| Scientists know that
stress boosts levels of stress hormones - glucocorticoids such as
cortisol - that inhibit the body's main sex hormone, gonadotropin
releasing hormone (GnRH), and subsequently suppresses sperm count,
ovulation and sexual activity. The new research
shows that stress also increases brain levels of a reproductive hormone
named gonadotropin-inhibitory hormone, or GnIH, discovered nine years
ago in birds and known to be present in humans and other mammals. This
small protein hormone, a so-called RFamide-related peptide (RFRP), puts
the brakes on reproduction by directly inhibiting GnRH.
The common thread appears to be the glucocorticoid
stress hormones, which not only suppress GnRH but boost the suppressor
GnIH - a double whammy for the reproductive system.
"We know stress affects the top-tier reproductive
hormone, GnRH, but we show, in fact, that stress also affects another
high-level hormone, GnIH, to cause reproductive dysfunction," said lead
author Elizabeth Kirby, a graduate student at UC Berkeley's Helen Wills
Neuroscience Institute. "This work provides a new target for
researchers, a new way to think about infertility and dysfunction. The
more we know, the more we can look for ways to treat it."
The results will be published the week of June 15 in
the Online Early Edition of the journal Proceedings of the National
Academy of Sciences (PNAS)
The conclusions are based on experiments in rats and
inferences from the effects of the hormone in birds. But if this new
reproductive hormone acts the same way in all mammals, researchers say
the finding could not only change the way physicians look at human
reproductive problems, but also affect how breeders approach animal
husbandry and captive breeding programs for endangered species.
"There is a growing body of work that points to GnIH
as being a big player in the inhibition of reproduction in mammals,"
said co-author George Bentley, UC Berkeley assistant professor of
integrative biology. "We didn't have any hint of this stress effect nine
years ago, when GnIH was first discovered."
In humans, chronic stress can lead to a drop in sex
drive as well as a drop in fertility. Even the stress of infertility
treatments can block their effectiveness, as evidenced by many anecdotes
about couples conceiving children after the failure of assisted
reproduction.
Animal breeding also is affected by stress. Zoos, in
particular, have difficulty getting some animals to reproduce in
captivity, Bentley said.
Based on animal experiments, researchers attribute
much of this stress effect on sexual function to an increase in
glucocorticoids - stress hormones - produced by the adrenal gland. In
the brain, these glucocorticoids suppress the main reproductive hormone,
GnRH, which in turn causes a shut-down of the release of the
gonadotropins luteinizing hormone and follicle-stimulating hormone by
the pituitary, and then a suppression of testosterone, estradiol and
sexual behavior.
In 2000, however, a new reproductive hormone was
discovered in birds and dubbed gonadotropin-inhibitory hormone (GnIH)
because it had the opposite effect of GnRH - it inhibited release of
gonadotropins, thereby suppressing reproduction.
"It's very adaptive to not be wasting resources on
reproduction during times of acute stress, to just shut down
reproduction for 24 hours or so until the stress is gone," said
co-author Daniela Kaufer, a UC Berkeley assistant professor of
integrative biology who looks at how stress affects molecular processes
in the brain. "These functions go back in evolution a long way."
Because of the negative effects of GnIH on
reproduction, Bentley, who helped establish the critical role played by
GnIH in birds, teamed up with Kaufer and Kirby to explore whether stress
might affect GnIH levels in the brain. The homologous hormones in
mammals have been dubbed RFamide-related peptides, or RFRPs.
Kirby showed that acutely stressed rats showed
increased RFRP levels for several hours, but that levels returned to
normal by the next day. Chronically stressed rats, however, were left
with longer-term elevations of RFRP levels in the dorsomedial
hypothalamus area of the brain, and suppression of activity in the
reproductive axis - the hypothalamus-pituitary-gonadal hormone cascade -
that is associated with lowered sexual activity.
"With chronic stress, glucocorticoids went sky high,"
Kirby said.
To determine the role of glucocorticoids, Kirby
removed the adrenal glands of male rats, eliminating the source of the
hormone. Without adrenals, stress no longer affected RFRP levels in the
brain. The researchers also showed that the cells that produce RFRP have
receptors for glucocorticoids, a clear indication that these stress
hormones can directly affect the cells that produce RFRP.
"Critically, we show that RFRP neurons express the
receptors for glucocorticoids, which are released from the adrenal
glands in response to stress, and that removal of the adrenal glands
prevents the stress-induced, up-regulation of RFRP," Bentley said.
"Thus, we believe we have identified an entirely novel pathway for
stress-induced reproductive dysfunction."
Kirby noted that adrenal hormones are critical to
survival, so removing the gland and thus glucocorticoids is not a
solution to chronic stress.
However, Kaufer said, it may be possible to block GnIH
to reduce some of the effects of stress on reproduction.
The researchers plan to confirm the results in female
rats and investigate further the role of GnIH in reproduction.
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