Metabollism (Including liver structure)

Question 1

What are the characteristics of the outer mitochondrial membrane?

Answer 1

Smooth and freely permeable to molecules under 5kDa

No ionic or electrical gradients

Question 2

What are the characteristics of the inner mitochondrial membrane?

Answer 2

Permeable to only a small number of molecules via specific transporters
More protein than lipid
Folded into Cristal
Good insulator, maintains electrical and ionic gradients

Question 3

What is the blood supply to the liver

Answer 3

INPUT = hepatic artery and portal vein. Receives 25% of cardiac output (75% of which comes from the portal vein and 25% of which comes from the hepatic artery)
OUTPUT = hepatic venules drain into the hepatic vein which drains into the IVC

Question 4

What is the structure of a liver lobule?

Answer 4

Liver divided into lobule separated by connective tissue, lobules are hexagonal with a portal triad at each vertice, the blood from the hepatic artery and portal vein flows through sinusoids in between plates of hepatocytes into a central venule which drains into the hepatic vein. Bile is secreted by cells and runs in bile canaliculi to hepatic duct (runs in opposite direction to blood)

Question 5

In the liver what is the name of the space between endothelial cells and hepatocytes and what does it contain?

Answer 5

Space of Disse, contains collagen and stellate cells

Question 6

What is special about the endothelial cells in the internal structure of the liver?

Answer 6

pores and fenestra ensure that endothelial cells do not form a barrier for most small molecules (though particles the size of chylomicrons are excluded).

Question 7

What are the 5 cell types found in the liver?

Answer 7

1) Hepatocytes
2) Endothelial cells (lining sinusoids)
3) Kupffer cells (macrophages in sinusoidal lining, phagocytose old erythrocytes, gut derived bacteria etc.)
4) Hepatic stellate cells (fat filled cells, primary vitamin A storage, control turnover of connective tissue synthesising collagen and regulate contractility of sinusoids)
5) Pit cells (liver associated lymphocytes), natural killer cells that protect the liver from viruses/tumour cells

Question 8

What are the basic functions of the liver?

Answer 8

Factory: protein, lipid and carbohydrate metabolism, bile formation
Waste management: detoxify xenobiotics, remove internal waste and degrade bilirubin

Question 9

What are the components of bile?

Answer 9

Water, bicarbonate, bile salts, phospholipids, free cholesterol

Question 10

What from and where are bile salts formed?

Answer 10

Formed from cholesterol in the liver

Question 11

What are the steps in bile salt synthesis?

Answer 11

In liver:

1) Hydroxylation of cholesterol to from primary bile acids
2) Primary bile acids conjugated with either Glycine or taurine and excreted in bile

Question 12

How are secondary bile acids formed?

Answer 12

In the gut, gut derived bacteria can deconjugate bile salts and can also dehydroxylate primary bile acids to form secondary bile acids (which can be taken back up by gut and circulate to the liver where they can be conjugated to bile salts and secreted in the bile)

Question 13

Describe the recirculation of bile?

Answer 13

Either conjugated (bile salts) or deconjugated bile acids (primary or secondary) can be reabsorbed by the gut and circulate to the liver where they can be processed and excreted again in the bile

Question 14

How is bile acid synthesis controlled?

Answer 14

Bile acids inhibit bile acid synthesis - feedback inhibition

Question 15

What is cholestyramine and how does it work?

Answer 15

Cholesterol reducing drug which works by binding to bile salts and preventing them from being recirculated and thus increases bile salt synthesis from cholesterol

Question 16

How does increasing dietary fibre reduce cholesterol?

Answer 16

Fibre binds to bile salts and prevents them being circulated so more bile acids are synthesised from cholesterol

Question 17

Why do gall stones occur?

Answer 17

Bile contains free cholesterol as well as bile salts, if more cholesterol enters the bile than can be solubilised by the bile acids then cholesterol precipitates out

Question 18

What percentage of bile salts are recirculated?

Answer 18

95%

Question 19

What are xenobiotics?

Answer 19

They are potentially toxic substances with no nutritional value eg. Drugs/ food toxins or additives

Question 20

What are the 3 main waste products from the body?

Answer 20

1) Hormones eg. Growth hormone, insulin
2) Bilirubin from the break down of Hb
3) Urea to remove ammonium ions mostly from the breakdown of proteins but some derived from gut bacteria

Question 21

How are xenobiotics normally broken down?

Answer 21

Phase 1 reactions (oxidation, hydroxylation, reduction, hydrolysis:
Xenobiotic to primary metabolite
Phase 2 reactions (conjugation, sulphation, glucuronidation):
Primary metabolite to secondary metabolite
-Metabolites are normally pharmacologically inactive and more hydrophilic, they are excreted into he urine or bile

Question 22

Where do phase 1 reactions of metabolism of Xenobiotic normally occur?

Answer 22

In hepatocytes

Question 23

Which group of enzymes are mainly involved in phase 1 reactions of metabolism of Xenobiotic and where are they found?

Answer 23

Cytochrome P450 enzymes, large family of haem proteins (mono-oxygenases) found in the SER of hepatocytes
They are inducible by some drugs and alcohol
Individual variation in P450 enzymes could be of importance in therapeutics

Question 24

Why can detoxification of Xenobiotic sometimes present a problem in therapeutics?

Answer 24

Can create problems when drugs delivered orally because of first pass metabolism

Question 25

Where do phase 2 reactions of the metabolism of Xenobiotic occur and what do they involve?

Answer 25

Many enzymes involved, occur primarily in the liver but also in lung and kidney. Addition of glucuronyl, methyl, acetyl, sulphate and glycyl groups

Question 26

When is alcohol metabolised by Cytochrome P450 enzymes?

Answer 26

Alcohol is only metabolised by these enzymes when alcohol levels are high, chronic alcohol use induces the synthesis of P450 enzymes

Question 27

How is alcohol normally metabolised in the liver?

