The Pyruvate Dehydrogenase Complex and the TCA cycle. Flashcards

Question 1

Q

What are co-enzymes?

Answer

A

Small organic molecules that will help an enzyme perform its job. Co-enzymes are often derived from vitamins.

Question 2

Q

What are kinases?

Answer

A

These enzymes will add phosphate groups to proteins.

Question 3

Q

What amino acid residues get phosphorylated?

Answer

A

Serine.

Threonine.

Tyrosine residues.

Question 4

Q

What are phosphatases?

Answer

A

These enzymes will remove phosphate groups from proteins.

Question 5

Q

What is the final product of glycolysis?

Answer

A

2 Pyruvate molecules.

Question 6

Q

How many carbons does each pyruvate molecule have?

Question 7

Q

What happens when pyruvate is oxidised further?

Answer

A

All of the electrons are removed to form CO2 and water.

Question 8

Q

Is the breakdown of pyruvate catabolic or anabolic?

Answer

A

Catabolic.

Question 9

Q

What are the goals of the PDH cycle and the ETC?

Answer

A

To get energy out of pyruvate.

Question 10

Q

Where are the 2 molecules of pyruvate formed?

Answer

A

In the cytoplasm.

Question 11

Q

Where are the enzymes for the TCA cycle and the PDH cycle found?

Answer

A

In the mitochondria.

Question 12

Q

What are the main energy producers in the cell?

Answer

A

The mitochondria.

Question 13

Q

Describe the interior of the mitochondria?

Answer

A

The interior of a mitochondrion is made up of 2 layers or membranes that are separated by a space.

Question 14

Q

What are the 2 membranes in the mitochondria called?

Answer

A

The outer and inner membrane.

Question 15

Q

What is the space between the outer an inner membrane called?

Answer

A

The inter-membranous space.

Question 16

Q

Why is the inner mitochondrial membrane invaginated?

Answer

A

To increase surface area.

Question 17

Q

Is the inner mitochondrial membrane easy for molecules to penetrate?

Answer

A

No.

It is highly impermeable.

Question 18

Q

Where in the mitochondria does the TCA cycle and PDH step occur?

Answer

A

In the mitochondrial matrix.

Question 19

Q

Where is the mitochondrial matrix located?

Answer

A

On the inside of the inner mitochondrial membrane.

Question 20

Q

What metabolic functions occur in the outer membrane of the mitochondria?

Answer

A

Phospholipid synthesis.

Fatty acid de-saturation.

Fatty acid elongation.

Question 21

Q

What metabolic functions occur in the inner membrane of the mitochondria?

Answer

A

Electron transport.

Oxidative phosphorylation.

Metabolite transport.

Question 22

Q

What metabolic functions occur in the inter membranous space of the mitochondria?

Answer

A

Nucleotide phosphorylation

Question 23

Q

What metabolic functions occur in the mitochondrial matrix of the mitochondria?

Answer

A

TCA cycle.

Pyruvate oxidation.

DNA replication.

Beta oxidation of fats.

Protein synthesis.

RNA synthesis.

Question 24

Q

Does the PDH step or the TCA cycle occur first?

Answer

A

The pyruvate molecules enter the PDH complex first then go into the TCA cycle.

Question 25

Q

What is formed in the PDH complex?

Answer

A

Pyruvate is oxidised to ACoA.

Question 26

Q

How many carbons does ACoA have?

Question 27

Q

Are the any by products of the oxidation of pyruvate to ACoA in the PDH step?

Answer

A

The carbon that is removed from pyruvate is lost as CO2.

The energy from the oxidation forms an NADH.

Question 28

Q

What molecule enters the TCA cycle?

Question 29

Q

Can the formation of ACoA from pyruvate be reversed?

Answer

A

No.

The reaction is irreversible.

Question 30

Q

Is the PDH complex a single enzyme or multiple enzymes?

Answer

A

A single enzyme.

Question 31

Q

Where is the PDH complex found?

Answer

A

In the mitochondrial matrix.

Question 32

Q

How many enzymes does the PDH complex contain?

Question 33

Q

How many regulatory proteins does the PDH complex contain?

Question 34

Q

How many coenzymes does the PDH complex require so that it can function?

Question 35

Q

What are the 3 enzymes or catalytic proteins in the PDH complex?

Answer

A

Pyruvate dehydrogenase.

Dihydrolipoyl dehydrogenase.

