Metabolism

Question 1

Name the 3 non carbohydrate precursors of glucose :

Answer 1

1 lactate
2 amino acids (alanine in skeletal muscle)
3 glycerol (triacylglycerols in fat tissue )

Question 2

Which organs are involved in gluconeogenesis :

Answer 2

Liver (90%), kidney and small intestine

Question 3

Where in the cells does gluconeogenesis occur?

Answer 3

Cytosol (except for the first reaction )
Most of the same glycolysis enzymes involved

Question 4

Summarise how gluconeogenesis occurs:

Answer 4

Reversal of glycolysis except for 3 steps

1. Pyruvate converted to PEP
2. F1,6BP converted to F6P
3. G6P converted to glucose

Question 5

Explain the importance of pyruvate carboxylate

Answer 5

Catalyses an important anapleurotic reaction
This means it maintains the conc of Krebs cycle intermediates, allowing it to be a continuous process

Question 6

Name the reactions involved in gluconeogenesis and the enzymes involved

Answer 6

Question 7

How do the 3 glucose precursors join the gluconeogenesis pathway ?

Answer 7

Lactate —> pyruvate
Lactate DH

Amino acids —> oxaloacetate + pyruvate
Transamination

Glycerol —>dihydroxyacetone phosphate —>glyceraldehyde 3-phosphate

Question 8

State the 2 condition for gluconeogenesis

Answer 8

Low [glucose] and high [ATP]

Question 9

glycolysis and gluconeogenesis can occur simultaneously

true or false

Answer 9

False

when one pathway is active, the other must be inactive

Question 10

What conditions inhibit Gluconeogenesis

Answer 10

High AMP/F1,6P/ADP

Question 11

What conditions stimulate gluconeogenesis

Answer 11

High acetyl CoA / citrate

Question 12

What conditions inhibit glycolysis

Answer 12

High ATP/Citrate/H+/alanine

Question 13

What conditions stimulate glycolysis

Answer 13

High F2,6P as this stimulate PFK-1 involved in the irreversible step; high AMP (as this indicate there is low ATP); insulin secretion

Question 14

Describe the effects of insulin

Answer 14

Promote synthesis of glycolysis enzymes e.g. PFK/PK/PFK2
Inhibit synthesis of PEPCK ; this inhibits gluconeogenesis

Question 15

Describe the effects of glucagon

Answer 15

Increases expression of PEPCK/F1,6BPase

increased gluconeogenesis

Question 16

Draw the Krebs cycle

Answer 16

citrate is krebs special substrate for making oxaloacetate.

Question 17

What is the PDH reaction

Answer 17

the link reaction

converts pyruvate to acetyl CoA

Question 18

Name the4 5 coenzymes of PDH

Answer 18

Thiamine pyrophosphate (TPP)

Lipoamide

CoA

FAD⁺

NAD⁺

Question 19

draw the mechanism of the PDH reaction

Answer 19

Question 20

Name the 3 enzymes found within the PDH complex

Answer 20

E1 pyruvate decarboxylase

E2 hydrolipoyl transacetylase

E3 dihydrolipoyl dehydrogenase

Question 21

What conditions cause activation of PDH

Answer 21

Increased [insulin] and [Ca2+]

this cause dephosphorylation of PDH

Question 22

What conditions cause the inhibition of PDH

Answer 22

Increased ATP/NADH/Acetyl CoA

results in phosphorylation of PDH via kinase

Question 23

Name the 3 enzymes needed for glycogen formation

Answer 23

Glycogenin

glycogen synthase

branching enzyme

Question 24

State the role of glycogenin

Answer 24

Combine UDP-glucose (activated form of glucose) to tyrosine

Question 25

describe the role of glycogen synthase

Answer 25

Make alpha 1,4 glycosidic bond cause the chain to extend

Question 26

describe the role of the branching enzyme

Answer 26

Breaks off part of the amylose chain and branches it via the formation of alpha 1,6 glycosidic bonds

