L3: Reproductive Endocrinology

Question 1

Which are the water soluble reproductive hormones?

Answer 1

Peptides and proteins:
- Gonadotrophin releasing hormone (GnRH)
- Follicle stimulating hormone (FSH)
- Luteinising hormone (LH)
- Prolactin
- Oxytocin
- Anti-Mullerian hormone
- inhibins/activins

Question 2

What is the site of secretion of GnRH?

Answer 2

Hypothalamus

Question 3

What is the site of secretion of FSH?

Answer 3

Anterior pituitary

Question 4

What is the site of secretion of LH?

Answer 4

Anterior pituitary

Question 5

What is the site of secretion of prolactin?

Answer 5

Anterior pituitary

Question 6

What is the site of secretion of oxytocin?

Answer 6

Posterior pituitary

Question 7

What is the site of secretion of anti-Mullerian hormone?

Answer 7

Ovary

Question 8

Which are the lipid soluble reproductive hormones?

Answer 8

Steroid hormones:
- androgens (testosterone, 5alphaDHT)
- Oestrogens (oestradiol, oestriol, oestrone)
- progestagens (progesterone)

Question 9

What is 5alphaDHT?

Answer 9

Converted from testosterone, much more potent

Question 10

What are the different oestrogens and when are they expressed?

Answer 10

• oestradiol during reproductive age
• oestriol and oestrone is post-menopausal

Question 11

What is the site of secretion of androgens?

Answer 11

testes

Question 12

What is the site of secretion of oestrogens?

Answer 12

ovary

Question 13

What is the site of secretion of progestagens?

Answer 13

ovary

Question 14

What is the mechanism of action of water soluble hormone transport?

Answer 14

1. Binding of hormone (first messenger) to its receptors activates G proteins, which activate adenylate cyclase
2. activated adenylate cyclase converts ATP to cAMP
3. cAMP serves as a second messenger to activate protein kinases
4. activated protein kinases phosphorylate other enzymes
5. millions of phosphorylated enzymes catalyze reactions that produce physiological reactions that produce physiological responses
6. phosphodiesterase inactivates cAMP

water soluble hormones travel freely around the blood; they cannot diffuse through the membrane so they work through GPCRs

SEE L3, SLIDE 5 for diagram

Question 15

What is the mechanism of action of lipid soluble hormone transport?

Answer 15

1. lipid-soluble hormone diffuses into cell
2. activated receptor-hormone complex alters gene expression in the nucleus
3. newly formed mRNA directs synthesis of specific proteins on ribosomes
4. new proteins alter cell’s activity

hydrophobic, so diffuse through the membrane, don’t travel in blood freely, need transport proteins; acts as transcription factors
SEE L3, SLIDE 5 for diagram

Question 16

What is the action of gonadotropins in males?

Answer 16

• LH and FSH travels down from pituitary.
• FSH mainly acts on Sertoli cells (support maturation of sperm), within seminiferous tubules.
• Leydig cells are found in the interstitial space between the seminiferous tubules and they are hormonal cells. Produces testosterone under the influence of LH.

SEE L3, SLIDE 6 for diagram

Question 17

What is the action of gonadotropins in females?

Answer 17

• FSH primary works on granulosa cells, stimulates production of oestradiol.
• Androstenedione (essential enzyme for production of oestradiol) comes from theca cells, and it’s made under the influence of LH.
• Two-cell – two-gonadotropin hypothesis.

OR

• LH acts on theca, produces androstenedione
• FSH acts on granulosa, which converts androstenedione to oestradiol
  SEE L3, SLIDE 7 for diagram

Question 18

What are the examples of steroid hormones?

Answer 18

Testosterone, 5-alpha-dihydrotestosterone, oestradiol, progesterone

Question 19

What do testosterone and 5alpha-dihydrotestosterone regulate?

