Biochemistry 10: Carbohydrate Metabolism II

Question 1

acetyl-coA

Answer 1

contains a high-energy thioester bond that can be used to drive other reactions when hydrolyzed

can be formed from…

• pyruvate dehydrogenase
• fatty acids
• carbon skeletons of ketogenic amino acids, ketone bodies, and alcohol

Question 2

pyruvate dehydrogenase

Answer 2

enzyme of pyruvate dehydrogenase complex

oxidizes pyruvate, creating CO2

requires thiamine pyrophosphate (TPP) and Mg2+

Question 3

dihydrolipoyl transacetylase

Answer 3

enzyme of pyruvate dehydrogenase complex

oxidizes the remaining 2-carbon molecule after CO2 release using lipoic acid

transfers the acetyl group to CoA, forming acetyl-CoA

Question 4

dihydrolipoyl dehydrogenase

Answer 4

enzyme of pyruvate dehydrogenase complex

uses FAD to reoxidize lipoic acid, making FADH2

Question 5

pyruvate dehydrogenase phosphatase

Answer 5

enzyme of pyruvate dehydrogenase complex

dephosphorylates PDH when ADP levels are high, turning the enzyme on

Question 6

pyruvate dehydrogenase kinase

Answer 6

enzyme of pyruvate dehydrogenase complex

phosphorylates PDH when ATP or acetyl-CoA levels are high, turning off the enzyme

Question 7

how does fatty acid oxidation (beta-oxidation) contribute to the formation of acetyl CoA?

Answer 7

1. in cytosol, fatty acid + CoA –> fatty acyl-CoA, which moves into the intermembrane space
2. fatty acid (acyl) group is transferred to carnitine –> acyl-carnitine, which crosses the inner membrane
3. acyl group transferred to mitochondrial CoA –> fatty acyl-CoA
4. fatty acyl-CoA undergoes beta-oxidation to form acetyl CoA

Question 8

how does amino acid catabolism form acetyl-CoA?

Answer 8

ketogenic amino acids lose their amino group via transamination and their carbon skeletons form ketone bodies

Question 9

how does alcohol form acetyl-CoA?

Answer 9

enzymes alcohol dehydrogenase and acetaldehyde dehydrogenase

alcohol —> acetyl CoA

reaction also builds up NADH, which inhibits the citric acid cycle

acetyl-CoA formed through this process is usually used to make fatty acids

Question 10

Control Points of the Citric Acid Cycle

Answer 10

Citrate synthase

Isocitrate dehydrogenase,

alpha-Ketoglutarate dehydrogenase complex

Question 11

Citrate synthase

Answer 11

enzyme in citric acid cycle

acetyl-CoA + oxaloacetate —>—> citrate + CoA-SH

ATP and NADH function as allosteric inhibitors

high levels of ATP and NADH imply that the cell is energetically satisfied

Question 12

aconitase

Answer 12

enzyme in the citric acid cycle

isomerizes citrate to isocitrate

Question 13

Isocitrate Dehydrogenase

Answer 13

enzyme in the citric acid cycle; rate-limiting step

oxidizes and decarboxylates isocitrate –> a-ketoglutarate

creates the first CO2 and NADH of the cycle

inhibited by ATP and NADH

ADP and NAD+ function as allosteric activators

Question 14

a-Ketoglutarate dehydrogenase complex

Answer 14

enzyme in the citric acid cycle

a-ketoglutarate —> succinyl-CoA

creates the second CO2 and NADH of the cycle

inhibited by succinyl-CoA, NADH, and ATP

stimulated by ADP and Ca2+

Question 15

succinyl-CoA synthetase

Answer 15

enzyme in the citric acid cycle

hydrolyzes the thioester bond in succinyl-CoA –> succinate + CoA-SH

creates GTP

Question 16

fumarase

Answer 16

enzyme in the citric acid cycle

hydrolyzes the alkene bond of fumarate —> malate

Question 17

malate dehydrogenase

Answer 17

enzyme in the citric acid cycle

oxidizes malate —> oxaloacetate

denerates the third NADH of the cycle

Question 18

what is the order of the substrates in the citric acid cycle?

Answer 18

Pyruvate

Citrate

Isocitrate

a-Ketoglutarate

Succinyl-CoA

Succinate

Fumarate

Malate

Oxaloacetate

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Question 19

what is the net yield of acetyl-CoA formation and the citric acid cycle per pyruvate?

Answer 19

PDH:

1 NADH

Citric acid cycle:

3 NADH

1 FADH

1 GTP

net ATP production -

4 NADH(2.5) = 10 ATP

1 FADH(1.5) = 1.5 ATP

1 GTP = 1 ATP

total = 12.5 ATP per pyruvate

Question 20

why is the formation of ATP coupled to electron transport?