Answer 27

1) Ethanol to Acetaldehyde (by alcohol dehydrogenase in the cytosol of hepatocytes)
2) Acetaldehyde to acetate (be acetaldehyde dehydrogenase in the mitochondria of hepatocytes)
Both reactions produce NADH

Question 28

How are red blood cells broken down and Bilirubin produced?

Answer 28

1)Old erythrocytes phagocytosed mainly by kupffer cells in the liver but also in the spleen or bone marrow
2) The Globin protein in Hb is degraded but the haem is converted to biliverdin (green) (iron part removed here) then to Bilirubin
HAEM - BILIVERDIN - BILIRUBIN

Question 29

How is Bilirubin from the break down of erythrocytes transported to the liver?

Answer 29

Bound to albumin (as Bilirubin is very insoluble)

Question 30

What processes does Bilirubin undergo in the liver?

Answer 30

1) Conjugation (mainly with glucuronic acid)

2) Secretion into bile canaliculi (an active process requiring ATP)

Question 31

What happens to conjugated Bilirubin when it reaches the gut?

Answer 31

1) Conjugate Bilirubin is metabolised to urobilinogen by gut bacteria
2) Urobilinogen can then either be reabsorbed by the gut and circulate in the blood to the kidneys where is is converted to urobilin and excreted in the urine or…
3) Urobilinogen can be further metabolised in the gut to stercobillin which is excreted in the faeces

Question 32

What happens to conjugated Bilirubin when it reaches the gut?

Answer 32

1) Conjugate Bilirubin is metabolised to urobilinogen by gut bacteria
2) Urobilinogen can then either be reabsorbed by the gut and circulate in the blood to the kidneys where is is converted to urobilin and excreted in the urine or…
3) Urobilinogen can be further metabolised in the gut to stercobillin which is excreted in the faeces

Question 33

What is pre-hepatic jaundice?

Answer 33

Haemolytic anaemia eg. Sickle cell anaemia, no problem with liver function but simply too much Bilirubin is being produced to be processed by the liver

Question 34

What is jaundice?

Answer 34

Can occur due to problems at various stages in the metabolism of Bilirubin, where unconjugated or conjugated Bilirubin cannot be excreted and builds up in the blood and gets deposited in the tissues

Question 35

What is intrahepatic jaundice?

Answer 35

Can be caused by liver damage, cirrhosis, inflammation infection (or inherited - Gilbert’s syndrome) Liver fails to conjugate Bilirubin and excrete it in the bile

Question 36

What is extrahepatic jaundice?

Answer 36

Due to a blockage in the bile duct eg. Gall stones, pancreatic carcinoma, bile cannot be excreted (so neither can Bilirubin which builds up and leaks into blood if alternative route is blocked)

Question 37

What is pre-hepatic jaundice?

Answer 37

Haemolytic anaemia eg. Sickle cell anaemia, no problem with liver function but simply too much Bilirubin is being produced to be processed by the liver

Question 38

What are the energy stores for a healthy 70kg man?

Answer 38

Fat 400MJ
Usable protein 100MJ
Liver glycogen 2.4MJ
Blood glucose 0.16MJ

Question 39

In MJ what are the daily energy needs of a 70 kg man?

Answer 39

12MJ

Question 40

In MJ what are the daily energy needs of a 70 kg man?

Answer 40

12MJ

Question 41

How much ATP does the average human body contain and what is the rate of turnover of ATP?

Answer 41

Contains 75g but rate of turnover is about 75kg per day

Question 42

How much energy in food is converted into ATP?

Answer 42

About half is converted into ATP and half is lost a ‘useful’ work

Question 43

Under aerobic conditions how much cellular ATP is produced in the mitochondria?

Answer 43

About 95%

Question 44

What are the 2 mitochondrial spaces called?

Answer 44

Matrix and intermembrane space

Question 45

What are the characteristics of the mitochondrial matrix?

Answer 45

1) Contains a wide range of enzymes - fatty acid oxidation, krebs cycle, urea cycle (only in liver)
2) High concentration of co factors, substrates and ions
3) Contains mitochondrial DNA, RNA and ribosomes, though few mitochondrial proteins are coded on mitochondrial DNA

Question 46

What are the characteristics of the intermembrane space in mitochondria?

Answer 46

1) Has metabolite and ion concentrations similar to cytosol

2) Contains cytochrome c

Question 47

In respiration what is the link reaction?

Answer 47

The conversion of pyruvate to acetyl Co A

Question 48

Which enzyme catalyses the link cycle of respiration?

Answer 48

Pyruvate dehydrogenase

Question 49

Name an important co factor of the enzyme pyruvate dehydrogenase?

Answer 49

TPP (Thiamine Pyrophosphatase) Vitamin B1

Question 50

What does deficiency in Vitamin B1 (Thiamine) cause and why?

Answer 50

Beri Beri (neurological/cardiovascular symptoms) - disrupts the function of Pyruvate dehydrogenase (from the link reaction)

Question 51

What does deficiency in Vitamin B1 (Thiamine) cause and why?

Answer 51

Beri Beri (neurological/cardiovascular symptoms) - disrupts the function of Pyruvate dehydrogenase (from the link reaction)

Question 52

What is Wernicke-Korsakoff syndrome?

Answer 52

Syndrome caused by lack of thiamine seen in alcohol addicts

Question 53

How is action of the enzyme pyruvate dehydrogenase controlled?

Answer 53

PDH is inactivated (phosphorylated) when energy levels are high, activation is prompted by any sudden demands on the cell signalled by Ca2+

Question 54

Why is the link reaction a ‘key decision point’ in metabolism?

Answer 54

Acetyl Co A cannot be converted back to glucose in humans, conversion commits the carbon atoms to energy production (lost as CO2) or lipid synthesis

Question 55

What are the main outputs of the Krebs/citric acid cycle?

Answer 55

Reduced co enzymes NADH and FADH2, CO2 (waste product) and 1 GTP (=1 ATP)

Question 56

What are the main outputs of the Krebs/citric acid cycle?

Answer 56

1) Reduced co enzymes NADH and FADH2
2) CO2 (waste product)
3) 1 GTP (=1 ATP)

Question 57

How is action of the enzyme pyruvate dehydrogenase controlled?