Question 27

When does glycogenesis occur in the liver and skeletal muscle

Answer 27

In the liver - during well fed periods

in skeletal muscle : during rest periods

Question 28

Describe the hormonal regulation of glycogenolysis

Answer 28

Glucagon bind to receptors on hepatocytes / adrenaline binds to myocyte/hepatocytes

adenylyl cyclase activated by G proteins ; makes cAMP

cAMP activates protein kinase A ; phosphorylates glycogen

inhibition of glycogen synthesis

Question 29

Characteristics of high energy state

Answer 29

Question 30

Characteristics of low energy state

Answer 30

Question 31

Breakdown of adipose tissue forms:

Answer 31

Triacylglycerol which is converted to free fatty acid (FFA) and glycerol

glycerol acts as a gluceneogenic substrate

FFA form acetyl CoA

Question 32

describe the structure of triacylglycerol

Answer 32

glycerol backbone with 3 fatty acid chains attached

the fatty acid chains may be saturated or unsaturated

Question 33

Describe the mobilisation of fatty acids

Answer 33

In response to glucagon or adrenaline , hormone-sensitive lipase hydrolyses triacylglycerol in adipose tissue to free fatty acids and glycerol

Question 34

How are fatty acids transported to the skeletal muscle from adipose tissue?

Answer 34

Free fatty acids(FFA) bind to albumin in blood and travel via circulation to muscle

Question 35

Describe mitochondrial beta oxidation of fatty acids

Answer 35

Long Chain fatty acids (LCFA) activated in cytosol to form fatty acyl CoA

these are then transported to mito where beta oxidation in matrix occurs to form NADH, FADH2 and acetyl CoA

2C removed from fatty acids in each round ; this continues until the LCFAs are fully broken down

Question 36

State the energy yield starting with a C16 saturated fatty acid (typical fatty acid)

Answer 36

7FADH₂ = 14 ATP (beta-oxidation occurs 7 times)

7NADH = 21 ATP

8 acetyl CoA = 96 ATP via the TCA cycle

Net yield of 129 ATP (2 needed to form LC fatty acylCoA)

Question 37

Describe the pathway of fatty acid synthesis

Answer 37

Acetyl CoA (2C-CoA) ⇒ malonyl CoA (3C-CoA) ⇒ 16C-CoA ⇒TAG

Question 38

state the two functions of acetyl CoA

Answer 38

Fed into TCA cycle

form ketone bodies

Question 39

What are Ketone bodies

Answer 39

Alternate fuel for cells during starvation/uncontrolled diabetes ; especially important for brain

made from acetyl CoA in liver mitochondria

occur when high [AcCoA]

Question 40

Name the ketone bodies

Answer 40

Acetoacetate ⇒ beta-hydroxybutyrate + acetone

Question 41

Utilisation of ketone bodies

Answer 41

preferentially metabolised in brain/heart during starvation to preserve glucose for use elsewhere

Question 42

Ketoacidosis - what is this

Answer 42

when [ketone body] is too high , ketones are secreted in urine (ketonuria)

ketone bodies are acidic so lower blood pH which can be life threatening

Question 43

what is cholesterol

Answer 43

essential molecule

component of cell membrane

precursor to bile acids, steroid hormones and vitamin D

Question 44

Biosynthesis of cholesterol

Answer 44

Question 45

what is the purpose of lipoproteins

Answer 45

Allow transport of lipids around the body

Question 46

Structure of lipoproteins

Answer 46

Globular shape

outer layer of unesterified cholesterol and phospholipid

inside cholesteryl ester and TAG

apoprotein wrapped around the outside

Question 47

Function of apoproteins

Answer 47

Interact with cellular receptors

activate and inhibit enzymes involved in lipoprotein metabolism

Question 48

Function of chylomicrons

Answer 48

Secreted into lymph and reach blood plasma via thoracic duct

they are then transported to adipose tissue or muscle where they are converted to FFA so they can cross the capillary endothelium

the FFA are then converted back into TG once inside the adipose/muscle tissue

Question 49

describe the intestinal uptake of dietary lipids

Answer 49

Triacylglycerides broken down fatty acids + monocyglycerols just outside cell then recombined once they enter the cell

triacylglycerides are combined with other lipids and proteins to form chylomicrons which are transported to circulatory system via the lymph system

Question 50

What is the importance of the apoprotein CII

Answer 50

Activates lipoprotein lipase (LPL)

LPL catalyses the reaction TG⇒FFA + glycerol

LPL found on surface of endothelial cells

this means FFA are liberated when chylomicrons reach their end destination in the blood

Question 51

What are chylomicron remnants ?

what is their function ?

