in estrogen secretion follicles below some critical number decreases fertility,
during menopause, an average woman in the United and the drop in estrogen levels resulting from follicle
States spends about one-third of her life with very low depletion changes the endocrine feedback on the hypo-
levels of estrogens, which influence over 300 bodily thalamus and pituitary. Recently, scientists have also
functions! The major circulating estrogen in postmeno- addressed the possible neural control of menopause,
pausal women is estrone (Figure 7.1). Androstenedione, suggesting that age-related changes in the central ner-
produced by the adrenal glands, is aromatized to estrone vous system may secondarily affect the hypothalamus,
predominantly in adipose (fat) tissue. Obese women pituitary, and ovaries.
therefore have higher levels of estrone compared to lean
women.
Hot flashes occur when estradiol levels are lowered DECLINE IN FERTILITY
relatively slowly, such as in women in normal meno-
pause, or abruptly, such as in premenopausal women Many women can observe changes in the length or
after surgical removal of the ovaries or those given anti- regularity of their menstrual cycles during perimeno-
estrogen treatment for cancer. Even men can experience pause. In addition, most women experience hot flashes
hot flashes when their testosterone levels drop sud- and other perimenopausal symptoms as their reproduc-
denly after surgical or chemical treatment for testicular tive life nears its end. Certainly they are aware of the ter-
or prostate cancer. Treatment with estrogens reliably mination of their cycles at menopause, though this event
relieves hot flashes in women. However, low estrogen is only observed in retrospect. However, the decline in
levels alone cannot explain hot flashes as estrogen levels fertility during the years prior to menopause is mostly
do not d ­ iffer between symptomatic and asymptomatic a silent phenomenon. How does reproductive poten-
women. Hot flashes occur when a woman’s sympathetic tial change during a woman’s reproductive lifetime?
nervous system is activated, causing dilation ­(widening) That is, given a sexually active woman between puberty
of blood vessels in the skin, which results in warm blood and menopause, how do her chances of becoming preg-
being carried to these regions. Sympathetic activation nant change as she ages? This question is surprisingly
also causes sweating, as well as an increase in heart rate difficult to answer. One could simply look at the num-
­during the flashes. It had long been thought that hot ber of births at each maternal age in a population. But
flashes were triggered by a brief, abrupt dysregulation with the widespread use of contraception, women can
of the thermoregulatory system. Normally, body tem- suppress reproduction, which masks the true natural
perature is maintained within a comfortable temperature fertility rate. Furthermore, the frequency of coitus may
range known as the thermoneutral zone. If core tempera- change throughout a woman’s life, and this affects preg-
ture rises above the thermoneutral zone, sweating results nancy rate. Other determinants of reproductive capacity
to cool the body down, and if it drops below the ther- encompass physiological, behavioral, and sociological
moneutral zone, shivering raises the core temperature. factors including the proportion of ovulatory cycles,
Recent research has shown that women who experience length of cycles, rate of fetal loss, the length of time that a
hot flashes have such a narrowed thermoneutral zone woman nurses her child, and male factors. The best infor-
that even a small rise in temperature results in sweating. mation about female reproductive capacity comes from
Women with a wider thermoneutral zone don’t tend to studies of married or cohabiting women in “natural fer-
have hot flashes. Much of the basic physiology of this tility” populations using no contraception (Figure 7.2).
very common menopausal symptom is still unknown. Data from these studies show that peak female fertil-
We have described many changes in a woman’s ity occurs in the early to mid-twenties and begins to
body that occur during menopause, but what aspect of decline by age 30. At 33, a woman’s fecundity (chance
reproductive aging actually causes menopause? A post- of becoming pregnant) per cycle is only 75% of that in
menopausal woman’s reproductive tract and external her 20s. By age 35, her ability to become pregnant has
genitalia remain functional. She can continue to engage declined to less than 50% of her peak fertility years.
in normal sexual activity. Using a younger woman’s egg, A 40-year-old woman, despite being 10 years away from
her uterus retains the ability to sustain a full-term preg- menopause, has only a 30% chance of pregnancy com-
nancy at least until her late sixties! But her ovaries age pared to in her twenties. After age 30, the rate of miscar-
more rapidly than other reproductive organs. Both the riage also increases, and thus the chance of delivering
quantity and quality of oocytes decline as a woman ages. a healthy baby is further reduced. Historical data from
Continuing a steep reduction in the number of ovarian populations using no contraceptives show that women
follicles through infancy and childhood, follicles are had their last child at an average age of 41; i.e. this is the
steadily lost by atresia throughout a woman’s reproduc- average age of the loss of fertility.
tive years (Figure 7.3). A reduction in number of oocytes During a woman’s reproductive years, both the quan-
drives menopause. Clearly, the depletion of ovarian tity and quality of her oocytes decline. By the age of 15,

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Determining Female Reproductive Age 123
100 100
90
Probability of conception (%)