Answer 57

PDH is inactivated (phosphorylated) when energy levels and levels of AcetylCoA from fat oxidation are high, activation is prompted by any sudden demands on the cell signalled by Ca2+

Question 58

What are the main outputs of the Krebs/citric acid cycle?

Answer 58

1) Reduced co enzymes NADH and FADH2
2) CO2 (waste product)
3) 1 GTP (=1 ATP)

Question 59

Where does the link reaction take place?

Answer 59

In the mitochondrial matrix. Pyruvate is transported across the inner mitochondrial membrane from the cytosol to the mitochondrial matrix

Question 60

What are the 2 main stages of the Krebs cycle?

Answer 60

1) Synthesis of 6-C compound (citrate - by combining oxaloacetate and acetyl co A) which then loses 2 C as CO2 to become 4-C compound (succinyl CoA)
2) Oxidation of 4-C compound to regenerate oxaloacetate and initiate another round of the cycle

Question 61

What is the TCA (tricarboxylic acid cycle)?

Answer 61

Another name for the Krebs cycle

Question 62

Where does the Krebs/citric acid/TCA cycle take place?

Answer 62

Mitochondrial matrix

Question 63

What are the key enzymes (control points) in Krebs cycle?

Answer 63

1) Citrate synthase (AcetylCoA + Oxaloacetate)
2) Isocitrate dehydrogenase (Isocitrate to a-ketoglutarate)
3) a-ketoglutarate dehydrogenase (a-ketoglutarate to succinyl co-A)

Question 64

How are the key enzymes in the Krebs cycle controlled?

Answer 64

1) Inhibited by high levels of NADH and ATP (and succinyl CoA and citrate at points)
2) Stimulated by ADP and NAD+ (only isocitrate dehydrogenase)

Question 65

How does the Krebs cycle act as an exchange for intermediates of other metabolic pathways?

Answer 65

1) Amino acid carbon chains can be fed into the Krebs cycle
2) Odd chain fatty acids can be fed in (succinyl CoA)
3) Citrate can be used in fatty acid and cholesterol synthesis
4) Malate (one step before oxaloacetate) can be used for glucose synthesis
5) a-ketoglutarate and oxaloacetate can be used in amino acid synthesis
6) SYNTHESIS OF OXALOACETATE FROM PYRUVATE (+CO2) IS IMPORTANT IN REPLENISHING OXALOACETATE FOR KREBS CYCLE TO CONTINUE - oxaloacetate can also come from amino acid carbon chains

Question 66

Why can diabetic patients not effectively use blood glucose?

Answer 66

In the absence of insulin cells cannot detect blood glucose so start synthesising glucose (even when blood glucose levels are high)

Question 67

Why do patients with Type 1 diabetes synthesise ketones?

Answer 67

1) Glycolysis is inhibited so conc. pyruvate is low
2) Gluconeogenesis is not inhibited so oxaloacetate and Malate being removed to synthesise glucose
3) In the absence of insulin fatty acids are mobilised from adipose tissue and oxidised to acetyl co A
4) Lack of oxaloacetate prevents this acetyl Co A from entering the Krebs cycle so it is used to synthesis ketones instead

Question 68

Why do patients with type 1 diabetes develop ketoacidosis?

Answer 68

Even though ketones are being synthesised, brain doesn’t take up ketones as it simply uses the blood glucose that is present but cells can’t detect. Ketones then build up in the blood.

Question 69

What are the 2 processes in oxidative phosphorylation?

Answer 69

1) Electron transport chain: OXIDATION

2) ATP Synthesis: PHOSPHORYLATION

Question 70

Where do the processes of oxidative phosphorylation take place?

Answer 70

Across the inner mitochondrial membrane

Question 71

What are the components of the electron transport chain?

Answer 71

Transmembrane proteins: Complexes 1-4 (also ubiquinone and Cytochrome c)

Question 72

What process occurs in the electron transport chain of oxidative phosphorylation?

Answer 72

Electrons from NADH and FADH2 enter the ETC and Electrons are transferred from one electron carrier to the next - energy released is used
When the electrons reach Complex IV they are donated to oxygen, reducing it to water – this removes them from the chain.

Question 73

What process occurs in the electron transport chain of oxidative phosphorylation?

Answer 73

Electrons from NADH and FADH2 enter the ETC and Electrons are transferred from one electron carrier to the next, each reduction step results in the release of energy - energy released is used to pump H+ across the inner mitochondrial membrane (4+4+2 = 10) creating a large proton gradient across the inner mitochondrial membrane
When the electrons reach Complex IV they are donated to oxygen, reducing it to water – this removes them from the chain.

Question 74

Why is cyanide poisonous?

Answer 74

It blocks the accepting of electrons by oxygen to form water at the end of the ETC, electrons block up along the chain and stop you producing ATP - suffocate despite access to sufficient oxygen

Question 75

Why are more H+ pumped across the inner mitochondrial membrane using electrons from NADH than FADH2?

Answer 75

FADH2 enters the ETC further along than NADH (at complex 2) so only pumps 8H+ across instead of 10

Question 76

In oxidative phosphorylation how is ATP synthesised?

Answer 76

Protons flow across through the F0F1 ATPase enzyme down the concentration gradient, this provides the energy required to synthesise ATP

Question 77

How many hydrogen ions are required to flow through F0F1 ATPase enzyme to produce 1 molecule ATP?

Answer 77

3

Question 78

What transporters involved in ATP synthesis of oxidative phosphorylation are present in the inner mitochondrial membrane?

Answer 78

1) ADP/ATP antiporter - synthesised ATP flows out in exchange for APD to be used in ATP synthesis
2) Pi/H+ co transporter - Pi transport into matrix requires the removal of 1 H+ from intermembrane space (so synthesis of ATP actually requires 4 (3+1) H+ ions)

Question 79

How does NADH produced in the cytosol reach the matrix?

Answer 79

NADH cannot directly cross the inner mitochondrial membrane so has to be oxidised in the cytosol, cross the inner mitochondrial membrane as NAD then be reduced in the matrix by electron transport

Question 80

Why is ATP synthesis not possible if the ETC isn’t functioning?

