Chapter 10 The Citrate Cycle

Question 1

What is the citrate cycle?

Answer 1

a central pathway in oxidative respiration that converts acetyl units to CO2 with the concomitant production of FADH2, NADH, and ATP

Question 2

Why is the citrate cycle considered the “hub” of cellular metabolism?

Answer 2

1. it is central to aerobic metabolism and ATP production by generating the bulk of NADH and FADH2, which are oxidized by the ETC to generate ATP by oxidative phosphorylation
2. it links the oxidation of various metabolic fuels (carbs, fatty acids, and proteins) to ATP synthesis through shared intermediates
3. it provides metabolites for numerous biosynthetic pathways

Question 3

Where does the citrate cycle occur?

Answer 3

in the mitochondrial matrix

Question 4

What is the primary function of the citrate cycle?

Answer 4

oxidize acetyl-CoA

Question 5

What does each turn of the citrate cycle generate in terms of reducing power?

Answer 5

each turn transfers 8 electrons from intermediates to NAD+ and FADH, generating 3 NADH, 1 FADH2, and 1 GTP

Question 6

Who pieced together/discovered the citrate cycle?

Answer 6

Hans Krebs

fled Germany, described cycle in 1937, won Nobel Prize in 1953 with Fritz Lipmann, who discovered the role of acetyl-CoA in metabolism

Question 7

Why is oxaloacetate so important to the cycle?

Answer 7

It is the substrate for the first reaction (catalyzed by citrate synthase) and the product of the last reaction (catalyzed by malate dehydrogenase)

Question 8

What controls the flow of acetyl-CoA into the cycle?

Answer 8

pyruvate dehydrogenase

Question 9

What controls the flow of oxaloacetate into the cycle?

Answer 9

pyruvate carboxylase

Question 10

What inhibits pyruvate dehydrogenase?

Answer 10

ATP and NADH (high levels signal acetyl-CoA to be diverted to fatty acid synthesis)

Question 11

How much CO2 is generated per turn of the citrate cycle? In what steps?

Answer 11

2 CO2 given off as waste; produced in steps 3 and 4

Question 12

What is the overall net reaction of the citrate cycle?

Answer 12

Acetyl-CoA + 3NAD+ + FAD + GDP + P + 2H2O —-> CoA + 2CO2 + 3NADH + 3H+ + FADH2 + GTP

Question 13

What are the key enzymes of the citrate cycle?

Answer 13

• pyruvate dehydrogenase (technically outside of the cycle, but important because it regulates flux of acetyl-CoA)
• citrate synthase (step 1)
• isocitrate dehydrogenase (step 3)
• alpha-ketogluterate dehydrogenase (step 4)

Question 14

Which enzyme in the citrate cycle is activated by CoA?

Answer 14

pyruvate dehyrogenase

Question 15

oxidation

Answer 15

molecule or functional group loses electrons

Question 16

reduction

Answer 16

molecule or functional group gains electrons

Question 17

Oxidant/oxidizing agent

Answer 17

accept electrons and are reduced

Question 18

Reductant/reducing agent

Answer 18

lose electrons and are oxidized

Question 19

In linked metabolic pathways, the oxidants in subsequent reactions must ….

Answer 19

have progressively higher standard reduction potentials

Question 20

Define vitamin

Answer 20

any of a group of organic compounds which are essential for normal growth and nutrition and are required in small quantities because the body does not synthesize them

Question 21

What five coenzymes are required for pyruvate dehydrogenase to work?

Answer 21

1. NAD+
2. FAD
3. CoA
4. Thiamine pyrophosphate (TPP)
5. alpha-lipoic acid (lipoamide)

Question 22

Where is NAD+ derived from?

Answer 22

niacin/vitamin B3

Question 23

Where is FAD derived from?

Answer 23

riboflavin/vitamin B2

Question 24

Where is CoA derived from?

Answer 24

pantothenic acid/vitamin B5

Question 25

Where it TPP derived from?

Answer 25

thiamine/vitamin B1

Question 26

Where do we get alpha lipoic acid from?

Answer 26

It is synthesized in the body (not a vitamin)

Question 27

What three subunits are part of the pyruvate dehydrogenase complex?

Answer 27

E1: pyruvate dehydrogenase
E2: dihydrolipoyl acetyltransferase
E3: dihydrolipoyl dehydrogenase

Question 28

What are the five catalytic steps performed by the pyruvate dehydrogenase enzyme complex?

