Bioenergetics

Question 1

At rest how much ATP does the body make a day?

Answer 1

1/2 your body weight. With normal amounts of work your full body weight and with heavy work one tonne.

Question 2

What does chemiosmosis involve?

Answer 2

One or more energy release reactions. Redox creates a transmembrane gradient used to make ATP and ATP can make an energy gradient.

Question 3

What are the two main sources for the Proton Motive Force?

Answer 3

Respiration and photosynthesis.

Question 4

What are the three main uses of PFM?

Answer 4

ATP synthesis.
Motility.
Soulte transport.

Question 5

What is the central dogma of energy conversion?

Answer 5

‘Release, transfer, trapping.’

Redox… transmembrane gradient…. ATP synthesis.

Question 6

What step of the central drogma of energy conversion is reversible?

Answer 6

Transmembrane gradient…. ATP synthesis.

Question 7

What step of the central dogma of energy conversion is not easily reversible?

Answer 7

Redox… transmembrane gradient.

Question 8

How can a cell membrane resit osmosis?

Answer 8

If work is put in to push in the opposite direction.

Question 9

What does a ‘leaky membrane’ result in?

Answer 9

The movement of some H+ through the membrane without any useful energy being produced.

Question 10

Why do the outer membrane in bacteria and mitochondria not use chemiosmosis?

Answer 10

They have holes in them.

Question 11

Where is the N phase found in regards to a cell?

Answer 11

Outside and inside an organelle.

Question 12

Where is the P phase found in regards to a cell?

Answer 12

In the cytoplasm.

Question 13

What two things can cause the breakdown of the cytoplasmic membrane?

Answer 13

Lsyzome and osmotic shock.

Question 14

What type of bacterium does the P and N phase apply to?

Answer 14

Intact bacteria.

Question 15

In gram negative bacteria what phase is the periplasm considered as?

Answer 15

P.

Question 16

In what phase is ATPsynthase normally found?

Answer 16

N.

Question 17

After osmotic shock and lyzosome activity where is the ATPase found?

Answer 17

Right-side-out of vesicle (N).

Question 18

After the french press where is the ATPase found?

Answer 18

Outside out (O).

Question 19

What are Mitchells 4 postulates?

Answer 19

1. Respiratory and photosynthetic electron transfer should translocate protons.
2. The ATPase should function as a reversible proton translocating ATPase.
3. Energy transducing membranes should have a low effective proton conductance.
4. Energy transuding membranes should posses specific exchange carriers to permit metabolites to penetrate and osmotic stability to be maintained at a high energy potential.

Question 20

Why did measuring the driving force allow?

Answer 20

1. Quantitative approach allowing calculation away from equilibrium.
2. The replacement of the wrong idea about a high energy intermediate.
3. Eliminates thermodynamically imposible reactions.

Question 21

Energy from ATP does not come from the high energy phosphate bond. Where does the energy come form instead?

Answer 21

How far the mass action ratio is equilibrium.

Question 22

What drives a reaction?

Answer 22

A increase in entropy.

Question 23

How can you asses the entropy change of a system?

Answer 23

Measuring the flow of heat/ enthalpy across a system.

Question 24

In photosynthesis what can Gibbs energy quantify?

Answer 24

Light absorption.

Question 25

In a closed system if A becomes B what is the observed mass action ratio?

Answer 25

[B} obvs/ [A} obvs.

Question 26

As the mass action ratio is displaced from K what happens to Gibbs free energy?

Answer 26

It increases.

Question 27

What is Gibbs free energy at equilibrium?

Answer 27

0.

Question 28

If the mass action ratio is smaller than K what is Gibbs?

Answer 28

Negative.

Question 29

If the mass action ratio is bigger than K what is Gibbs?

Answer 29

Positive.

Question 30

What two forces act on an ion gradient?

Answer 30

1. Concentration gradient.

2. Electrochemical potential difference.

Question 31

What is the membrane potential?

Answer 31

The electrochemical potential difference across the membrane.

Question 32

What charge is inside the mitrochrondria/ bacterial cell and why?

Answer 32

H+ move out.

Question 33

What is delta P?

Answer 33

The function of the electrochemical proton gradient. It has the units of mv and was defined by Mitchell.

Question 34

How can TTP be used to measure the membrane potential?

Answer 34

The inside of the cell is negative and TTP has a positive charge (it is a cation). Despite being charged TTP can cross the membrane and sit in the bilayer as it is very hydrophobic. The amount of TTP that travels into the cell will determine the membrane potential. The TTP used is radiolaballed to quantify the data.

Question 35

What is used to measure the pH of the membrane potential?

Answer 35

A weak acid such as acetate. This dissociates into H+ and A-. The A- will accumulate inside and HA will be at the same concentration on both sides.

Question 36

What is special about thylakoid membranes and what does this show?

