Exam 3

Question 1

Glycogen

Answer 1

Storage form of glucose. Highly branched structure.

Question 2

Glycogenesis

Answer 2

The formation of glycogen from sugar. It takes place in the liver and muscle.
Glucose (using hexokinase) Glucose-6-P Glucose-1-P -> UDP-Glucose->GLYCOGEN (in muscle)
Glucose (using glucokinase) Glucose-6-P Glucose-1-P -> UDP-Glucose->GLYCOGEN (in liver)
Glucokinase is an isozyme and has a high Km value.
Consumes the free energy of UTP.

Question 3

Glycogenolysis

Answer 3

The biochemical breakdown of glycogen to glucose.
Glycogen->Glucose-1-P->Glucose-6-P->GLUCOSE (liver)
Glycogen->Glucose-6-P->Glycolysis->ATP (Muscle)
Glycogen degradation

Question 4

Glycogenin

Answer 4

An enzyme converting glucose to glycogen. A glycogen primer that glycogen synthesis needs.

Question 5

Glucagon

Answer 5

Peptide hormone produced by alpha cells of the pancreas. Stimulates glycogen breakdown.

Question 6

Gluconeogenesis

Answer 6

Synthesis of glucose from non-carbohydrate precursors (amino acids, lactate, glycerol); occurs in liver; occurs in fasting state; the reverse of glycolysis.

Question 7

General overview to gluconeogenesis

Answer 7

RBC-lactate-pyruvate-oxaloacetate (glucogenic amino acids)-triose phosphate (DHP & GAP)-glucose.
Glucogenic amino acids are all acids except Leu and Lys. They are ketogenic.

Question 8

Step 1

Pyruvate is converted in 2 steps.

Answer 8

Pyruvate is an a-ketoacid.
Pyruvate carboxylase takes a bicarbonate ion + ATP and releases ADP + Pi.
Oxaloacetate is formed (an acetate group on carbon 4). This conversion requires energy.
Phosphoenolpyruvate carboxykinase takes GTP and releases GDP + CO2.
Phosphoenolpyruvate is a 3 carbon chain with a phosphate group on carbon 2.
This is an irreversible step.

Question 9

Pyruvate carboxylase uses ________ as a cofactor.

Answer 9

Biotin

Question 10

Biotin is covalently attached to a _______ residue in the enzyme.

Answer 10

Lys (Lysine)

Question 11

True/False
CO2 reacts with ATP such that some of the free energy released in the removal of ATP’s phosphoryl group is conserved in the formation of the “activated” compound carboxyphosphate.

Answer 11

True

Question 12

Like ATP, _________ releases a large amount of free energy when its phosphoryl group is liberated.

Answer 12

Carboxyphosphate

Question 13

In the pyruvate carboxylase mechanism, the enzyme abstracts a ______ from _______, forming a carbanion.

Answer 13

Proton; pyruvate

Question 14

In the pyruvate carboxylase mechanism, the carbanion attacks the ________ group attached to ______, generating oxaloacetate.

Answer 14

Carboxyl; biotin

Question 15

Step 2

Enolase

Answer 15

Converts (2) PHOSPHOENOLPYRUVATE (alkene) + H2O to (2) 2-PHOSPHOGLYCERATE
Reversible reaction
Enolase catalyze a dehydration reaction

Question 16

Step 3

Phosphoglycerate mutase

Answer 16

Converts (2) 2-PHOSPHOGLYCERATE to (2) 3-PHOSPHOGLYCERATE
Reversible reaction.
Isomerase reaction

Question 17

Step 4

Phosphoglycerate kinase

Answer 17

Converts (2) 3-PHOSPHOGLYCERATE + ATP to (2) 1,3-BISPHOSPHOGLYCERATE + ADP
Reversible reaction
Transferase reaction
1,3-bisphosphoglycerate is a high energy intermediate

