The Electron Transport Chain.

Question 1

What is a prosthetic group?

Answer 1

These are organic in nature and not made of protein.

They are very tightly bound (usually covalently) to the enzyme.

Question 2

What are prosthetic groups also known as?

Answer 2

A coenzyme.

Question 3

Which step of aerobic respiration will generate the most ATP?

Answer 3

The ETC.

Question 4

What is the final electron acceptor in the ETC?

Answer 4

Oxygen.

Question 5

What is the goal of the ETC?

Answer 5

To produce energy in the form of ATP via the oxidation of NADH and FADH2.

Question 6

Where in the cell does the ETC occur?

Answer 6

In the mitochondrial matrix and in the inner mitochondrial membrane.

Question 7

Give a quick summary of the ETC?

Answer 7

Hydrogen atoms are stripped from NADH and FADH2 and transported into the inter membranous space.

This creates a proton gradient and the ions want to re-enter the mitochondrial matrix.

The ions can re-enter by passing through ATP synthase.

As each H+ ion passes through, one molecule of ATP is generated.

Question 8

How many complexes are in the ETC?

Answer 8

4.

Question 9

Where are the 4 complexes in the ETC found?

Answer 9

Embedded into the inner mitochondrial membrane.

Question 10

What are the 4 complexes in the ETC?

Answer 10

Complex 1. The NADH dehydrogenase complex.

Complex 2 = Succinate dehydrogenase.

Complex 3 = Cytochrome reductase.

Complex 4 = Cytochrome oxidase.

Question 11

What are the 2 mobile electron carriers in the ETC?

Answer 11

Co-enzyme Q.

Cytochrome C.

Question 12

What 2 prosthetic groups are used at complex 1?

Answer 12

FAD.

FMN.

Question 13

What gets oxidised at complex 1?

Answer 13

NADH.

Question 14

What happens at complex 1 in the ETC?

Answer 14

NADH is oxidised and the electrons passed on to co-enzyme Q.

2 H+ ions are pumped into the inter-membranous space.

Question 15

What prosthetic groups are used at complex 2?

Answer 15

None.

Question 16

What happens at complex 2 in the ETC?

Answer 16

FADH2 is oxidised by co-enzyme Q.

The electrons 2 are also passed to complex 3 by co-enzyme Q to complex 3.

Question 17

What gets oxidised at complex 2 in the ETC?

Answer 17

FADH2.

Question 18

What oxidises FADH2 at complex 2?

Answer 18

Co enzyme Q.

Question 19

Is succinate dehydrogenase involved in any other steps of aerobic respiration?

Answer 19

In the TCA cycle in step 6 where the 2 FADH2 molecules are made.

Question 20

What happens at complex 3 in the ETC?

Answer 20

Co-enzyme Q delivers electrons from complex 1 and 2 to reduce complex 3.

2 more H+ ions are pumped into the inter-membranous space.

The electrons will then be handed to cytochrome C to be transferred to complex 4.

Question 21

What prosthetic groups are used at complex 3?

Answer 21

Heme.

Question 22

What happens at complex 4 in the ETC?

Answer 22

Cytochrome C delivers electrons to complex 4 and they are passed onto O2.

2 more H+ ions are pumped into the inter-membranous space.

Question 23

What prosthetic groups does complex 4 have?

Answer 23

Heme.

Calcium ions.

Question 24

What complexes will pump H+ into the inter membranous space?

Answer 24

Complexes 1, 3 and 4.

Question 25

Which complexes contain iron sulphur proteins which are involved in the electron transfer process?

Answer 25

Complexes 1,2 and 3.

Question 26

What is complex 1 called?

Answer 26

NADH dehydrogenase complex.

Question 27

What is complex 2 called?

Answer 27

Succinate dehydrogenase.

Question 28

What is complex 3 called?

Answer 28

Cytochrome reductase.

Question 29

What is complex 4 called?

Answer 29

Cytochrome oxidase.

Question 30

Why cant the H+ ions cross back through the inner mitochondrial membrane?

Answer 30

It is highly impermeable.

Question 31

How can H+ ions re-enter the cell?

Answer 31

Through ATP synthase.

Question 32

ATP synthase is also known as what complex?

Answer 32

Complex 5.

Question 33

What happens when the H+ ions pass through ATP synthase?

Answer 33

It causes the enzyme to rotate which generates enough kinetic energy to phosphorylate an ADP.

Question 34

Is ATP a bi-functional enzyme?

Answer 34

Yes.

It allows the protons to pass through while generating ATP at the same time.

Question 35

At what steps of the TCA cycle is NADH formed?

Answer 35

Malate dehydrogenase step.

Alpha keto gluterate dehydrogenase step.

Isocitrate dehydrogenase step.

Question 36

Is any NADH formed at the PDH complex?

Answer 36

1.

Question 37

What are other sources of NADH?

Answer 37

Beta oxidation of fatty acids.

Sources from outside the mitochondria (glycolysis).

Question 38

What step in the TCA cycle is FADH2 generated?

Answer 38

Succinate dehydrogenase step.

Question 39

What are other sources of FADH2?

Answer 39

Glycerol phosphate shuttle.

Beta oxidation of fatty acids.

Question 40

How does the ATP formed in the ETC get to the cytoplasm?

Answer 40

Adenine nucleotide translocase will transport ATP to the cytoplasm.

Question 41

How does ADP get from the cytoplasm to the mitochondria?

Answer 41

Adenine nucleotide translocase will transport ADP from to the mitochondria to be phosphorylated.

