Mitochondrial function and dysfunction

Question 1

functions of mitochondria

Answer 1

• oxidation of fat, protein and CHO for energy
• steroid hormones and neurotransmitter synthesis
• nucleotide synthesis
• calcium buffering
• growth and proliferation
• apoptosis and cell growth

Question 2

anatomy of mitochondrion

Answer 2

• outer membrane
• intermembrane space
• innermembrane
• matrix
• cristae junction
• F0, F1 complexes
• DNA
• ribosomes

Question 3

what is the mitochondria inner membrane permeable to

Answer 3

O2, CO2 and H2O

Question 4

what is the mitochondria outer membrane permeable to

Answer 4

<5000 Da

Question 5

3 stages of cellular respiration

Answer 5

• production of acetyl CoA (link reaction)
• oxidation of acetyl Coa
  = TCA cycle
• electron transport and chemiosmosis

Question 6

how is acetyl CoA produced

Answer 6

from pyruvate in the link reaction

Question 7

TCA Cycle

Answer 7

1. Acetyl CoA (from link)
2. citric acid
3. isocitric acid
4. alpha-ketoglutaric acid
5. succinyl CoA
6. Succinate
7. Fumarate
8. Malate
9. oxaloacetate
10. acetyl CoA

Question 8

where in TCA is NADH produced

Answer 8

• isocitric acid -> alpha-ketoglutaric acid
• alpha-ketoglutaric acid -> succinyl CoA
• malate -> oxaloacetate

= 3 x NADH

Question 9

Where in TCA is FADH2 produced

Answer 9

• succinate -> fumarate

= 1 x FADH2

Question 10

Where is CO2 produced in the TCA cycle

Answer 10

• isocitric acid -> alpha-ketoglutaric acid
• alpha-ketoglutaric acid -> succinyl CoA

= 2 x CO2

Question 11

where is ATP produced in the TCA cycle

Answer 11

• succinyl CoA -> succinate

= 1 x ATP

Question 12

reduced NAD

Answer 12

NADH

Question 13

Steps of ETC

Answer 13

1. Complex I takes 2e- from NADH. Energy released is used to pump 4H+ across the membrane
2. complex II takes 2e- from FADH2. No H+ is pumpd across the membrane
3. Ubiquinone (Q) takes 2e- from complex I and II and transfers to complex III
4. Complex III accepts these 2e- from Q. Energy released is used to pump H+ across the membrane
5. Cyt C takes e- from complex III and transfers to complex IV
6. Complex IV accepts e- from Cyt C
7. cycle repeats and Complex IV accumulates 4e-
8. 4e- used to reduce molecular oxygen to water

Question 14

what transfers electrons from Complex I and II to complex III

Answer 14

ubiquinone (Q)

Question 15

what does ubiquinone do in ETC

Answer 15

transfers e- from Complex I and II to complex III

Question 16

Where does complex I take it 2e- from

Answer 16

NADH

Question 17

Where does complex Ii take it 2e- from

Answer 17

FADH2

Question 18

Where does complex III get its 2e- from

Answer 18

Ubiquinione, Q

Question 19

what does Cyt C do

Answer 19

takes e- from complex III to complex IV

Question 20

where does complex IV get its e- from

Answer 20

Cyt c, from complex IV

Question 21

What happens when complex IV accumulates 4e-

Answer 21

4e- used to reduce molecular oxygen to water

Question 22

which complexes pump H across membrane

Answer 22

I, III and IV

Question 23

where to pumped protons go

Answer 23

enter ATPase to produce ATP via chemiosmosis

Question 24

where is Q

Answer 24

inner mitochondrial membrane

Question 25

where is Cyt C

Answer 25

intermembrane space

Question 26

where is Complex I

Answer 26

inner mitochondrial membrane

Question 27

where is complex II

Answer 27

mitochondrial matrix

Question 28

where is complex III

Answer 28

inner mitochondrial membrane

Question 29

where is complex IV

Answer 29

inner mitochondrial membrane

Question 30

where is ATPase

Answer 30

inner mitochondrial membrane through to matrix

Question 31

list electron carriers

Answer 31

• NAD+
• flavoprotens
• iron-sulphur clusters
• Ubiquinone
• cytochromes

Question 32

NAD+ as electron carrier

Answer 32

• accepts 2e- and one H+ = NADH

Question 33

flavoproteins as electron carriers

Answer 33

accept 1e- in semiquinone form or 2e-, and 2 H+

• FAD -> FADH2
• FMN -> FMNH2

Question 34

iron sulphur clusters as electron carriers

Answer 34

• Fe-S accept and release one e- at a time

non haem prosthetic group associated with flavin enzymes.
Fe2+ or Fe3+ ; net charge is somewhere inbetween as electrons are dispersed amount Fe