Question 18

Step 5

Glyceraldehyde-3-phosphate dehydrogenase

Answer 18

Converts (2) 1,3-BISPHOSPHOGLYCERATE + NADH plus H+ to GLYCERALDEHYDE-3-PHOSPHATE plus NAD+
Reversible reaction.
NADH plus H+ is oxidized to NAD+; phosphate group does not come from ATP.
Reaction is both a phosphorylation and an oxidation-reduction.
1,3-bisphosphoglycerate is a high energy intermediate.
Covalent catalysis (direct bond between enzyme and substrate)

Question 19

Step 6

Triose phosphate isomerase

Answer 19

Converts glyceraldehyde-3-phosphate to Dihydroxyacetone phosphate
Isomerization reaction (moves a group or a double bond within the same molecule)
Reversible reaction
Can convert back and forth

Question 20

Step 7

Aldolase

Answer 20

Converts GAP and DHP to fructose-1,6-bisphosphate
Reversible reaction
Aldolase is a lyase (cleaves to make the 2 molecules)
GAP and DHP have 3 carbons each. After condensation it makes 1, 6 carbon chain.

Question 21

Step 8

Fructose-1,6-bisphosphatase

Answer 21

Converts Fructose-1,6-bisphospate and H2O to fructose-6-phosphate and Pi.
Irreversible step.
Removes the phosphate group on carbon 1.
#1 regulated step.

Question 22

Step 9

Phosphoglucose isomerase

Answer 22

Converts fructose-6-phosphate to glucose-6-phosphate.

Reversible step

Question 23

Step 10

Glucose-6-phosphatase

Answer 23

Converts glucose-6-phosphate and H2O to glucose and Pi.

Irreversible step

Question 24

What would happen if glycolysis and gluconeogenesis occurred simultaneously?

Answer 24

There would be a net consumption of ATP. Goal of producing ATP would be futile. Instead, glycolysis and gluconeogenesis are regulated based on the cell’s needs.

Question 25

Fructose-2,6-bisphosphate increases/decreases the activity of __________ and increases/decreases the activity of ____________.

Answer 25

Increases; phosphofructokinase; decreases; fructose-1,6-bisphosphatase

Question 26

Precursor molecules for gluconeogenesis

Answer 26

Amino acids, lactate and glycerol. No carbohydrates

Question 27

What enzyme is used to convert glucose to glucose-6-phosphate in glycogenesis in the liver?

Answer 27

Glucokinase; it is an isozyme; only happens in the liver. This enzyme takes longer to get saturated by the substrate (less efficient for binding to substrate).

Question 28

Phosphoglucomutase

Answer 28

Converts glucose-6-phosphate to glucose-1-phosphate.
Reversible step.
Isomerase
Moves phosphate group from carbon 6 to carbon 1.

Question 29

UDP-glucose pyrophosphorylase

Answer 29

Converts glucose-1-phosphate to UDP-glucose and hydrolyzes the 2 phosphate groups (pyrophosphate) as PPi. Inorganic pyrophosphatase converts it to 2 Pi.
UDP-glucose is the activated form of glucose.
The hydrolysis of inorganic pyrophosphate drives the reaction; dG=-19.2 KJ*mol-1 (exergonic).

Question 30

Glycogen synthase

Answer 30

Converts UDP-glucose and glycogen to UDP + Glycogen (n+1 residues) which is an alpha-1,4-glycosidic bond. First molecule on the left, carbon 1 determines alpha or beta.
Glycogen used is an existing strand.

Question 31

What is transglycosylase?

Answer 31

It’s a branching enzyme that cleaves off the seven residue segment and reattaches it to the glucose C6-OH to create an alpha-1,6 branch point.
Seven-residue segment is a 7-glucose strand.

Question 32

How are linear chains in glycogen broken down?

Answer 32

Via phosphorolysis with the enzyme glycogen phosphorylase; makes glucose-1-P

Question 33

How are branched chains in glycogen broken down?

Answer 33

Via hydrolysis with the enzyme glucose-6-phosphatase; yields glucose

Question 34

Which step does glucose-6-phosphate enter in glycolysis for glycogenolysis in the muscle?

