Insulin Signalling

Question 1

What receptors does insulin signalling involve?

Answer 1

Receptor tyrosine kinases

Question 2

What type of conditions do mutations in insulin signalling result in?

What function are these mutations involved with?

Answer 2

Inherited conditions

Not always involved with sugar metabolism - other functions too (especially growth)

Question 3

What are 3 conditions arising from mutations in insulin signalling?

Answer 3

1) Leprechaunism
2) Rabson-Mendenhall syndrome
3) Type A insulin resistance

Question 4

What is the phenotype of Leprechaunsim and what is the life expectancy?

Answer 4

• ‘elfin-like’ facial appearance
• Large hands and feet
• Decreased subcutaneous fat and muscle mass
• Skin abnormal
• Increased hair growth

Fatal within the first 2 years of life

Question 5

What is the phenotype of Rabson-Mendenhall syndrome and what is the life expectancy?

Answer 5

• Skin and teeth abnormalities
• Hair outgrowth
• Pineal hyperplasia

Survival into 2nd decade

Question 6

Where is insulin made?

Answer 6

In Beta cells of the Islets of Langerhans

Question 7

How is insulin made?

Answer 7

1) Synthesised as a short protein

2) Cleaved to a mature protein using proteases to remove the middle portion of protein

Question 8

What are the proteases which cleave the insulin protein?

Answer 8

PC2, PC3, endoproteases, carboxypeptidase

Question 9

Where are cysteine bridges formed and why can they form?

Answer 9

Present extracellularly

Cysteine have sulphur atom attached - oxidative environment of extracellular region allows disulphide bridges to form

Question 10

Why can cysteine bridges not form intracellularly?

Answer 10

The intracellular environment is reductive

Question 11

What ensures that the correct cysteine bridges form?

Answer 11

Enzymes in the ER

Question 12

What is the function of cysteine bridges in insulin?

Answer 12

Hold the 2 ends of insulin together, after the middle portion has been cleaved out

Question 13

What is the immediate effect of insulin?

Answer 13

Glucose uptake from the blood into muscle cells and adipocytes

Question 14

What happens when there is long-term exposure to insulin?

Answer 14

Effects on transcription:
- Increased expression of liver enzymes that synthesise glycogen

• Increased expression of adipocyte enzymes that synthesise triacylgylcerols
• Stores the energy of glucose

Question 15

What type of receptors is the insulin receptor?

Answer 15

RTK

Question 16

How are the alpha and beta subunits of the insulin receptor synthesised?

How does it create the different subunits?

Answer 16

As a single polypeptide

Cleaved into 2 fragments

Question 17

How is the insulin receptor different to canonical TK signalling?

Answer 17

Normal signaling involves phosphorylating many regions of the receptor to make docking sites for many different proteins

Insulin signalling - TK goes on to phosphorylate IRS which acts as the docking site, bound to the insulin receptor through a phosphorylated tyrosine

Question 18

How is IRS held to the insulin receptor?

Answer 18

• By its docking site through the PTB domain (phosphotyrosine binding domain)
• Recognises the phosphoylated tyrosine on the insulin receptor and neighbouring amino acids

Question 19

How is IRS held to the insulin receptor?

Answer 19

• By its docking site through the PTB domain (phosphotyrosine binding domain)
• Recognises the phosphoylated tyrosine on the insulin receptor and neighbouring amino acids

Question 20

What is the structure of PI-3 kinase?

Answer 20

2 subunits:

• P85 - containing the SH2 domain
• P110 (larger) - kinase

Question 21

What is phosphoinositol (PI)?

Answer 21

An intracellular molecule with a lipid anchor inserted into the membrane

Question 22

When PI is phosphorylated, what can it act as?

Answer 22

A docking site

Question 23

What happens to PI-3 kinase when insulin is bound to its receptor and why?

Answer 23

It is recruited to the membrane - binds to IRS which is phosphorylated by the insulin receptor

Question 24

What happens when PI-3 kinase binds to IRS?

Answer 24

Creates docking sites for protein kinase B, recruiting it to the membrane by:

1) Phosphorylating PI 4,5-biphosphoglycerate –> PI 3,4,5-trisphosphate
2) Phosphorylating PI 4-phosphate –> PI 3,4-biphosphate

Question 25

What domains does protein kinase B have?

Answer 25

pH domain

Kinase domain

Question 26

What are the 4 proteins that PKB phosphorylates?

Which contribute to the immediate responses and which contribute to longer-term responses

Answer 26

1) Glycogen Synthase Kinase (GSK)
- Immedaite

2) GLUcose Transporter 4 (GLUT4)
- Immediate

3) FOXO
- Longer-term

4)PhosphoEnolPyruvate carboxyKinase (glucose synthesis enzyme)

Question 27

What happens to GLUT 4 when phosphorylated by PKB? (at high levels of glucose)

Answer 27

• Vesicles that contain GLUT4 (in an inactive state) fuse with the plasma membrane
• GLUT4 fuse with the plasma membrane, more transport proteins in the membrane, pull glucose out of the blood

Question 28

What happens to GSK when phosphorylated by PKB? (at high levels of glucose)

What does this cause?

