Hypothalamus and the control of energy balance

Question 1

When looking at the hypothalamus, what is widely used as an animal model?

How is this model used?

Answer 1

The mouse

Manipulate the genome
Dissect out the brain

Question 2

What did early lesion studies of the mouse brain show?

Answer 2

The hypothalamus regulates food intake (to regulate energy balance)

Question 3

What did lesions of the VMN lead to?
What did lesions of the lateral hypothalamus lead to?

What were the conclusions?

Why can these conclusions not be entirely trusted

Answer 3

VMN: Hyperphagia (over eating) and obesity
Lateral hypothalamus: Aphagia and starvation

Conclusion: Hypothalamus contains a ‘feeding centre’ and a ‘satiety center’

Not trusted: Lesion studies lead to damage of other parts of the hypothalamus

Question 4

What is satiety?

Answer 4

Feeling of being full

Question 5

What is the modern view of energy homeostasis?

What is central to this view?

Answer 5

INTEGRATED system:

Complicated sets of neurons in different nuclei of the hypothalamus operate TOGETHER to generate appropriate responses related to the bodies energy STATE/STORAGE

Central to this view:
- Some neurons in the Arc are activated in a ‘fasting’ situation and some in an ‘over-eaten’ situation (eg, feeding and satiety centres are the neurons that respond)

Question 6

In regards to food intake and energy balance, what does the hypothalamus respond and control? (modern)

Answer 6

The ENERGY STATE of the body:

• How much energy is STORED
• How much energy is CIRCULATING in the blood

Question 7

What signals is the hypothalamus sensitive to?

Answer 7

ADIPOSITY signals: hormones leptin and insulin (signals for energy)

Question 8

Where is leptin secreted from?

Answer 8

Adipose tissue (fat cells)

Question 9

Where is insulin secreted from?

Answer 9

The pancreas

Question 10

What neurons detect how much leptin is circulating in the body?

How?

Answer 10

Neurons of the Arc

Contain leptin receptors

Question 11

How do leptin and insulin signal to the hypothalamus?

Answer 11

Modulate neuronal activity in the Arc –> transduce hormonal signals into neuronal response

Question 12

How does leptin from the circulation reach the Arc?

Answer 12

Via 2 different types of tanycytes:

• Leptin to the blood-hypothalamic interface
• Through tanycytes to the medial eminence
• Through other tanycytes to the Arc, where leptin binds to neurons with leptin receptors

Question 13

Where are the tanycytes and where do they project?

Answer 13

Line the 3rd ventricle and project to either:

• Nuclei of the hypothalamus (VMN, Arc)
• Medial eminence - contact the periphery where the blood-hypothalamic interface is (fenestrated capillaries)

Question 14

Where do neurons of the Arc project to?

Why?

Answer 14

To other neurons of the hypothalamus:
- PVN
- LMN
- LH 
To elicit local responses 

Or to the BRAINSTEM:
- Send neuronal signals back via efferent Vagus nerve to all necessary targets

Question 15

What do the neurons within the PVN do?

Answer 15

Make hormone releasing factors and project back to the medial eminence to the anterior pituitary to regulate hormone release

Question 16

What does the combined activity of all the neuronal targets that are signalled to by the Arc do?

How?

Answer 16

Elicits a FEEDBACK SYSTEM to the body –> to respond to the leptin trigger event

To control food intake and energy expenditure through neuronal and hormonal signals that regulate:

• BEHAVIOUR
• AUTONOMIC ACTIVITY
• METABOLIC RATE

Question 17

Why is food intake only PART of how energy balance is maintained?

Answer 17

Energy balance is involved in behaviours,

Eg. stressed –> don’t eat, staying in bed

Question 18

What are the key neurons that act the antagonistic situations of ‘fasting’ and ‘over eating’?

Answer 18

Leptin responsive neurons in the Arc

Question 19

What signals do the neurons in the Arc respond to?

Answer 19

Short term: hungry vs full

Long term: fasting vs over-eating

Question 20

What are the 2 classes of neurons in the arc that are responsive to leptin (contain leptin receptors)?

Answer 20

1) Pomc

2) NPY

Question 21

How many Arc nuclei are there in the body?

Answer 21

2 - one on either side of the head

Question 22

Which Arc neurons are ACTIVATED by leptin/adiposity signals?

Answer 22

The POMC neurons

Question 23

Which Arc neurons are INHIBITED by leptin/adiposity signals?

Answer 23

The NPY neurons

Question 24

What do POMC neurons do?

