Week 5 - Citric Acid Cycle (TCA)

Question 1

What is the citric acid cycle

Answer 1

• A central catabolic pathway in the mitochondria which produces energy in the form of GTP and the reduced electron carriers NADH and FADH2
• It requires acetyl-CoA hence from the glycolysis pathway there’s an additional step to convert the pyruvate into Acetyl-CoA

Question 2

Where does the citric acid cycle occur

Answer 2

Mitochondrial Matrix

Question 3

What reaction occurs before the TCA

Answer 3

oxidative decarboxylation

Question 4

What is oxidative decarboxylation

Answer 4

• Process which occurs before TCA to convert pyruvate from glycolysis and transform it into Acetyl-CoA
• This occurs in Aerobic conditions
• 5 steps

Question 5

What is the equation for oxidative decarboxylation

Answer 5

Question 6

Where does oxidative decarboxylation occur

Answer 6

Matrix of the mitochondria

Question 7

What is the enzyme complex involved in oxidative decarboxylation

Answer 7

pyruvate dehydrogenase

Question 8

What is the input for TCA

Answer 8

acetyl-CoA

Question 9

What is step 1 of the TCA

Answer 9

Acetyl CoA enters at step 1 and syntheses with oxaloacetate (which was produced from the last step in TCA) and releases CoA (Coenzyme A) to be recycled

Question 10

What is step 3 of TCA

Answer 10

NAD+ is reduced to form NADH which is the first step (3) where we’re actually creating energy. And is the first point where CO2 is loss

Question 11

What occurs in step 4 of TCA

Answer 11

CO2 is loss again and NAD+ is reduced to NADH

Question 12

What occurs in step 5 of TCA

Answer 12

Create the first direct energy usable molecule GTP

Question 13

What occurs in step 6 of TCA

Answer 13

Forms another electron proton carrier, FADH2 through the reduction of FAD

Question 14

What occurs in step 8 of TCA

Answer 14

Captures energy again to make another NADH through the reduction of NAD+

Question 15

What are the oxidation steps in TCA

Answer 15

Step 3, 4, 6, 8
(molecules are being reduced hence other molecules must be oxidized)

Question 16

What steps produce NADH

Answer 16

Step 3, 4, 8

Question 17

How is NADH produced in TCA

Answer 17

NAD+ is reduced to form NADH and releases CO2 (makes the process a form of respiration)

Question 18

When is GTP produced in TCA

Answer 18

Step 5

Question 19

When is FADH2 created

Answer 19

Step 6

Question 20

What is the change of carbon chain during the TCA

Answer 20

Question 21

What is the RDS in TCA

Answer 21

Step 3 (NAD+ is reduced to form NADH which is the first step (3) where we’re actually creating energy)

Question 22

What is step 1 of TCA

Answer 22

Question 23

What is step 3 of TCA

Answer 23

Question 24

What is step 4 of TCA

Answer 24

Question 25

Which steps of TCA is regulated

Answer 25

• Step 1
• Step 3
• Step 4

Question 26

What is the enzyme which catalyzes step 1 of TCA

Answer 26

citrate synthase

Question 27

What is the enzyme which catalyzes step 3 of TCA

Answer 27

isocitrate dehydrogenase

Question 28

What is the enzyme which catalyzes step 4 of TCA

Answer 28

a-ketoglutarate dehydrogenase complex

Question 29

What is step 1 regulated by

Answer 29

Inhibited by ATP and NADH, succinyl-CoA (S4) and the product citrate

Question 30

What is step 3 regulated by

Answer 30

activated by ADP and NAD+
inhibited by ATP and NADH

Question 31

What is step 4 regulated by

Answer 31

activated by ADP and NAD+
inhibited by ATP and NADH and product of this step succinyl-CoA

Question 32

What is the overall reaction of the TCA cycle

Answer 32

Question 33

What occurs after the TCA

Answer 33

Oxidative phosphorylation
The remaining energy is located in redox/H+ carriers FADH2 and NADH, it is now converted into available energy using an ATP synthase in the mitochondrial inner membrane