Question 35

uniquinone as electron carrier

Answer 35

aka coenzyme Q10

• only electron carrier not bound to protein complex
• freely diffusable in the non-polar interior of the IMM

Question 36

cytochromes as electron carrier

Answer 36

c1, c, a and a3

• capable of absorbing visible light due to haem group
• haem prosthetic group oscialte between Fe2+ and Fe3+ after acceptin an electron
• cytochromes carry one e-
• cyt c is mobile

Question 37

what is complex I

Answer 37

NADH dehydrogenase

Question 38

role of complex I

Answer 38

• oxidises NADH from TCA cycle, glycolysis and FA oxidation
• reduces Q for rest of ETC
• transports H+ across IMM to support ATP synthesis
• major contributor to cellular reactive oxygen species productive and oxidative stress

Question 39

structure of complex I

Answer 39

NADH dehydrogenase
integral membrane enzyme composed of:
- 9 redox cofactors
- 44 different subunits 
has a membrane arm and a matrix arm 
- many iron-sulphur centres
- FMN containing flavoprotein

Question 40

how does complex I transfer electrons from NADH to Q

Answer 40

• FMN in the matrix arm accepts 2e- from NADH converting it to reduced form FMNH2
• Fe-S clusters in the matrix arm transfer 2e- protein N2 in membrane arm, one at a time
• electrons transfer from N2 through membrane arm to Q
• Q is reduced to QH2
• 2H+ are pulled from the matrix

Question 41

function of complex I in ETC

Answer 41

catalyses two simultaneous and coupled processes

• takes 2e- from NADH and passes them to Q, pulling 2H+ from matrix to generate QH2
• transfers 4H+ from matrix to intermembrane

Question 42

what is complex III

Answer 42

cytochrome c oxidoreductase

Question 43

where does QH2 go

Answer 43

complex III

Question 44

Structure of Complex III

Answer 44

• cytochrome c oxidoreductase
• membrane protein
• dimer of identical monomers
• each monomer has 11 different subunits
• Cyt C1 and Rieske of Complex III project into the IMS and interact with CytC
• has 2 distinct binding sites of QH2

Question 45

examples of some of the different subunits found in each monomer of complex III

Answer 45

• cytochrome b, with 2 haem groups
• rieske, Fe2S2 protein
• cytochrome C1, with heam group

Question 46

what are the two binding sites on complex III for QH2

Answer 46

QN and QP

Question 47

summary equation of the Q cycle

Answer 47

QH2 + 2Cytc (Fe3+) + 2H+ (m) -> Q + 4H+ (ims) + 2Cytc (Fe2+)

QH2 + 2H+ -> Q + 2e- + 4H+

Question 48

what is the Q cycle

Answer 48

Oxidation of QH2 by Cytochrome C, catalysed by complex III. Protons are also pumped across the IMM

Question 49

Structure of Cytochrome C

Answer 49

• small
• single haem group and single e-
• 12kDa
• 104 amino acids

Question 50

what does leakage of cytochrome C out of mitochondrial memebrane trigger

Answer 50

apoptosis

Question 51

what is complex IV

Answer 51

cytochrome C oxidase

Question 52

structure of complex IV

Answer 52

cytochome C oxidase

• 14 protein subunits
• 2 catalytic subunits
• 2 haems: Cyt a and Cyt a3
• 2 copper centres: CuA and CuB

Question 53

what is sepcial about complex IV

Answer 53

it reduces oxygen without generating superoxide // free radicals

Question 54

process of complex IV actions

Answer 54

1. two molecules of reduced Cyt C each donate an e- to CuA
2. first e- passes through haem group of subnits 1 to the Fe-CuB centre to reduce copper
3. second e- stops at haem a3, reducing Fe3+ to Fe2+
4. oxygen now recruited, forming haem a3-oxygen complex
5. proximity of reduced Cu to the haem complex reduces it to copper peroxied which bridges haem and Cu
6. Cyt C delivers 3rd e- which cleaves O-O peroxide bond, with help of 2 matirix H+ = generation of Fe4+ with haem a3
7. Cyt c delivers final e- which reduces Fe4+ to Fe3+
8. 2 more H+ release 2 molecules of water and reset the system
9. Complex IV also pumps 4H+ into IMM