Percentage of follicles remaining
80
80
70
60
60
40 50
40
20
30
20
0
15 20 25 30 35 40 45 50 10
Age (years)
0
FIGURE 7.2 Change in probability that conception will occur with- 15 20 25 30 35 40 45 50 55
in one menstrual cycle in women aged 15–50. Data are from natural Age (years)
fertility populations, using no artificial contraceptive practices. Prob-
ability of pregnancy depends on many factors including biological fer-
FIGURE 7.3 Percentage of follicles remaining between ages 15–55.
One hundred percent is set as the number of follicles at age 15, near the
tility as well as frequency of intercourse. One hundred percent is the
beginning of the female reproductive years. However, a 15-year-old
conception rate of women age 22.
female has already lost about half of the follicles she was born with.

she has already lost half of the follicles she was born with. becoming stepmothers or adoptive mothers. However,
Before the age of 25, her oocyte pool is again reduced by an understanding of the timing of the decline in female
half (Figure 7.3). On average, by age 35 about 16,000 fol- fertility, and in particular a test that would inform indi-
licles remain, and this is further reduced to a few hun- vidual women of their current fertility status, will help
dred by menopause. Some studies show an accelerated women and their partners plan childbearing.
decline starting at age 38. But this ongoing depletion of
follicles does not tell the whole story. In addition to hav-
ing fewer eggs ovulating, the quality of a woman’s eggs DETERMINING FEMALE REPRODUCTIVE
declines. The follicles undergo a process of aging and AGE
deterioration. This includes the introduction of genetic
mutations in the oocyte nuclear DNA and cytoplasmic Because a woman’s fertility changes throughout her
changes such as loss of mitochondria and mutations of lifetime, it is helpful for women to have information
mitochondrial DNA. Aging of supporting cells in the fol- about their reproductive status to make informed choices
licle wall may also occur. By age 40, half of a woman’s regarding the timing of pregnancy and/or contracep-
eggs are chromosomally abnormal, and two years later tive use. To help provide this information to individual
that figure rises to 90%. Figure 7.4 shows the dramatic women, researchers have developed a staging method
increase in the number of trisomic embryos with increas- similar to the method used to determine the stages of
ing maternal age. Thus, even if a woman in her thirties or puberty (Chapter 6). Two factors are taken into account
forties is able to conceive, the risk of miscarriage increas- when determining “reproductive age.” One is the length
ingly rises (see Box 7.1). Thus, if a woman is to become a and regularity of menstrual cycles. The second is the
mother, she is most likely to first give birth in her twen- measurement of circulating levels of FSH. These stages
ties. However, women today live longer and enjoy bet- are shown in Table 7.1. Note that there is no age range
ter health than in previous generations. Many women for a given reproductive stage. This is because there is
now delay childbearing because of their careers, educa- a great deal of individual variation in the age at which
tion, and desire to pursue their interests before starting women enter reproductive stages and also in the length
a family. Increasingly, women are becoming ready for of each stage. For example, if a woman in the late repro-
childbearing at an older age, only to find that they are ductive stage decides to have a baby, it is not possible to
in perimenopause and that their fertility is decreasing predict whether she will take five months or five years
rapidly. Thus, the timing of fertility decline is becom- to become pregnant. Furthermore, women who have
ing a greater constraint on women’s ability to plan their conditions that may alter their endocrine state (e.g. those
families. In the United States, nearly one in five women who are extremely thin or obese, extremely athletic, have
between the ages of 40 and 44 has not borne a child, and irregular cycles, have endometriosis or uterine fibroids,
the rate of childlessness has doubled in the past 20 years. are heavy smokers, or who have had a hysterectomy)
Of course, not all of these childless women desire to may be difficult to stage. Nevertheless, an awareness of
have a family, and others achieve their family goals by the natural progression of the female reproductive stages

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
124 7. REPRODUCTIVE AGING

35 and 10 mm in diameter can be visualized by transvaginal
ultrasound, and this is usually done early in the follicular
stage. However, like other tests of ovarian reserve, it does
not provide information about oocyte quality.
Inhibin-B is a hormone produced by granulosa and
30
theca cells of developing small antral follicles early in
the follicular phase. It selectively inhibits the production
and/or release of FSH from the pituitary gland. In the
premenopausal ovary, inhibin-B levels are reduced as the
25 number of antral follicles declines, and inhibin-B is very
low or undetectable about four years before the final men-
strual period (Figure 7.1). Thus, a lowering of circulating
inhibin-B is a marker of ovarian aging. Because levels of
20
this hormone fluctuate during the female cycle, it should
be measured during the follicular phase of the cycle.
Trisomies (%)