Dihydrolipoyl transacetylase.

Question 36

Q

What are the 2 regulatory proteins in the PDH complex?

Answer

A

Protein kinase (PDH kinase).

Protein phosphatase (PDH phosphatase).

Question 37

Q

What are the 5 coenzymes required by the PDH complex?

Answer

A

NAD+.

FAD.

Thiamine pyrophosphate (TPP).

Lipoic acid.

CoASH (co-enzyme A).

Nobody.

Fucks.

The.

Large.

Chicks.

Question 38

Q

What happens if a coenzyme is missing from the PDH complex?

Answer

A

Then the PDH complex cannot function.

Question 39

Q

Which coenzymes are vitamins?

Answer

A

NAD+.

FAD.

Thiamine pyrophosphate (TPP).

CoASH (co-enzyme A).

Question 40

Q

Which coenzyme is not a vitamin?

Answer

A

Lipoic acid.

Question 41

Q

How are the co-enzymes that are vitamins in the PDH complex acquired?

Answer

A

From the diet.

Question 42

Q

What enzymes in the PDH complex are involved in the conversion of pyruvate to ACoA?

Answer

A

All 3 of them.

Question 43

Q

Which co-enzymes will carry the acetyl group through the complex and to give it to CoA and form ACoA?

Answer

A

Co-ASH and TPP.

Question 44

Q

Which co-enzymes will transfer electrons from substances that have been oxidised to eventually form NADH.

Answer

A

Lipoic acid, NAD+ and FAD

Question 45

Q

What will be the output of 1 pyruvate molecule in the PDH complex?

Answer

A

1 ACoA, 1 Pyruvate and 1 CO2.

Question 46

Q

What will be the output of 1 glucose molecule in the PDH complex?

Answer

A

2 ACoA, 2 Pyruvate and 2 CO2.

Question 47

Q

When will the PDH complex be active?

Answer

A

When it is de-phosphorylated.

Question 48

Q

What will de-phosphorylate the PDH complex?

Answer

A

The regulatory enzyme, PDH phosphatase.

Question 49

Q

What stimulates the de-phosphorylation of the PDH complex by PDH phosphatase?

Answer

A

High levels of insulin in the liver.

High levels of calcium or magnesium in skeletal muscle.

Question 50

Q

When will the PDH complex not be active?

Answer

A

When it is phosphorylated.

Question 51

Q

What will phosphorylate the PDH complex?

Answer

A

The regulatory enzyme, PDH kinase.

Question 52

Q

What will activate PDH kinase?

Answer

A

ATP.

ACoA.

NADH.

Question 53

Q

Other than the PDH complex, what other methods can be used to create ACoA?

Answer

A

Triglycerides to ACoA.

Protein to ACoA.

Glycogen to ACoA.

Question 54

Q

How does glycogen for ACoA?

Answer

A

It can be broken down by glycogenolysis to form glucose.

Glucose can then form pyruvate.

Question 55

Q

What are triglycerides?

Answer

A

Fats which are a form of stored energy.

Question 56

Q

How can triglycerides form ACoA?

Answer

A

Triglycerides are broken down to glycerol and free fatty acids by lipolysis.

Free fatty acids are then broken down via beta oxidation to form ACoA.

Question 57

Q

How can proteins be used to form ACoA?

Answer

A

Via proteolysis which breaks them down to amino acids.

The amino acids can be broken down by oxidative de-amination to ACoA.

Question 58

Q

What other names can the TCA cycle be referred to as?

Answer

A

The tricarboxylic acid cycle (TCA cycle).

The krebs cycle.

The citrate cycle.

Question 59

Q

Where does the TCA cycle occur?

Answer

A

In the mitochondrial matrix.

Question 60

Q

What happens in the 1st step of the TCA cycle?

Answer

A

ACoA is added to oxaloacetate which creates a molecule called citrate.

Question 61

Q

How many carbons does oxaloacetate have?

Question 62

Q

How many carbons does citrate have?

Question 63

Q

How many steps are in the TCA cycle?

Question 64

Q

What is the final product of the TCA cycle?

Answer

A

Citrate allowing the whole cycle to repeat itself.

Answer 56

A

3 NADH = 9 ATP.
1 GTP = 1 ATP.
1 FADH2 = 2 ATP.

Total = 12 ATP.