Answer 34

At step 2; it will be an inhibitor.
One less ATP is consumed in the muscle compared to glucose from the bloodstream;the net gain of ATP is higher (3 ATP instead of 2)

Question 35

What type of receptor does glucagon use?

Answer 35

G-protein receptor.

Question 36

What type of bonds are found in the active form of insulin?

Answer 36

Disulfide bonds; insulin is a zymogen and must be cleaved to be active.

Question 37

How does insulin stimulate glycogen synthesis?

Answer 37

A ligand binds to the receptor tyrosine kinase, it is transported through the membrane where it goes through autophosphorylation (phosphorylation of the kinase by itself). ATP -> ADP (Kinase 1 goes from an inactive state to active). The active kinase 1 is phosphorylated by ATP kinase 2 goes from inactive to active. It then goes through changes in metabolic activity and gene expression.

Question 38

How does glucagon stimulate glycogen breakdown?

Answer 38

A ligand binds to a G-protein receptor, the G-protein goes from inactive to active and is now a substrate that is bound to an enzyme. The substrate is broken down to a second messenger, cAMP. 3 alpha/beta subunits are target proteins.

Question 39

Explain regulation of glycogen synthesis

Answer 39

Glucagon leads to phosphorylation of glycogen synthase. If glucagon is being released and phosphorylating glycogen synthase, you don’t want to make glycogen.

Question 40

In the presence of glucagon, is glycogenolysis active or inactive?

Answer 40

Active. During fasting or starvation, glucagon is released to make glucose, so there is no need to make glycogen.

Question 41

What are the 3 pathways of glucose-6-P in the muscle?

Answer 41

1) NADPH -> reductive biosynthesis (anabolic pathway)
2) Fructose-6-phosphate, Glyceraldehyde-3-phosphate -> glycolysis/gluconeogenesis
3) Ribose-5-phosphate -> nucleic acid synthesis

Question 42

What is the oxidative reactions of the pentose phosphate pathway to produce NADPH?

Answer 42

1) Glucose-6-phosphate is reduced by the enzyme glucose-6-phosphate dehydrogenase; this step is an oxidative reduction (removing hydrogen) where NADPH plus H+ are released. 2) 6-phosphoglucose-delta-lactone; this molecule contains a cyclized ester at carbon 1, where the bond will be broken during hydrolysis. 3) 6-phosphogluconate + NADPH + H+ is formed from a cyclical 6 carbon to a linear 6 carbon chain.

Question 43

Explain the third pathway of the pentose phosphate pathway that involves oxidative decarboxylation.

Answer 43

6-phosphogluconate is a 6 carbon linear chain with a carbonyl group on the first carbon. The enzyme 6-phosphogluconate dehydrogenase takes NADP+ and oxidizes it to then release NADPH + CO2. Ribulose-5-phosphate is generated with a ketone on carbon 2. This will be reductive biosynthesis, an irreversible reaction.

Question 44

Ribose-5-phosphate is a precursor of what?

Answer 44

The ribose unit of nucleotides.

Question 45

Describe the isomerazation of ribulose-5-phosphate to ribose-5-phosphate.

Answer 45

The ketose, ribulose-6-phosphate, is converted with enzyme, ribulose-5-phosphate isomerase, to make the aldose, ribose-5-phosphate. The aldehyde group, O=C-H, is located on carbon 1 of the chain. This step is reversible.

Question 46

What is the non-oxidative reaction of the pentose phosphate pathway?

Answer 46

It is a set of interconversions that produce 3,4,5,6 and 7 carbon sugars. The non-oxidative reactions are reversible. It either becomes a nucleic acid synthesis or glycolysis/gluconeogenesis.

Question 47

Net reaction for pentose phosphate pathway

Answer 47

Ribose derivative is produced
2 NADPH molecules are formed
Pathway is active in rapidly dividing cells

Question 48

What are other names for the citric acid cycle?

Answer 48

Kreb’s cycle and Tricarboxylic acid cycle (TCA)

This occurs in the mitochondria matrix

Question 49

What is the oxidized and reduced form of nicotinamide adenine dinucleotide?