As inhibin levels decline, the lifting of this feedback
restraint allows FSH levels to rise during female repro-
ductive aging (Figure 7.1). Elevated FSH usually occurs
15 in women starting at age 35–40, when the oocyte pool
has shrunk to about 10% of that present at puberty. A rise
in FSH is therefore a marker of ovarian aging.
Anti-müllerian hormone (AMH) is a small glycopro-
10 tein that is released by Sertoli cells in the developing testis
and causes degeneration of the müllerian ducts in males
(see Chapter 5) Although this hormone probably plays
no role in the ovary during sex differentiation, starting
around the time of birth AMH is produced and secreted
5 by granulosa cells of primary, secondary, and early ter-
tiary follicles. Its role may be to limit initial recruitment of
primordial follicles into the growing follicular pool, and
to limit the response of small growing follicles to FSH.
0 Blood levels of AMH are a good indication of the number
15 20 25 30 35 40 42 of healthy early tertiary follicles. Because the number of
Age (years) early antral (tertiary) follicles is related to the number of
FIGURE 7.4 Genetic analysis of clinically recognized pregnancies primordial follicles, the level of AMH also indicates the
shows a dramatic increase in trisomies after a maternal age of 35. Tri- size of the ovarian reserve. Circulating AMH levels begin
somy 16 is the most common trisomy; it results in miscarriage, usually to decrease after the peak fertility years, and are very low
within the first trimester. This contributes to the decrease in fertility of
women in their later reproductive years. The slightly higher incidence
or undetectable by five years prior to the last menstrual
of trisomies in women under the age of 17 may reflect non-disjunction period (Figure 7.1). This reduction in AMH can be seen
in meiosis during the earliest cycles after puberty. before changes in other age-related markers such as FSH
and inhibin-B. Because AMH does not fluctuate during
may help women move more comfortably through their the menstrual cycle, it can be tested at any stage of the
reproductive life span and beyond. cycle. For these reasons, a decline in AMH is considered
Other methods to help women determine their fertility the most promising marker of the loss of fertility.
status focus on assessing the number of primordial folli- It should be noted that many of the studies of markers
cles in the ovary, called the ovarian reserve. For a woman of ovarian reserve have focused on the markers’ ability
in her peak reproductive years, at the beginning of each to predict an ovarian response to gonadotropin stimu-
monthly cycle several antral follicles are present in each lation for assisted fertility treatments (see Chapter 15).
ovary; these follicles are selectable for further growth More information is needed about the changes in these
and maturation. As the ovary ages, fewer early antral markers in women of normal fertility.
oocytes are present in each cycle. Because the antral fol- Is it possible to push the frontiers of female fertility
licle count mirrors the size of the ovarian reserve, it is a into a woman’s forties, fifties, and beyond? In 1994, a
reasonably good indicator of potential fertility. Thus, one 63-year-old Italian woman gave birth to a baby using
way to assess fertility is to count the number of antral fol- an egg donated by a younger woman (see Chapter 15).
licles available during a cycle. Antral follicles between 2 Since then, many other women even older have used

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Determining Female Reproductive Age 125

BOX 7.1

EGG AGING
In women, the chances of infertility increase with age. ognized pregnancy, and aneuploidy explains about 60% of
For example, infertility rates in American women are 4.1% at these. The number of preembryos that have chromosomal
ages 20 to 24, 5.5% at ages 25 to 29, 9.4% at ages 30 to 34, and abnormalities and fail to implant is high (by one estimate,
19.7% at ages 35 to 39. An individual woman’s fertility de- about 31% of all conceptions). For a woman in her 20s
pends on her age and also how close in years she is to meno- with a clinically recognized pregnancy, the rate of trisomy
pause. Up to age 40, the main cause of infertility in women is only about 2–3%. But this increases to about 35% for
is not the failure to ovulate or the inability of the uterus to a woman in her 40s. Many of these pregnancies end in
implant an egg, but instead the increasing loss of preembryos ­spontaneous abortion, and surviving children born with
or early implanted embryos. Only after age 40 does female trisomies face developmental disabilities.
infertility increase rapidly due to a failing of ovarian function There is, however, another theory to explain the ­increase
and of the ability to conceive. Thus, the decline in ovulated in aneuploid births in older women. This theory says that
egg quality precedes the decline in ovulated egg quantity. the higher incidence of late miscarriages and birth defects
Remember from Chapter 5 that each ovary has about in older women is due to a decrease in the efficiency of the
500,000 oocytes in follicles at birth and that these primary mechanism that causes spontaneous abortion of abnormal
oocytes are arrested in prophase of the first meiotic divi- embryos. This theory assumes that a mother has a screen-
sion for up to 50 years unless they die by atresia or are ing system, probably of uterine origin, that regulates off-
ovulated. As a result, most of the oocytes in the ovary age spring quality, and that this system falters with age. This
for many years or even decades, and apparently this aging relaxed screening of abnormal embryos then causes the
can cause problems in the selected few that finally reiniti- observed increase in defective embryos in miscarriages
ate meiosis and ovulate. and the increase in genetically abnormal fetuses carried
Problems in meiosis can produce embryos that have too to term in older mothers. The evolutionary explanation
many sets of chromosomes, having cells that are 3N or even for this relaxation could be that, since an older woman is
4N instead of 2N. This is called polyploidy, and all of these nearing menopause, it benefits her to relax the screen and
polyploid embryos are lost through spontaneous abortion. to allow more successful implantation, taking the “good“
A more common chromosomal error is aneuploidy, in which embryos with the “bad”, since this is her final chance to
both members of a homologous pair of chromosomes end pass on her genes. This theory is in contrast to the first
up in one cell during meiosis (resulting in embryonic theory because it predicts that older and younger women
­trisomy), with the other cell of the abnormal division hav- ovulate the same percentage of embryos with chromosom-
ing no chromosomes of that pair (resulting in monosomy). al abnormalities.
Perhaps the homologous sets of chromosomes are unable What about the sperm of older men? Aneuploidy dur-
to separate as well during meiosis in older oocytes, thus ing meiosis and other genetic abnormalities do occur in
leading to aneuploidy. Although most trisomic embryos the testes, with increased frequency in older men. It is
are aborted spontaneously, trisomies of chromosomes 13, ­likely that a great majority of these abnormal sperm do not
18, and 21 are often born, but with severe developmental fertilize an egg. Some do, however, as evidenced by the
and mental disorders. Trisomies of sex chromosomes (XXY, increase in miscarriages associated with fertilization by
XYY, XXX) are discussed in Chapter 5. Monosomic new- sperm from older men. Male fertility decreases with age.
borns with Turner’s syndrome (XO) develop mental and At age 24, the probability of a man producing a pregnancy
developmental abnormalities (Chapter 5). within a year of frequent, unprotected coitus is about 92%.
Because the incidence of chromosomal abnormalities From then on, this probability decreases about 3% for
in newborns increases with the mother’s age, one theory ­every subsequent year, regardless of the age of the woman.
has been that there are more oocytes ovulated with chro- Chance of conceiving a child with Down syndrome or with
mosomal abnormalities in older women, which lowers any aneuploidy at different maternal ages
female fertility. Central to this hypothesis is that certain
preembryos are rejected by the uterus before or during Maternal age (years) Down syndrome Any
implantation through some as yet unknown mechanism. 15–24 1/1300 1/500
Even if these abnormal embryos implant and a pregnancy 25–29 1/1100 1/385
is established, many miscarry early in the first trimester. 35 1/350 1/178
Most estimates suggest that chromosomal abnormalities 40 1/100 1/63
account for about one-half of early miscarriages after a rec- 45 1/25 1/18