Question 55

overall reaction at complex IV

Answer 55

4cyt c (reduced) + 8H+ + O2 -> 4Cyt c (oxidised) + 2H2O + 4H+

Question 56

How many H+ does complex IV remove from the matrix

Answer 56

8

• removes 4 by chemical reaction to form water
• pumps 4 across membrane into IMM

Question 57

What is compelx II

Answer 57

succinate dehydrogenase

Question 58

how many protons does complex II pump

Answer 58

none

Question 59

which complex pumps no protons

Answer 59

complex II

Question 60

structure of complex II

Answer 60

succinate dehydrogenase, has 4 subunits
- SDH-A : FAD as a proton acceptor
- SDH-B: 3 Fe-S clusters
- SDH-C: cytochrome b
- SDH-D: cytochrome b
also has Q binding site

Question 61

role of Complex II

Answer 61

Involved in production of FADH2, via TCA cycle

takes 2e- from FADH2 to give to Q

Question 62

what is the overall purpose of thee ETC

Answer 62

to generate proton gradient to drive ATP synthase

Question 63

what powers the ETC

Answer 63

Redox reactions

- simultaneous reduction and oxidation resulting in transfer of electrons

Question 64

what is a redox potential

Answer 64

the measure of ease with which a molecule will accepy protons
- more positive the redox potential, the more readily a molecule is reduced

Question 65

why does ETC happen via lots of small reactions

Answer 65

lots of little reactions each produce a small amount of energy.
this is favourable becuase it is easier to control than one large sum of energy that would be produced if reaction went straight from NADH -> O2

Question 66

PMF

Answer 66

proton motive force

Question 67

what forces are involved in the electrochemical gradient of H+ across the IMM

Answer 67

• large force due to membrane potential

- smaller force due to [H+] gradient

Question 68

what is complex V

Answer 68

F1F0 ATP synthase

Question 69

structure of complex V

Answer 69

F1F0ATP synthase

• 500kDa complex which makes use of electrochemical gradient
• F0 is hydrophobic unit in membrane with 10 identical subunits
• F1 is hydrophillic catalytic unit with 3 identical alpha beta subunits

Question 70

what drives complex V

Answer 70

spins at 150 Hz

• flow of H+ down electrochemical grad drives the F0 roto that lies in the membrane
• H+ bind to empty F0 subunits
• once protonated F0 subunits complete a full circle, protons exit the matrix

Question 71

what is the energy conversion at complex V

Answer 71

energy stored in proton gradient is converted to rotational energy

Question 72

rotatory catalysis model

Answer 72

• when F1 is in the open state, ADP and P enter the active site
• protein then closes around ADP and P and binds them loosely
• protein undergoes another conformational change forcing ADP and P closer together
  = AS is now in a T-state to produce ATP with very high affinity
• AS goes back to open which releases the ATP and binds more ADP and P for next cycle

Question 73

what happens if F1 doesnt have ADP and P attached

Answer 73

F1 will not allow F0 and stalk to rotate

- very important for respiratory control

Question 74

total ATP made from oxidative phosphorylation

Answer 74

26-28

• 3-5 from glycolysis (via NADH)
• 5 from link reaction (via NADH)
• 18 from TCA cycle (via NADH and FADH2)

Question 75

types of mitochondrial dysfunction

Answer 75

1. impairment of ETC and ATPsynthesis machinery
2. inadequate no. of mitochondria
3. accumulation of damaged mitochondria

Question 76

what causes impairment of ETC and ATPsynthesis machinery

Answer 76

single enzme disorder or ROS/RNS

Question 77

RNS and ROS

Answer 77

reactive nitrogen species

reactive oxygen species

Question 78

what causes inadequate no. of mitochondria

Answer 78

imparied mitochondrial dynamics / biogenesis

Question 79

what causes accumulation of damaged mitochondria

Answer 79

impaired mitophagy

Question 80

what is the most common single enzyme mitochondrial disorder

Answer 80

complex I disorder

Question 81

complex I disorder

Answer 81

• most common single enzyme mitochondrial disorder
• mutations discovered in 26/44 genes, 7mtDNA and 21nDNA
• range of symptons and severity
  
  • 50% fatal under 2yo
  • 75% fatal under 10yo

Question 82

what does complex I disorder causes

Answer 82

• lactic acidosis which is fatal bc of sever inhibiton of ETC
• mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS)
• Leigh syndrome

