TCA Cycle

Question 1

What is so special about the TCA cycle?

Answer 1

Major energy producing pathway in the body

Question 2

Where does the TCA cycle occur?

Answer 2

Mitochondria

Question 3

In what form does food product reach the TCA cycle?

Answer 3

Acetyl CoA

Question 4

What is the general idea of the CA cycle?

Answer 4

Take Acetyl CoA and oxidize it to make carbon dioxide and water in order to make energy.

Question 5

Where are all of the enzymes we need for the TCA cycle?

Answer 5

All the enzymes of the TCA cycle are in the mitochondrial matrix except succinate dehydrogenase, which is in the inner mitochondrial matrix

Question 6

Acetyl CoA and ozaloacetate condense to form what?

Answer 6

Citrate

Question 7

What enzyme condenses acetyl-CoA and oxaloacetate to make citrate?

Answer 7

Citrate synthase

Question 8

Citrate is isomerized to what?

Answer 8

Isocitrate

Question 9

What enzyme turns citrate to isocitrate?

Answer 9

Aconitase

Question 10

Isocitrate is oxidized to what?

Answer 10

Alpha ketoglutarate

Question 11

What two step process is involved in turning isocitrate to alpha ketoglutarate?

Answer 11

Oxidation
Decarboxylation

(CO2 is produced and the electrons are passed to NAD+ to form NADH and H+)

Question 12

What enzyme turns isocitrate to alpha ketoglutarate?

Answer 12

Isocitrate dehydrogenase

Question 13

What activates isocitrate dehydrogenase? Inhibits it?

Answer 13

This key regulatory enzyme of the TCA cycle is allosterically activated by ADP and inhibited by NADH

Question 14

What happens to alpha ketoglutarate once it is made?

Answer 14

converted to succinyl-CoA

Question 15

Alpha ketoglutarate to Succinyl-CoA is an example of what kind of reaction?

Answer 15

oxidative decarboxylation reaction

Question 16

What enzyme turns alpha-ketoglutarate to succinyl CoA?

Answer 16

α-ketoglutarate dehydrogenase

Question 17

What cofactors are required for α-ketoglutarate dehydrogenase?

Answer 17

This enzyme requires five cofactors: thiamine pyrophosphate, lipoic acid, CoASH, FAD, and NAD+

Question 18

What happens to succinyl CoA?

Answer 18

cleaved to succinate

Question 19

How do we get energy from the succinyl CoA to succinate reaction?

Answer 19

Cleavage of the high-energy thioester bond of succinyl-CoA provides energy for the substrate-level phosphorylation of GDP to GTP

Question 20

What enzyme cleaves succinyl CoA to succinate?

Answer 20

succinate thiokinase aka succinyl-CoA synthetase

Question 21

What happens to succinate?

Answer 21

oxidized to fumarate

Question 22

What electron carrier is involved at the step where sucinate becomes fumarate?

Answer 22

succinate transfers two hydrogens together with their electrons to FAD, which forms FADH2

Question 23

What enzyme oxidizes succinate to fumarate?

Answer 23

succinate dehydrogenase

Question 24

Where does the succinate to fumarate rxn occur?

Answer 24

Inner mitochondrial membrane

Question 25

What happens to fumarate?

Answer 25

Converted to malate

Question 26

What enzyme turns fumarate to malate?

Answer 26

Fumarase

Question 27

How does fumarase turn fumarate to malate?

Answer 27

Adds water across the double bond

Question 28

What happens to malate?

Answer 28

Oxidized to regenerate oxaloacetate

Question 29

What oxidizes malate to oxaloacetate?

Answer 29

Malate dehydrogenase

Question 30

What enzyme carrier is involved with the malate dehydrogenase rxn?

Answer 30

two hydrogens along with their electrons are passed to NAD+, producing NADH and H+

Question 31

How much ATP per NADH?

Answer 31

2.5 ATP

Question 32

How much ATP per FADH2

Answer 32

1.5

Question 33

How much ATP per turn of the TCA cycle?

Answer 33

1 mole of acetyl CoA gives us 10 moles of ATP

Question 34

What happens during fasting?

Answer 34

Intermediates of the TCA cycle are utilized in the fasting state in the liver for the production of glucose and in the fed state for the synthesis of fatty acids

Question 35

What are anaplerotic reactions?

Answer 35

Anaplerotic reactions replenish intermediates of the TCA cycle as they are removed for the synthesis of glucose, fatty acids, amino acids, or other compounds

Question 36

One of the most important anaplerotic reactions?

Answer 36

Carboxylation of pyruvate to oxaloacetate

Question 37

What enzyme carboxylates pyruvate to oxaloacetate?

Answer 37

pyruvate carboxylase

Question 38

What cofactor does pyruvate carboxylase need?

Answer 38

Biotin

Question 39

What activates the enzyme pyruvate carboxylase besides its cofactor biotin?

Answer 39

Acetyl-CoA

Question 40

Where is pyruvate carboxylase found?

Answer 40

Liver
Brain
Adipose Tissue

Question 41

What reactions do amino acids do to produce TCA intermediates?

Answer 41

Anaplerotic reactions

Question 42

What amino acids form glutamate?

Answer 42

Glutamine, proline, arginine and histidine

Question 43

What amino acid forms aspartate?

Answer 43

Asparagine

Question 44

What becomes oxaloacetate?

Answer 44

Aspartate

Question 45

Name of the reaction type that turns aspartate to oxaloacetate

Answer 45

Transamination

Question 46

How is Succinyl CoA formed?

Answer 46

Propionyl-CoA gets converted to methylmalonyl-CoA and subsequently to Succinyl-CoA

Question 47

Formation of propionyl CoA

Answer 47

You need Valine, isoleucine, methionine and threonine

Question 48

What amino acids make fumarate?