Question 42

What 2 toxins can inhibit the transport of ATP from the mitochondrial matrix to the cytoplasm

Answer 42

Atractyloside.

Bongkrekic acid.

Question 43

What is adenine nucleotide translocase inhibited by?

Answer 43

Atractyloside.

Bongkrekic acid.

Question 44

What 3 inhibitors will affect complex 1?

Answer 44

Rotenone.

Piericidin A (antibiotic).

The barbiturate amytal.

Question 45

What inhibitor will affect complex 3?

Answer 45

Antimycin A (antibiotic).

Question 46

What 3 inhibitors will affect complex 4?

Answer 46

Carbon monoxide (CO).

Hydrogen sulphide (H2S).

Cyanide.

Question 47

What inhibitor will affect complex ATP synthase?

Answer 47

Oligomycin (antibiotic).

Question 48

Inhibitors of the ETC will result in what?

Answer 48

A decrease in ATP synthesis.

A decrease the rate of the ETC.

A decrease in oxygen consumption.

Question 49

What are uncouplers?

Answer 49

A class of inhibitors and they will create holes in the inner mitochondrial membrane.

Question 50

What effect will uncouplers have on the ETC?

Answer 50

The holes allow hydrogen ions to re-enter the mitochondrial matrix.

No proton gradient is formed.

Hydrogen ions do not pass through ATP synthase, so no ATP is generated.

Question 51

What are the 4 classes of uncouplers?

Answer 51

DNP (Dinitrophenol).

ASA (aspirin).

Thermogenin.

Ionophores.

Question 52

How will uncouplers affect ATP synthesis and oxygen consumption?

Answer 52

They will decrease ATP synthesis.

Increase the rate of the ETC.

Increase oxygen consumption

Question 53

The NADH and FADH2 produced in the ETC and PDH complex will be located in what organelle?

Answer 53

The mitochondrial matrix.

Question 54

Where are the 2 NADH molecules that are produced in glycolysis located?

Answer 54

In the cytoplasm

Question 55

What must happen to the 2 NADH molecules from glycolysis for them to enter the ETC?

Answer 55

They must travel from the cytoplasm to the mitochondrial matrix.

Question 56

What are the 2 shuttles that transport the NADH from glycolysis to the mitochondrial matrix?

Answer 56

The glycerol phosphate shuttle.

The malate-aspartate shuttle.

Question 57

How does the malate aspartate shuttle work?

Answer 57

NADH goes to the inter membranous space in the mitochondria.

An enzyme will transfer the electrons from NADH to reduce oxaloacetate and form malate and NAD+.

Malate crosses into the matrix where it is oxidised back to oxaloacetate.

This reduction allows NAD+ to be oxidised to NADH.

Question 58

What enzyme converts NADH and oxaloacetate to malate in the malate aspartate shuttle?

Answer 58

Cytosolic malate dehydrogenase.

Question 59

Can NADH cross the inner mitochondrial membrane?

Answer 59

No.

Question 60

What is NADH converted to to cross the mitochondrial membrane in the malate aspartate shuttle?

Answer 60

Oxaloacetate is reduced to malate.

Question 61

What enzyme converts malate to oxaloacetate and NADH in the malate aspartate shuttle?

Answer 61

Mitochondrial malate dehydrogenase.

Question 62

What happens in the glycerol phosphate shuttle?

Answer 62

NADH goes to the inter membranous space.

DHAP is oxidised to glycerol 3-phosphate.

NADH is reduced to NAD+.

G 3-P can enter the matrix and is re-oxidised to DHAP andFAD is reduced to FADH2.

Question 63

Will more energy be produced by use of the glycerol phosphate shuttle or by the malate aspartate shuttle?

Answer 63

The malate aspartate shuttle.

Question 64

What enzyme converts NADH and DHAP to glycerol 3-phosphate in the glycerol phosphate shuttle?

Answer 64

Cytosolic glycerophosphate dehydrogenase.

Question 65

What enzyme converts G 3-P to DHAP and FADH2 in the glycerol phosphate shuttle?

Answer 65

Mitochondrial glycerophosphate dehydrogenase.

Question 66

Every NADH that enters the glycerol phosphate shuttle will form what?

Answer 66

FADH2.

Question 67

How much ATP from NADH is generated from glycolysis if the malate aspartate shuttle is used?

Answer 67

6 ATP generated.

Question 68

How much ATP from NADH is generated from glycolysis if the glycerol phosphate shuttle is used?

Answer 68

4 ATP generated.

Question 69

How much total ATP is generated from glycolysis if the malate aspartate shuttle is used?

Answer 69

6 ATP from 2 NADH + 2 ATP from glycolysis = 8 ATP.

Question 70

How much total ATP is generated from glycolysis if the malate aspartate shuttle is used?

Answer 70

4 ATP from 2 FADH2 + 2 ATP from glycolysis = 6 ATP.

Question 71

The ETC is driven by the ratios of what molecules?

Answer 71

NADH/NAD+ and ATP/ADP.

Question 72

What molecules will activate the ETC?

Answer 72

A lot of NADH.

A lot of ADP.

Question 73

What are the substrates in the ETC?

Answer 73

NADH.

ADP.

Question 74

What are the products of the ETC?

Answer 74

NAD+.

ATP.

Question 75

What will inhibit the ETC?

Answer 75

High levels of NAD+.

High levels of ATP.

Question 76

What is hypoxia?

Answer 76

A deficiency in oxygen.

Question 77

What happens in the ETC if someone is hypoxic?

Answer 77

The energy from FADH2 and NADH will not be converted to ATP.