Answer 36

They have a massive pH difference and almost no membrane potential. delta P is the opposite to this. this shows that l is determined by the combination of the two and IF YOU MAKE ONE SMALLER THE OTHER GETS LARGER.

Question 37

Delta p is a combination of the membrane potential and the pH difference. How was it shown that if you increase one the other will decrease?

Answer 37

K+ was added to reduce the membrane potential the pH difference goes up.

Question 38

Membrane potential and ph difference are defined as P phase minus N phase. Which is positive and which is negative?

Answer 38

Membrane potential is positive as positive outside and pH diff is negative as acidic outside.

Question 39

What do classic uncouplers do?

Answer 39

They uncouple electron transfer by carrying H+ across the membrane and not through ATP synthase. Causes energy to be wasted as heat.

Question 40

FCCP/ CCP and 2-4DNP are classic uncouplers. What else are they?

Answer 40

Catalysts as they never get used up. This means that you only need them in small amounts.

Question 41

What uncoupler is toxic and can be used as a slimming agent?

Answer 41

2-4 DNP.

Question 42

Classic uncouplers move H+ across the membrane. What does the other category of uncouplers do to uncouple electron transfer?

Answer 42

They distrupt the ATP synthase so H+ can not be translocated.

Question 43

What technique can be used to determine the bacterial H+/O ratio?

Answer 43

The oxygen pulse/ proton pulse technique.

Question 44

What are the four steps of the oxygen pulse/ proton pulse technique?

Answer 44

1. Oxidisable substrate is added to the chamber, all oxygen in the chamber is used and the bacteria become anerobic.
2. Air saturated with a known oxygen medium. This causes the pumping go H+ ions and a drop in pH.
3. Oxygen is exhausted and pH transient decays as the H+ leaks back in. This can be accelerated by the use of FCCP.
4. Calibration with anerobic HCL occurs.

Question 45

What two things does the buffer used in the oxygen pulse/ proton pulse contain and why?

Answer 45

Valinomycin and K+. V moves K+ across the membrane so the charge balance does not change throughout the experiment and the full extend of H+ movement can be measured.

Question 46

Genes that encode ATPase are all similar in size. True or false?

Answer 46

False, they are all very different and can range between 79-500 amino acids.

Question 47

What genes products make up the F0 domain of ATPase?

Answer 47

A, C, B

Question 48

What gene products make up the F1 domain of ATPase?

Answer 48

Delta, alpha, gamma, betta, epsilon.

Question 49

What did ATP genes used to make called?

Answer 49

unc genes (as discovered through uncoupled mutants.)

Question 50

Are more genes for ATPase encoded in the mitochondria or the chloroplast?

Answer 50

Chlorplast. Only two genes (8,6) are now encoded in the mitochondria.

Question 51

What domain of the ATPase is found in the membrane?

Answer 51

F0 (named after the biding drug oligomycin)

Question 52

What portion of the ATPase is catalytic?

Answer 52

F1.

Question 53

What subunits of the ATPase make up the F1 domain?

Answer 53

Alpha, beta, gama, delta, eplison.

Question 54

What subunits of the ATPase make up the F0 domain?

Answer 54

A, C, B.

Question 55

What subunit of the ATPase can you recover a crystal structure of?

Answer 55

F1.

Question 56

How many subunits of C can be present?

Answer 56

6-10.

Question 57

What two subunits go through the middle of AB in the F1 domain of ATPase?

Answer 57

Eplison and gamma.

Question 58

What does the catalytic mechanism of ATPase PROBABLY involve?

Answer 58

The rotation of the gamma subunit along with rotation of the epsilon and C subunit.

Question 59

How was the rotation of the gamma/ eplison and C subunit in ATPase shown?

Answer 59

Experimentally though uncoupled proton translocation.

Question 60

What bacterium was the rotary catalysis of ATPase found in?

Answer 60

Thermaphillic bacterium PS3 (bacillus species).

Question 61

What were the 5 steps in determining rotary catalysis in the PS3 bacillus species?

Answer 61

1. Express genes in E.coli so the the protein has 10 terminal his residues on each B subunit.
2. Purify sub complex 3a-3b-1y.
3. Bind this subunit to slide coated with Ni2+- NTA.
4. Bind actin filament to 1 gamma.
5. Using fluorescence microscopy watch what happens when ATP is added.

Question 62

When the F0 subunit is mutated ATP synthesis will not take place. True or false?

Answer 62

False. ATP synthesis can take place without the proton translocating F0 portion.

Question 63

What is the first step in ATP synthesis?

Answer 63

Proton motor force drives protons through ATPase rotating the C subunits relative to the a and b subunits.

Question 64

What is the second step in ATP synthesis?

Answer 64

Rotation is passed onto the delta and elipson subunits.

Question 65

What is the third step in ATP synthesis?

