Oxidative Phosphorylation

Question 1

Mitochondrial membrane structure

Answer 1

• outer membrane (very impermeable)
• intermembrane space
• inner membrane
• matrix

Question 2

What is the structure of the mitochondrial genome?

Answer 2

Circular (no chromatin, histones, etc)

Question 3

What are the contents of the mitochondrial genome?

Answer 3

~17kb = 37 genes (13 proteins, 22 tRNAs, 2 rRNAs)

Question 4

Describe the structure of a voltage dependent anion channel.

Answer 4

B barrel with a-helix that opens/closes the channel in a voltage dependent manner

Question 5

Where are voltage dependent anion channels located and what do they transport?

Answer 5

• Outer mitochondrial membrane

- ATP/ADP, Pi, pyruvate, citrate

Question 6

What are some inner membrane transporters and what are their substrates?

Answer 6

• Adenine Nucleotide Transporter = ATP/ADP
• Dicarboxylate carrier = malate/phosphate
• Tricarboxylate carrier = citrate + H+/malate
• Pyruvate carrier = OH-/pyruvate
• Phosphate carrier = OH-/phosphate
• Ornithine transporter = ornithine/citrulline

Question 7

What key reactants/products are transported in/out of the mitochondria for oxidative phosphorylation?

Answer 7

IN: O2, ADP, food-derived pyruvate and FAs
OUT: CO2, ATP

Question 8

What is the purpose of the glycerol-3-phosphate shuttle?

Answer 8

Regenerate oxidized NAD+ for glycolysis

Question 9

What reaction is catalyzed by cytosolic glycerol-3-P DH?

Answer 9

• Reduces DHAP to glycerol-3-P, requiring 1 NADH

- Regenerates oxidized NAD+ for glycolysis

Question 10

What reaction is catalyzed by mitochondrial glycerol-3-P DH?

Answer 10

• Glycerol-3-P is oxidized back to DHAP, generating 1 FADH

- Protein is inner-membrane bound: DHAP remains in cytosol and electrons from FADH are transferred to the ETC

Question 11

What are the major and minor pathways for transporting re-oxidizing the NADH generated in glycolysis to NAD+?

Answer 11

Major: G3P shuttle
Minor: malate-aspartate shuttle

Question 12

What is the purpose of the malate-aspartate shuttle?

Answer 12

Regenerate oxidized NAD+ for glycolysis

Question 13

What are the steps of the malate-aspartate shuttle?

Answer 13

Overall: transport + carbon skeleton recycling

1. cytosolic OAA reduced to malate, requiring 1 NADH (and regenerating an NAD+ for glycolysis)
2. Malate transport across inner mitochondrial membrane
3. Malate oxidized to OAA, generating 1 NADH (goes into ETC)
4. OAA is transaminated to aspartate, requiring glu and generating a-KG
5. Aspartate is transported across the inner mitochondrial membrane to cytosol
6. Aspartate transaminated to OAA, requiring a-KG and generating glu

*glu and a-KG transported across inner membrane

Question 14

What is the function of complex 1?

Answer 14

NADH dehydrogenase:

• accepts 2 electrons from NADH
• electron transfer via FMN and Fe-S clusters to CoQ
• 4 protons pumped into IM space

Question 15

What is the function of complex 2?

Answer 15

Succinate dehydrogenase (TCA enzyme) + ETF CoQ oxidoreductase + G3PDH:

• accepts electrons from succinate
• electron transfer via FAD to CoQ
• does not span membrane nor pump protons

Question 16

What is the function of complex 3?

Answer 16

Cytb-c1 complex:

• accepts electrons from reduced CoQ (CoQH2)
• electron transfer via cyt b and Fe-S clusters to cyt c
• cytochromes have a bound heme
• pumps 4 protons across membrane

Question 17

What is the function of complex 4?

Answer 17

Cyt c oxidase:

• accepts electrons from cyt c
• electron transfer via Cu and Fe ions and cyt a’s to O2
• pumps 2 protons across membrane

Question 18

What is ubiquinone?

Answer 18

• Electron carrier that moves through the membrane to transport 2 protons and 2 electrons from complexes 1 and 2 to complex 3 in its reduced form
• hydrophobic hydrocarbon tail is produced via cholesterol biosynthesis

Question 19

What is cytochrome c?

Answer 19

• Electron carrier that transports electrons from complex 3 to complex 4
• Uses iron-sulfur clusters to complex electrons

Question 20

What is the purpose of iron-sulfur clusters?

Answer 20

• Coordinate electrons for transport
• Heme holds iron
• Proteins fold to expose free sulfhydrils on cysteines

Question 21

How does redox potential change across the ETC?

Answer 21

• Redox potential (electron affinity) increases

Question 22

How does the energy per electron change across the ETC?

Answer 22

• Decreases slightly as some energy is lost as heat and also used at each step

Question 23

Why are protons pumped across the inner membrane?

Answer 23

To create an electrochemical gradient: intermembrane space is + charged and acidic

Question 24

Which direction are protons pumped?

Answer 24

matrix -> intermembrane space

Question 25

What is the relationship between the cytoplasm and the intermembrane space?

Answer 25

Considered continuous because voltage gated channels allow for diffusion

Question 26

What is the chemiosmotic theory of oxidative phosphorylation?

