Ch. 9

Question 1

What do the central metabolic pathways do (i.e. what do they provide)?

Answer 1

Provide the precursors for all other pathways

Question 2

What are the major carbohydrate pathways? Which are only in prokaryotes?

Answer 2

• Glycolysis
• Pentose phosphate pathway (PPP)
• Entner-Doudoroff (ED) pathway: prokaryotes

Question 3

What 2 generalizations can be made about the 3 carbohydrate pathways?

Answer 3

1. All pathways convert glucose to phosphoglyceraldehyde (PGA)
2. All PGA to pyruvate (oxidation reaction) via the same reaction

Question 4

What happens to pyruvate in respiration vs. fermentation?

Answer 4

• Respiration: pyruvate –> oxidized to acetyl-CoA –> oxidized to carbon dioxide in the citric acid cycle
• Fermenation: converted to end products (alcohols, organic acids, solvents)

Question 5

Give an overview of carbohydrate catabolic pathways:
1. How many SLPs are there and when do they occur?
2. How many oxidation reactions are there and when do they occur?
3. What do the oxidations produce?
4. What happens to the oxidation products?

Answer 5

1. 3 SLPs
   - 2 during carbohydrate catabolism
   - 1 in citric acid cycle
2. 6 oxidation reactions
   - 1 in glycolysis
   - 1 in pyruvate dehydrogenase reaction
   - 4 in citric acid cycle
3. NADH and FADH₂
4. They get reoxidized into NAD⁺ and FAD

Question 6

What are the 2 stages of glycolysis? How many ATPs are used or generated per glucose?

Answer 6

1. Catalyzes the splitting of the glucose molecule into 2 phosphoglyceraldehyde molecules
   - 2 ATPs used per glucose
2. Catalyzes the oxidation of phosphoglyceraldehyde to pyruvate
   - 4 ATPs generated

Question 7

What is the net yield of ATP in glycolysis?

Answer 7

2 ATP

Question 8

What are the equations for the 2 stages of glycolysis? What is their sum?

Answer 8

• Stage 1: glucose + 2 ATP –> 2 PGALD + 2 ADP
• Stage 2: 2 PGALD + 2P_i + 4 ADP + 2 NAD⁺ –> 2 pyruvate + 4 ATP + 2 NADH + 2 H⁺
• Sum: glucose + 2 ADP + 2 P_i + 2 NAD⁺ –> 2 pyruvate + 2 ATP + 2 NADH + 2 H⁺

Question 9

What are the major outcomes of glycolysis?

Answer 9

• ATP is generated via SLP
• Provides precursor metabolites for many other pathways

Question 10

What must organisms do when they’re not growing on carbohydrate?

Answer 10

They must synthesize glycolytic intermediates from other carbon sources

Question 11

Why can the glycolytic pathway only be reversed from PEP to fructose 1,6-bisphosphate (FBP), and not at all from pyruvate?

Answer 11

Because the high free energy in the phosphoryl donors with respect to the phosphorylated products renders the kinase reactions irreversible
- Therefore, to reverse glycolysis, the kinase reactions are bypassed

Question 12

What are the 2 key enzymes in regulating the directionality of carbon flow in glycolysis?

Answer 12

1. Phosphofructokinase (PFK)
2. Fructose-1,6-bisphosphate kinase

Question 13

In glycolysis, high AMP and ADP concentrations are a signal that ATP levels are low. This is an example of _____ regulation.

Answer 13

allosteric

Question 14

What is the result of the glycolysis regulation?

Answer 14

ADP promotes glycolysis, AMP inhibits gluconeogenesis

Question 15

_____ is feedback inhibited by PEP. This is an example of _____ inhibition.

Answer 15

1. phosphofructokinase
2. end-product

Question 16

Consider the isomerization of glucose-6-phosphate to fructose-6-phosphate. What is the rationale for this isomerization?

Answer 16

It creates an electron-attacking keto group at the C2 of the sugar
- Necessary to break the bond between C3 and C4 in the aldolase reaction

Question 17

NAD⁺ is reduced during central metabolism. What would happen if it is not reoxidized?

Answer 17

All pathways (including glycolysis) that require NAD⁺ would stop

Question 18

What are the 3 NADH reoxidation pathways in bacteria?

Answer 18

1. Respiration
2. Fermentation
3. Hydrogenase reaction

Question 19

Why is the PPP important?