Answer 49

Oxidized- NAD+

Reduced- NADH

Question 50

What is the oxidized and reduced form of nicotinamide adenine dinucleotide phosphate?

Answer 50

Oxidized- NADP+

Reduced- NADPH

Question 51

What is the oxidized and reduced form of flavin adenine dinucleotide?

Answer 51

Oxidized- FAD

Reduced- FADH2

Question 52

What is the oxidized and reduced form of flavin mononucleotide?

Answer 52

Oxidized- FMN

Reduced- FMNH2

Question 53

What is the oxidized and reduced form of ubiquinone/ubiquinol?

Answer 53

Oxidized- Q

Reduced- QH2

Question 54

What is the pyruvate dehydrogenase reaction?

Answer 54

Pyruvate + CoA + NAD+ -> Acetyl-CoA + CO2 + NADH + H+

Pyruvate dehydrogenase is a multisubunit enzyme.

Question 55

What are the cofactors of the pyruvate dehydrogenase reaction?

Answer 55

Thiamine pyrophosphate (TPP)
Lipoamide
Flavin adenine dinucleotide (FAD)
all are bound to the three subunits 
(CoA and NAD+ are also cofactors)

Question 56

What is happening in the E1 phase of pyruvate dehydrogenase reaction?

Answer 56

Pyruvate goes through decarboxylation, which is removing the carboxylate group on pyruvate.

Question 57

What is happening in the E2 step of pyruvate dehydrogenase reaction?

Answer 57

The acetyl group is transferred to thiamine pyrophosphate and then to lipoamide.

Question 58

What is happening in the E3 step of pyruvate dehydrogenase reaction?

Answer 58

The acetyl group is transferred from the E2 subunit to CoA to become Acetyl-CoA.
FAD gets reduced to FADH2, and NAD+ is reduced to NADH + H+.
Acetyl-CoA then moves on to the Kreb’s cycle.

Question 59

How is pyruvate dehydrogenase regulated?

Answer 59

By product inhibition (NADH and Aceytl-CoA) And phosphorylation or dephosphorylation

Question 60

In the regulation of pyruvate dehydrogenase, what are the allosteric inhibitors (low energy)?

Answer 60

CoA, pyruvate, NAD+

These inhibitors will slow down the process of making acetyl-CoA when there are too many in the system.

Question 61

In the regulation of pyruvate dehydrogenase, what are the allosteric activators ( high energy)?

Answer 61

ATP, Acetyl-CoA, NADH

These activators will cause pyruvate to produce more acetyl-CoA.

Question 62

In the regulation of pyruvate dehydrogenase, what does calcium do?

Answer 62

Calcium, which comes from the muscle, can activate protein phosphatase and pyruvate dehydrogenase. The phosphatase will remove a phosphate group and this is what engages the Krebs cycle. Pyruvate dehydrogenase is then active by being dephosphorylated.

Question 63

What is the TCA cycle overview?

Answer 63

Eight reactions; acetyl-CoA + oxaloacetate; two carbon dioxide lost, oxaloacetate regenerated; 3 NADH, 1 QH2, 1 GTP produced; regulation at three steps

Question 64

The citric acid cycle is an energy generating cycle. How many ATPs does 1 glucose make?

Answer 64

In glycolysis it yields 7 ATP; in the conversion of pyruvate to acetyl-CoA, it yields 5 ATP; and in the TCA cycle it yields 20 ATP; for a total of 32 ATP.

Question 65

What is an example of product inhibition?

Answer 65

Citrate can inhibit its own enzyme, citrate synthase.

Question 66

When NADH or ATP inhibit Isocitrate or alpha ketoglutarate, what can activate the enzyme?

Answer 66

ADP and Ca2+ can activate isocitrate dehydrogenase.

Ca2+ can activate a-ketoglutarate dehydrogenase.

Question 67

Which intermediates flow in the citric acid cycle?