What does this cause?

Answer 24

Release POMC:

Projects to neurons via local neuronal circuits and leads the brain to co-ordinate array of neuronal activities that REDUCES food intake and INCREASES energy expenditure (when full)

Question 25

What is POMC and NPY?

Answer 25

Neurohormones

Question 26

What do NPY neurons do?

What does this cause?

Answer 26

Release NPY:

Projects to neurons via local neuronal circuits and leads the brain to co-ordinate array of neuronal activities that INCREASES food intake and REDUCES energy expenditure (when hungry)

Question 27

What dictates the energy balance of the body?

Answer 27

BALANCE between the activities of POMC and NPY and their neuronal targets

Question 28

When active, what neurons do the NPY neurons activate/inhibit?

Answer 28

Inhibit the PVN

Activate the LH area

Question 29

When active, what neurons do the POMC neurons activate/inhibit?

Answer 29

Activate the PVN

Inhibit the LH area

Question 30

What is the action of the PVN?

Answer 30

When active - net CATABOLIC ACTION:

• Releases CRH and oxytocin
• Decreases food intake

Question 31

What is the action of the LH area?

Answer 31

When active - net ANABOLIC ACTION

• Releases orexin and MCH
• Stimulate food intake

Question 32

What are the NPY neurons also called?

Answer 32

AgRP neurons

Question 33

Describe the overall pathway of energy balance

Answer 33

1) TWO adiposity signals: LEPTIN and INSULIN - produced in the periphery and travel via TANYCYTES (x2) and the medial eminence to the ARC, where they influence NPY and POMC neurons

2) Different classes of Arc neurons are activated/inhibited due to the presence or absence of adiposity signals:
POMC - activated by adiposity signals
NPY - inhibited by adiposity signals

3) Arc neurons signals to the brainstem and different parts of the HyP (LH and PVN) activating them/inhibiting them to release hormones –> to control energy expenditure and food intake

Question 34

What are the POMC neurons also called?

Answer 34

a-MSH or CART neurons

Question 35

What pathway is the feeding pathway intimately linked with?

Answer 35

The stress pathway

Question 36

What are the melanocortin neurons?

Answer 36

POMC and AgRP (NPY) neurons

Question 37

What specifies the identity of hypothalamic melanocotin neurons?

What is this critical for?

Answer 37

Islet 1 (HD transcription factor)

Critical for NORMAL food intake and ADIPOSITY in adulthood

Question 38

What is adiposity?

Answer 38

The condition of being severely overweight

Question 39

What does Islet1 do?

How is this seen?

Answer 39

Prefigures and predicts the expression of POMC (ATCH)

Seen using:

1) An overlay of immunohistochemistry (antibodies) detection of Islet 1 (red) and ATCH (green) - where they are both present - see yellow in the EMBRYO
- Shows the nuclei express both Islet 1 and POMC

2) Combination of immunohistochem and a transgenic reporter line (pomc-EGFP) in the ADULT
- Show a number of the Islet1 cells are POMC+

Question 40

How is POMC related to ATCH?

Answer 40

ATCH is a peptide produced from the protein POMC

Question 41

Wha antibody recognises POMC neurons?

Answer 41

ATCH antibody

Question 42

What does the TF Islet1 bind to?

Answer 42

Critical homeodomain binding DNA motifs in the neuronal POMC enhancers nPE1 and nPE2

Question 43

How many enhancers drive the expression of the POMC gene?

What is needed for the expression of the POMC gene?

Answer 43

2 enhancers: nPE1 and nPE2

Both nPE1 and nPE2 enhancer activity is needed for upregulation

Question 44

How can it be proved that Islet1 is necessary to up regulate POMC?

Answer 44

Mutate the sequences within nPE1 and nPE2 –> see if Isl1 no longer recognises the DNA/no longer binds and poc is no longer upregulated

Question 45

In the study, how were nPE1 and nPE2 mutated?

How can the effect of these mutations be visualised?

Answer 45

Using POINT MUTATIONS:

- Transgenic animal with the point mutations in the enhancers and cross with a reporter animal (POMC-EGFP)

Question 46

What is seen in nPE1 and nPE2 mutants and WT?

Answer 46

WT (cross WT with reporter animal):

• Use reporter to look for the normal expression pattern of POMC –> normal
• Islet1 able to bind and POMC upregulated

MUTANTS:

• No green
• POMC not up regulated due to the failure of Islet1 to bind to enhancers

Question 47

What experiments must be done to answer if Islet1 is REQUIRED for POC neurons?

