The Fed and Fasting State

Description

Nutrition and Metabolism Quiz on The Fed and Fasting State, created by Charlotte Jakes on 03/01/2020.
Charlotte Jakes
Quiz by Charlotte Jakes, updated more than 1 year ago
Charlotte Jakes
Created by Charlotte Jakes almost 5 years ago
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Resource summary

Question 1

Question
Which of the following hormones increase blood glucose by inhibiting insulin? Check all that apply.
Answer
  • Adrenaline
  • Cortisol
  • Growth hormone
  • Glucagon
  • Secretin

Question 2

Question
Which hormone increases blood glucose by inhibiting insulin over a long period of time?
Answer
  • Cortisol
  • Adrenaline
  • Glucagon
  • Growth hormone

Question 3

Question
Which hormone counteracts insulin by stimulating glucose and lipid metabolism but shares insulin's anabolic properties with respect to protein?
Answer
  • Growth hormone
  • Adrenaline
  • Cortisol
  • Glucagon

Question 4

Question
Which hormone stimulates insulin secretion after food intake before blood glucose increases?
Answer
  • Secretin
  • Cholecystokinin
  • Gastrin
  • Pancreatic peptide

Question 5

Question
Which type of glucose transporters are present on the B cells of the islets of Langerhans?
Answer
  • GLUT1
  • GLUT2
  • GLUT3
  • GLUT4

Question 6

Question
Which glucose kinase is present in the B cells of the islets of Langerhans?
Answer
  • Glucokinase
  • Hexokinase

Question 7

Question
Fill in the blanks to describe the stimulation of insulin secretion from the pancreatic B cells. 1. The B cells have [blank_start]GLUT2[blank_end] glucose transporters - these have [blank_start]low[blank_end] affinity so glucose only enters these cells at [blank_start]high[blank_end] concentration. 2. [blank_start]Gluco[blank_end]kinase is present in the B cells which has [blank_start]high[blank_end] Km so [blank_start]phosphorylates[blank_end] glucose with [blank_start]low[blank_end] affinity. This initiates [blank_start]glycolysis[blank_end]. 3. [blank_start]ATP[blank_end] from [blank_start]glycolysis[blank_end] inhibits [blank_start]ATP[blank_end]-sensitive [blank_start]K+[blank_end] channels on the membrane. 4. The prevention of [blank_start]K+[blank_end] leakage causes the membrane to become [blank_start]depolarised[blank_end]. 5. [blank_start]Voltage[blank_end]-gated [blank_start]Ca2+[blank_end] channel proteins open. 6. [blank_start]Ca2+[blank_end] enters the cell stimulating [blank_start]vesicular fusion[blank_end] and release of insulin.
Answer
  • GLUT2
  • low
  • high
  • Gluco
  • high
  • phosphorylates
  • low
  • glycolysis
  • ATP
  • glycolysis
  • ATP
  • K+
  • K+
  • depolarised
  • Ca2+
  • Voltage
  • Ca2+
  • vesicular fusion

Question 8

Question
What is proinsulin?
Answer
  • Commercially synthesised insulin for use in diabetes management
  • Inactive prehormone form of insulin
  • The inactive form of insulin secreted by the pancreas of those with type 2 diabetes
  • Insulin when bound in a vesicle in the pancreatic B cells

Question 9

Question
How do we activate proinsulin?
Answer
  • Cleave off the C-peptide
  • Cleave off the B-peptide
  • Hydrolyse the disulfide bridges
  • Substitution of histidine for proline on the a-chain

Question 10

Question
What type of receptor is the insulin receptor?
Answer
  • Tyrosine kinase
  • GPCR
  • Free cytosolic
  • Transmembrane channel

Question 11

Question
Which domain are the 2 a-subunits of the insulin receptor found?
Answer
  • Extracellular
  • Intracellular