Answer 28

1. E1 subunit (pyruvate dehydrogenase) binds pyruvate, catalyzing decarboxylation and releasing CO2
2. hydroxyethyl-TPP moiety of E1 reacts with lipoamide on the N-terminal domain of the E2 subunit (dihydrolipoyl acetyltransferase); generates acetyl-dihydrolipoamide
3. E2 acetyl-dihydrolipoamide carries acetyl group from E1 site to E2 catalytic site , yielding acetyl-CoA
4. dihydrolipoamide is reoxidized on the E3 subunit (dihydrolipoyl dehydrogenase), eventually forming E3-FADH2
5. E3-FADH2 coenzyme intermediate is reoxidized to produce NADH

Question 29

Which enzyme requires CoASH to produce acetyl-CoA?

Answer 29

pyruvate dehyrogenase

Question 30

Why does arsenic poisoning affect you more quickly than a Vitamin B deficiency?

Answer 30

Arsenic prevents the reformation of cyclic lipoamide, which is an essential component of the pyruvate dehydrogenase complex. Without it, the Citrate Cycle shuts down. With a deficiency in any of the B Vitamin precursors to pyruvate dehydrogenase coenzymes, the Citrate Cycle would slowly decrease in its ability to produce energy over time.

Question 31

What are two diseases caused by deficiencies in B Vitamins?

Answer 31

Pellagra, a deficiency in niacin/B3, causes inflamed skin, diarrhea, dementia, and sores in the mouth. Beriberi, a deficiency in thiamine/B1, is observed in chronic alcoholics and has neurological and cardiovascular symptoms.

Question 32

What is the catalytic “workhorse” of pyruvate dehydrogenase?

Answer 32

lipoamide

Question 33

What are the three metabolic fates of acetyl-CoA?

Answer 33

1. can be metabolized in the citrate cycle, ultimately converting redox energy to ATP by oxidative phosphorylation
2. can be used to store metabolic energy in the form of fatty acids, which are transported to adipose tissues as triglycerides
3. is a building block for the synthesis of membrane lipids, cholesterol, and ketones

Question 34

How is pyruvate dehydrogenase regulated?

Answer 34

Phosphorylation, NADH, ATP, and Acetyl-CoA all play a role in regulation. High levels of these molecules would provide negative feedback and downregulate the Citrate Cycle.

Question 35

Which steps of the Citrate Cycle produce reducing agents?

Answer 35

Steps 3, 4, and 8 produce NADH, and Step 6 produces FADH2.

Question 36

What is the protonation state of citrate at physiological pH?

Answer 36

Citrate is fully deprotonated at physiological pH, so it is not acidic.

Question 37

Why do NADH and ATP inhibit many of the key enzymes involved in the Citrate Cycle?

Answer 37

These molecules downregulate pyruvate dehydrogenase, citrate synthase, isocitrate dehydrogenase, and α-ketoglutarate dehydrogenase. High levels indicate that the cycle is running faster than the amount of input provided, so the cycle must slow down.

Question 38

How is pyruvate carboxylase activated?

Answer 38

activated allosterically by acetyl-CoA, leading to increased production of oxaloacetate

Question 39

What inhibits the regulatory enzymes?

Answer 39

High NADH to NAD+ ratio, NADH, ATP

citrate synthase and alpha-ketogluterate dehydrogenase are also inhibited by succinyl-CoA

citrate synthase inhibited by citrate

Question 40

The poison compound 1080 converts fluoroacetate to fluorocitrate. Which enzyme in the citrate cycle is inhibited by this poison?

Answer 40

aconitase

Question 41

amphibolic pathway

Answer 41

a metabolic pathway that functions in both catabolism and anabolism; ex. citrate cycle

Question 42

anaplerotic reaction

Answer 42

replenishes Citrate Cycle intermediates that have been shunted to biosynthetic pathways to produce other molecules

Question 43

What citrate cycle intermediates serve as precursors for other pathways?

Answer 43

citrate
alpha ketogluterate
succinyl-CoA
malate
oxaloacetate

Question 44

What enzyme catalyzes the primary anaplerotic reaction?

Answer 44

pyruvate carboxylase

it balances the input of oxaloacetate with acetyl-CoA by providing a way to convert pyruvate into OAA using an ATP dependent carboxylation reaction

Question 45

How is the citrate cycle used to produce ATP?

Answer 45

substrate-level phosphorylation reactions utilizing GTP