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
126 7. REPRODUCTIVE AGING

TABLE 7.1 Stages of a Woman’s Reproductive Life at a greater rate, and a condition called osteoporosis can
0. Prereproductive
develop. In this condition, the bones become weak and
prone to fracture, and a woman may lose height because
1. Early reproductive her vertebrae compress.
Menstrual cycles are variable to regular, FSH levels are normal In the United States, about one in four women over
age 50 develops osteoporosis or osteopenia (low bone
2. Peak reproductive
density that increases risk for osteoporosis). This means
Menstrual cycles are regular; FSH levels are normal that today about 25 million American women have this
3. Late reproductive condition. Osteoporosis results in about 1.3 million bone
fractures, leading to 30,000 deaths each year. Black and
Menstrual cycles are regular; FSH levels are elevated
Hispanic women tend to suffer less from osteoporosis.
4. Early menopausal transition The primary cause of osteoporosis is a lowering of estro-
 Length of cycles varies by seven days or more; FSH levels are gen levels in a woman’s blood. This can occur after natu-
elevated ral menopause, after “induced” menopause (i.e. surgical
5. Late menopausal transition
removal of the ovaries for some other reason), or dur-
ing amenorrhea. Factors that increase the risk of osteo-
Two or more cycles missed; FSH levels are elevated porosis include low physical activity or chronic intense
6. Early postmenopause exercise, low calcium intake, smoking, the use of alcohol
 Lasts for four years after menopause begins; FSH levels are
or caffeine, a fair complexion, being thin, never having
elevated been pregnant, early menopause (natural or induced),
and a family history of osteoporosis. Obese women
7. Late postmenopause
tend to have fewer problems with osteoporosis, perhaps
Lasts until death; FSH levels remain elevated because they have higher estrogen production from fat
cells.
Older women are at increased risk for a variety of
this method to become pregnant. In the future, it may be other diseases, which may be caused by hormonal
possible for women to prolong their own fertility after changes at menopause or may simply be associated
natural menopause. Some studies suggest that, contrary with the aging process. For example, women seldom
to long-standing views, female mammals may retain have cardiovascular disease before menopause, but the
ovarian stem cells well into adulthood. If this holds true risk increases greatly in postmenopausal women (pos-
for humans, it may be possible to develop therapies that sibly related to postmenopausal abdominal fat deposi-
prolong fertility through the proliferation and mainte- tion), making heart disease the leading cause of death in
nance of these stem cells. This approach may also lessen US women. The incidence of cancer, including cancers
or delay menopausal symptoms. of the reproductive organs, increases after menopause.
Some have questioned whether an older woman has Another group of diseases found predominantly in
a “right” to raise a child. Others feel that this is an out- postmenopausal women are various types of demen-
dated argument. Indeed, many grandparents are now tia, including Alzheimer’s. Because of the association
raising their grandchildren successfully. It has been between the natural loss of hormones at menopause and
shown that women in their fifties, after undergoing IVF the onset of these diseases, it was hoped that replacing
treatment with donor eggs (see Chapter 15), are able to some of a woman’s lost hormones artificially would pre-
carry a pregnancy as successfully as younger women. vent the diseases. Indeed, early studies, many of which
Older parents tend to have the financial and emotional were observational, demonstrated a widespread benefit
stability necessary for child rearing, and women (and of hormone replacement. However, as we shall see, the
men) who have the advantage of good health care and earlier promise of hormones as a “fountain of youth” has
living conditions can now expect to have more years of been sobered by the results of more recent studies.
excellent health than past generations. However, as sci-
ence and medicine stretch the boundaries of menopause,
these ethical and practical arguments will continue. TREATMENTS FOR MENOPAUSAL
SYMPTOMS: BENEFITS AND RISKS