Answer 19

• Male reproductive function (e.g. spermatogenesis, prostate secretions)
• Secondary male characteristics (e.g. anabolic (muscle build), facial and body hair, deep voice, libido, aggression) (in females with higher levels of testosterone, similar characteristics can be seen)
• Male sex determination and genital development

Question 20

What does oestradiol regulate?

Answer 20

• Endometrial proliferation during menstrual cycle (thickens the endometrium)
• Female genital development
• Secondary female sex characteristics (e.g. breast development, body fat distribution, bone (epiphyseal closure; that’s why women stop growing in height))

Question 21

What does progesterone regulate?

Answer 21

• progesterone prepares for pregnancy
• Endometrial secretion and vascularization during menstrual cycle (prepare uterus for pregnancy)
• Maintain pregnancy and support embryo

Question 22

What is hormonal contraception?

Answer 22

Manipulation of steroid gonadal hormones

Question 23

How does hormonal contraception work in females?

Answer 23

• suppress ovulation via negative feedback of progesterone
• oestrogen in combined pill provides additional feedback and promotes progesterone receptor expression (supports effects of progesterone)
• secondary effects on female genital tract (e.g. maintain endometrium in thin state; progesterone is able to thicken cervical mucus, acts as a plug, so sperm cannot enter; can make uterine environment not hospitable for sperm)

Question 24

How does hormonal contraception work in males?

Answer 24

• suppress spermatogenesis via negative feedback of testosterone
• progesterone used in combination with testosterone
• development has been slow due to lack long-lasting testosterone preparations

Question 25

What is the mechanism of action of negative feedback in HPG axis?

Answer 25

• hypothalamus releases GnRH which acts on pituitary gland
• pituitary gland releases FSH and LH which acts on ovaries and testes
• ovaries release oestrogens and progesterones which inhibit the action of hypothalamus and pituitary gland
• testes release androgens which inhibit the action of hypothalamus and pituitary gland

SEE L3, SLIDE 10 for diagram

Question 26

What is the function of activins in positive feedback in HPG axis?

Answer 26

Hormone produced by Sertoli cells and granulosa cells which encourages FSH secretion from anterior pituitary (semi-positive feedback loop)

Question 27

What are the examples of positive feedback in HPG axis?

Answer 27

• Main point where it’s seen is ovulation: as follicle grows it produces more oestrogen (negative –> positive). At a certain threshold, its effect reverses. It now has a positive effect on FSH secretion and causes LH surge, it’s still not fully known why)
• Another example (where it’s not really sure if it’s positive feedback or not: when females get potential blastocyst made. If fertilization occurs, blastocyst is made, it implants, then starts to make hCG (LH analogue). hCG has ability to bind on LH receptors, mainly on corpus luteum, thus CL does not regress. As CL is maintained then progesterone levels are also maintained. Progesterone then keeps the blastocyst healthy, until placenta takes over.

Question 28

What is the general function of prolactin and oxytocin?

Answer 28

lactation

Question 29

How are prolactin and oxytocin released?

Answer 29

suckling sends nerve impulses to brain –> release of prolactin (anterior pituitary) and oxytocin (posterior pituitary)

Question 30

How does prolactin act?

Answer 30

alveoli swell and secrete milk

Question 31

What prevents milk secretion prior to birth?

Answer 31

steroid block at placenta; because of the high levels of steroid hormones from the placenta during pregnancy –> it’s hard for a pregnant woman to breastfeed

Question 32

What are the effects of oxytocin?

Answer 32

Oxytocin has major effects on smooth muscle contraction:
- myoepithelial cell contraction around alveoli causing milk expulsion (milk ejection reflex)
- also used to induce labour (effects on uterine smooth muscle)
- also known as love/cuddle hormone, released during orgasm  peer bonding

Question 33

What is the function of anti-Mullerian hormone?

Answer 33

• critical for sex determination in male embryos
• and for female primordial follicles pause

Question 34

How is anti-Mullerian hormone activated in males?

