14-32: METABOLISM (GLYCOLYSIS, TCA)

Question 1

Control of metabolic pathways

Answer 1

• change rate of pathway to meet the needs of the cell
• allows adaptation to environment
• 3 main ways:
  1. change amount of enzyme (slow because has to start by changing rate of transcription)
  2. change activity of enzyme (main way; by allosteric regulation -v. fast; or by reversible covalent modification ie. (de) phosphorylation- fast)
  3. availability of substrate

Question 2

allosteric regulation

Answer 2

• allosteric enzymes undergo a conformational change as a result of binding of a regulatory molecule at a site distinct from BS
• changes structure of active site which increases or decreases affinity for S

Question 3

allosteric enzyme example

Answer 3

• PFK1: phosphofructokinase I
• converts Fru-6-P to Fru-1,6-bisP
• hydrolyses a molecule of ATP to transfer P group
• main regulatory step in glycolysis

Question 4

reversible covalent modification

Answer 4

-phosphorylation by protein kinase using ATP
-dephosphorylation by phosphoprotein phosphatase using water to hydrolyse
-enzymes have OH group on Ser or Thr residues that can be phosphorylated
-controlled by hormones:
e.g. insulin (released from pancreas when blood sugar is high)
glucagon (released from pancreas when blood sugar is low)
adrenaline (released from adrenal glands to fight/flight)

Question 5

glycolsysis

Answer 5

1. phosphorylation: Glu to Glu-6-P by hexokinase using ATP molecule
2. isomerization: glu-6-P to fru-6-P by phosphoglucoisomerase; move carbonyl from C1 to C2, aldo to keto sugar
3. phosphorylatiom: Fru-6-P to Fru-1,6-bisP using ATP for group transfer reaction
4. C-C cleavage: glyceraldehyde-3-P
5. oxidation by NAD/phosphorylation using Pi: NAD accepts 2e (reduced); enzyme glyceraldehyde-3-P DH produces 1,3-bisphosphoglycerate
6. ATP production #1: group transfer P from C1 to ADP to generate 3-phosphoglycerate by phosphoglycerate kinase
7. P is moved: from C3 to C2 by phosphoglycerate mutase
8. Dehydration: water removed from 2-phosphoglycerate to give phosphoenolpyruvate by enolase; activates P group for transfer to ATP
9. ATP production #2: unstable enol transfers P to ADP to generate ATP by substrate-level phosphorylation; converted to more stable ketone pyruvate

Question 6

control of glycolysis by allosteric regulation

Answer 6

• at irreversible steps: hexokinase reaction, PFK1 reaction (first committed step), pyruvate kinase reaction
• ATP inhibits PFK1; AMP stimulates it; decreases affinity for substrate
• PFK1 has different isozymes in liver and muscle; same catalytic mechanism but have different regulatory sites
• muscle: low pH inhibits PFK1
• liver: citrate inhibits PFK1; fru-2,6-bisP stimulates PFK1

Question 7

substrate level phosphorylation

Answer 7

• occurs in glycolysis at steps catalysed by phosphoglycerate kinase and pyruvate kinase
• need compound with higher phosphoryl transfer potential than ADP
• hydrolysis of ATP has large -ve ^G; free energy is released

Question 8

control of glycolysis by phosphorylation

Answer 8

• in liver
• pyruvate kinase regulated by reverse phosphorylation
• phosphorylated form is less active
• phosphorylated by protein kinase A (PKA) stimulated by glucagon hormone when blood glucose is low
• when blood glucose is high, P is taken off by phosphoprotein phosphatase

Question 9

importance of producing lactate from pyruvate

Answer 9

• catalysed by lactate DH enzyme
• reduction using NADH; oxidation back to pyruvate using NAD+
• red blood cells: generate NAD+ for glycolysis; do not have mitochondria so rely on glycolysis for ATP production in glyceraldehyde-3-P DH reaction; no mitochondria no ETC to oxidise NADH back to NAD+
• in rapidly contracting muscle, [O2] is low so ox.ph cannot provide ATP so anaerobic glycolysis is used; regenerates NAD+ so glycolysis can take place
• lactate released into blood and transported to liver; liver cells are well oxygenated; ox. ph in mitochondria is used to generate ATP and NAD+; lactate in liver is oxidised back to pyruvate and used to synthesise glucose via gluconeogenesis
• part of cori cycle Glu is released back to blood taken by muscle and red blood cells for glycolsysis

Question 10

Pyruvate dehydrogenase reaction

Answer 10

• links glycolysis to TCA cycle
• occurs in mitochondrial matrix
• PDH large enzyme complex of 3 enzymes + 5 cofactors
• oxidative decarboxylation reaction (1. decarboxylation 2, oxidation 3, transfer to CoA)
• pyruvate (CH3-C=O,COO-) to acetyl coA (CH3-C=O,S-CoA) + CO2
• NAD+ is reduced to NADH