Answer 65

Rotation of the asymmetric game subunit mechanically causes conformational changes in the alpha/beta hexamer. Each 120 degrees rotation of the gamma subunit forces 1 of 3 catalytic sites located in the alpha/beta interface into the opened conformaiton.

Question 66

What is the fourth step in ATP synthesis?

Answer 66

Newly synthesised ATP is released and ADP/ Pi are bound instead. High affinity of the open site to the phosphate impairs rebinding of ATP and favours ADP binding.

Question 67

What is the fifth step in ATP synthesis?

Answer 67

The gamma subunit turns another 120 degrees forcing the next site into the opened conformation, and the ADP and phosphate bound to the previous opened site are occluded and ATP synthesis takes place.

Question 68

What is the sixth step in ATP synthesis?

Answer 68

ATP is released once the gamma subunit has made the 360 degrees turn and the site opens again.

Question 69

What are the three conformations if the A/B subunit?

Answer 69

Open, tight, lose.

Question 70

What conformation of the A/B subunit is ATP made in?

Answer 70

Made in tight leaves from open.

Question 71

What conformational change of the A/B subunit requires energy?

Answer 71

LOT - TLO.

Question 72

How many degrees does the A/B subunit need to turn to make 1 ATP?

Answer 72

120 degrees.

Question 73

How many protons are needed for a complete turn of the A/B subunit?

Answer 73

The same number as there are C subunits.

Question 74

What does the H+/ATP ratio show?

Answer 74

How many hydrogens are required to make 1 ATP.

Question 75

What is the H+/ATP ratio for bovine mitochondria?

Answer 75

2.7.

Question 76

What is the H+/ATP ratio for yeast?

Answer 76

3.3.

Question 77

What is the H+/ATP for chloroplasts?

Answer 77

4.7.

Question 78

What is the H+/ATP for bacteria?

Answer 78

5.

Question 79

What is the K value for ATP synthesis?

Answer 79

10^5.

Question 80

What standard conditions are needed for the K value 10^5 for ATP synthesis?

Answer 80

pH7, 10mm Mg2+, 10mM Pi.

Question 81

When ATP/ ADP ratios are ten magnitudes from equilibrium how much Gibbs free energy is needed?

Answer 81

57 KJ.

Question 82

What is the purpose of the respiratory chain?

Answer 82

Oxidises reduced substrates and reduces an election acceptor.

Question 83

What is the H+/O ratio?

Answer 83

Every 1/2 O2 6 protons are pumped.

Question 84

What is the H+/ATP ratio?

Answer 84

3.3

Question 85

What is the P/O ratio?

Answer 85

2.

Question 86

In terms of reduction potentials what way do electrons flow?

Answer 86

From negative to positive.

Question 87

What protein family does cytochrome c fall into?

Answer 87

Haem proteins.

Question 88

What is unusual about cytochrome C?

Answer 88

It is soluble.

Question 89

How large is cytrochome C?

Answer 89

Small 12-14D.

Question 90

What shape is cytochrome C?

Answer 90

Square planer.

Question 91

What atom is central to cytochrome C?

Answer 91

Fe. This cycles from Fe2+- Fe3+- Fe4+.

Question 92

What coordinates the Fe atom in cytochrome C?

Answer 92

4 pyrrole rings each with a nitrogen.

Question 93

What colour is cytochrome C?

Answer 93

Bright orange.

Question 94

What changes when cytochrome C goes from oxidised to reduced?

Answer 94

Absorption spectra.

Question 95

What four classes of reaction centres in the respiratory chain?

Answer 95

1. FMN.
2. Iron-Sulphur clusters.
3. Haem B.
4. Ubiquinone (ox)- ubiquinol (red).

Question 96

What is the redox potential of Nad+- NADH?

Answer 96

-320mv.

Question 97

What is the redox potential of H20?

Answer 97

+820 mv.

Question 98

What is complex 1 in the respiratory chain?

Answer 98

NADH dehydrogenase.

Question 99

What reaction centres are found in the respiratory complexes?

Answer 99

FMN, 8 Fe/S.

Question 100

What is complex 2 of the respiratory chain?

Answer 100

Succinate dehydrogenase.

Question 101

What is complex 3 of the respiratory chain?

Answer 101

Cytochrome BC1.

Question 102

What is complex 4 of the respiratory chain?

Answer 102

2 haem groups and 3cu.

Question 103

What complex do the pesticides rotenone and piericdin inhibit?

Answer 103

Complex 1.

Question 104

What complex does the antibiotic antimycin inhibit?

Answer 104

Complex 3.

Question 105

What complex does CN-, CO and NO inhibit?

Answer 105

Complex 4.

Question 106

How do CN-, CO and NO inhibit complex 4?

Answer 106

They bind to the harm groups so there is no O reduction.