Answer 51

They are also formed when the CM are converted to FFA to allow exit from the plasm a

CM remnant deliver dietary cholesterol to the liver

Question 52

What are endogenous lipids ?

Answer 52

Formed when there is excess carbohydrate and lipids in diet

excess carbs/lipids ⇒ TAG (in liver)

Question 53

What are endogenous lipids ?

Answer 53

Formed when there is excess carbohydrate and lipids in diet

excess carbs/lipids ⇒ TAG (in liver)

Question 54

What is VLDL

Answer 54

Transports endogenous TAGs to peripheral tissues

Question 55

What are IDLs

Answer 55

Intermediate density lipoprotein

formed by removal of triacylglycerol from VLDL

they can either be sent to the liver and be destroyed or lose more triacylglycerol and become LDL such as cholesterol

Question 56

What is LDL

Answer 56

Formed via the removal of TG from IDL

contains apoB-100, esterified cholesterol and normal cholesterol

major cholesterol carrier to tissues

high levels of LDL associated with CHD

Question 57

Compare metabolism of dietary lipid vs endogenous lipids

Answer 57

Digestive lipids absorbed in liver; endogenous in liver

digestive lipids converted to CMs; endogenous to VLDL

both VLDL and CM catalysed by LPL to release FFA

VLDL broken down to form FFA and IDL ; CM broken down to form FFA and CM remnants

CM remnants go to liver ; IDL can either be converted to LDL or be destroyed in liver

Question 58

What is HDL

Answer 58

Transports cholesterol from peripheral tissue to liver ; this is called reverse cholesterol transport

it helps protect against CHD

Question 59

Define anabolism

Answer 59

Synthesise large molecules

Question 60

What are the 4 types of metabolic pathways

Answer 60

fuel oxidative pathways (breakdown substrates)

fuel storage and mobilisation

bio synthetic pathways

detoxification and waste disposal pathways

Question 61

What is catabolism

Answer 61

Breakdown on large molecules

Question 62

What is metabolic homeostasis

Answer 62

Control of the balance between substrate availability and need caused by anabolic and catabolic pathways

Question 63

Glucagon :

Where does it act

where is it made?

describe its effects

Answer 63

Made by alpha cells in islets of lagerhans in pancreas

Glucagon acts to maintain fuel availability

principally acts in liver and adipose tissue not in muscle however

Promotes glycogenolysis and gluconeogenesis/ketogenesis

mobilises fatty acids from adipose triacylglycerols

reduces glycogen synthesis in liver

increasses [adrenaline]

Question 64

how is insulin made?

Describe the action of insulin

Answer 64

Polypeptide synthesised as a preprohormone

degraded by liver, kidney and skeletal muscle where its converted to its final form

Acts on liver, muscle and adipose tissue

Question 65

How is glucagon made

Answer 65

Produces as preprohormone in RER

degraded by liver and kidneys

Question 66

What promotes glucagon release?

Answer 66

release of catceholamines (such as adrenaline)

high amino acid conc

low blood glucose

Question 67

Describe the 2 types of signal transduction

Answer 67

Receptor coupled to adenylate cyclise to produce cAMP

receptor/kinase activity

receptor couples to hydrolysis of PIP₂

Question 68

intracellular effects of insulin

Answer 68

overall has an anabolic effect

effect on carb metabolism:

• stimulates uptake of glucose from blood
  
  • incorporation of vesicles with GLUT4 receptors into membrane
• stimulates storage of glucose in liver primarily
  
  • phosphorylation of glucose/PFK/glycogen synthase = increased glycogen synthesis
• cells driven to preferentially oxidise carbs over fatty acids/AA

effect on lipid metabolism:

• promotes synthesis of FAs in liver from excess glucose which are then used to make lipoproteins which travel in blood
• promotes accumulation of TGs in adipose tissue by inhibiting hydrolysis of TGs

effect on protein metabolism

• increased uptake of amino acids/ protein synthesis

Question 69

intracellular events of glucagon

Answer 69

Secondary messenger activation

glucagon binds to G-protein coupled receptor

G protein dissociates = cAMP formed = protein kinase activated

protein kinase phosphorylase’s regulatory enzymes in order to control lipid/carb metabolism

Question 70

Complete this table

Answer 70

Question 71

what is the fed state ?

Answer 71

Period of 2-4 hrs after a meal

characterised by an anabolic state : increased TAG and glycogen synthesis

Question 72

How is the liver adapted for metabolism

Answer 72

Blood containing nutrients and hormones from gut and pancreas directly passes through liver before returning to heart

the liver absorbs the carbs/lipids/aa to be broken down, stored or redistributed

Question 73

Excess glucose is converted to ….

Answer 73

TAG which is then packages into very low density lipoproteins (VLDL)

Question 74

What happens after carb intake occurs

Answer 74

Increased glucose uptake by hepatocytes ; insulin independent glucose transporters (GLUT-2) have high Km

increased phosphorylation of glucose

excess glucose to form TAG

increased glycogenesis

increased activity of the pentose phosphate pathway/hexose monophosphate (uses up to 10% of glucose)

Question 75

When does glycolysis mainly occur ?

Answer 75

Glycolysis mainly occurs during the absorptive period after a carb rich meal

Question 76

Where is the primary site of fatty acid synthesis

Answer 76

The liver

Question 77

Describe the degradation of amino acids

Answer 77

Deamination of amino acids to form urea

carbon skeleton will be degraded to pyruvate, acetyl CoA, or TCA cycle intermediates

Question 78

What is the function of the pentose phosphate pathway

Answer 78

Produce NADPH which is needed for fat synthesis

Question 79

what occurs in the skeletal muscle during the fed state

Answer 79

Glucose used to replenish glycogen stores depleted by exercise

increased uptake of BCAAs

increased insulin:glucagon

FAs are of secondary importance to glucose during resting stage

Question 80

Describe the fuel used by the brain tissue

Answer 80

No significant glycogen/TAG stores as they cannot cross the blood-Brian barrier

blood glucose is the fuel used and sometimes ketone bodies

Question 81

Describe the symptoms refeeding syndrome

Answer 81

after prolonged starvation, a meal can bring complications

symptoms:

most commonly hypophosphataemia

hypokalaemia(cuases arrhythmias and cardiac arrest) and hypomagnesaemia (cardiac dysfunction)

can be fatal

Question 82

what kind of people at risk of refeeding syndrome

Answer 82

malnourished due to anorexia nervosa, dysphagia, alcoholism, depression, old age, uncontrolled diabetes

reduced ability to absorb due to bowel disorders such as IBS, coeliac disease, CF

increased metabolic demands due to cancer or surgery

Question 83

What happens during refeeding syndrome

Answer 83

During starved state, ketones and FAs become major fuel source

during prolonged starvation, intracellular minerals become depleted (These are needed as cofactors); with the aim to preserve muscle breakdown, decreased use of FA and ketones, brain switches to ketones

during refeeding, shift back to carb metabolism ;

insulin stimulates macromolecule synthesis which requires minerals

uptake of minerals by cell from blood leads to osmotic issues in cells and lack of PO₄^2-, K⁺ and Mg²⁺ in blood

Question 84

Breakdown of carbohydrates

Answer 84

digested by alpha-amylase and disaccharidases

glucose is oxidised for energy

glucose forms the carbon skeleton of most compounds

Question 85

Protein breakdown

Answer 85

cleaved by pepsin in stomach and proteolytic enzymes in pancreas

proteins used for neurotransmitter and heme synthesis

carbon skeleton may be oxidised

Question 86

How does glucose enter b-cells?