Answer 28

• GSK is inactivated by phosphorylation by PKB
• GSK normally phosphorylates glycogen synthesis to inactivate it
• So, at high glucose levels, PKB is activated, GSK is inactivated
• This releases the inactivation of glucose synthase
• Glucose is stored as glycogen

Question 29

What is FOXO?

What does it activate?

Answer 29

A transcription factor

Activates PEPCK (Phosphoenolpyruvate carboxykinase)

Question 30

What does PEPCK do?

Answer 30

Promotes glucose synthesis

Question 31

What happens to FOXO when phosphorylated by PKB? (at high levels of glucose)

What does this cause?

Answer 31

• Inhibition of FOXO by phosphorylation by PKB

- Inactivation of PEPCK, less glucose synthesis

Question 32

How can we identify genes that are activated by insulin signalling?

Answer 32

• Track changes in gene expression before and after adding insulin to cells in culture (using microarrays)
• Identify genes that are upregulated and downregulated
• Identify which branch of signalling that transduces the insulin signalling

Question 33

What determines if the insulin pathway activates or inactivates transcription?

Answer 33

Depends upon the enhancers located near the genes

Question 34

What happens to FOXO when sugar in the blood is low?

Answer 34

FOXO1 binds to IRS near PEPCK
Activate PEPCK
Stimulating glucose synthesis

Question 35

What are IRS and where are they present?

Answer 35

Insulin response sequences - present on DNA

Question 36

What 3 methods can be used to identify where transcription factors bind on DNA?

Answer 36

1) ESMA
2) DNAse footprinting I
3) PCR

Question 37

What 2 things can PCR do?

Answer 37

1) Amplify very small amounts of DNA - to be able to study

2) Quantify levels of RNA

Question 38

Describe the process of PCR

Answer 38

1) Start with a DNA template with part of the sequence known
2) Design 2 primers that bind to the sequence (one in each direction)
3) Heat the DNA to 95 degrees to denature the H bonds
4) Cool to 55 degrees to allow DNA to bind with primers
5) Heat to 72 degrees with a special DNA polymerase - allow DNA synthesis

Question 39

How are the primers direct DNA synthesis?

Answer 39

Towards each other

Question 40

What is the region between the 2 DNA primers?

Answer 40

The target sequence

Question 41

Where does the DNA polymerase used in PCR come from?

Answer 41

Thermus aquaticus bacteria (TAQ)

Question 42

What sized DNA does PCR not work for?

Answer 42

DNA above 10,000bp

Question 43

What is difference between cycles 1 and 2 and cycle 3 in PCR?

Answer 43

In cycles 1 and 2:
- Produce DNA that is longer than the target sequence

In cycle 3:
- Produce DNA that is the same length as the target sequence

Question 44

What occurs to the target sequence after cycle 3?

Answer 44

Amount of that sequence increases exponentially and is more common than the longer DNA

Question 45

How are the fragments of PCR separated?

Answer 45

Electrophoresis in a gel

Question 46

What is the process of quantitive PCR?

Answer 46

1) Extract all the RNA from a given tissue

2) Perform rtPCR
- Round 1: RNA –> DNA by reverse transcriptase
- Followed by amplification of DNA by PCR

3) Once amplified, perform PCR in the presence of a fluorescent dye, which only binds to dsDNA
4) Produce a graph (number of cycles vs fluorescence)
5) Can compare different tissues (different graphs)

Question 47

What is the idea behind qPCR?

Answer 47

• Direct relationship between the rate at which the PCR product is generated and the original concentration of the mRNA of interest
• Higher concentration of starting mRNA = quicker for the fluorescence to appear

Question 48

What is promoter bashing?

Answer 48

A way of looking at the genes regulatory sequence

To identify the transcription factor binding sites

Question 49

What is promoter bashing used in conjunction with?

Answer 49

ESMA

DNAse footprining I

Question 50

What is the process of promoter bashing?

Answer 50

1) Start with a GENOMIC CLONE of the gene of interest
2) Replace the gene with a reporter (Luciferase)
3) Insert this construct into a cell line or model organism (create a transgene)
4) Clone
5) Make a series of deletions and test the responsiveness to insulin

Question 51

In promoter bashing, why do you start with a GENOMIC clone of the gene of interest?

Answer 51

Contains the promoter of interest

Question 52

What does Luciferase do?

Answer 52

Encodes an enzyme which produces fluorescence when the substrate is added

Question 53

Why in promoter bashing is the gene replaced with Luciferase?

Answer 53

• So this reporter is now under the control of the all the regulatory sequences of interest (including promoter of interest)
• Certain levels of Luciferase at a given time

Question 54

In the case of an insulin responsive gene, what happens to Luciferase expression after insulin has been added?

Answer 54

It is maximally activated

Question 55

What does promoter bashing of an insulin responsive gene show?

Answer 55

• A critical region in the promoter which is needed to have insulin responsiveness at a 100% level (remove this portion - responsiveness to insulin is reduced dramatically)
• Highlights the DNA important in the regulation of the gene