16 Cellular respiration

Question 1

what are the needs for ATP?

Answer 1

active transport

chemical activation

anabolic synthesis

cellular ultrastructure

bioluminescence

exocytosis

movement (e.g. of flagella and cilia)

homeostasis

Question 2

why is ATP considered to be the ‘universal energy currency’?

Answer 2

found in all living eukaryotic and prokaryotic cells

links energy-releasing and energy-consuming reactions

Question 3

where does glycolysis take place? why?

Answer 3

cytosol

requires specific enzymes only found there

Question 4

what is the function of glycolysis?

Answer 4

to oxidise glucose and split a 6C hexose into 2x 3C triose (pyruvate)

Question 5

what is required for glycolysis?

Answer 5

1 glucose molecule

2 ATP

2 NAD+

Question 6

what are the products of glycolysis?

Answer 6

2 pyruvate

4 ATP (gross)

2 red. NAD

Question 7

give each stage of the conversion from a. glucose to pyruvate

Answer 7

a. glucose

glucose phosphate

fructose phosphate

fructose bisphosphate

2 glyceraldehyde 3-phosphate

2 glycerate 1,3-bisphosphate

2 glycerate 3-phosphate

2 pyruvate

Question 8

what is phosphorylation? what is its use in glycolysis?

Answer 8

addition of a phosphate group, providing a -ve charge to the substrate (which prevents glucose diffusing out of the cel)

increases the CPE of glucose ∴ Ea of next reaction decreases

Question 9

where does the link reaction take place? why?

Answer 9

mitochondrial matrix

CoA and other enzymes only found here

Question 10

what is required for the link reaction?

Answer 10

1 pyruvate

1 ATP

1 ACoA

Question 11

how does pyruvate reach the mitochondrial matrix?

Answer 11

moves across mitochondrial envelope through specialised intrinsic protein carriers via active transport

Question 12

what are the three reactions involved in the link reaction?

Answer 12

decarboxylation

redox

dehydrogenation

[collectively oxidative decarboxylation}

Question 13

what are the components of coenzyme A (CoA)?

Answer 13

pantothetic acid (a vitamin B complex)

ADP

-SH group (joins acetyl group to CoA)

Question 14

what are the products of the link reaction?

Answer 14

CO(2)

acetyl CoA (aCoA)

red. NAD

Question 15

how can fats be converted into a CoA molecule?

Answer 15

B. oxidation occurs - 2C fragments hydrolysed from hydrocarbon tails of fatty acids

each fragment can make 1 CoA

Question 16

where does the Krebs cycle take place?

Answer 16

mitochondrial matrix

Question 17

what is the Krebs cycle controlled/limited by?

Answer 17

substrate concentration

allosteric (non-competitive) inhibitors

end-product inhibition

Question 18

KC: what is added to oxaloacetate to produce citrate?

Answer 18

an acetyl group from aCoA

Question 19

KC: what is added/removed to citrate to produce a 5C intermediate?

Answer 19

• CO(2)

+ NAD+ (producing red. NAD)

Question 20

KC: what is added/removed to the 5C intermediate to produce a 4C intermediate?

Answer 20

• CO(2)

+ NAD+ (producing red. NAD)

+ ADP + P(i) (producing ATP)

Question 21

KC: what is added to the 4C intermediate to produce another 4C intermediate?

Answer 21

+ FAD (producing red. FAD)

Question 22

KC: what is added to the second 4C intermediate to reform oxaloacetate?

Answer 22

+ NAD+ (producing red. NAD)

Question 23

what is produced in 1 turn of the Krebs Cycle?

Answer 23

1 ATP

2 CO(2)

1 red. FAD

3 red. NAD

Question 24

what is the purpose of red. FAD and red. NAD?

Answer 24

co-enzymes

act as H carriers to the electron transport chain (eTC)

to allow production of ATP via oxidative phosphorylation

Question 25

where does oxidative phosphorylation take place?

Answer 25

cristae of inner mitochondrial membrane

Question 26

what molecules are involved in the eTC?

Answer 26

red. NAD
red. FAD

e- carriers

O2

Question 27

eTC: what are e- carriers?

Answer 27

specialised carrier globular proteins

accept/donate e-

have a quaternary structure (a prosthetic group:
- Fe3+ + e- Fe2+)

Question 28

eTC: what is the first e- carrier?

Answer 28

red. NAD dehydrogenase

Question 29

eTC: how do e- carriers pump H+ across inner mitochondrial membrane?

Answer 29

e- cause conformational change to protein structure

causes protein to pump H+ across membrane into the inter-membrane space

Question 30

eTC: how does the pumping of H+ in the eTC result in the formation of ATP?

Answer 30

pumping creates an electrochemical H+ gradient –> proton motive force

H+ diffuse back down gradient through ATP synthase channels into mitochondrial matrix

E released forms ATP from ADP and P(i)

Question 31

eTC: what is the role of oxygen?