Answer 34

activated by SOX9 in Sertoli cells

Question 35

How does anti-Mullerian hormone act in males?

Answer 35

Inhibits development of Mullerian ducts (fallopian tubes, upper vagina, uterus)

Question 36

How does anti-Mullerian hormone act in females?

Answer 36

• Made by granulosa cells from primary stage onwards
• Inhibitory effect on follicle development (as the ovary has more and more follicles produced, it produces more AMH, then AMH can act on primordial follicle pool and can pause primordial follicle growth; no AMH receptors on follicles seen, so may be not a direct effect)
• Unaffected by gonadotropins/steroid hormones – used clinically for a reliable reflection of growing follicles (standalone hormone, not involved in feedback loops; doesn’t tell about quality, just the number of follicles)

Question 37

Where is GnRH synthesised?

Answer 37

Synthesised by hypothalamic GnRH neurons. Cell bodies in medial preoptic area and arcuate nucleus with projections to median eminence.

Question 38

Why is pulsatile release of GnRH into hypophyseal portal system important?

Answer 38

• prevents receptor desensitisation and downregulation
• surge prior to ovulation
• important for timing of puberty and menstrual cycle

Question 39

What are the effects of GnRH on FSH and LH?

Answer 39

FSH secretion more irregular than LH:
- The way it’s released means that GnRH has different effects on FSH and LH secretion – FSH secretion more irregular than LH.
- If GnRH is released really quickly it affects LH secretion, needed ovulation
- if it’s released slowly it affects FSH secretion. - When GnRH is removed from the system, LH levels drop really quickly, whereas FSH levels drop much more slowly.

Question 40

What is the importance of kisspeptin signalling pathway?

Answer 40

• essential for puberty, gonadotropin secretion and regulation of reproduction
• regulation of sexual and social behaviour, emotional brain processing, mood, audition, olfaction, metabolism, body composition and cardiac function

Question 41

What is the kisspeptin receptor? Where is it located?

Answer 41

KiSS1 receptor is a G-protein-coupled receptor located on KiSS neurons found in hypothalamus

Question 42

What is the key experimental evidence for kisspeptin signalling pathway?

Answer 42

• Cannot measure GnRH in circulation so LH is measured as a proxy (hard to measure, changes quickly)
• One experiment showed: Kisspeptin causes depolarization and increases firing rate of GnRH neurons, which shows that kisspeptin stimulates secretion of GnRH in hypothalamic explant cultures
• Then it’s observed that GnRH mRNA is up-regulated in GnRH neurons following kisspeptin exposure
• Some evidence suggests kisspeptin can directly stimulate pituitary gonadotropes to release LH/FSH but this is probably secondary
• Pubertal disorders in humans with KiSSR mutations
  i) Inactivating mutations – cause delayed puberty
  ii) Activating/missense mutations – precocious puberty (less common)

Question 43

What is the mechanism of action of kisspeptin signalling pathway?

Answer 43

A lot that is known about kisspeptin signalling comes from rodents, human studies slightly limited.
- There is differences of kisspeptin neuron locations in the brain between humans and rodents.
- There are two different types of kisspeptin neurons:
i) Kisspeptin neurons – just release kisspeptin
ii) KNDy neurone: not only releases kisspeptin, but also neurokinin B (NKB) and dynorphin (Dyn). Dynorphin and neurokinin can act on KNDy neurone to monitor kisspeptin output from those neurons
iii) It is believed that majority of the neurons in the brain are KNDy neurons.
- Essentially there is a pathway that ends up in sex steroids being produced, which then have the ability to act on KNDy neurons, as they have ERalpha and PR receptors

SEE L3, SLIDE 19

Question 44

What are the two types of kisspeptin neurons? What is the difference between them?

Answer 44

i) Kisspeptin neurons – just release kisspeptin
ii) KNDy neurone: not only releases kisspeptin, but also neurokinin B (NKB) and dynorphin (Dyn). Dynorphin and neurokinin can act on KNDy neurone to monitor kisspeptin output from those neurons
iii) It is believed that majority of the neurons in the brain are KNDy neurons.