Question 83

MELAS

Answer 83

mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes

Question 84

what is heteroplasmy

Answer 84

presence of >1 type of mitochondrial genome

• multiple copies of mtDNA per cell and not segregated like nuclear genome
• proprtion of mutant DNA vary between indivuduals and tissues
• bottleneck at myosis - few mitochondria transmitted so variable mutaton burden in offspring

Question 85

how does diabetes affect mitochondria metabolism

Answer 85

• causes marked inhibition of mitochondrial metabolism in pancreatic beta cells
• mitochondrially-generated ATP stimulates insulin secretion and senses glucose
• mouse model of T2D showed reduced mitochondrial metabolism and ATP function

Question 86

what are the major source of ROS

Answer 86

mitochondria

Question 87

what are the most likely origins of ROS in intact cells

Answer 87

complex I and III

Question 88

how are ROS produced

Answer 88

leak of e- as they progress from donor redox centres to molecular oxygen (ETC)
- premature single e- reduction of molecualr oxygen earier in the ETC forms superoxide radical

Question 89

ROS production

Answer 89

highlight reactive •OH generated from O2•- and H2O

• initiates formation of lipid radicals and lipid peroxyl radiocals
• mitochondria are also exposed to RNS (NO•) which can react with O2•- to form peroxynitrate ONOO-

Question 90

Superoxide anion

Answer 90

O2•-

Question 91

what do O2•- and NO• form

Answer 91

peroxynitrate ONOO-

Question 92

how many types of DNA to mitochondria have

Answer 92

2

• nuclear DNA
• mitochondrial DNA

Question 93

mitochondrial DNA

Answer 93

• maternally inherited
• multiple copies per mitochondrion
• located in The matrix
• encodes critical subunits of the ETC

Question 94

what do ROS do to mitochondrial DNA

Answer 94

cause base pari lesions which accumulate with age

• H2O2 forms reactive •OH which causes formation of 8-oxoG from purines
• produces G-T inversions on replication

Question 95

Mitochondrial maintenace

Answer 95

methods of minimising dysfunction

• fusion and fission
• ROS scavenging
• mitophagy

Question 96

ROS scavenging

Answer 96

removal of ROS

O2•- is converted to H2O2 by superoxide dismutase

Question 97

mitochondrial dynamics

Answer 97

fission and fusion

fission: required for cell division, increased itochondrial number and segregation of damaged mitochondrial
fusion: allows mitochondria contents to mix and may inrease ATP production

Question 98

Fission

Answer 98

required for cell division, increased itochondrial number and segregation of damaged mitochondrial

Question 99

Fusion

Answer 99

allows mitochondria contents to mix and may inrease ATP production

Question 100

steps of fission

Answer 100

• cystolic Drp1 is phosphorylated
• Drp1 recruited to mitochondria and binds receptors
• forms cuff around mitochondria which constricts the organelle
• constriction severs both membranes
• new mitochondria generated

Question 101

steps of fusion

Answer 101

• Mfn1 and 2 localise o the outer membranes and dock the two mitochondrion together by fusion of outer membrane
• OPA 1 localised on inner membrane, responsible for fusing the two inner membranes together
• shares content of mitochondria and dilutes the effects of any damage

Question 102

what is OPA 1 used for

Answer 102

localised on he inner membrane of mitochondria to fuse the two inner membranes together during fusion

Question 103

where else is OPA 1 critical

Answer 103

ETC function and apoptosis

• OPA1 bridges the entrance to the cristae within the mitochondrion
• disruption of OPA1 bridge disrupts the ETC and releases CytC
• Cyc C escapes the mitochondrion and promotes apoptosis

Question 104

quality control of mitochondria

Answer 104

mitophagy

Question 105

mitophagy

Answer 105

quality control of mitochondria

• selective mitochondrial degradation/recycling
• usually upregulated in response to stress

Question 106

healthy mitochondria

Answer 106

PINK1 degraded by proteomsomes

Question 107

Depolarised mitochondria

Answer 107

PINK1 and parkin act on the outer MM proteins to recruit them into autophagosomes for recycling

Question 108

pathologies of mitochondiral dysfunction

Answer 108

Complex II : huntington’s
Complex IV: Alzheimer’s
PINK1/Parkin: parkinson;s
ROS: autism

chronic fatigue, diabetes, epilipsy, cerebral palsy, muscular dystrophy, cardiomyopathy and more

Question 109

where is cytochrome c reoxidised

Answer 109

Complex IV of the Electron Transport Chain

Question 110

Which components of the Electron Transport Chain are the most likely producers of Reactive Oxygen Species (ROS) in mitochondria

Answer 110

Complexes I and III