Question 34

What processes occur in oxidative phosphorylation

Answer 34

• electron transport chain
• Chemiosmosis

Question 35

Where does oxidative phosphorylation occur

Answer 35

inner membrane of the mitochondrion

Question 36

What are the electron carriers in the electron transport chain

Answer 36

coenzyme Q and cytochrome C

Question 37

What is the process of the electron transport chain

Answer 37

1. NADH approaches complex 1 and gives up its protons and electrons to form NAD+, in turn donating its electron to complex 1 - supercharging it
2. Supercharged complex 1 has the energy to pump protons (H+) from the mitochondrial matrix into the intermembrane space - creating an accumulation of protons on this side (forming a proton gradient)
3. Complex 1 passes its electron to CoQ
4. FADH2 gives up it’s electrons to complex 2 to form FAD, however complex 2 cannot pump protons
5. Complex 2 transfers its electron to CoQ
6. Electrons in CoQ are passed to complex 3 - providing it energy to pump more protons from the mitochondrial matriz into the intermembrane space
7. Complex 3 passes its electrons to Cytochrome C
8. Cytochrome C passes it’s electrons to complex 4 which then becomes supercharged and pumps more protons into the intermembrane space adding to the strong proton gradient
9. Complex 4 passes its electrons to oxygen (O2) forming 2 oxygen ions, and then protons are added, forming 2 water molecules

Question 38

What is chemiosmosis

Answer 38

the process which takes the stored electrochemical energy in the ion gradient and converts it into a high energy bond in ATP.
This uses an ATP synthase

Question 39

What is the protein which brings about the synthesis of ATP oxidative phosphorylation

Answer 39

ATP synthase

Question 40

What is the chemiosmotic theory

Answer 40

the flow of H+ through ATP synthase due to the proton gradient lead to conformational changes in ATP synthase which

1. binds ADP
2. phosphorylates ADP into ATP
3. releases the ATP

This occurs in a binding change mechanism within the ATP synthase. ATP synthase may be regarded as a rotating molecular motor, as a flow of protons turns the motor clockwise.

Question 41

What is the overall reaction of oxidative phosphorylation

Answer 41

Question 42

Why is anaerobic metabolism used instead of aerobic metabolism when active

Answer 42

Aerobic metabolism releases energy at a low rate so when someone is running they will switch to anaerobic metabolism and the body will deal with the build of lactic acid in their muscles because anaerobic metabolism will release energy at a greater rate.

Question 43

What is the ATP yield of the whole aerobic glycolysis + TCA + OxPhos

Answer 43

36 ATP
(30-38 ATP)

Question 44

What is the ATP yield of anaerobic glycolysis

Answer 44

net 2 ATP from the conversion of 1 molecule of glucose to 2 molecules of lactic acid

Question 45

How much ATP is produced by the NADH produced from glycolysis and TCA

Answer 45

Glycolysis NADH = 2 ATP
TCA NADH = 3ATP

Question 46

Why does the NADH produced in glycolysis produce less ATP than the NADH produced in TCA

Answer 46

For NADH to be converted into ATP from the electron transport chain it must be in the mitochondria
Hence NADH from glycolysis is in the cytosol and uses up some energy to get into the mitochondria
On the other hand NADH from TCA is already in the mitochondria

Question 47

How many ATP molecules are produced from oxidative decarboxylation

Answer 47

6
as it produces 2 NADH (from 2 pyruvate molecules) (1 NADH = 3 ATP)

Question 48

How many ATP molecules are produced from TCA and oxidative phosphorylation

Answer 48

24

Question 49

What does the electron transport chain create

Answer 49

A proton gradient (pH) gradient) across the membrane which represents stored potential energy - a voltage gradient

Question 50

what is a voltage gradient

Answer 50

Difference in concentration of H+ ions across the membrane
It is an electrochemical potential

Question 51

How many H+ are pumped out per NADH

Answer 51

6 H+

Question 52

How many H+ are pumped out per FADH2

Answer 52

4H+

Question 53

What is the terminal electron acceptor in ETC

Answer 53

O2 (oxygen)