Lect-11-6-24 Endoc1 PDF

Summary

This document is a set of lecture notes on neuroendocrine control, focusing on the brain-pituitary-gonadal axis and the stress-adrenal axis. The document also includes information on the hypothalamus-pituitary-gland axis and other related topics. These notes cover many topics related to the neuroendocrine system in the body.

Full Transcript

Lecture: Neuroendocrine Control I

The brain-pituitary-gonadal axis
Stress – adrenal axis
11/6/24

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F. Gomez-Pinilla, IBP, UCLA

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Hypothalamus-pituitary- gland axis

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 Hypothalamus-pituitary-gonad axis
Gonadotropin releasing hormone (GnRH) produced by
hypothalamic neurons stimulate production of
gonadotropins from ant. pituitary gonadotropes:
Luteinizing hormone (LH)
Follicle-stimulating hormone (FSH) Image result for GnRH

Activity of the axis varies during lifespan

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Hypogonadal (hpg) mice is an animal model to study the Kallmann’s Syndrome -
- genetic defect in GnRH production, but gonadal function can be restored in both
sexes with pusatile GnRH.
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 Circadian control of reproduction
Season is main factor in controlling reproduction in most mammal
Day length determines melatonin production
Melatonin production controls seasonal reproduction
ablation of SCN disrupts estrus cycle by affecting release of
GnRH from hypoth/pituitary
Melatonin affects the function and size of gonads

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Photoperiodicity regulates melatonin synthesis

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 Pulsatile stimulation of pituitary gonadotropes by
GnRH is crucial to maintain normal LH/FSH secretion:
Exposure of pituitary to continuous GnRH leads to
downregulation of GnRH receptors
Importance of a physiological frequency of GnRH pulses that
varies across age and circumstances
narrow window of acceptable frequencies to stimulate GnRH
without downregulation

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 Feedback control of GnRH release
Hypothalamic level; feedback regulation decreases pulse frequency of
GnRH and LH
Effects can be direct on GnRH neurons or indirect via brain regions that
project onto GnRH neurons using (GABA, catecholamines) or
endorphins (opiates).
Pituitary, Feedback (-) by estradiol and testosterone decrease LH pulses
by reducing sensitivity to GnRH
Inhibin is a glycoprotein produced by gonads that acts at the pituitary to
suppress FSH release
Ovarectomy (OVX) decreases synaptic input on GnRH neurons Image result for GnRH

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 Brain control of GnRH release

GnRH neurons receive connections from various brain regions within
and outside the hypothalamus
GnRH neurons receive cues regarding nutrition status, exercise,
thermogenesis, stress, social cues to coordinate reproduction timing
Just a small subset of GnRH neurons is necessary for normal function
of the axis. You can delete most of neurons and still have normal
pulsatile secretion of GnRH. The system is redundant, presumably to
preserve reproduction and protect species from going extinct.
Although most GnRH neurosecretory cells project to the median
eminence -- at least 20% of GnRH neurons send axons to other
hypothalamic regions, perhaps playing a role as a neurotransmitter or
in reproductive behaviors.

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 Factors causing alterations in ovarian function
Menopause: depletion of ovarian follicles -- loss of estrogen
production releases feedback (-) on hypoth (high LH/FSH).
Tissue damage (osteoporosis, cardiovascular disease)
Circadian, diurnal rhythms - testosterone (night), LH (day)
Environmental polymodal hypothalamic input, such as:
Seasonal, environmental adaptation signaled by day length
Nutritional factors, undernutrition can disrupt ovarian cycle or
spermatogenesis.
Extraneous exercise can disrupt ovarian cycle
Chronic stress acting at hypothalamic and pituitary levels can
suppress pulsatile release of GnRH and LH

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 Stress and loss of homeostasis

Hans Selye (1907-1982)
Coined a word from
Physics STRESS to
describe the non-specific
response of body to any
demand

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 STRESS: Adaptive response to noxious stimuli, e.g.,
disease, fever, psychological
 Fight or Flight Reaction

Short latency response
Heart acceleration
Increase in blood pressure
Dilation of blood vessels in skeletal
muscle
Constriction of blood vessels in GI
tract and skin
Pupil dilation
Sweating
 Factors affecting stress response

Food deprivation
Sleep deprivation
Emotions
Exercise
Heat or Fever
Cold or hypothermia
Anesthetics

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Hypothalamus-pituitary-adrenal axis

Medial parvicellular part of PVN releases
corticotropin-releasing hormone (CRH) to portal
vessels to stimulate release of adrenocorticotropic
hormone (ACTH) from anterior lobe cells. ACTH
stimulates the adrenal cortex to secrete
glucocorticoids
Corticotropes in anterior Pituitary express receptors
for CRH and AVP, and release ACTH
 ACTH reaches the adrenal cortex and
stimulates synthesis and release of
glucocorticoids

Adrenal gland Releases Stress Mediators
Adrenal cortex:
Glucocorticoids such as cortisol in humans (corticosterone in rodents, glucose metabolism)
Mineralocorticoids such as aldosterone (renin-angiotensin system) regulate sodium and
potassium balance.