OSTEOPOROSIS AND OTHER Some women have mild menopausal symptoms and
POSTMENOPAUSAL DISORDERS may not seek medical treatment. Those women who
have moderate to severe symptoms before, during, or
During menopause and the postmenopausal state, after menopause may decide to take hormone replacement
calcium and phosphorus are lost from women’s bones therapy (HRT) to alleviate the symptoms. An estrogen

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Treatments for Menopausal Symptoms: Benefits and Risks 127
or a combination of estrogen plus progestin is taken to Taking HRT appears to increase the risk of devel-
“replace” the hormones released previously by the ova- oping breast cancer, elevating the risk about 2.3% for
ries. Estrogens are commonly delivered by pill form or every year of use. A study of 122,000 American nurses
through a skin patch. The estrogen may be synthesized indicated that those aged 55 to 59 who were taking ERT
from a plant source or obtained from the urine of preg- for at least five years had a 54% increased risk of breast
nant horses. The latter, such as Premarin (a mixture of six cancer, and ERT at age 60–64 years increased the risk to
estrogens derived from pregnant mare’s urine) is admin- 71%. In this study, there was no ERT effect on breast can-
istered most commonly as a pill. Women who are still cer if used for less than five years. Other studies have
cycling often take an estrogen pill daily, adding proges- concluded that the risk of breast cancer from combined
tin for 12–14 days a month, followed by progestin with- estrogen plus progestin use is greater than that from the
drawal to allow menstruation to occur. A daily estrogen use of estrogen only. The good news is that five years
plus progestin pill is given most commonly to women after having stopped HRT treatment, a woman’s risk of
who have stopped cycling. ­Estrogen-containing vaginal breast cancer is no greater than that of a woman who
creams are also used to decrease vaginal dryness and never used HRT.
lessen painful coitus. A strong correlation exists between ERT and inci-
Hormone replacement therapy is very effective in dence of endometrial cancer. Estrogen alone for at
alleviating the hot flashes, night sweats, and sleep dis- least one year increases risk of this cancer 6–14 times,
turbances of menopause. These symptoms are the main depending on estrogen dose and duration of treat-
reason for prescribing HRT. In addition, the hormone(s) ment. It is not clear if this increased risk goes away
relieves urogenital discomfort (vaginal dryness and pain after ERT is discontinued. Unlike for breast cancer,
and frequent urination). Early HRT, especially if taken however, adding a progestin to the estrogen decreases
starting in the first three years after menopause, reduces the estrogenic effect on endometrial cancer signifi-
the spine and hip fractures due to osteoporosis. How- cantly. Therefore, it is recommended that women who
ever, one must continue to take estrogen for the benefits have their uterus (i.e. those who have not had a hys-
to persist; the bones begin to lose density when HRT is terectomy) should use the combined HRT instead of
discontinued. Other nonhormonal treatments for osteo- estrogen alone (ERT).
porosis are available. Combined estrogen plus proges- One study of 240,000 American women showed that
tin (but not estrogen alone) appears to reduce the risk of ERT given for at least six years increases the risk of fatal
colorectal cancer. It is not known whether the protective ovarian cancer by 40%, and this risk increased to 70%
benefits of HRT on this type of cancer continue after a if ERT continued for 11 years. This was confirmed by
woman stops taking the hormones. another study that found a 60% greater risk of devel-
Earlier studies had indicated that estrogen lowered oping ovarian cancer in women taking estrogen-only
the incidence and mortality rate of cardiovascular dis- HRT for 10 years or more. The effect of combined
ease in postmenopausal women. Based on this informa- estrogen plus progestogen HRT on ovarian cancer is
tion, many women used HRT to protect against heart inconclusive.
attacks and stroke, as well as osteoporosis, even if their Finally, ERT and combined HRT increase the risk
menopausal symptoms were not distressing. However, of gallbladder disease, and ERT appears to cause the
in 2002, a large federally funded study examining the growth of benign uterine fibroids.
health effects of HRT on 16,000 postmenopausal women In summary, HRT has benefits for some women but
was halted abruptly when it was found that women tak- can have dangerous side effects in others (Table 7.2).
ing estrogen and progestin were actually at higher risk Certainly, a woman’s individual and family history of
of heart disease, strokes, and blood clots. Combined hor- cancer of the reproductive tract should be considered
monal treatment increased the risk of heart disease by before she chooses HRT. One must also consider relative
29% and the risk of stroke by 41%. Thus, HRT should not risks. HRT raises the risk of heart disease, which kills
be used to protect against cardiovascular disease. After 250,000 American women each year, and also increases
the results of this study were made public, many women the risk of breast cancer, which kills 46,000 women each
discontinued their use of HRT. year. Thus, women who are at high risk for heart dis-
Earlier studies also reported that HRT increased short- ease or who have a family history of breast cancer are
term memory and the ability to learn new tasks and usually discouraged from using HRT. However, estro-
decreased the risk of developing Alzheimer’s disease by gen maintains bone density, protecting against osteopo-
40%. However, a large controlled study of nearly 3000 rosis and the resulting hip and spinal fractures that can
women found that estrogen replacement therapy (ERT) in be debilitating for older women and kill 30,000 women
postmenopausal women who have had a hysterectomy per year. Some women may choose to take HRT for one
not only failed to prevent memory loss, but actually or more years to alleviate menopausal symptoms and
increased the risk of dementia. then discontinue its use because of associated health