Answer 80

No proton gradient to drive ATP syntheses enzyme

Question 81

Why is ETC not possible if ATP synthesis is not occurring?

Answer 81

Protons flow across through the F0F1 ATPase enzyme down the concentration gradient
Energy cannot be released from the electron carriers, so they can’t accept any more electrons – electron transport stops

Question 82

What are uncouplers into the context of oxidative phosphorylation?

Answer 82

Uncouplers are weak acids which are soluble in the membrane
When they penetrate the inner mitochondrial membrane they diffuse freely
At the inter-membrane space interface they associate with protons – driven by the relatively high [H+]
At the matrix surface they release protons – driven by relatively low [H+]
Overall effect is to dissipate the proton gradient and ETC can continue without ATP synthesis

Question 83

How is uncoupling used in new born babies?

Answer 83

1) Babies possess brown adipose tissue – has more mitochondria/ different appearance to white adipose tissue
2) Mitochondria in brown adipose tissue contain thermogenin (uncoupling protein-1)
3) When core body temperature drops, sympathetic nervous system release of noradrenalin leads to increased concentrations of free fatty acids in the cytosol, which activate thermogenin
Babies use this mechanism to maintain core body temperature - they uses the ETC to generate heat rather than for ATP synthesis

Question 84

What is the significance of brown adipose tissue in adults?

Answer 84

Recently identified in adults, decreases with obesity and age, may be a valuable therapeutic target to promote triglyceride clearance and weight loss

Question 85

What is dinitrophenol?

Answer 85

Was available as a slimming pill, However side effects including hyperthermia, tachycardia, excess sweating, blindness (due to cataracts) & fatalities led to it being withdrawn in 1938

Question 86

What are the 5 possible uses of amino acids in the body and what must be removed from them before they can be put to any of these uses?

Answer 86

Nitrogen must be removed

1) Protein synthesis
2) Glucose/ glycogen synthesis
3) Fatty acid, ketone body synthesis
4) Break down to form ATP
5) Synthesis of nitrogen containing metabollites

Question 87

The nitrogen containing compounds dopamine, noradrenaline and adrenaline are synthesised from which amino acid?

Answer 87

Tyrosine

Question 88

The nitrogen containing compound haem is synthesised from which amino acid?

Answer 88

Glycine

Question 89

The nitrogen containing compound serotonin is synthesised from which amino acid?

Answer 89

Tryptophan

Question 90

The nitrogen containing compound histamine is synthesised from which amino acid?

Answer 90

Histidine

Question 91

The nitrogen containing compound creatine is synthesised from which amino acids?

Answer 91

Glycine and Arginine

Question 92

The nitrogen containing compounds purine bases are synthesised from which amino acids?

Answer 92

glycine, aspartate and glutamine

Question 93

Why would severe malnutrition lead to:

1) susceptibility to infection,
2) changes in hair/skin colour,
3) poor skin condition and poor nutrient absorption
4) Abdominal bloating
5) lower limb odema?

Answer 93

1) Ab made out of proteins
2) Not enough melanin
3) epithelial cells have fast turnover, tend to be the first hit by malnutrition
4) Cant make proteins to transfer lipids that are synthesised
5) Albumin is a key protein for maintaining oncotic pressure of the blood

Question 94

What is kwashiorkor syndrome?

Answer 94

Lack of protein in severe malnutrition, predominantly a disease in children in developing countries

Question 95

How is the nitrogen formed from amino acids excreted from the body?

Answer 95

As ammonia

Question 96

What is hyperammonaemia, symptoms and causes?

Answer 96

High levels of ammonia in the blood
Symptoms - tremor, vomiting, cerebral oedema, coma and death
Causes - can occasionally result from a defect in urease enzymes but is more commonly caused by liver disease - hepatitis or cirrhosis

Question 97

Where does disposal of ammonia occur?

Answer 97

Mainly in the liver, ammonia is converted to urea for excretion by the kidneys

Question 98

What are the 3 steps in excretion of nitrogen and where do they principally occur?

Answer 98

1) Transamination - transfer of amino group from amino acid to a-ketoglutarate forming glutamate (IN MOST TISSUES)
2) Deamination - release of ammonia from glutamate (MAINLY IN LIVER)
3) Urea synthesis - urea cycle (IN THE LIVER)

Question 99

How is ammonia transferred in the blood?

Answer 99

As glutamate (carrying 1 ammonia) or as glutamine (Extra ammonia added so carrying 2)

Question 100

In the liver describe the process of deamination in the excretion of nitrogen?

Answer 100

Reverse of the transamination step that occurs in peripheral/muscle tissues
( 1) Ammonia removed from glutamine to make glutamate)
2) Ammonia released from glutamate to make a-ketoglutarate

Question 101

Which enzyme (and co factor) is required in the transamination step of excretion of nitrogen

Answer 101

Transaminase, require pyridoxal phosphate (active form of vit B6)

Question 102

Which enzyme is involved in the deamination step of excretion of nitrogen?

Answer 102

Glutamate dehydrogenase

Question 103

As well as transamination of amino acids what is pyridoxal phosphate (active form of vit B6) required for?

Answer 103

1) Synthesis of amino acids
2) Decarboxylation reactions required for neurotransmitter synthesis
3) Haem synthesis
4) Some aspects of energy metabolism and lipid synthesis

Question 104

What are the symptoms of Vit B6 (pyridoxal phosphate)?

Answer 104

1) Anaemia (lack of haem synthesis)
2) Neurological symptoms (lack of neurotransmitter and lipid synthesis)
3) Poor growth, skin lesions, poor immune response (lack of amino acid and thus protein synthesis)

Question 105

Where in the hepatocytes does the urea cycle occur?

Answer 105

Mitochondrial matrix

Question 106

Where in the hepatocytes does the urea cycle occur?

Answer 106

First bit in mitochondrial matrix
second bit in cytosol
(Changes compartments halfway through)

Question 107

In the urea cycle what is the control step?