Question 107

Unlike the mitochondria respiratory chain the respiratory apparatus of bacteria is highly ______. It is _____ meaning component assembly can be mixed and matched for a particular function. This system is ______. This is all controlled by circuits of gene regulation.

Answer 107

Flexible, modular, branched.

Question 108

What does the bacteria respiratory chain consist of?

Answer 108

1. Numerous dehydrogenase.
2. Several quinone types.
3. 3 oxidases.
4. Numerous anaerobic reductases.

Question 109

Is NDH1/ NADH dehydrogenase a proton pump in E.coli?

Answer 109

Yes.

Question 110

What two oxidases in E.coli are not pumps but do translocate protons?

Answer 110

2 and 3.

Question 111

What are the names of the two oxidases in E.coli that are not pumps but do translocate protons?

Answer 111

CydAB and AppBC.

Question 112

What is the H+/0 ratio from the second and third oxidase in E.coli?

Answer 112

1.

Question 113

The second and third oxidases in E.coli are not pumps. How many subunits are they made of and where are they found?

Answer 113

2 and they are found in the membrane.

Question 114

The second and third oxidases in E.coli use proton translocation. What does this involve the spatial separation of?

Answer 114

H+ and e- from H2. (found in QH2).

Question 115

Why are the second and third terminal oxidases in E.coli similar?

Answer 115

It is not known. Knocking out either the CydAB or AppBc gene has little effect.

Question 116

What can bacteria alter to manipulate energy conversion?

Answer 116

The expression of certain dehydrogenase or oxidases.

Question 117

What two deyhydrogenases can E.coli encode to alter energy conservation?

Answer 117

NDH1 and NDH2.

Question 118

Does NDH1 or NDH2 pump 4H+ in E.coli?

Answer 118

NDH1.

Question 119

What two terminal oxidases can E.coli encode to alter energy conservation?

Answer 119

Cytbo, Cytbd.

Question 120

Does Cytb0 or Cytbd pump 4H+ in E.coli?

Answer 120

Cytob0.

Question 121

What small bacteria has one of the highest respiratory capacities known?

Answer 121

Azotobacter vinelandii.

Question 122

What type of aerobe is Azotobacter vinelandii?

Answer 122

Obligate

Question 123

What is one of the main roles of Azotobacter vinelandii?

Answer 123

It fixes atmospheric nitrogen to ammonia through the use of the nitrogenase enzyme.

Question 124

Azotobacter vinelandii is an obligate aerobe but the nitrogenase enzyme it uses is sensitive to oxygen. How does it overcome this?

Answer 124

The internal oxygen is removed by oxidase activity of cytochrome bc1.

Question 125

What can the bd mutant of Azotobacter not do?

Answer 125

Grow by nitrogen fixation from the air.

Question 126

What else can be driven by the proton motive force that doesn’t involve channels?

Answer 126

Flagella rotation.

Question 127

What does H2SO4 produced by sulphur oxidising bacteria allow?

Answer 127

Leaching of metals from ores.

Question 128

Why do bacteria that grow in a pH of 1-3 originally face a problem?

Answer 128

As H+ ions want to re enter the cell down the concentration gradient.

Question 129

How do bacteria that grow in a low pH ensure that the H+ ions move the correct way?

Answer 129

The pH difference is maintained by respiration/ synthase and K+ and other positive ions are imported to balance the charge meaning H+ is not.

Question 130

What type of circulation allows for alkaliphiles to live in a high pH?

Answer 130

Na+ circulation. These are pumped out of the cell by the respiratory chain and decarboxylases.

Question 131

Do facultative, fermentable or photolithotropic bacteria use ATP for CO2 reduction in addition to using it for biosynthesis and transport?

Answer 131

Photolithotrophic.

Question 132

Do facultative, fermentable or photolithotropic bacteria not use glycolysis to make ATP?

Answer 132

Photolithotrophic.

Question 133

Do facultative, fermentable or photolithotropic bacteria use the hydrogen electrochemical gradient for reducing power in addition to using it for motility and transport?

Answer 133

Facultative.

Question 134

Do facultative, fermentable or photolithotropic bacteria only use ATP for the hydrogen electrochemical gradient?

Answer 134

Fermentable.

Question 135

Do facultative, fermentable or photolithotropic bacteria use light, H2S and reducing power to generate a hydrogen electrochemical gradient?

Answer 135

Photolithotrophic.

Question 136

Do facultative, fermentable or photolithotropic bacteria use anaerobic redox and respiration as well as ATP to drive the hydrogen electrochemical gradient?

Answer 136

Facultative.

Question 137

Do facultative, fermentable or photolithotropic bacteria use only ATP to drive the hydrogen electrochemical gradient?

Answer 137

Fermentable.

Question 138

Do facultative, fermentable or photolithotropic bacteria use only the hydrogen electrochemical gradient to power ATP synthesis?

Answer 138

Photolithotrophic.