Answer 48

Phenylalanine, tyrosine, and aspartate

Question 49

What pathway slows down the TCA cycle?

Answer 49

Gluconeogenesis, which uses intermediates of the TCAcycle

Question 50

What happens to the TCA cycle as glucose is synthesized?

Answer 50

malate or oxaloacetate is removed from the TCA cycle and replenished by anaplerotic reactions

Question 51

Pyruvate is formed by what compounds?

Answer 51

Lactate or alanine

Question 52

What product of the TCA cycle is important for fatty acid synthesis?

Answer 52

Citrate

Question 53

What catalyzes the anaplerotic reactions that replenish the TCA cycle intermediates?

Answer 53

Pyruvate Carboxylase

Question 54

How can we get amino acids from glucose via the oxaloacetate pathway?

Answer 54

Glucose is converted to pyruvate, which forms oxaloacetate, which by transamination forms aspartate and, subsequently, asparagine

Question 55

How can we get amino acids from glucose via the oxaloacetate and acetyl CoA pathway?

Answer 55

Glucose is converted to pyruvate, which forms both oxaloacetate and acetyl-CoA, which condense, forming citrate. Citrate forms isocitrate and then α-ketoglutarate, from which glutamate, glutamine, proline, and arginine are produced

Question 56

What accelerates the ETC?

Answer 56

When ADP levels are high relative to ATP the reactions of the electron transport chain are accelerated.

Question 57

What speeds up the TCA cycle?

Answer 57

NADH is rapidly oxidized by the ETC; consequently, the TCA cycle speeds up

Question 58

What slows down the ETC?

Answer 58

When the concentration of ATP is high the electron transport chain slows down

Question 59

What slows down the TCA cycle?

Answer 59

When the concentration of ATP is high the electron transport chain slows down, NADH builds up, and consequently the TCA cycle is inhibited

Question 60

How, specifically, does the TCA cycle slow down (this is very involved, but think about the process)

Answer 60

NADH allosterically inhibits isocitrate dehydrogenase. Isocitrate accumulates, and because the aconitase equilibrium favors citrate, the concentration of citrate rises. Citrate inhibits citrate synthase, the first enzyme of the cycle.

Question 61

What happens to oxaloacetate when NADH is high?

Answer 61

Oxaloacetate is converted to malate when NADH is high and, therefore, less substrate (OAA) is available for the citrate synthase reaction

Question 62

What reactions are NAD used in?

Answer 62

isocitrate dehydrogenase, α-ketoglutarate dehydrogenase, and malate dehydrogenase reactions

Question 63

What is niacin important for?

Answer 63

Niacin is used for the synthesis of the nicotinamide portion of NAD

Question 64

What is important for the production of FAD?

Answer 64

Riboflavin

Question 65

What is thiamine important for?

Answer 65

the synthesis of thiamine pyrophosphate

Question 66

Importance of Pantothenate?

Answer 66

synthesis of CoASH

Question 67

Effects of low Vitamin A

Answer 67

Night blindness and xerophthalmia

Question 68

Effects of low Vitamin D

Answer 68

Inadequate bone mineralization, rickets in children

Question 69

Effects of low Vitamin E

Answer 69

Reproductive failure, muscular dystrophy, neurologic abnormalities

Question 70

Effects of low Vitamin K

Answer 70

Defective blood coagulation

Question 71

Effects of low Vitamin C

Answer 71

Scurvy

Question 72

Effects of low thiamine?

Answer 72

Berriberi

Question 73

Effects of low riboflavin?

Answer 73

Oral-buccal cavity lesions

Question 74

Effects of low niacin?

Answer 74

Pellagra (diarrhea, dermatitis, dementia, death)

Question 75

Effects of low Vitamin B6

Answer 75

Convulsions, dermatitis, anemia

Question 76

Effects of low Folate

Answer 76

Megaloblastic Anemia

Question 77

Effects of low Vitamin B12?

Answer 77

Megaloblastic Anemia and neurological symptoms

Question 78

Effects of low biotin

Answer 78

Anorexia, nausea, vomitis, glossitis, alopecia

Question 79

Effects of low pantothenic acid

Answer 79

Listlessness, fatigue, burning feet syndrome

Question 80

How do Carbons from glucose enter the TCA cycle?

Answer 80

In order for carbons from glucose to enter the TCA cycle, glucose is first converted to pyruvate by glycolysis, then pyruvate forms acetyl-CoA

Question 81

How is acetyl CoA formed?

Answer 81

Pyruvate dehydrogenase catalyzes the oxidative decarboxylation of pyruvate, forming acetyl-CoA

Question 82

Where is pyruvate dehydrogenase?

Answer 82

Pyruvate dehydrogenase, a multienzyme complex located exclusively in the mitochondrial matrix

Question 83

What is similar between pyruvate dehydrogenase and alpha ketoglutarate?

Answer 83

They need the same 5 components

Question 84

What is different between pyruvate dehydrogenase and alpha ketoglutarate?

Answer 84

In contrast to α-ketoglutarate dehydrogenase, a pyruvate dehydrogenase exists in a phosphorylated (inactive) form and a dephosphorylated (active) form

Question 85

How is pyruvate decarboxylase deactivated?

Answer 85

CoASH and NAD+. Can also be inactivated by ADP

Question 86

What activates the pyruvate decarboxylase?

Answer 86

The products of the pyruvate dehydrogenase reactions, acetyl-CoA and NADH. It is activated specifically by a phosphatase

Question 87

How is pyruvate decarboxylase controlled, generally?

Answer 87

When the concentration of substrates is high, the dehydrogenase is active, and pyruvate is converted to acetyl-CoA. When the concentration of products is high, the dehydrogenase is relatively inactive