Question 12

Question
Which domain are the 2 b-subunits of the insulin receptor found?
Answer
  • Extracellular
  • Intracellular

Question 13

Question
The insulin receptor is described as being catalytic.
Answer
  • True
  • False

Question 14

Question
What happens when insulin binds to the insulin receptor?
Answer
  • Autophosphorylation of tyrosine residues
  • Autophosphorylation of lysine residues
  • Activation of a G protein
  • Opening of transmembrane channel

Question 15

Question
Fill in the blanks below to describe the activation of protein kinase B by insulin. 1. Insulin binds to its [blank_start]tyrosine[blank_end] receptor. 2. This binding stimulates [blank_start]autophosphorylation[blank_end] of [blank_start]tyrosine[blank_end] residues. 3. This [blank_start]phosphorylation[blank_end] allows [blank_start]phosphorylation[blank_end] of [blank_start]Insulin Receptor Substrate[blank_end] (IRS 1/2). 4. [blank_start]Insulin Receptor Substrate[blank_end] activates [blank_start]P13 kinase[blank_end]. 5. [blank_start]P13 kinase[blank_end] phosphorylates [blank_start]PiP2[blank_end] to [blank_start]PiP3[blank_end] in the cell membrane. 6. [blank_start]PiP3[blank_end] activated [blank_start]PDK1[blank_end]. 7. [blank_start]PDK1[blank_end] activates [blank_start]protein kinase B[blank_end].
Answer
  • tyrosine
  • autophosphorylation
  • tyrosine
  • phosphorylation
  • phosphorylation
  • Insulin Receptor Substrate
  • Insulin Receptor Substrate
  • P13 kinase
  • P13 kinase
  • PiP2
  • PiP3
  • PiP3
  • PDK1
  • PDK1
  • protein kinase B

Question 16

Question
Fill in the blanks below to describe how insulin activates glycogen synthesis. 1. When insulin binds to its tyrosine kinase receptor, [blank_start]protein kinase B[blank_end] is activated by a series of [blank_start]phosphorylations[blank_end]. 2. [blank_start]Protein kinase B[blank_end] causes [blank_start]GLUT4[blank_end] channels to be translocated to the membrane via [blank_start]vesicular fusion[blank_end] to encourage glucose uptake. 3. [blank_start]Protein kinase B[blank_end] phosphorylates [blank_start]glycogen synthase kinase[blank_end]. This [blank_start]inactivates[blank_end] glycogen synthase kinase. 4. [blank_start]Glycogen synthase[blank_end] remains unphosphorylated so remains in its [blank_start]active[blank_end] form. 5. Glycogen syntheiss can take place.
Answer
  • protein kinase B
  • phosphorylations
  • Protein kinase B
  • GLUT4
  • vesicular fusion
  • Protein kinase B
  • glycogen synthase kinase
  • inactivates
  • Glycogen synthase
  • active

Question 17

Question
The active form of glycogen synthase kinase is...
Answer
  • Phosphorylated
  • Not phosphorylated

Question 18

Question
The active form of glycogen synthase is...
Answer
  • Phosphorylated
  • Not phosphorylated

Question 19

Question
Fill in the blanks below to describe how insulin inhibits lipolysis. 1. When insulin binds to its [blank_start]tyrosine kinase[blank_end] receptor, [blank_start]protein kinase B[blank_end] is activated by a series of [blank_start]phosphorylations[blank_end]. 2. [blank_start]Protein kinase B[blank_end] phosphorylates [blank_start]phosphodiesterase[blank_end] to activate it. 3. [blank_start]Phosphodiesterase[blank_end] converts [blank_start]cAMP[blank_end] to AMP. 4. [blank_start]Protein kinase A[blank_end] is therefore inhibited and thus [blank_start]hormone sensitive lipase[blank_end] is not activated. 5. Triacylglycerols are not hydrolyses and the triacylglycerol store in adipose tissue is preserved.
Answer
  • protein kinase B
  • tyrosine kinase
  • phosphorylations
  • Protein kinase B
  • phosphodiesterase
  • Phosphodiesterase
  • cAMP
  • Protein kinase A
  • hormone sensitive lipase