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
128 7. REPRODUCTIVE AGING

TABLE 7.2 Possible Benefits and Risks of Estrogen Replacement contains a precursor of estrogens (see Chapter 2)
Therapy for Menopause that has been proposed as an antiaging substance.
Benefits Risks In summary, the Food and Drug Administration
now recommends that women with moderate to severe
Relieves hot flashes, night sweats, Increased risk of endometrial
menopausal symptoms use HRT at the lowest effective
insomnia cancer (unless a progestin is
used with estrogen) dose and for the shortest possible time. Results from the
Women’s Health Initiative dispelled the notion that HRT
Relieves vaginal and skin dryness, Increased risk of breast cancer
should be used broadly as an antiaging drug. HRT may
genital shrinking
be prescribed for women at high risk of osteoporosis, but
Reduced osteoporosis (especially if Increased risk of heart disease hormone therapy should not be used to prevent heart
a progestin is also used)
disease or dementia.
Reduced risk of colorectal cancer Increased risk of gallbladder
disease

Increased risk of fatal ovarian ANDROPAUSE
cancer

Increased risk of benign uterine Testicular Function in Old Age
fibroids
Some older men undergo a phenomenon that is
similar to menopause in women; it is commonly called
risks. Those entering menopause prematurely can andropause. In women, menopause usually occurs over
probably safely take HRT for longer. Whether to add a period of a few months or years, but andropause typi-
a progestin to the ERT is also a choice. Both estrogens cally occurs over decades, usually between the ages of
and progestins cause mitosis of mammary gland cells. 48 and 70. It may begin in a man’s forties or later. One
In contrast, estrogens increase, but progestins decrease, sign of andropause is that erections may take longer to
mitosis of endometrial cells. Because increased mitosis achieve, and it may require more active stimulation of
raises the chance of genetic error and cancer, progestins foreplay to enable a couple to have sexual intercourse
support the increased risk of breast cancer after ERT (see Chapter 8). Male libido may also decrease, and
but reduce the risk of endometrial cancer after ERT. men may experience fatigue, depression, and cognitive
Progestins may even enhance the beneficial effects of decline. These and other symptoms are at least partly a
ERT in relation to osteoporosis. However, the addition result of a decline in testosterone levels in some older
of progestin increases the incidence of premenstrual men. Male sexual characteristics also may change: the
syndrome, menstrual cramps, and unpredictable men- voice may rise in pitch, facial hair growth may decrease,
strual bleeding. Most women today take a progestin as and the scrotum and penis may shrink. Sex accessory
part of their HRT. Some recommend “natural” proges- structures, such as the seminal vesicles and other glands,
terone derived from a progesterone building block in may become reduced in size. There is also a decline in
plants such as the wild yam. muscle mass and strength, and osteoporosis can begin.
Often women choose other remedies besides ERT for Men over 70 who are sexually active have higher blood
menopausal symptoms. Factors that reduce the risk of testosterone levels than those abstaining from sex, but it
osteoporosis include weight-bearing exercise as well as is not clear if the high levels in these men increased their
prescription drugs that inhibit bone breakdown, such as sexual motivation or if their sexual activity increased
calcitonin, etidronate sodium, and alendronate. Calcium their testosterone levels.
supplements appear to help, especially later on in post- The term andropause has been criticized because
menopausal years and when accompanied by weight- androgen production does not cease and normally
bearing exercise. The National Institutes of Health declines very slowly. Some have suggested that the con-
recommend 1000–1500 mg per day of calcium for post- stellation of symptoms resulting from lower androgen
menopausal women and 1000 mg per day for women aged levels in older men be renamed ADAM (androgen defi-
25 to 50. These calcium requirements can be obtained by ciency in the aging male). However, age-related changes
diet (about 400 mg per day, excluding dairy products) or in males also include reductions in other hormones such
calcium supplements, but a caution is that greater than as DHEA, growth hormone, insulin-like growth factor-I,
2000 mg per day can cause kidney damage. Potassium and melatonin.
bicarbonate taken orally has been shown to decrease The reduction in sex hormones in men is gradual. It
bone loss. Natural foods also contain hormones that may is estimated that male testosterone levels typically drop
slightly alleviate menopausal symptoms. Many of these 0.8% per year after age 40. However, this relatively small
contain small amounts of phytoestrogens (Chapter 2); decrease may underestimate the physiological effects
examples include soy products. Wild yam root also of testosterone reduction during aging. Because levels