Answer 20

ADP + Pi –> ATP is endergonic

electron transport is exergonic since electrons move through the complexes up their reduction potential gradient (spontaneous) until reaching O2 (highest reduction potential)

coupled so that energy from one rxn can fuel the other

Question 21

Complex I (NADH-CoQ oxidoreductase)

Answer 21

includes an iron-sulfur cluster and flavoprotein covalently bonded to flavin mononucleotide (FMN)

movement of electrons:

NADH —-> FMN

Flavoprotein becomes reoxidized while the iron-sulfur subunit is reduced

iron-sulfur subunit —> coenzyme Q

pumps 4 protons

Question 22

Complex II (Succinate-CoQ oxidoreductase)

Answer 22

includes an iron-sulfur cluster an is covalently bonded to FAD

movement of electrons:

succinate + FAD —-> fumarate + FADH2

FAD becomes reoxidized while the iron-sulfur subunit is reduced

iron-sulfur subunit —> coenzyme Q

does not pump any protons

transfers electrons to coenzyme Q; receives electrons from succinate succinate is oxidized and FAD is reduced to FADH2 FAD2 is oxidized to FAD as it reduces an iron-sulfur protein The iron-sulfur protein is reoxidized as coenzyme Q is reduced No hydrogen pumping occurs here to contribute to the proton gradient

Question 23

Complex III (CoQH2-cytochrome c oxidoreductase) (cytochrome reductase)

Answer 23

includes an iron-sulfur cluster

movement of electrons:

CoQH2 —-> cytochrome c + 2H+

4 protons are pumped

main contribution to the proton-motive force is via the Q cycle

Question 24

Q cycle

Answer 24

linked to complex III

cycle of moving electrons from coenzyme Q to cytochrome c

two electrons are shuttled from a molecule of CoQH2 to a molecule of CoQ

another two electrons attach to heme moieties on cytochrome c

moves 4 protons into the intermembrane space

continues to increase the gradient of the proton-motive force across the inner mitochondrial membrane

Question 25

Complex IV (cytochrome c oxidase)

Answer 25

movement of electrons:

cytochrome c —> oxygen, the final electron acceptor

includes subunits of cytochrome a, cytochrome a3, and Cu2+ ions

pumps 2 protons across the membrane

Question 26

Cytochrome oxidase

Answer 26

made up of cytochromes a and a3

this gets oxidized as oxygen becomes reduced and forms water

this is the final location on the transport chain where proton pumping occurs

Question 27

The increase of hydrogen ions in the intermembrane space causes:

Answer 27

pH of the intermembrane space to drop

voltage difference between the intermembrane space and matrix increases due to proton pumping

Question 28

what two shuttle mechanisms help NADH enter the mitochondrial matrix from glycolysis?

Answer 28

shuttle mechanism: transfers high-energy electrons of NADH to carrier that can cross the inner mitochondrial membrane, making ATP in the process

glycerol 3-phosphate shuttle

malate-aspartate shuttle

Question 29

Glycerol 3-phosphate shuttle

Answer 29

electrons transferred from NADH to DHAP —> G3P by the cytosolic enzyme glycerol 3-phosphate dehydrogenase

electrons are then transferred to FAD, Complex II and eventually CoQ using mitochondrial glycerol 3-phosphate dehydrogenase

the enzyme recreates DHAP to continue the cycle

NADH makes 1.5 ATP by using this shuttle mechanism

Question 30

Malate-aspartate shuttle

Answer 30

electrons are transferred from NADH to OAA —> malate

malate is able to cross the inner mitochondrial membrane and transfer electrons back to NAD+ recreating NADH and reforming OAA in mitochondria

OAA can be transaminated —> aspartate, which can cross into the cytosol and be reconverted to OAA

malate dehydrogenase exists in both the cytosol and the mitochondria, can perform both reactions

more efficient because it produces 2.5 ATP for each NADH

Question 31

F₀

Answer 31

the portion of ATP synthase that spans the inner mitochondrial membrane

functions as an ion channel, so protons travel through F₀ along their gradient back into the matrix

Question 32

F₁

Answer 32

portion of atp synthase that utilizes the energy released from the electrochemical gradient to phosphorylate ADP to ATP

Question 33

what regulates oxidative phosphorylation?

Answer 33

when O2 limited, electrons can’t leave the ETC

also increases NADH levels (backs up everything up to the citric acid cycle)

when ADP is limited, there isn’t enough to be phosphorylated into ATP

ADP also activates isocitrate dehydrogenase, pushing the citric acid cycle forward

Question 34

respiratory control

Answer 34

the coordination of the citric acid cycle and oxidative phosphorylation