Question 20

Question
What hormone activates hormone sensitive lipase to cause TAG hydrolysis?
Answer
  • Glucagon
  • Insulin
  • Secretin
  • Ghrelin

Question 21

Question
Fill in the blanks below to describe how insulin affects gene expression. 1. Insulin binds to its [blank_start]tyrosine kinase[blank_end] receptor stimulating [blank_start]autophosphorylation[blank_end] of [blank_start]tyrosine[blank_end] residues. 2. This phosphorylation leads to activation of [blank_start]RasGTP[blank_end]. 3. [blank_start]RasGTP[blank_end] activates the protein kinase cascade to phosphorylate first [blank_start]RAF[blank_end], then [blank_start]MEK[blank_end], then [blank_start]ERK[blank_end]. 4. [blank_start]ERK[blank_end] or MAPK activates or inhibits [blank_start]transcription factors[blank_end] leading to gene activation or suppression.
Answer
  • tyrosine kinase
  • autophosphorylation
  • tyrosine
  • RasGTP
  • RasGTP
  • RAF
  • MEK
  • ERK
  • ERK
  • transcription factors

Question 22

Question
The brain and erythrocytes will always take up glucose and metabolise it. Why?
Answer
  • GLUT3 transporters have high affinity
  • Glucokinase present which has high Km
  • Membranes freely permeable to glucose
  • Insulin directs glucose towards these tissues

Question 23

Question
In excess, how will pyruvate from glycolysis leave the liver?
Answer
  • As VLDL
  • As HDL
  • As LDL
  • As chylomicrons

Question 24

Question
Why does muscle and adipose tissue only uptake glucose at very high concentrations?
Answer
  • GLUT4 transporters present
  • Hexokinase present
  • Glucokinase present
  • Glycogen synthase present

Question 25

Question
Which biomolecules deposit fatty acids into adipose tissue in the fed state? Select all that apply.
Answer
  • Chylomicrons
  • VLDL
  • HDL
  • LDL

Question 26

Question
What are the actions of cortisol?
Answer
  • Long term blood glucose regulation
  • Stimulation of amino acid mobilisation from muscle
  • Stimulation of gluconeogenesis
  • Stimulation of TAG release from adipose tissue
  • Activation of glycogen synthase
  • Inhibition of lipoprotein lipase
  • Recruitment of GLUT4 transporters to cell membranes

Question 27

Question
The liver is engaged in gluconeogenesis at all times except during...
Answer
  • The fed state
  • The fasting state
  • Prolonged starvation
  • Satiety signalling

Question 28

Question
Why is the glucose kinase in the liver glucokinase, which has low affinity?
Answer
  • No competition for glucose with the brain when concentration is low
  • Concentration of glucose in the liver is always high
  • To compete for glucose against the brain when concentration is low
  • Concentration of glucose in the liver is always low

Question 29

Question
During the fed state, acetyl CoA carboxylase is activated to form malonyl CoA. What does malonyl CoA do?
Answer
  • Inhibits acyl carnitine transferase to prevent entry of fatty acids into mitochondrion for oxidation
  • Activations acyl carnitine transferase to encourage entry of fatty acids into mitochondrion for oxidation
  • Activates lipoprotein lipase to encourage TAG storage in adipose tissue
  • Activates LCAT to increase cholesterol uptake from peripheral tissues

Question 30

Question
Why does the brain rely on glucose as fuel?
Answer
  • Fatty acids cannot cross the blood-brain barrier
  • Fatty acids are broken down in the cerebrospinal fluid
  • Fatty acids are toxic to neurons
  • The neurons have no mitochondria