Answer 19

1. It produces the pentose phosphates (precursors to ribose and deoxyribose in nucleic acids)
2. It provides erythrose phosphate (precursor to aromatic amino acids)
3. Produces NADPH (source of electrons for biosynthesis)
4. Several reactions are the same as those in the Calvin cycle

Question 20

What are the 3 stages of the PPP? What are the products of each stage?

Answer 20

1. Oxidation-decarboxylation reactions
   - Produces CO₂ and NADPH
2. Isomerization reactions
   - Produces precursors for stage 3
3. Sugar rearrangements
   - Produces phosphoglyceraldehyde

Question 21

Stage 1 of the PPP:
- General description
- Steps
- What are the products?
- What enzymes are involved?

Answer 21

• Reactions oxidize the C1 in glucose-6-P to a carboxyl group and remove it as carbon dioxide
• Steps
  1. Glucose-6-P is oxidized by NADP⁺ to 6-P-gluconolactone by glucose-6-P dehydrogenase
  2. Hydrolysis: 6-P-gluconolactone –> 6-P-gluconate by gluconolactonase
  3. Oxidation: 6-P-gluconate is oxidaized on the C3 –> keto group β to the carboxyl
  4. β-decarboxylation: generates ribulose-5-P
• Products: CO₂, NADPH, RuMP
• Enzymes: G-6-P dehydrogenase, gluconolactonase

Question 22

Stage 2 of the PPP:
- What happens in it?
- What are the enzymes involved and what products do they make?

Answer 22

• Some RuMP is isomerized to ribose-5-P and xylulose-5-P
• RuMP epimerase makes xylulose-5-P (moves -OH group)
• R-5-P isomerase makes ribose-5-P (moves keto group)

Question 23

Stage 3 of the PPP:
- What are the 2 types of sugar arrangements (i.e. what enzyme)?

Answer 23

1. Tranketolase (TK): transfers 2-carbon fragments from a ketose to an aldose
2. Transaldolase (TA): transfers 3-carbon fragment from a ketose to an aldose

Question 24

What are isomers?

Answer 24

Molecules with the same chemical formula but different structural formulas

Question 25

What is the rule for sugar rearrangements?

Answer 25

The donor is always a ketose and the acceptor is always an aldose

Question 26

Summarize the PPP (what is each reaction, products).

Answer 26

A. Reactions 1-3: oxidative decarboxylation reactions of stage 1
- Produces 3 moles of ribulose-5-P
B. Reactions 4 and 5: isomerization reactions of stage 2
- Produces 1 mole of of ribose-5-P and 2 moles of xylulose-5-P
C. Reaction 6-8: sugar rearrangements of stage 3
- Reaction 6: TK reaction
- Reaction 7: TA reaction
- Reaction 8: TK reaction

Question 27

Some bacteria rely completely on the PPP for _____.

Answer 27

sugar catabolism

Question 28

Where do the PPP and glycolysis interconnect?

Answer 28

At phosphoglyceraldehyde and fructose-6-P

Question 29

What are the reactions of the Entner-Doudoroff (ED) pathway?

Answer 29

2. Oxidation of C1 in glucose-6-P to the carboxyl in 6-P-gluconate
3. Dehydration reaction forms KDPG
4. KDPG is split by KDPG aldolase to pyruvate and phosphoglyceraldehyde
   5-9. identical to stage 3 of glycolysis

Question 30

Why does the ED pathway generate less ATP than glycolysis?

Answer 30

ED pathway only produces 1 phosphoglyceradehyde (glycolysis makes 2 phosphoglyceraldehyde)

Question 31

Give an example of the use of the ED pathway.

Answer 31

E. coli transferred from a medium containing glucose as the carbon source to one with gluconate as the carbon source

Question 32

What are the 2 fates of pyruvate?

Answer 32

1. Fermentation
2. Oxidation to acetyl-CoA –> citric acid cycle –> oxidized completely to CO₂

Question 33

The oxidation of pyruvate to acetyl-CoA during aerobic growth is carried out by the enzyme complex _____.

Answer 33

pyruvate dehydrogenase

Question 34

What are the 3 enzymes of the PDH complex?

Answer 34

1. E1: pyruvate dehydrogenase
2. E2: dihydrolipoate transacetylase
3. E3: dihydrolipoate dehydrogenase

Question 35

What are the 5 cofactors of the PDH complex?

Answer 35

1. Thiamine pyruphosphate (TPP)
2. FAD
3. α-lipoic acid (RS₂)
4. NAD⁺
5. Coenzyme A

Question 36

What are the 5 steps of the PDH complex?

