The stress axis

Question 1

What is the function of the hypothalamus?

Answer 1

Ancient, conserved, central regulator of homeostasis

Question 2

What are the main nuclei in the hypothalamus?

Answer 2

Paraventricular nucleus (PVN)

Arcuate nucleus (Arc)

Ventromedial nucleus (VMN)

Question 3

Where do the neurons in the Arc and VMN nuclei develop from?

Answer 3

Progenitors that either:

1) Transiently express shh
2) Respond to shh

Question 4

What neurons are in the Arc nucleus?

What do these neurons do?

Answer 4

PomC+ neurons

Make precursor protein (Pomc) that is made into many hormones - some that impact on CRH
–> Makes ATCH

Question 5

What neurons are in the VMN?

What do these neurons do?

Answer 5

SF1+ neurons

Help to regulate the maturation of steroidal hormones –> form active hormones

Question 6

Where do the neurons in the PVN develop from?

What neurons are born in the PVN?

Answer 6

EARLY where Shh is REPRESSED in progenitors

CRH/CRF neurons

Question 7

What is useful about the hypothalamus in simpler vertebrates?

Answer 7

SAME organisation of hypothalamus and the SAME neurons in the SAME nuclei SAME neurotransmitters and neurohormones

Can investigate problems happening in humans

Question 8

Why need very high numbers of model organisms to do behavioural work?

Why is the zebrafish a good model for the hypothalamus?

Answer 8

Many VARIABLES in behaviour

Zebrafish - good model can link genetics to behaviour (screen MANY fish)

Question 9

What neurons are important in the production of the stress hormone and therefore the regulation of stress?

Answer 9

• Pomc neurons (arc)
• SF1 neurons (VMN)
• CRH neurons (PVN)

Question 10

Where do the CRH neurons project to?

What happens here?

Answer 10

Medial eminence

HPA axis:
1) End feet release CRH - taken up by the portal capillaries –> pituitary gland

2) In PG - regulates an endocrine cell –> release ACTH (adrenocorticotrophic hormone)
3) ACTH acts on the ADRENAL GLANDS –> release cortisol

Question 11

What are the CRH neurons responsible for?

Answer 11

CRH released in response to stress

Question 12

What is the main stress hormone?

Where is it released from?

Answer 12

Cortisol

Released from the adrenal gland when stimulated by ACTH

Question 13

What is the DISC1 gene?

Results of this gene?

Answer 13

Deleted in Schizophrenia 1

High risk of mental illness

Question 14

When was DISC1 identified?

Answer 14

Through genetic analysis of an inbred family with high-risk of mental problems:
- Each sibling/cousin had inherited a copy of the allele where this gene was deleted

Question 15

What is the first question must ask if there is a phenotype resulting from a deleted gene?

Answer 15

WHERE is the gene NORMALLY expressed?

WHY lack of function –> mental illness

Question 16

Where is DISC1 normally expressed?

How can see this?

Answer 16

Normally in the hypothalamus, with expression overlapping with cells expressing Fgf+ and Shh+ (early progenitors)

SPECIFIC to the hypoT - not in the rest of the body

Seen in zebrafish using IN SITU HYBRIDISATION

Question 17

Why is it hard to determine what the DISC1 protein does?

Answer 17

Likely to interact with many proteins due to its structure:

• Large protein
• Globular domain at N terminus
• Alpha-helix domain
• Coiled coil domains

Question 18

How was a disease model of DISC1 created in the zebrafish?

Answer 18

Create 2 lines of zebrafish mutants (with different point mutation in the globular domain - N terminus)

Fish are homozygous viable but DO NOT make the DISC1 mRNA/protein

Question 19

Why were 2 zebrafish transgenic lines made in the disease model for DISC1?

Answer 19

To increase confidence in results

Question 20

How are the WT and DISC1 mutant fish different to each other?

How can this been seen?

Answer 20

DISC1 mutants:
- Not as many progenitors and progenitors differentiate PREMATURELY (Interferes with the balance of stem/progenitor/differentiated cells)

• Hypothalamic neurons (especially ones involved in stress regulation) differentiate abnormally

Seen using ISH of zebrafish mutants/WT

Question 21

How does DISC1 interfere with progenitor levels?