Answer 107

The first step that occurs - the formation of carbamoyl phosphate from ammonia and bicarbonate (CO2)

Question 108

What steps of the urea cycle occur in the mitochondrial matrix?

Answer 108

1) Carbamoyl phosphate formed from ammonia and bicarbonate - CONTROL STEP
2) Carbamoyl group transferred to ornithine to form citrulline

Question 109

What steps of the urea cycle occur in the cytosol?

Answer 109

(the second half of the cycle)

3) Second amino group added to citrulline from aspartate
4) Argininosuccinate and then arginine is formed
5) UREA IS RELEASED
6) Ornithine produced goes back into mitochondrial matrix to be combined with carbonyl phosphate

Question 110

When is the urea cycle activated?

Answer 110

When levels of amino acids are high

Question 111

How is the urea cycle activated?

Answer 111

Carbomyl phosphatase synthase 1 is the enzyme that catalyses the control step of the cycle, this is allosterically activated by N-acetylglutamat which is formed when glutamate levels are high (signalling high levels of protein catabolism)

Question 112

What is the difference between urea and uric acid?

Answer 112

They are not the same thing! But both do contain nitrogen, uric acid is derived from purine nucleotides rather than proteins

Question 113

What it hyperuricaemia and what can it lead to?

Answer 113

Excess uric acid in the blood, it can lead to deposition of sodium urate crystals in the kidneys (kidney stones) and in the joints (gout)

Question 114

What is the cause of hyperuricaemia?

Answer 114

Either due to over production of urate or poor excretion via the kidneys, high purine food (Red meat, seafood, yeast containing foods including beer) should be avoided

Question 115

Name 3 common pathways that the carbon skeletons of amino acids can be fed into?

Answer 115

1) Krebs cycle used to synthesise ATP
2) Fatty acid and ketone synthesis
3) Glucose synthesis (gluconeogenesis)

Question 116

What are the 2 common amino acids which cannot be made into glucose but are solely ketogenic - can only be made into acetyl CoA & ketone bodies?

Answer 116

Lysine and Leucine

Question 117

What is gluconeogenesis?

Answer 117

Synthesising glucose from non carbohydrate intermediates - during fasting or exercise

Question 118

Where does gluconeogenesis mainly take place?

Answer 118

Mainly in the cytosol of the liver and kidneys

Question 119

What are the 3 main non carbohydrate intermediates used in gluconeogenesis?

Answer 119

1) Keto acids - derived from amino acids (particularly alanine)
2) Lactate - derived from anaerobic glycoslysis
3) Glycerol - from triacylglycerol breakdown

Question 120

Many reactions in gluconeogenesis are simply reversal of glycolysis reactions, but 3 steps in glycolysis are irreversible, which 3 steps are catalysed by different enzymes in gluconeogenesis?

Answer 120

1) Pyruvate -> phosphoenolpyruvate (requires several stages)
2) Fructose 1,6 bisphosphate -> fructose 6 phosphate (fructose 1,6 bisphosphatase)
3) Glucose 6 phosphate -> glucose (glucose 6 phosphatase)
Nb. in gluconeogenesis 6ATP are required

Question 121

How are gluconeogenesis and glycolysis controlled?

Answer 121

They are reciprocally regulated:

• High glucose and/or low energy = glycolysis
• Low glucose and/or high energy = gluconeogenesis

Question 122

What are the effects of glucagon and insulin on glycolysis and gluconeogenesis?

Answer 122

• Glycolysis is inhibited by glucagon and activated by insulin
• Gluconeogenesis is activated by glucagon and inhibited by insulin

Question 123

Other than insulin and glucagon which substances activate/inhibit gluconeogenesis?

Answer 123

Inhibited by AMP and ADP

Activated by citrate and acetyl coA

Question 124

What is the core cycle?

Answer 124

The core cycle converts lactate from rapidly respiring muscle back to glucose

Question 125

Where does the core cycle take place?

Answer 125

Glucose converted to lactate (via pyruvate) in MUSCLE
Lactate carried in the blood to the LIVER where the lactate is converted to glucose (via pyruvate) and the glucose is carried in the blood back to the muscle where it can be used again

Question 126

What is the purpose of the glucose-alanine cycle?

Answer 126

To sustain transamination in peripheral tissue, by providing a safe way to transfer nitrogen in the blood to the liver and also a way of regenerating a-ketoglutarate (cells that are rapidly breaking down amino acids run out of a-ketoglutarate)

Question 127

What happens in the glucose-alanine cycle?

Answer 127

Some glutamate produced in peripheral

Question 128

What happens in the glucose-alanine cycle?

Answer 128

1) Some glutamate produced in peripheral tissues transfers its amino group to pyruvate to produce alanine and regenerate a-ketoglutarate
2) Alanine travels in the blood to the liver where it transfers its amino group on to a-ketoglutarate to regenerate glutamate and pyruvate
3) Pyruvate is converted to glucose in the liver, the glucose travels in the blood to the peripheral tissues where it is converted to pyruvate and the whole cycle can start again

Question 129

Why does alcohol make you hungry?

Answer 129

1) Ethanol metabolism produces large amounts of NADH
2) High levels of NADH tend to cause conversion of pyruvate (including that produced from alanine) to lactate (reaction is reversible)
3) high levels of NADH also prevent conversion of glycerol to G3P (glyceraldehyde 3 phosphate - which would become glucose)
4) thus high levels NADH inhibit gluconeogenesis and thus lower blood sugar making you hungry

Question 130

What do deficiency in and excess growth hormone lead to in children?

Answer 130

Deficiency = dwarfism
Excess = gigantism

Question 131

What does excess growth hormone lead to in adults?

Answer 131

Epiphyses are closed so bones cant increase in length so there is no change to stature, however excess growth hormone in adults leads to acromegaly: bones become excessively thickened, other tissues overgrow

Question 132

What does deficiency in growth hormone lead to in adults?

Answer 132

No obvious disease but replacement increases lean body mass, decreases fat and increases vigour

Question 133

GRH (growth hormone-releasing hormone) is released from where in response to what?