Question 31

Question
Glucose transport into the brain and erythrocytes is independent of insulin.
Answer
  • True
  • False

Question 32

Question
The erythrocytes have no mitochondria.
Answer
  • True
  • False

Question 33

Question
When do blood glucose concentrations peak?
Answer
  • 1 hour after eating
  • 2 hours after eating
  • 4 hours after eating
  • 30 mins after eating

Question 34

Question
Following a meal, when have blood glucose levels normally returned to normal by?
Answer
  • 2 hours
  • 1 hour
  • 4 hours
  • 6 hours

Question 35

Question
Why can't fatty acids be used in gluconeogenesis?
Answer
  • Acetyl CoA cannot be converted back to pyruvate - acetyl CoA is an end product of B-oxidation
  • Fatty acids cannot cross the hepatocyte cell membranes
  • It is more efficient to store fatty acids as TAGs in adipose tissue
  • Fatty acids cannot be converted to citrate

Question 36

Question
Which of the following molecules are gluconeogenic substrates?
Answer
  • Lactate
  • Glycerol
  • Glucogenic amino acids
  • Ketogenic amino acids
  • Fatty acids
  • Malonyl CoA

Question 37

Question
Ketone bodies consist of two molecules of what bonded together?
Answer
  • Acetyl CoA
  • Malonyl CoA
  • Carbon dioxide
  • Lactate

Question 38

Question
What is the purpose of the ketone bodies?
Answer
  • Provide a source of acetyl CoA to the muscles
  • Provide a source of acetyl CoA to the brain
  • Buffer system in the blood
  • Activate glycogen phosphorylase

Question 39

Question
In the fasting state, glucagon activates [blank_start]glycogen phosphorylase kinase[blank_end]. Thus, [blank_start]glycogen phosphorylase[blank_end] is phosphorylated and put into its [blank_start]active[blank_end] state. This means [blank_start]glycogen[blank_end] is phosphorylated and [blank_start]glucose[blank_end] can enter the blood.
Answer
  • glycogen phosphorylase kinase
  • glycogen phosphorylase
  • active
  • glycogen
  • glucose

Question 40

Question
Where is lactate sourced from for gluconeogenesis?
Answer
  • Erythrocytes
  • Brain
  • Adipose tissue
  • Kidney

Question 41

Question
Why do the erythrocytes produce lactate?
Answer
  • Can only perform anaerobic respiration
  • Can only perform aerobic respiration
  • Haem breakdown
  • Byproduct of oxyhaemoglobin formation

Question 42

Question
When does acetyl CoA form ketone bodies?
Answer
  • When it exceeds the capacity of the TCA cycle
  • When insulin activates hepatocytes
  • When ATP concentration is high in the hepatocytes
  • During the fed state

Question 43

Question
Why do ketone bodies stimulate insulin secretion?
Answer
  • To prevent muscle breakdown
  • To prevent fatty acid oxidation
  • To prevent urea toxicity
  • To prevent hepatocyte death

Question 44

Question
The brain can use ketone bodies in metabolism.
Answer
  • True
  • False

Question 45

Question
When does urea excretion and thus protein breakdown peak during starvation?
Answer
  • After 12 hours
  • 1 week
  • 2 weeks
  • After 48 hours

Question 46

Question
Why does urea excretion and thus protein breakdown decrease over time?
Answer
  • Ketone bodies stimulate insulin secretion
  • Ketone bodies stimulate glucagon secretion
  • After a certain period there is no mobilisable protein left
  • After a certain period urea transporters in the nephron are saturated

Question 47

Question
Why do the muscle begin to utilise fatty acids for energy as starvation progresses?
Answer
  • To increase availability of ketone bodies to brain
  • To reduce urea toxicity
  • To increase availability of amino acids to brain
  • To prevent kidney damage

Question 48

Question
For how long can a human survive without food?
Answer
  • 40 days
  • 20 days
  • 80 days
  • 7 days