Answer 31

to act as the final e- acceptor and combine with 2H+ and 2e- to form H(2)O

Question 32

how many ATP molecules are produced in:

• glycolysis
• link reaction
• krebs cycle
• oxidative phosphorylation

as substrate-level phosphorylation?

Answer 32

• 4
• 0
• 2
• 0

Question 33

how many ATP molecules are produced indirectly from:

• 2 red. NAD from glycolysis
• 2 red. NAD from link reaction
• 6 red. NAD from Krebs cycle
• 2 red. FAD from Krebs cycle?

Answer 33

• 4
• 4
• 18
• 4

Question 34

why is the net gain of ATP always less than the theoretical gain?

Answer 34

used for active transport of pyruvate

used to move ADP into matrix

used to shuttle red. NAD from glycolysis into mitochondria

some protons leak from the inter-membrane space ∴ reduced proton motive force ∴ less ATP made

Question 35

what is anaerobic respiration?

Answer 35

when molecules other than oxygen are used as final electron acceptors

Question 36

what is the purpose of anaerobic respiration?

Answer 36

to allow glycolysis to continue and produce 2 ATP

Question 37

what type of anaerobic respiration takes place in skeletal muscles?

Answer 37

lactate fermentation

following vigorous exercise

Question 38

outline the stages of lactate fermentation

Answer 38

H removed from red. NAD

combines with pyruvate –> lactate

NAD oxidised to NAD+ ==> NAD+ can accept more e- and glycolysis can continue

Question 39

what can result from a build up of lactate?

Answer 39

inhibition of glycolysis

cramp and fatigue in skeletal muscles

lactic acidosis

Question 40

what is the fate of lactate?

Answer 40

transported to liver in plasma

oxidised back to pyruvate by lactate dehydrogenase forming red. NAD

1/5 = respired aerobically, producing ATP in the Krebs cycle

4/5 = converted to glucose-6-phosphate and then to glycogen in glycogenesis in liver cells

Question 41

what type of anaerobic respiration takes place in yeast?

Answer 41

alcoholic fermentation

Question 42

why is yeast considered a ‘facultive anaerobe’?

Answer 42

it can survive in both anaerobic and aerobic conditions (although growth is faster in aerobic)

Question 43

outline the stages of alcoholic fermentation

Answer 43

pyruvate is decarboxylated to ethanAl and CO(2) by pyruvate decarboxylase

ethanAl acts as H+ acceptor and removes H+ from red. NAD

forming ethanOl (catalysed by ethanOl dehydrogenase)

oxidising red. NAD back to NAD+ ==> NAD+ can now accept more e- and glycolysis can continue

Question 44

why is alcoholic fermentation considered wasteful for the yeast?

Answer 44

CPE is trapped in the ethanOl ∴ it is wasted

Question 45

what is a respiratory substrate?

Answer 45

an organic molecule that can be oxidised in respiration to produce ATP

Question 46

why do different respiratory substrates produce different amounts of ATP?

Answer 46

have different amounts of hydrogen

∴ different number of H+ that can be pumped into the IMS

∴ different proton motive forces generated

∴ different numbers of ATP molecules can be produced

Question 47

name two cells that only use glucose as a respiratory substrate

Answer 47

brain cells

erythrocytes

Question 48

how are proteins converted and used as respiratory substrates?

Answer 48

excess amino acids are deaminated (removal of amino group –> converted to urea in ornithine cycle)

remainder of molecule is converted to glycogen or lipids for storage

during starvation, can be hydrolysed to release a.a.

Question 49

how are lipids converted and used as respiratory substrate?

Answer 49

triglycerides hydrolysed to 3 fatty acids and 1 glycerol

converted to glyceraldehyde

then pyruvate and respired

fatty acids broken down during B. oxidation to release acetyl groups –> join a CoA to form aCoA –> Krebs cycle

Question 50

what is the respiratory quotient (RQ)?

Answer 50

the ration of the volume of carbon dioxide evolved to that of oxygen consumed by an organism, tissue or cell in a given time

Question 51

what does the RQ indicate?

Answer 51

the type of respiratory substrate being used

Question 52

how is RQ calculated?

Answer 52

mol/vol of CO(2) evolved / mol/vol of O(2) taken up

Question 53

what is the RQ value for anaerobic conditions?

Answer 53

{infinitely large}

Question 54

what is the RQ value for carbohydrates?

Answer 54

1

Question 55

what is the RQ value for lipids?

Answer 55

0.70 - 0.72

Question 56

what is the RQ value for proteins?

Answer 56

0.80 - 0.90

Question 57

why is the RQ value for carbohydrates higher than proteins and lipids?

Answer 57

less oxygen is required to oxidise carbohydrates