Answer 133

Released from the arcuate nucleus of the hypothalamus

Released in response to: Low glucose, amino acids, TRH, Ghrelin, sex hormones, sleep, exercise and stress

Question 134

Where is growth hormone released from and in response to what?

Answer 134

Growth hormone is released from the anterior pituitary

Release is stimulated by GRH and inhibited by Somatostatin aswell as IGF’s (insulin like growth factors)

Question 135

What are the target organs of GH?

Answer 135

Fat, Cartilage and Bones, Liver

Question 136

What is the role of somatostatin in GH release, where is it released from, stimulated by what and inhibited by what?

Answer 136

Somatostatin released from the paraventricular nucleus of the hypothalamus
Somatostatin released in response to GH and it inhibits the release of GH from the anterior pituitary (-ve feedback)
Somatostatin also inhibits the release of GRH (-ve feedback) and the release of somatostatin is inhibited by GRH to keep a balance

Question 137

Which 3 hormones act on the anterior pituitary to control the release of Growth hormone?

Answer 137

1) Somatostatin inhibits release
2) GRH (growth-hormone releasing hormone) stimulates release
3) IGF’s inhibit release

Question 138

What is the pattern of secretion of growth hormone?

Answer 138

Pulsatile releases (lots of rapid pulses) with more released during sleep

Question 139

What kind of receptor is the GRH (or GHRH) receptor at the anterior pituitary?

Answer 139

A GPCR, acts through adenylyl cyclase and cAMP

Question 140

What kind of receptor is the Somatostatin receptor at the anterior pituitary?

Answer 140

A GPCR, acts through Gi

Question 141

How many splice variants of growth hormone exist?

Answer 141

2 (Come from same DNA but different splicing)

22kDa = main form, some 20kDa

Question 142

How is about 40% of growth hormone released carried in the blood and why?

Answer 142

Binds to plasma proteins made by cleaving its receptor - this buffers it and protects it from the proteases in the circulation

Question 143

What kind of receptor does growth hormone act through>

Answer 143

Tyrosine Kinase ASSOCIATED receptor leading to protein phosphorylation

Question 144

What are the rapid/acute effects of GH on liver muscle and fat?

Answer 144

Diabetogenic effects

1) Liver: increased gluconeogenesis
2) Fat: Increased lipolysis
3) Muscle: decreased glucose uptake
4) Insulin resistance

Question 145

What hormone are the long term effects of GH on growth mediated via and where is it released from?

Answer 145

Mediated via insulin-like growth factor 1 (IGF1) (also called somatomedin), released from liver, cartilage and bones in response to GH

Question 146

What are the 2 forms of IGF’s (somatomedins) and which one is more active and which one is not controlled by GH?

Answer 146

IGF1, IGF2
IGF 1 is more active
IGF 2 is not controlled by GH

Question 147

What are the broad effects of IGF’s (somatomedins)?

Answer 147

Enhance protein synthesis and growth

Can cause hypoglycaemia (cross reactivity with insulin)

Question 148

What is the role of insulin in growth?

Answer 148

Need insulin to facilitate growth, need growth hormone to make it happen but glucose say we have enough energy for it to happen (especially needed in utero)

Question 149

What is the role of steroids in growth?

Answer 149

Sex steroids accelerate growth, but hasten maturity

Glucocorticoids typically slow growth

Question 150

What is the role of thyroid hormones in growth?

Answer 150

Act like insulin as a facilitator, essential for normal growth and response to GH

Question 151

How are thyroid hormones carried in the blood?

Answer 151

Tightly bound to proteins (especially thyroid binding globulin and transthyretin)

Question 152

Why are thyroid hormones carried in the blood tightly bound to proteins?

Answer 152

Greatly prolongs half lives (T4 - 8 days, T3- 1 day)

Question 153

Where are thyroid hormones released from and in response to what?

Answer 153

Released from the thyroid gland in response to TSH released from pituitary

Question 154

What is the general effect of thyroid hormone on metabolism?

Answer 154

Increase metabolic rate and heat generation

Question 155

What are the 3 forms of thyroid hormone, which has most activity and which is produced in the greatest amounts in the thyroid gland?

Answer 155

T3 - active form
T4 - little activity but 90% secreted is in this form
rT3 - inactive

Question 156

What hormone stimulates nearly all the steps in the production of thyroid hormone?

Answer 156

TSH

Question 157

What is iodination in the production of thyroid hormone and what process follows?

Answer 157

In the lumen of the gland - Iodine (taken up by the follicular cells from the blood and released into the lumen) is added to thyroglobulin (secreted into lumen from follicular cells)
Conjugation follows then endocytosis, then proteolysis then secretion of T3 or T4 into blood

Question 158

What happens to T4 in the periphery to make T3?

Answer 158

T4 gets deiodinated by 2 enzymes to form T3

Question 159

Where are Type 1 and 2 enzymes that deiodinate T4 to T3 found?

Answer 159

Type 1 - found in liver kidney and thyroid, inhibited by stress and caloric restriction
Type 2 - found in pituitary, CNS and placenta, is constitutive (works all the time)

Question 160

What receptor does Thyroid hormone act through?

Answer 160

Nuclear receptor which initiates gene transcription (may be additional non genomic effects)

Question 161

What are the acute effects of thyroid hormone?

Answer 161

1) Increases basal metabolic rate and heat production via ‘futile cycles’ (forward and backward reactions at the same time) and mitochondrial uncoupling
2) Causes both lipolysis and lipogenesis
3) Increases proteolysis but also protein synthesis - net muscle wasting
4) Increases Na+/K+ATPase and leak
5) increases Beta receptor expression
6) usually no hyperglycaemia (insulin control normal)

Question 162

What are the chronic effects of thyroid hormone, what does deficiency in infancy or in later childhood lead to and what does low TH lead to which is common in areas with low environmental iodine?

Answer 162

1) Crucial for normal brain development and growth
2) Deficiency in infancy leads to cretinism and dwarfism
3) Later in childhood there is severe impairment of growth: catch-up growth is possible
4) TSH drives thyroid hypertrophy, so low TH (And lack of feedback) leads to a goitre: common in areas with low environmental iodine

Question 163

How can auto immunity cause hyperthyroidism?