Answer 57

A

6 NADH = 12 ATP.
2 GTP = 2 ATP.
2 FADH2 = 4 ATP.

Total = 24 ATP.

Answer 58

A

Acetyl CoA combines with oxaloacetate to form citrate.

A water molecule will then remove CoA.

Answer 59

A

Citrate synthase.

Answer 60

A

An isomerisation reaction takes place and an isocitrate is formed.

Answer 61

A

An OH is moved from carbon 3 to carbon 4.

The acetyl group is lost as CO2.

Answer 62

A

Acontinase.

Answer 63

A

Isocitrate is de-carboxylated and the 1st CO2 molecule is removed to form alpha-ketogluterate.

Answer 64

A

α-ketogluterate loses a CO2 molecule and COA is added in its place.

This forms succinyl CoA and NADH.

AKDH is similar to pyruvate dehydrogenase as it requires the same 5 coenzymes.

Answer 65

A

4 carbons bound to CoA.

Answer 66

A

Alpha-ketoglutarate dehydrogenase.

Answer 67

A

The high energy bond between succinyl and CoA is broken to form succinate.

Answer 68

A

Succinyl CoA synthetase (succinate thiokinase).

Answer 69

A

2H atoms are oxidised and removed from succinate to form fumarate.

Answer 70

A

A double bond is formed within succinate to compensate for the loss of the 2 H atoms

Answer 71

A

Succinate dehydrogenase.

Answer 72

A

A water molecule is added to fumarate by a hydrolase to create L-malate.

Answer 73

A

It adds an OH and an H to carbons on either side of the double bond.

This removes the double bond that was formed in the previous step.

Answer 74

A

Fumarase.

Answer 75

A

L-malate is oxidised to oxaloacetate.

Answer 76

A

Malate dehydrogenase.

Answer 77

A

It is re-entered into the TCA cycle.

Answer 78

A

Step 3.

Step 4.

Step 5.

Step 6.

Step 8.

Answer 79

A

1 NADH.

1 CO2.

Answer 80

A

1 NADH.

1 CO2.

Answer 81

A

Citrate synthase.

Isocitrate dehydrogenase.

Alpha KG dehydrogenase.

Succinate dehydrogenase.

Answer 82

A

High energy molecules.

NADH.

ATP.

Answer 83

A

Substrate availability.

ADP.

Calcium.

Answer 84

A

Fatty acyl CoA.

ATP.

NADH.

Succinly CoA.

Answer 85

A

Calcium.

ADP.

Answer 86

A

ATP.

NADH.

Answer 87

A

ATP.

GTP.

NADH.

Succinly CoA.

Answer 88

A

ADP.

Succinate.

Phosphate.

Answer 89

A

Oxaloacetate.

Answer 90

A

PFK-1 in step 3.

Answer 91

A

Fatty acid and sterol synthesis.

Answer 92

A

36-38 molecules of ATP produced per glucose molecule.

Answer 93

A

The use of different shuttles will determine whether 36 or 38 ATPs are generated.

Answer 94

A

1 turn = 2.

2 turns = 4.

Answer 95

A

6 = 2 turns.

3 = 1 turn.

Answer 96

A

9 = 1 turn.

18 = 2 turns.

Answer 97

A

1 = 1 turn.

2 = 2 turns.

Answer 98

A

1 turn = 2 ATP.

2 turns = 4 ATP.

Answer 99

A

1 = 1 turn.

2 = 2 turns.

Answer 100

A

1 turn = 1.

2 turns = 2.

Answer 101

A

Lactic acidosis.

Neurological defects.

Myopathy.

Death.

Answer 102

A

Pyruvate cannot be converted to ACoA and will result in a build up of pyruvate molecules in the mitochondria.

The body converts pyruvate to lactate and alanine.

This will cause lactic acidosis.

Answer 103

A

If pyruvate cannot be converted to lactate then the body is missing out on most of its energy.

Answer 104

A

It will decrease it.

Answer 105

A

Ataxia.

Ophthalmolplagia.

Memory loss.

Cerebral haemorrhage.

Answer 106

A

In the PDH complex.

Answer 107

A

Thiamine.

Answer 108

A

Werneke-Korsakoff syndrome.

Answer 109

A

Alcoholics and malnourished individuals.

Answer 110

A

Thiamine is also required for alpha-KG which is used in the TCA cycle.

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The Pyruvate Dehydrogenase Complex and the TCA cycle. Flashcards

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