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Summary 129
of steroid-binding proteins in the blood of older men potential risks are well understood. One of the concerns
increase by 1.6% per year, bioavailable testosterone drops to be addressed is the possibility that ART could increase
by 2% per year. One study found that 30% of men aged the risk of prostate cancer or exacerbate existing (possibly
60–70 and 70% of men aged 70–80 have low bioavail- undiagnosed) prostate cancer.
able testosterone. A primary cause of lowered testoster- The trend toward delaying marriage and childbearing
one appears to be a decrease in the ability of the testes means that men, like women, are increasingly seeking to
to respond to pituitary gonadotropins. There is also a reproduce at a later age. Although men do not experi-
reduction in the number of Leydig cells in the ­testes that ence an inevitable final end to reproductive functioning
produce testosterone. Men who are chronically ill, obese, like women do, their fertility often declines gradually
take prescription medications, or drink alcohol exces- after about age 40. Increased paternal age (above age 40)
sively have lower average testosterone levels than found also increases the risk for miscarriage. In addition, older
in healthy older men. In some older men, lower blood fathers have a higher risk of having children with neu-
levels of testosterone cause a decrease in negative feed- rological disorders, especially autism spectrum disorder
back of testosterone on LH secretion, resulting in higher and schizophrenia. This well-documented association
LH levels. Reduced inhibin production by the Sertoli may be explained by an increase in the rate of small
cells results in a rise in circulating FSH levels. Blood lev- mutations in the sperm of older men. A recent study of
els of estrogens also rise in older men. The testes may be Icelandic families analyzed the number of small muta-
less functional because their blood supply is, for some tions in the DNA of children with and without autism;
unknown reason, reduced. The seminiferous tubules these new mutations were not inherited from either of
show damage in some older men, and semen volume, as their parents. Children of older fathers tended to have
well as sperm motility and percent normal morphology, more of these de novo mutations. It was estimated that,
decrease with age. However, there is wide variation in on average, newborns have 60 spontaneous small muta-
the fertility of individual males, and some men continue tions. Surprisingly, the number of mutations is strongly
to be fertile into very old age. dependent on paternal age. At age 20, a father trans-
Treatment of older men with an androgen (androgen mits about 25 mutations to his offspring; this increases
replacement therapy; ART), along with short-term psycho- to 65 mutations when the father is 40. Thus, each addi-
logical counseling, may reverse some of the symptoms tional year of paternal age loads on two new mutations.
associated with the reduction in testosterone secretion. (In comparison, mothers transmit about 15 mutations
Testosterone can be given as an injection, but the rapid regardless of their age. These small mutations con-
increase in circulating levels of the hormone could have trast with the more major chromosomal errors such as
adverse side effects. Thus, testosterone is usually given trisomies, which clearly increase with maternal age.
as a skin patch or a topical gel. Another androgen, DHEA Although most small mutations are harmless, any del-
(see Chapter 4), is also popular as a nonprescription eterious mutations would be especially likely to affect
remedy for andropause. neurological functioning, as brain development extends
Studies indicate that ART can protect against osteopo- over a long period of time and more genes are expressed
rosis in older men. One study showed that testosterone in the brain than in any other organ. Of course, many
increases bone density in the lower spine by about 10% older fathers have perfectly healthy children, but young
and in the hip by at least 2%. As an additional protec- men who plan to delay fatherhood until their forties or
tion against osteoporosis in men, the National Institutes fifties may want to store their sperm for later use!
of Health recommends a calcium intake (through diet
or calcium supplements) of 1000 mg daily for men aged
25–65 and 1000–1500 mg daily for men over 65, not to SUMMARY
exceed 2000 mg/day. Weight-bearing exercise can assist
these other therapies. Menopause occurs as menstrual cycles cease when a
The use of ART in older men has been shown to increase woman reaches 45–55 years of age. At this time, ovar-
muscle mass and decrease body fat. In younger men with ian function declines, resulting in a syndrome of physi-
decreased testosterone due to testicular cancer or injury, cal changes. Menopause is preceded by perimenopause,
ART can cause the secondary sex characteristics and sex a stage of gradual loss of ovarian function, which lasts
accessory structures to return to their normal condition. In about four years. In addition to loss of fertility, symp-
addition, sex drive and the ability to have an erection often toms of menopause include hot flashes, sleep distur-
improve in these men. It is not yet clear, however, whether bances, weight gain, and loss of bone mineralization.
ART can significantly improve energy, sex drive, ­sexual Other changes in female physiology during this time
function, or depression in older men. More research is may be caused by menopause or by the aging process.
needed to examine the effects of hormone replacement in Endocrine changes during menopause include an early
older men; currently neither the potential benefits nor the drop in AMH and inhibin, followed by increases in FSH