Answer 163

antibodies against the TSH receptor may activate it, driving excess thyroid hormone production and cause hyperthyroidism (eg. graves disease)

Question 164

What are the symptoms of graves disease?

Answer 164

(all hyperthyroidism): weight loss, tremor, sweating , tachychardia, dislike hot weather
(Graves disease): exophthalmos (eyes stick out), double vision, pretibial myxoedema (growth of tissue in front of shin, feels woody)

Question 165

How can auto immunity cause hypothyroidism?

Answer 165

Ab that destroy TSH receptors or other targets cause hypothyroidism (eg. Hashimoto’s thyroiditis)

Question 166

What is myxodema?

Answer 166

Another name for hypothyroidism

Question 167

What are the symptoms of hypothyroidism?

Answer 167

Weight gain, hypothermia, tiredness, constipation, skin thickening and oedema, bradychardia, dislike of cold weather, secondary anovulation (don’t ovulate, lose menstruation cycle)

Question 168

What is the main natural glucocorticoid in man?

Answer 168

cortisol

Question 169

Where is CRH (corticotrophin releasing hormone) released from?

Answer 169

Hypothalamus integrates diurnal rhythm, physical, environment and biochemical stress factors to release CRH

Question 170

What does CRH act on and what does it cause?

Answer 170

Acts on GPCR receptors in the anterior pituitary to cause the release of ACTH (adrenocorticotropic hormone)

Question 171

What does ACTH act on and what does it cause?

Answer 171

ACTH stimulates the adrenal cortex hypertrophy and cortisol production

Question 172

How is the release of ACTH inhibited?

Answer 172

Iatrogenic steroids suppress ACTH release and cause adrenal atrophy

Question 173

What are the acute effects of glucocorticoids in general, in liver, in fat and in muscle?

Answer 173

1) Inhibit insulin response and enhance SNS responses (target glucose to the brain, other organs use fats)
2) In liver: promotes gluconeogenesis and glucose release
3) In fat: lipolysis (glycerol for gluconeogenesis and FFA for energy)
4) In muscle: protein breakdown for gluconeogenesis

Question 174

What kind of receptor do glucocorticoids act via?

Answer 174

Nuclear receptor, inducing gene transcription

Question 175

What are the chronic effects of glucocorticoids?

Answer 175

1) Immunosuppression
2) Reduction in inflammation and cytokine production
3) Stimulate haematopoiesis and GI tract mucosae
4) Fat redistribution - peripheral to central
5) Skin thinning, muscle wasting, osteoporosis
6) Complex CNS effects: euphoria to psychosis

Question 176

What is disease is caused by excess glucocorticoids?

Answer 176

Cushing’s sydrome

Question 177

What disease is caused by adrenocortical insufficiency?

Answer 177

Addison’s disease (high ACTH gives slaty pigmentation)

Question 178

GH, TH and insulin work together to increase growth, in the simplest terms when do they allow growth?

Answer 178

Restrict growth when food is short and enhance growth when food is plentiful

Question 179

Are GLUT 1- 5 glucose transporters passive of Na+ symporters?

Answer 179

Passive

Question 180

Are SGLT-1 and 2 glucose transporters passive or Na+ symporters?

Answer 180

Na+ symporters

Question 181

What is the affinity of GLUT 2 for glucose and which tissue is it found in?

Answer 181

Has low affinity and found in kidneys, ileum, liver and pancreatic beta cells

Question 182

What is characteristic of GLUT 4 for glucose and which tissues is it found in?

Answer 182

insulin responsive (inserted into the membrane in response to insulin), found in skeletal muscle, heart and adipocytes

Question 183

Where are SGLT 1 and 2 glucose transporters found?

Answer 183

In apical brush border of the small intestine

Question 184

Which cells of the islets of Langerhans of the pancreas release insulin?

Answer 184

Beta cells found mostly in the core

Question 185

Which cells of the islets of Langerhans of the pancreas release glucagon>

Answer 185

alpha cells found mostly on the periphery of the gland

Question 186

Which cells of the islets of Langerhans produce somatostatin?

Answer 186

delta cells

Question 187

What do the F cells of the islets of Langerhans release?

Answer 187

pancreatic polypeptide

Question 188

Through what transporter does glucose enter the beta cells of the islets of Langerhans?

Answer 188

GLUT 2 (which is insulin insensitive and low affinity)

Question 189

After the entry of glucose into the beta cells of the pancreas how is insulin released?

Answer 189

1) Beta cells sense glucose (and AA) in the blood by using it to make ATP
2) ATP closes K+ATP channels (Stopping it moving out) depolarising the membrane
3) Depolarisation causes Ca2+ influx (from outside) and CICR (Calcium induced calcium release from the SER)
4) The high levels of calcium induce exocytosis of insulin

Question 190

Which deliver of glucose induces higher release of insulin: IV or oral?

Answer 190

Oral

Question 191

What is significant about the pattern of insulin release with a rapid load of glucose?

Answer 191

Its biphasic (2 peaks)

Question 192

What is the action of the ANS (autonomic nervous system) on insulin release?

Answer 192

PNS drives insulin secretion

SNS inhibits insulin secretion

Question 193

What else acts on insulin release aswell as ANS and glucose?

Answer 193

Secretagogues (incretins) act via cAMP or PLC pathways to increase exocytosis
Inhibitors can antagonise eg. via Gi

Question 194

What is the role of C peptide (from insulin production) in terms of markers?

Answer 194

C peptide is inactive, but clinically is a useful marker of endogenous insulin production

Question 195

What is the rough process (in terms of protein chain etc.) of the production of insulin?

Answer 195

1) Insulin is produced as a preprohormone which is quickly cleaved to a prohormone
2) Internal disulphide bonds fold it up
3) During processing in the Golgi it is cleaved to an A and B chains which are linked and a free C peptide

Question 196

What kind of receptor is the insulin receptor?