Question 49

Question
Fill in the blanks below to describe type 1 diabetes. Type 1 diabetes is caused by the [blank_start]autoimmune[blank_end] destruction of [blank_start]B[blank_end] cells in the [blank_start]pancreas[blank_end]. It often has an [blank_start]early[blank_end] onset. Symptoms include polyuria, polydipsea, [blank_start]polyphagia[blank_end] (excessive appetite), fatigue and weakness as well as weight loss and muscle wasting. It requires treatment with exogenous [blank_start]insulin[blank_end] whereby the dosage is matched with [blank_start]carbohydrate intake[blank_end].
Answer
  • autoimmune
  • B
  • pancreas
  • early
  • polyphagia
  • insulin
  • carbohydrate intake

Question 50

Question
Which of these indicate type 1 diabetes?
Answer
  • Hyperglycaemia and ketoacidosis
  • Hyperglycaemia only
  • Ketoacidosis only
  • Hypoglycaemia and ketoacidosis

Question 51

Question
Fill in the blanks below to describe Type 2 diabetes. Type 2 diabetes is caused by insulin [blank_start]resistance[blank_end]. Is is usually [blank_start]later[blank_end] onset than type 1. Type 2 diabetes can be treated with dietary changes and oral [blank_start]hypoglycaemic[blank_end] agents.
Answer
  • resistance
  • later
  • hypoglycaemic

Question 52

Question
What do biguanides do in the treatment of Type II diabetes?
Answer
  • Increase recruitment of GLUT4 to increase glucose uptake
  • Reduce recruitment of GLUT4 to reduce glucose uptake
  • Act on B cells to improve insulin secretion
  • Destroy ketone bodies in the blood

Question 53

Question
What do sulphonylureas do in the treatment of Type 2 diabetes?
Answer
  • Act on B cells to improve insulin secretion
  • Destroy ketone bodies
  • Increase recruitment of GLUT4 to encourage glucose uptake
  • Reduce recruitment of GLUT4 to reduce glucose uptake

Question 54

Question
Which hormone acts unopposed in diabetes mellitus?
Answer
  • Glucagon
  • Insulin
  • Adrenaline
  • Cortisol

Question 55

Question
In a healthy individual, [blank_start]ketone bodies[blank_end] stimulate [blank_start]insulin[blank_end] release to limit muscle protein breakdown. In diabetics, this cannot occur. Thus, protein is broken down in an uncontrolled matter, [blank_start]gluconeogenesis[blank_end] is not controlled, fat breakdown is not controlled and [blank_start]ketone body[blank_end] production is not controlled. Glucose and [blank_start]ketone bodies[blank_end] may be present in the urine.
Answer
  • insulin
  • ketone bodies
  • gluconeogenesis
  • ketone body
  • ketone bodies

Question 56

Question
Drag and drop the correct pathologies to name some of the complications of diabetes mellitus. [blank_start]Microangiopathy[blank_end] - disease of the capillaries causing thickening of the wlals [blank_start]Retinopathy[blank_end] - damage to the retina affecting vision [blank_start]Nephropathy[blank_end] - damage to the kidneys [blank_start]Neuropathy[blank_end] - results in impotence, foot ulcers etc
Answer
  • Microangiopathy
  • Retinopathy
  • Nephropathy
  • Neuropathy

Question 57

Question
To be diagnosed with metabolic syndrome, patients must have any 1 of: [blank_start]high[blank_end] fasting glucose, [blank_start]insulin[blank_end] resistance or [blank_start]type 2[blank_end] diabetes. Patients must also have any 2 of [blank_start]hyper[blank_end]tension, [blank_start]dyslipidemia[blank_end] (abnormal lipid content in blood), [blank_start]central[blank_end] obesity (fat buildup around the abdomen) or microalbuminuria
Answer
  • high
  • insulin
  • type 2
  • hyper
  • dyslipidemia
  • central
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