Answer 36

1. E1: Pyruvate decarboxylated –> active acetaldehyde bound to TPP
2. E1: Active acetaldehyde oxidized to a carboxyl by disulfide in lipoic acid; TPP displace
3. E2: Transacetylation (lipoid acid displaced by CoA-SH –> acetyl-CoA)
4. E3: Lipoate electron transferred to FAD
5. E3: Electrons transferred from FADH₂ to NAD⁺

Question 37

The physiologically irreversible PDH reaction is under allosteric regulation. How is the PDH reaction regulated?

Answer 37

1. Feedback inhibition (end product): acetyl-CoA and NADH
2. Positive regulation: PEP (signals that more pyruvate is on the way) and AMP (signals low ATP)

Question 38

What is the rationale behind end product inhibition of the PDH reaction?

Answer 38

Ensures that the enzyme only produces as much acetyl-CoA and NADH as can be used immediately

Question 39

What does the citric acid cycle produce?

Answer 39

• 2 NADH
• 1 NADPH
• 1 FADH₂
• 1 ATP via SLP

Question 40

What are the following molecules precursors for and what pathway are they from?

Answer 40

Question 41

What are the 10 reactions of the citric acid cycle?

Answer 41

1. Addition of acetyl group fro acetyl-CoA to oxaloacetate –> citrate
2. Dehydration of citrate –> cis-aconitate
3. Rehydration of cis-aconitate –> isocitrate
4. Oxidation of isocitrate –> oxalosuccinate
5. Decarboxylation of oxalosuccinate –> α-ketoglutarate
6. Oxidative decarboxylation of α-ketoglutarate –> succinyl-CoA
7. SLP forms ATP
8. Oxidation of succinate –> fumarate
9. Hydration of fumarate –> malate
10. Oxidation of malate -> oxaloacetate

Question 42

What are the enzymes for each of the reactions in the citric acid cycle? Which ones are irreversible?

Answer 42

1. Citrate synthase (irreversible)
2. Aconitase
3. Aconitase
4. Isocitrate dehydrogenase
5. Isocitrate dehydrogenase
6. α-ketoglutarate dehydrogenase (irreversible)
7. Succinate thiokinase
8. Succinate dehydrogenase
9. Fumarase
10. Malate dehydrogenase

Question 43

How is the citric acid cycle regulated in Gram-negative vs. Gram-positive bacteria?

Answer 43

1. Gram-negative bacteria: citrate synthase is alloesterically inhibited by NADH (prevent oversynthesis of NADH)
   - In facultative anaerobes: α-ketoglutarate is an additional inhibitor (prevent overprodution of glutamate)
2. Gram-positive bacteria and eukaryotes: citrate synthase inhibited by ATP

Question 44

In what way is the citric acid cycle also an anabolic pathway?

Answer 44

It provides the precursors for 10 or 20 amino acids

Question 45

What amino acid precursors does the citric acid cycle make?

Answer 45

• Succinuyl-CoA –> L-lysine and L-methionine
• Oxaloacetate –> aspartate
• α-Ketoglutarate –> glutamate

Question 46

Because the citric acid cycle intermediates are constantly being removed to provide precursors for biosynthesis, they must be replaced. How are they replaced?

Answer 46

• Growth on amino acids: can use amino acids to replenish oxaloacetate
• Growth on sugar: carboxylation of pyruvate or PEP to replenish oxaloacetate

Question 47

What is the glyoxylate cycle?

Answer 47

A second pathway for the metabolism of acetyl-CoA

Question 48

When is the glyoxylate cycle required?

Answer 48

Required by aerobic bacteria to grow on fatty acids and acetate

Question 49

Compare the glyoxylate cycle and the citric acid cycle.

Answer 49

• Pathways diverge at isocitrate
• Glyoxylate cycle bypasses 2 decarboxylation reactions
• No CO₂ formed

Question 50

What are the 2 reactions of the glyoxylate cycle?

Answer 50

1. Isocitrate lyase: socitrate is cleaved to succinate and glyoxylate
2. Malate synthase: glyoxylate condenses with acetyl-CoA –> malate –> replenishes oxaloacetate

Question 51

What are the products of the glyoxylate cycle?

Answer 51

• 1 succinate –> oxidized to oxaloacetate –> converted to PEP
• 1 NADH

Question 52

What is the net result of the glyoxylate cycle?

Answer 52

Condensation of 2 acetyl-CoA to form succinate