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
130 7. REPRODUCTIVE AGING

BOX 7.2

T H E E V O L U T I O N O F M E N O PAU S E I N H U M A N S
Human females are unique among mammals in that ­ owever, risking death during childbirth might jeop-
H
the ovaries stop functioning after about 50 years, at meno- ardize the well-being of her existing older children by
pause, which is often followed by a long postreproductive abruptly ending her continuing care of them. The increas-
life. Only a very few other mammals undergo menopause ing possibility of unsuccessful pregnancies or nursing
(e.g. the short-finned pilot whale, the African elephant, and difficulties in older mothers would also drain important
African chimpanzee). There are two general ideas about maternal resources. The trade-off may favor nurturing her
the presence of menopause in humans: (1) it is a deleteri- existing children and foregoing additional pregnancies.
ous effect of civilization or (2) it is an adaptive trait in our A third adaptive a­ dvantage of menopause is related to this
species that evolved under the forces of natural selection. concept. The idea is that older females could contribute
The idea that menopause is a deleterious condition is more of their genes to the population by investing their
­inspired by the fact that the risk of some life-threatening behavioral energy in kin, especially their grandchildren.
disorders such as breast cancer, osteoporosis, and cardio- This would have been their “best” evolutionary choice at
vascular disease increases markedly after menopause, an older age. This is called the grandmother hypothesis and
when the ovaries stop producing estrogen. This theory is currently the most prevalent hypothesis about the evo-
says that menopause is a condition of civilization result- lution of human menopause. Older women who help their
ing from the increase in life expectancy, which in turn is children care for their own offspring would allow their
caused by better sanitation, nutrition, and healthcare in the daughters (and perhaps daughters-in-law) to have more
­modern world. Implied is that our hunter-gatherer female children. This would increase a grandmother’s own evo-
ancestors died on average much earlier than the 50 years lutionary success. Grandmothers even today often care for
it would have taken for their ovaries to run out of follicles. their grandchildren and perform duties perhaps similar
Studies of the bones of our hunter-gatherer ancestors have in general to our hunter-gatherer ancestors, e.g. gathering
suggested that most did not live past their thirties, which food, patrolling against danger, assigning tasks, nurturing
supports the aforementioned theory. However, older skel- (holding and rocking), assessing, coaching, caretaking, and
etons do not preserve as well, and it is now believed from managing. Our ancestral grandmothers may have helped
studies of present hunter-gatherers that a short average their children, and therefore their grandchildren, by par-
life span does not mean that no postmenopausal women ticipating in foraging and hunting activities. In t­oday’s
were present. In fact, in present-day hunter-gatherers the modern world, they can watch the grandchildren while
life expectancy from birth averages in the thirties, but the their parents work. In this and other ways, g ­ randmothers
average life span for women who have already reached can assist in passing on their genes to future generations,
age 45 is 50–60. And this is an average, so there are many the measure of evolutionary success.
women who live past their seventies. The lower average What about older men? As you know, the reproduc-
life expectancy from birth is because many children die tive system of older men does not suddenly cease to func-
before age 15 in present hunter-gatherer cultures, so there tion as it does in women. Instead, andropause in men
probably were many women in our ancestors who were involves a slow, highly variable decline in sperm quality
postmenopausal, and menopause is not simply an artifact and quantity as well as plasma testosterone levels. Nev-
of prolonging life span in modern societies. ertheless, men of our hunter-gatherer ancestors probably
Instead, menopause may have evolved as an adaptive lived as long as women, and there must have been an age
trait in our species. What might be the adaptive a­ dvantage period when they could “help their genetic success” by
of menopause? First, it limits the ovulation of o ­ ocytes assisting in the care of their grandchildren through some
with chromosomal abnormalities, which increase with of the same activities as older women instead of going on
age in humans. This argument is challenged by the fact relatively unsuccessful hunts. In fact, this is so in present-
that most older mothers have genetically normal children day hunter-gatherer societies. Perhaps an additional im-
despite the increased risk of chromosomal ­errors. Second, portant role of elders of both sexes was as a repository of
menopause ensures that mothers are young enough to information critical to the survival of the group, such as
withstand the stresses of pregnancy, birth, and child care. how to survive a sporadic climatic event that may occur
One might a­ rgue that any chance to have additional off- only once a lifetime. So perhaps there should also be a
spring would increase a woman’s evolutionary success. “grandfather hypothesis.”

II. SEXUAL DIFFERENTIATION AND DEVELOPMENT
 Summary 131
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