Answer 21

We are not sure

Question 22

How do the hypothalamic neurons of the zebrafish DISC1 mutant differentiate abnormally?

Answer 22

Pomc+ (Arc) neurons REDUCED

Sf1+ (VMN) neurons INCREASED

Crh+ (PVN) neurons INCREASED

Question 23

What do the differences between the WT and the DISC1 mutant fish show?

Answer 23

Imbalance in early progenitors has a KNOCK-ON effect and leads to the ABERRANT DIFFERENTIATION of HYPOTHALAMIC NEURONS that are involved in STRESS REGULATION

Question 24

How can we measure an output to see if the difference in neurons has an impact on the physiology and/or behaviour of the fish?

Answer 24

1) Behavioural analysis

2) Assays - look at endocrine function

Question 25

What is the normal neuroendocrine function?

Answer 25

Upregulation of neurohormones and cortisol after stress

Question 26

How is the behaviour of the fish assayed?

Answer 26

With response to Shreckstoff or increased NaCl concentraion

Question 27

What is Shreckstoff?

Answer 27

Pheramone released from damaged fish (eg. by predator) to warn other fish

Causes a stress response in the receiving fish

Question 28

What happens to the behaviour of the fish when they are stressed?

Answer 28

Turn around and swim away quickly and erratically

Question 29

Why does NaCl evoke a stress response in zebrafish?

Answer 29

Zebrafish from the Ganges (close to the sea - zebrafish don’t survive in the sea)

Sea - higher salt conc

When detect higher salt conc, zebrafish turn around and swim away

Question 30

What is different about the stress response in WT and DISC1 mutant zebrafish?

Answer 30

DISC1 mutant - no stress response

Question 31

What is different about the neuroendocrine function in WT and DISC1 mutant zebrafish?

Answer 31

In the WT - increase in cortisol and ff1b (sf1)

In the mutant - no increase

Question 32

How can determine neuroendocrine function in zebrafish?

Answer 32

Expose to stress factor

Kill fish and extract cortisol to measure the levels

Question 33

Why is it important to test both behaviour and endocrine function of the fish?

Answer 33

Test things in different ways:

Same result –> more believable outcome

Question 34

What does cortisol do?

Why?

Answer 34

Triggers a feedback loop that down regulates the stress response

Hypothalamus works through systems that let you know when deviating away from the optimum set point

Question 35

Why is it important to have oscillations in levels in early life?

How may this be altered in humans with DISC1 mutant?

Answer 35

To be able to understand where the MEDIAL LEVEL is

May be altered in DISC1 mutant humans: may noe be able to set up optimal set point –> Knock on effect in ability to process info in a way that is not stressful

Question 36

How do we think DISC1 works in humans?

Answer 36

Effects the cells in the stress circuit and their differentiation –> crucial for the regulation of normal cortisol and behaviour

Question 37

What is the stress axis AKA?

What is this modulated by and how?

Answer 37

The hypothalamus pituitary adrenal axis

Modulated by emotional responses as:
- Emotional responses modulate the ANS, that is responsible for the fight/flight response

• Fight/flight response carried out by the HPAA

Question 38

Describe the stress axis

Answer 38

…

Question 39

What is the function of CRH from the PVN in stress?

Answer 39

1) Released from the endfeet of CRH+ neurons in the PVN onto portal capillary
2) Portal capillary –> corticotroph cell in the pituitary gland
3) Corticotroph releases ATCH into GENERAL CIRCULATION

Question 40

What is the role of ACTH

Answer 40

Made from POMC precursor
Released from corticotroph in the pituitary gland

–> Adrenal gland to stimulate the release of the stress hormone CORTISOL

Question 41

What does cortiso do when released from the adrenal gland?

Answer 41

Acts on cells to produce a coordinated response (eg. run away)

Acts on the hypothalamus in a NEGATIVE FEEDBACK mechanism –> Return to baseline optimal level