Adrenal medulla (innervated by SNS): innermost part of adrenal gland, releases catecholamines
to blood (epinephrine and norepinephrine) and can potentiate the stress response.
 Glucocorticoid (cortisol/corticosterone)
functions
Acts in coordination with the ANS to mobilize energy
and prepare the body for defense
Cardiovascular system (elevates heart rate and blood
pressure)
Mobilize energy: Enhances breakdown of glycogen
(glycogenolysis), allows glycogen utilization in liver,
lungs, and adrenal medulla.
Enhances synthesis of glucose from precursors
(gluconeogenesis)
Decreases uptake of glucose by secondary tissues
Modulate immune function by regulating cytokine
production and inflammatory response
Interact with hormones of other systems: thyroid,
growth, reproduction

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 Feedback inhibition of the CRH axis by
corticosteroids

Can occur at multiple levels to turn
off stress response:
– Hypothalamic (inhibits CRH)
– pituitary (inhibits ACTH)
– Adrenal (local inhibition)

– fast regulation by ACTH
secretion (minutes to shut off
stress axis)
 feedback regulation of stress
Negative feedback of glucocorticoids on the axis:
Adrenal ablation (ADX) increases CRH and AVP
in mpPVN
Hippocampal lesion increases levels of
glucocorticoids

Glucocorticoids activates neurons with steroid
receptors (GR, MR) in PVN neurons. GR are
throughout the brain -- what are the
implications for the action/regulation of stress?

Mineralocorticoid receptor (MR) and
glucocorticoid (GR) recognize cortisol, and are
highly expressed in the hippocampus (Sapolsky,
McEwen).

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 Receptors mediating stress are almost everywhere -
-IMPLICATIONS??
CRH receptors found in brain (primarily cerebellum, cerebral cortex,
olfactory bulb, striatum, spinal cord, hippocampus, hypothalamus,
thalamus, pons) and outside the brain (adrenal gland, placenta, ovaries,
immune tissues)
Glucocorticoid receptors (GR) are widespread in the CNS, most
abundant in hippocampus and hypothalamus, in addition to cerebral
cortex, amygdala, septum, thalamus, midbrain, raphe nuclei,
cerebellum, brain stem.

ACTH receptor derives proopiomelanocortin (POMC). It is primarily
expressed in the adrenal cortex. This conversion is an important site
for stress regulation such as beta-endorphin.

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 Rhythmic activity of brain-pituitary adrenal axis

7 am 7 pm 12
ACTH
glucocorticoids

CRH

most sensitive to stress
Timing Context

Stress hormones exhibit both pulsatile and circadian cycles
Glucocorticoids levels are highest by awakening and lowest by end of the day (different
patterns depending on if nocturnal or not).
The system is more sensitive to stress during resting

CRH expression in PVN is regulated by the suprachiamatic nucleus (SCN) and food
intake.
 Stress affects learning and memory
Most of our learning is emotional!!
Abundance of GR and MR in hippocampus
Learning is motivated by stressful or aversive stimuli such as attention and
arousal.
ACTH injection before or shortly after a learning situation enhances
memory
Acute stress (inescapable) interferes with instrumental learning. Gain of
control reverses effect and may enhance learning
Reduced learning capacity in aging has been associated to chronic stress
(too much glucocorticoids)?
“Stress system is an active monitoring system that constantly compares
current events to past experiences, interprets their relevance for survival,
determines ability to cope with new events, and recruits physiological
mechanisms as needed”
Stress not just an alarm system!!

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 Too much or too little glucocorticoids can
damage the brain
Chronic excess of glucocorticoid can damage hippocampal CA3 cells;
however:
Lack of glucocorticoids may damage hippocampal dentate gyrus cells.

Circulating corticosteroids affect fetal development.
Early development of the brain-pituitary adrenal axis. Prenatal stress produces
physical and behavioral alterations
Neonatal stress (maternal separation) affects adult behavior and brain
plasticity.

Adrenal dysregulation by reduction of MR and GR in hippocampus in aging
reduces feedback. High levels of glucocorticoids due to reduced feedback can
deteriorate hippocampal neurons -- spatial memory problems

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Health consequences of disruptions in stress homeostasis
Hyper-activation
Alzheimer’s: loss of neurons involved in feedback as well as adrenal
dysfunction
Mental Illness: anxiety and depression
Inflammation
Susceptibility to infection, tumors, autoimmune disease
Insulin-resistant diabetes (commonly associated with hypercortisolism)

Hypo-activation (under-activity): increased susceptibility to
autoimmune disease and inflammation

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 Image result for addison disease

Addison’s disease: under activity of
stress axis. Low glucocorticoids.
fatigue, muscle weakness,
psychological

Image result for cushing disease

Cushing’s Disease: oversecretion of
cortisol. High level of cortisol
suppress release of CRH. immune
compromise, increase in appetite,
type II diabetes risk, high blood
pressure and changes in fat
distribution
 Development of adrenal gland

Adrenal gland develops 20-25 days of age
Ant Pituitary activity starts 7-8 weeks
CRH 16th week.
Diurnal rhythm Not established until 6 months postnatal, although
HPA axis matures early
Babies are highly susceptible to stress

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 Impact of cortisol during pregnancy

Cortisol levels are high during pregnancy and (during parturition ) and
play an important role in developing of the fetus
Steroids easily cross placenta
Pregnant women under high stress have higher incidence of babies with
physical, developmental and behavioral problems (underweight,
eczema, bronchitis, delay in walking or talking)

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 Stress good or bad?
“Stress system is an active monitoring system that determines ability to cope with new
events, and recruits physiological mechanisms as needed”

It seems that some stress may be good: helps insulin signaling,
and release of glucose to produce energy (ATP)
Experiments in animals have shown that mild postnatal stress
makes animal less anxious when they become adult
In general, mild stress is an important stimulus to enhance
brain plasticity and health (what does not kill you can make
you stronger)

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