Answer 26

• A proton motive force is generated from the electrochemical proton gradient established across the inner membrane
• Protons want to move from the positively charged, acidic inner membrane space down the gradient into the matrix

Question 27

What is the purpose of F0F1 ATP synthase?

Answer 27

• Transfers chemical energy (protons) into mechanical energy (rotor) back to chemical energy (ATP)
• As protons move down the gradient through the rotor, conformational changes to the protein allow for generation of ATP

Question 28

Why is ATP synthase reversible?

Answer 28

• Can hydrolyze ATP to pump protons into the inter membrane space
• Allows electrochemical gradient/membrane potential to be maintained for other processes (other than ATP synthesis) while the cell is in a high energy state and no ATP synthesis is needed (ie ETC is inactive)

Question 29

How is the rate of oxygen consumption by complex 4 controlled?

Answer 29

ADP concentration

Question 30

What is oligomycin?

Answer 30

ETC inhibitor that blocks the F0 channel of ATP synthase?

Question 31

What are some inhibitors of of CoQ reduction?

Answer 31

via complex 1: piericidin A, amobarbital, rotenone

via complex 2: carboxin, TTFA

Question 32

What are some inhibitors of complexes 2, 3, and 4?

Answer 32

2: malonate
3: BAL, antimycin A
4: H2S, CO, CN-

Question 33

How do ETC uncouplers work?

Answer 33

• Facilitate transport of protons across inner membrane, dissipating the gradient
• Heat is generated instead of ATP

Question 34

thermogenin

Answer 34

• ETC uncoupling protein
• found in inner mitochondrial membrane in brown fat in infants
• transports protons back into the matrix after they are transported into the inner membrane space via the etc to produce heat

Question 35

2,4-DNP

Answer 35

• chemical etc uncoupler
• small hydrophobic molecule binds proton in the acidic IM space and diffuses across the membrane to the matrix
• used as a weight loss drug as FAs could be burned w/o ATP generation

Question 36

What are other functions of the electrochemical gradient?

Answer 36

• Voltage gradient: drives transport of ADP (-3) into the matrix and ATP (-4) into the IM space/cytosol
• pH gradient: phosphate (-) and pyruvate (-) import

Question 37

What does it mean that the mitochondria is a calcium sink?

Answer 37

Takes in and releases Ca2+ ions to maintain cytosolic [Ca2+]

Question 38

What is the function of the mitochondrial permeability transition pore?

Answer 38

• Allows free passage of water and solutes into the mitochondria => lysis
• Involved in apoptosis

Question 39

What are the components of the mitochondrial permeability transition pore?

Answer 39

• ANT in inner membrane + VDAC in outer membrane
• CK in IM space to accept ATP
• HK in cytosol to accept ATP

Question 40

What regulates mitochondrial permeability transition pore formation?

Answer 40

+ : atractyloside, Ca2+, Bax, PO4, ROS

- : bongkrekic acid, ATP

Question 41

What reactions generate ROS?

Answer 41

• Fenton reaction: H2O2 + iron => hydroxyl ion + hydroxyl radical
• O2 + electron => superoxide (ROS)
• superoxide + electron + 2 protons => H2O2 which can combine with a proton and an electron to make water and a hydroxyl radical

Question 42

Why is it dangerous to have free iron in the cell?

Answer 42

• Can generate hydroxyl radicals by reducing H2O2

- This is why we need heme, ferritin

Question 43

What are some NOS’s?

Answer 43

• nitric oxide = free radical
• peroxynitrite = strong oxidizing agent
• peroxynitrous acid
• nitronium ion = nitrating agent
• nitrogen dioxide = free radical
• nitrogen trioxide = nitrosating agent

Question 44

What are some sources of NOS’s?

Answer 44

• Nitric oxide synthase generates nitric oxide with conversion of arginine to citrulline
• Diet and gut bacteria generate nitrite which can be converted to nitrogen trioxide

Question 45

What are some non-enzymatic antioxidants?

Answer 45

• vitamins C and E
• carotenoids (dietary)
• flavonoids (dietary)
• uric acid (purine catabolism)
• melatonin

Question 46

What antioxidant enzymes defend against oxygen radicals?

Answer 46

• superoxide dismutase (cytosol and mitochondria) converts 2 superoxide into O2 + H2O2
• catalase (peroxisome) converts 2 H2O2 into 2 H2O + O2
• glutathione peroxidase reduces H2O2 to H2O with the oxidation of 2 GSH

Question 47

What is glutathione?

Answer 47

• GSH = gly + cys + glu

- the free sulfhydryls on the cys residues of 2 GSH will form a disulfide bond that can be used as a reducing agent

Question 48

How is reduced 2 GSH regenerated from GSSG?

Answer 48

Glutathione reductase reduces GSSG using NADPH

Question 49

What cellular damage is caused by ROS?

Answer 49

• Protein damage => aggregation
• DNA damage => apoptosis, cancer
• Membrane lipid peroxidation => “contagious” as damaged lipids act as free radicals too => change in membrane permeability
• Membrane damage => Ca2+, Na+, and water influx => cell swelling

Question 50

Generally, how are ROS and NOS generated?

Answer 50

oxidative metabolism