Answer 86

GLUT-2 transporter = facilitated diffusion phosphorylated by glucokinase glucose-6-phosphate metabolised via glycolysis

Question 87

what happens after glucose enters Beta cells in islets of langerhans ?

Answer 87

ATP levels rise rise in ATP = potassium pump starts working, leaves cell, voltage potential changes, calcium diffuses in, signalling molecules are told to release insulin

Question 88

How does the liver aid in metabolism?

Answer 88

connection between digestive tract and circulatory system

venous drainage of gut and pancreas passes through the hepatic portal vein

liver takes up carbohydrates, lipids and amino acids from blood

Question 89

describe carb metabolism during the fed state [7]

Answer 89

Increased glucose uptake by hepatocytes (GLUT2),

increased phosphorylation of glucose (glucokinase creates G6P),

Excess glucose is converted to TAG (packaged in VLDL),

increased glycogenesis (glycogen synthase activated),

increased activity of pentose phosphate pathway,

increased insulin-to-glucagon results in increased

glycolytic enzymes (glucokinase, PFK1, pyruvate kinase), decreased production of glucose

Question 90

Import of LCFAs into mitochondria

Answer 90

CoA esters cannot cross mitochondrial inner membrane,

long chain fatty acyl group transferred to carnitine,

LCF acyl carnitine transported into mitochondrial matrix (carnitin exported),

LCF acyl group transferred to CoA

Question 91

how do short and medium fatty acids get converted to fatty acylCoAs?

Answer 91

short and medium chain fatty acids pass directly into mitochondria where they are activated to fatty acylCoAs

Question 92

describe carbohydrate metabolism (starved state)

Answer 92

Liver: Glycogen degradation occurs first, followed by gluconeogenesis. Also produces ketone bodies.

The carbon skeletons from gluconeogenesis are derived from glucogenic aa, lactate from muscle and glycerol from adipose tissue.

Question 93

reaction 1 of glycolysis

Answer 93

Irreversible.

Phosphorylation: -traps glucose inside the cell;

-ive charge at physiological pH.

conserves metabolic energy.

phosphates interact with enzyme active sites and lower activation energy.

Catalysed by GLUCOKINASE in the liver or HEXOKINASE in muscle/fat.

Question 94

describe reaction 3 of glycolysis

what are the enzymes involved

what type of reaction is it

Answer 94

the phosphorylation of fructose 6-phosPhate

irreversible reaction,

rate limiting,

catalysed by phosphofructokinase-1.

Most important control point

Inhibited by high ATP and citrate

Question 95

how are glycogenolysis and calcium linked

Answer 95

calcium is released into cytoplasm after neutral stimulation, released from sarcoplasmic reticulum

this leads to glycogenolysis in the muscle

Question 96

what is the importance of glycerol ?

Answer 96

transported to liver, phosphorylated to glycerol-3-phosphate and converted to DHAP: used in glycolysis or gluconeogenesis

Question 97

gluconeogenesis ;

when does it occur and which substrate is used

Answer 97

Exercise: lactate Sort term fasting: alanine Diabetes: insulin sensitivity Trauma: peripheral insulin resistance

Question 98

how is metabolic flux controlled?

Answer 98

by controlling enzymes involved, hence inhibiting or stimulating different reactions

Question 99

when does the starved state occur?

Answer 99

>3 days after last meal

Question 100

Describe the fuel use of muscle

Answer 100

Glucose, fatty acids and ketone bodies

glycogen store can be converted to glucose for contraction (glucose prioritised for contraction)

FAs are primarily used by resting muscle

Question 101

Describe the fuel use of the heart

Answer 101

Fatty acids

ketone bodies

lactate

no glycogen reserves

Question 102

Describe the fuel use of adipose tissue

Answer 102

Needs glycerol 3-phosphate to creat triacylglycerols

needs glucose for glycolytic intermediate dihydroxyacetone phosphate (then it is reduced to G-3-P)

Question 103

Metabolic functions of liver

Answer 103

makes fuel for brain, muscle and peripheral organs

metabolises ⅔ of glucose to form glycogen

turns fatty acids to ketone bodies

uses alpha-keto acids from amino acids

Question 104

Describe what occurs in the liver during the starved state

Answer 104

in liver:

• glycogenolysis first then gluconeogenesis
  
  • increased glucagon:insulin
  • Carbon skeletons of glucose derived from glucogenic amino acids, lactate from muscle and glycerol from adipose
• ketone body production (conc drops during prolonged starvation due to organ shutdown)
  
  • NADH produced inhibits TCA cycle
    
    • Acetyl CoA produced activates pyruvate carboxylase and inhibits pyruvate dehydrogenase
• Fatty acid Oxidation is the major energy source

Question 105

What occurs in adipose tissue during the starved state

Answer 105

TAG lipolysis = releases FAs

decreased uptake of fatty acids and glucose so reduced glycolysis/TAG synthesis

Question 106

role of kidney in fasting state

Answer 106

In late fasting 50% of gluconeogenesis occurs here

uses self generated glucose

compensates for acidosis caused by ketone bodies

Question 107

Summary of starved state

Answer 107

at first brain uses glucose

beyond 2-3 weeks ketone bodies replace glucose usage

as glucose no longer required, protein catabolism for gluconeogenesis not needed either - lower protein degradation

kidney becomes more important : most gluconeogenesis occurs here now to provide kidneys with glucose to counteract acidosis from ketone bodies

Question 108

Diabetes mellitus

type 1

describe and explain the symptoms

Answer 108

early onset - childhood or adolescence; hyperglycaemia causes increased urination/thirst/weight loss/ increased appetite; diabetic ketoacidosis = persistent fatigue, dry or flushed skin, abdominal pain, nausea or vomiting, confusion, trouble breathing, and a fruity breath odor

Question 108

Diabetes mellitus

type 1

describe and explain the pathophysiology

Answer 108

caused by autoimmune attack on beta cells in islets of langerhans

hyperglycaemia and ketoacidosis :

• increased gluconeogenesis
• increased mobilisation/oxidation of FAs
  
  • leads to increased 3-hydroxybutyrate and acetoactetate

Hypertriacylglycerolemia:

• excess FAs are converted to TAG
• low lipoprotein degradation by LPL
  
  • reduced enzyme production
    
    • excess chylomicrons and VLDL

Question 109

Type II diabetes

explain the pathophysiology

Answer 109

Caused by a combination of insulin resistance and dysfunctional beta cells

hyperglycaemia

• increased hepatic production and reduced peripheral use
• ketosis is minimal as insulin is usually present in small amounts

dislipidemia

• FAs converted to TAG and secreted as VLDL (can cause plaques)
• chylomicrons synthesised from dietary lipids in intestine
• but LPL is low so VLDL/chylomicrons are elevated

Question 110

Describe how ATP is formed from NADH and FADH₂

Answer 110

TCA cycle produces 1 FADH₂ and 3NADH molecules (8 e- in total)

NADH binds to complex I and it transfers its e- to CoQ ; 4 H+ pumped from matrix to IMS

complex II accepts e- from FADH₂ and transfers them to CoQ

CoQ transfer all these e- to complex III ; e- accepting by heme group within ; the e- are then given to cytochrome c ; 2 H+ also pumped

cytochrome c transfer the e- to complex IV ; e- transferred to oxygen to form water ; 8 protons pumped across

Question 111

Describe the ETC

Answer 111

Found on inner mitochondrial membrane

4 protein complexes :

3 proton pumps(complexes I,III and IV) and 1 linking to the TCA cycle (complex II)

2 small components:

CoQ and cytochrome C - they are free to move inbetween membranes

H+ return to matrix via ATP synthase; coupled with ATP synthesis

NADH makes 3 ATP

FADH₂ makes 2 ATP

Question 112

Name 3 examples of ETC inhibitors

Answer 112

cyanide

azide

CO

(all these inhibit complex IV)

Question 113

Name 3 examples of ETC uncouplers

Answer 113

Dinitrophenol (synthetic)

thermogenin (natural)

Question 114

what would high lactate DH in blood indicate?

Answer 114

lots of anaerobic resp so there must be a lack of oxygen ; MI/ischaemia/necrotic bowel