Answer 196

Receptor itself is an enzyme - tyrosine kinase receptor

Question 197

How does the insulin receptor work?

Answer 197

The TK domains phosphorylate eachother and nearby proteins, in particular a family of insulin receptor substrates

Question 198

What are the 2 basic pathways that occur once insulin reaches the insulin receptor?

Answer 198

1) Signal and lead to an acute response: GLUT 4 transporters put in membrane and glucose taken up into cells
2) Slower, gene expression is altered, transcription activated (via MAPK pathway) and various proteins made

Question 199

Through which transporter is glucose taken up into the liver?

Answer 199

The GLUT 2 transporter, its non insulin sensitive and has a low affinity for glucose so only takes up a decent amount of glucose when glucose v high

Question 200

What reactions in liver cells are stimulated by insulin?

Answer 200

1) Glycogen storage increased

2) VLDL production increased

Question 201

What reactions in liver cells are inhibited by insulin?

Answer 201

1) Gluconeogenesis inhibited

2) Ketone body production inhibited

Question 202

In response to insulin, through what transporter is glucose taken up into muscle cells and adipose cells?

Answer 202

GLUT 4 inserted and glucose taken up via GLUT 4 - GLUT 4 favours use of glucose

Question 203

What reactions increase in muscle cells in response to insulin?

Answer 203

1) Glycogen synthesis increase
2) Protein synthesis increase
(3) Break down of fatty acids inhibited)

Question 204

Other than insulin what else induces GLUT 4 insertion into the muscle cell membrane?

Answer 204

Exercise via adrenaline

Question 205

What reactions in fat cells are increased and decreased in response to insulin?

Answer 205

1) Triglyceride storage increased
2) Export of FFA (for energy) and glycerol (for gluconeogenesis) reduced
3) LPL exported to endothelium, where it extracts FFA from VLDL (just released by liver in response to insulin)

Question 206

What is glucagon release from alpha cells antagonised and driven by?

Answer 206

Antagonised by glucose and driven by amino acids

Question 207

Proglucagon can be turned into 2 things during primary processing, where does the processing of each take place?

Answer 207

1) Processed to glucagon in the alpha pancreatic cells

2) Processed to GLP1 in intestinal L cells, a potent incretin (as is glucagon itself)

Question 208

What kind of receptor is a glucagon receptor?

Answer 208

GPCR linked to Gs

Question 209

What are the effects of glucagon on liver cells?

Answer 209

1) Glycogen breakdown and gluconeogenesis
2) Presence of G6Pase allows G6P to be broken to glucose and then exported
3) Fatty acids used as an energy source and for ketone body production

Question 210

(At high levels) what are the effects of glucagon on muscle cells and adipocytes?

Answer 210

1) Adipocytes: Lipolysis

2) Muscle: Proteolysis to free up amino acids for gluconeogenesis

Question 211

Why is there no effect of glucagon on muscle and adipocytes normally?

Answer 211

First pass metabolism of liver

Question 212

What is the shift in metabolism to do with when glucose in the blood falls?

Answer 212

Largely due simply to a decrease in insulin as glucose falls

Question 213

Somatostatin is released from what cells in what 3 parts of the body?

Answer 213

Released from the D cells of the stomach, pancreas and duodenum (also released from the hypothalamus - suppresses GH release)

Question 214

What is the main mode of secretion of somatostatin?

Answer 214

Acts in a paracrine fashion (and possibly in an endocrine fashion)

Question 215

What is somatostatin released in response to and inhibited by?

Answer 215

1) release stimulated by [H+]

2) release is inhibited by ACh

Question 216

What is the action of somatostatin?

Answer 216

1) Acts on G cells to inhibit the release of gastrin
2) Inhibits the release of CCK and secretin (and insulin and glucagon, if it can get into cells)
(3) Inhibits release of GH from anterior pituitary)

Question 217

What hormone is released during exercise that causes the metabollic effects of exercise?

Answer 217

Adrenaline (acts through cAMP) (cortisol also has same effects)

Question 218

What are the effects of exercise (ie. adrenaline) on metabollism?

Answer 218

1) Glucose production in liver (inc. via Cori cycle)
2) Glycogen breakdown in muscle and GLUT 4 insertion (also via intrinsic AMPK)
3) Fatty acids released from adipocytes

Question 219

Polyuria, polydipsia, weight loss, blurred vision and ketoacidosis are symptoms of what disease and why?

Answer 219

Diabetes
Polyuria - increase in urine production (glucose lost in urine and pulls water with it)
Polydipsia - more thirsty
Weight loss - losing energy in urine
Blurred vision - high glucose = difficult to focus eyes
Ketoacidosis - liver fooled by lack of insulin so produces ketones (despite high glucose) and brain uses glucose in liver so ketones build up

Question 220

What is the cause of diabetes mellitus (type 1)?

Answer 220

Inability to produce insulin,

autoimmune cells, in which beta cells are destroyed

Question 221

What imbalance in the blood leads to lipolysis, proteolysis, gluconeogenesis and ketogenesis in the liver?

Answer 221

Excess glucagon or glucagon: insulin imbalance

Question 222

What is the cause of diabetes mellitis (type 2)?

Answer 222

Impaired cellular response to insulin - receptor down regulation, reduced signalling
strongly associated with obesity

Question 223

Is ketoacidosis common in diabetes type 2?

Answer 223

no

Question 224

Which kind of diabetes mellitis require exogenous insulin?

Answer 224

Type 1 (type 2 rarely does)

Question 225

What is the treatment for diabetes type 2?

Answer 225

1) diet to reverse the problem
2) Drugs to enhance insulin secretion (sulphonylureas, incretins)
3) Drugs to enhance insulin sensitivity (piaglitazone)
4) Drugs to inhibit gluconeogenesis (metformin)

Question 226

What problems are poor control of diabetes mellitis associated with?

Answer 226

Poor control associated with serious long-term vascular, ocular, renal and neurological problems (glucose binds to stuff and messes it up)

Question 227

Why can IGFs cause hypoglycaemia?

Answer 227

Cross reactivity with insulin