Question 11

NAD+ and NADH

Answer 11

• NAD+ is an oxidizing agent

- it is reduced to NADH

Question 12

Coenzyme A

Answer 12

• acts as an activated carrier of acyl groups (particularly acetyl)
• derived from pantothenic acid (Vit B5)
• CoA = adenine + ribose-3-P + phosphopantotheine
• has very reactive thiol group (SH) which reacts w/carboxylic acid to form thioester; hydrolysis of thioester bond has large -^G so acetyl group from CoA can be readily transferred to other molecules

Question 13

TCA cycle net reaction

Answer 13

• newly generates 3x NADH and 1x FADH2 in ox. phosphorylation
• 1x NADH enter in cycle generates 2.5 ATP
• 1x FADH2 enter in cycle generates 1.5 ATP
• reduced cofactors can carry e into ETC for ATP generation
• no new synthesis of C (oxaloacetate); 2C comes in, 2 comes out

Question 14

TCA cycle

Answer 14

1. CONDENSATION by citrate synthase
   - acetyl CoA + oxaloacetate = citrate
   - methyl group of acetyl CoA to CH2 in citrate
   - needs H2O; releases CoA-SH + H+
2. ISOMERISATION by aconitase
   - citrate to isocitrate
   - reposition OH to set up decarboxylation in next step
3. OX. DECARBOXYLATION by isocitrate dehydrogenase
   - isocitrate to a-ketoglutarate
   - lose 1C as CO2
   - NAD+ accepts 2e to form NADH
4. OX. DECARBOXYLATION by a-ketoglutarate dehydrogenase
   - a-ketoglutarate to succinyl CoA
   - CoA-SH comes in; 1C is lost as CO2
   - requires NAD+
5. SUBS-LEVEL PHOSPHO by succinyl CoA synthetase
   - succinyl CoA to succinate
   - CoA is hydrolysed; energy of thioester bond hydrolysis provides driving force for GTP/ATP synthesis from GDP/ADP + Pi
6. OXIDATION by succinate dehydrogenase
   - succinate to fumarate
   - introduces double bond
   - uses FAD as e acceptor
7. HYDRATION REACTION by fumarase
   - fumarate to malate
   - water is added across double bond; introduces OH into malate
8. OXIDATION by malate dehydrogenase
   - malate to oxaloacetate
   - oxidation of OH to C=O
   - uses NAD+
   - regenerates oxaloacetate; available to react w/another acetyl CoA and cycle continues

Question 15

TCA building blocks to synthesise other molecules

Answer 15

• citrate used to synthesise fatty acids and sterols
• a-ketoglutarate and oxaloacetate important precursors for AAs
• oxaloacetate precursor for nucleotides
• succinyl CoA used to make porphyrins and haem

Question 16

generation of ATP from TCA cycle

Answer 16

1. substrate-level phosphorylation
   - succinyl CoA to succinate (hydrolysis of thioester, CoA, provides enough energy to synthesise ATP/GTP)
   - catalysed by succinyl CoA synthetase; 2 forms of enzyme in mammals
2. oxidative phosphorylation (main way)
   - NADH and FADH2 are produced and reoxidised in the ETC as they pass e (eventually to O); the passage of e is coupled to ATP production

Question 17

electron carriers

Answer 17

NAD+

• made from niacin (vit B3); has nicotinamide ring
• requires higher energy to be reduced
• always releases H+

FAD
-made from riboflavin (vit B2); has flavin compound
-does not release H+
(* in oxidation of succinate, energy change of reaction is not high enough to reduce NAD)

-both can accept 2e; have adenine + 2 ribose

Question 18

production of oxaloacetate to replenish TCA cycle

Answer 18

• pyruvate carboxylase reaction
• required to replace intermediates taken out of TCA cycle for biosynthesis
• anapleurotic reaction
• pyruvate uses bicarbonate in ATP dependent reaction
• biotin is uses as a cofactor (derived from vit B7)
  1. biotin (attached via amide linkage to lys residue on enzyme) reacts w/bicarbonate; requires ATP hydrolysis
  2. pyruvate comes in and oxaloacetate is generated

Question 19

allosteric regulation of TCA cycle

Answer 19

• responds to energy change (ATP:AMP ratio)
• entry of pyruvate is regulated –PDH inhibited by ATP, NADH, acetyl coA
• isocitrate DH inhibited by ATP, NADH; activated by ADP
• a-ketoglutarate DH inhibited by ATP, NADH, succinyl CoA

Question 20

PDH regulation

Answer 20

PDH is regulated by reversible phosphorylation

• the Ser residue on E1 subunit is phosphorylated
• P PDH is inactive
• PDH kinase uses ATP to add P; activated by NADH, acetyl CoA, ATP
• PDH phosphatase hydrolysis off the P; activated by Ca2+ in muscle which is high when muscle contracts which requires ATP