Why use this approach?

Answer 47

Make a CONDITIONAL KNOCK-OUT animal (where sequences encoding ISL1 are absent)

Why use this approach:
- Islet1 is required for vascular development - KO die very early in embryogenesis (even before Islet1 is expressed in the HyP)

• So, KO Islet1 at a later time point or in SPECIFIC tissue (after jobs in development)

Question 48

How can Islet1 be KO in a SPECIFIC STAGE of embryogenesis?

Answer 48

Using a CONDITIONAL KO and TAMOXIFEN

Question 49

What is the process of making a temporal conditional KO?

Answer 49

2 transgenic mice

MOUSE 1:
- Contains Cre –> when translated and transcribed recognises the loxP sites and cuts them - deleting the gene

• Cre fused to ERT2 (mutant estrogen ligand-binding domain that requires the presence of TAMOXIFEN to function –> CreERT (downstream of a general promoter)

MOUSE 2:
- Contains flanked Islet1 gene - loxP sites either side of exon2

BREED MICE and add tamoxifen at any stage in life –> recombine out exon 2 –> KO Islet1

Question 50

What is the critical exon of Islet1?

What occurs if this exon is deleted?

Answer 50

Exon 2

If deleted - aberrant Islet1 mRNA –> degraded/non-functional

Question 51

What does KO of islet 1 at E9.5 and E11.5 show?

Answer 51

Absence of POMC - Islet1 required for POMC

Question 52

What does conditional KO of islet1/Pomc show?

Why?

Answer 52

Early onset obesity

Normally:
- POMC INHIBITS food intake and increases energy expenditure - if not functional –> will not inhibit food intake –> obese

Question 53

How is Islet1 and the development of POMC neurons linked to the development of the hypothalamus?

Answer 53

Islet1+ progenitor cells that give rise to the POMC neurons differentiate from the anterior progenitors that differentiate from the Fgf10 expressing stem/progenitor cells

Question 54

What happens to the Fgf10+ cells in the hypothalamus?

Answer 54

They change over embryogenesis from neuroepithelial cells to radial glial like cells (tanycytes) and are maintained into adulthood as radial-glial like cells (tanycytes)

Continue to express Fgf10

SOME Fgf10+ expressing tancytes:
- Retain ‘stem like/progenitor cell activity’ and give rise to Arc neurons throughout life

Question 55

What are is the function of tanycytes that project to the ME and the Arc?

Answer 55

Allow the transport of leptin

Question 56

How do the Arc neurons continue to develop over adult life?

Answer 56

When hypothalamic tancytyes (radial glial like cell with cell body at the ventricle) divide - give rise to:
1) 1 daughter that stays at the ventricle - tanycyte

2) 1 daughter that takes neuronal fate and migrates up the tanycyte scaffold to the Arc - Arc neuron

Question 57

What happens to glucose (energy) requirements throughout life?

What does this mean?

Answer 57

They CHANGE

Need to alter the optimal set point of glucose in the body

Question 58

How does the hypothalamus change the optimal set points of glucose requirement?

Answer 58

EMERGING IDEA:
- NPY and POMC neurons can be generated from the hypothalamic stem cells (some Fgf10+ tanycytes) throughout life to ANTICIPATE and/or RESPOND to the changing needs of the body

Question 59

What is allostasis?

Answer 59

Idea that optimal set points change throughout life

Question 60

What is the working hypothesis about tanycyte stem cells?

Answer 60

Stimulated by metabolites/hormones provided by the components of the HYPOTHALAMIC NICHE –> and RESPOND to these signals

–> Giving rise to NEW NEURONS

(Respond to changes in energy needs)

Question 61

What is the hypothesis leading to T2D?

Answer 61

Loss of hypothalamic neurons/circuits/ loss of function –> key event that leads to T2D

Question 62

What do REPORTER LINES depend upon?

Answer 62

The fact that genes are DIFFERENTIALLY TRANSCRIBED as a function of the interaction of their PROMOTER/ENHANCER with CELL-SPECIFIC transcription factors/activators

Question 63

How are reporter lines made?

Answer 63

1) Fuse tissue specific promoter to the coding sequence of the gene that fluoresces when shine UV light on them

Eg. GFP (eGFP), Kaede - green
RFP, tomato - red

2) Make a transgenic animal in which this extra gene is stably incorporated into the genome

Mouse - Tg (promoter:flourescent gene)