Question 45

How are KISS neurons special?

Answer 45

KiSS neurons are special as they have ability to integrate signals from multiple hormonal paths from the body, take information through:
i) Adrenal gland – through secretion of cortisol, thus for example stress affects menstrual cycle
ii) Body fat – leptin – weight changes affect fertility
iii) Immune cell
iv) Environmental cues – shift work, airline industry

Question 46

What is the function of kisspeptin signalling in males?

Answer 46

• Kisspeptin drives LH secretion and testosterone production
• Testosterone is aromatized before binding to ERalpha on KiSS neurons
  i) Only female AVPV neurons can cause LH surge
  ii) Exposure to sex steroids in utero important in establishing neuron ‘gender’
• Physiological importance of kisspeptin effects on steroidogenesis and sperm function, and whether these are paracrine or endocrine manifestations, remain unclear – no pathways known

Question 47

In what disorders do high LH pulsatility states appear?

Answer 47

PCOS, precocious puberty, menopause

Question 48

In what disorders do low LH pulsatility states appear?

Answer 48

pubertal delay, hypothalamic ammenorrhoea, obesity/type 2 diabetes

Question 49

In what disorders do normal LH pulsatility states appear?

Answer 49

prostatic hypertrophy, endometriosis

Question 50

What is Hypogonadotropic hypogonadism?

Answer 50

Hypogonadism - gonads producing too little hormones
Hypogonadotropic - problem with pituitary or hypothalamus

Question 51

What is the indication of hypogonadotropic hypogonadism in newborn males?

Answer 51

Micropenis, cryptochidism

Question 52

What is the indication of hypogonadotropic hypogonadism in females?

Answer 52

delayed puberty

Question 53

What is hypogonadotropic hypogonadism caused by?

Answer 53

i) Structural lesion in pituitary/hypothalamus area (HPG axis off)
ii) Congenital (e.g. mutations in genes that affect GnRH (Calvin syndrome) neuron migration, effect GnRH and gonadotropin secretion)
iii) Acquired infections, trauma, drugs, tumours
iv) Functional (usually reversible; e.g. diet, over-exercise, stress)

Question 54

What is the treatment for hypogonadotropic hypogonadism?

Answer 54

HRT (need additional therapy to achieve pregnancy)

Question 55

What is the Polycystic ovarian syndrome?

Answer 55

Heterogenous condition, no equivalent in men; quite common 1/5 women

Question 56

How is PCOS diagnosed?

Answer 56

(need 2 out of 3 to diagnose); oligo/anovulation, evidence of hyperandrogenism, polycystic ovaries (when scanned – paused development of follicles seen, not actual cysts)

Question 57

What happens during PCOS?

Answer 57

• high LH/low FSH - imbalance
• increases androgen production from follicle
• excess androgens causes cystic ovaries (inhibits growth of larger follicles and encourages growth of smaller follicles)
• increased weight –> decreased SHBG (sex hormone-binding globulin)
• insulin augments theca cell androgen production
• vicious cycle between insulin and weight gain

Question 58

What is the management/treatment of PCOS?

Answer 58

• lifestyle changes
• metformin
• HRT

Question 59

What is Premature ovarian insufficiency?

Answer 59

characterised by depletion of follicles before age of 40 years - amenorrhea, hypoestrogenism and loss of fertility

Question 60

How is Premature ovarian insufficiency diagnosed?

Answer 60

• High LH,
• High FSH,
• low oestrogen

Question 61

What are the causes of Premature ovarian insufficiency?

Answer 61

• genetic
• iatrogenic
• autoimmune
• idiopathic (unknown)

Question 62

What is the treatment for Premature ovarian insufficiency?

Answer 62

HRT, however no treatment will allow pregnancy, only option is donor eggs/adoption