Answer 67

Anaplerotic reactions:
Amino acids (to fumarate, succinyl-CoA, a-ketoglutarate and oxaloacetate)
Odd chain fatty acids (to succinyl-CoA)
Pyruvate (to oxaloacetate)

Question 68

Which intermediates flow out of the citric acid cycle?

Answer 68

Glucose (from oxaloacetate)
Fatty acids and cholesterol (from citrate)
Heme (from succinyl-CoA)

Question 69

Describe an example of an amino acid formation from the citric acid cycle intermediate

Answer 69

Alpha ketoglutarate and NH4+ (an amine group) is converted to glutamate + H2O by the enzyme glutamate dehydrogenase. NADH + H+ is oxidized to NAD+. Glutamate will have two carboxylic acid’s at carbon 1 and 5, and NH3+ on carbon 4.

Question 70

How can citrate and pyruvate cross the mitochondrial membrane?

Answer 70

Via specific transport proteins. The citrate crosses the inner mitochondrial membrane from the matrix to the cytosol; the pyruvate crosses from the cytosol to the matrix.

Question 71

Give an example of a half reaction of ubiquinone

Answer 71

Q + 2H+ + 2e- QH2

Question 72

What is reduction potential?

Answer 72

Reduction potential indicates a substance’s tendency to accept electrons. The greater the reduction potential, the greater the tendency of a substance to accept electrons, and be reduced.

Question 73

What is the reducing equivalent in the electron transport chain of NADH?

Answer 73

NAD+ + H+ + 2e-

Question 74

What is the reducing equivalent in the electron transport chain of FADH2?

Answer 74

FAD + 2H+ + 2e-

Question 75

What is the reducing equivalent in the electron transport chain of QH2?

Answer 75

Q + 2H+ + 2e-

Question 76

What is the reducing equivalent in the electron transport chain of Cytochrome (FE2+)?

Answer 76

Cytochrome (Fe3+) + e-

It has a prosthetic group (Heme)

Question 77

Where does the electron transport take place?

Answer 77

In the mitochondrion.
The outer membrane is porous.
The inner membrane is impermeable, that’s where the electron transport chain runs through.
The inter-membrane space is cytosol.
In the matrix, the citric acid cycle and fatty acid oxidation takes place. Oxidative phosphorylation occurs as electrons flow through the respiratory chain from reduced cofactors to oxygen; the formation of ATP.

Question 78

What transports reducing agents across the inner mitochondrial membrane?

Answer 78

The malate-aspartate shuttle.
Aspartate is in the matrix and is transported by the aspartate transporter protein to the cytosol. Aspartate -> Oxaloacetate where NADH + H+ is oxidized by cytosolic malate dehydrogenase to Malate. Malate is transported from the cytosol to the matrix via the malate transporter protein. NAD+ is reduced to NADH + H+ with the enzyme matrix malate dehydrogenase to form Oxaloacetate, which is converted to Aspartate.
NADH is generated through intermediaries that are reduced within the matrix.

Question 79

Which complexes mediate the oxidation-reduction reactions in the electron transport?

Answer 79

Complex I, II, III.

The free energy powers ATP synthesis. All 3 complexes are highly exergonic.

Question 80

What is another name for Complex I?

Answer 80

NADH dehydrogenase

Question 81

What does Complex I do?

Answer 81

It transfers electrons from NADH to Q. The electrons transfer from NADH to FMN, then from FMNH2 to Q (Q is lipid soluble).
The electrons come from the matrix not NADH.

Question 82

What else is happening while the electrons are being transferred from NADH to ubiquinone (Q)?

Answer 82

Complex I transfers 4 protons (H+) from the matrix to the intermembrane space.
2e- -> 4 H+

Question 83

What is another name for Complex II?

Answer 83

Succinate dehydrogenase
In this step, there is no flow of H+.
Electrons from FADH2 directly enter Complex II.
Complex I & II can produce QH2.

Question 84

How else is Complex III referred to?

Answer 84

Cytochrome bc1
Cytochromes are proteins with the heme prosthetic group.
The heme in cytochrome c undergoes reversible one-electron transfer.
In heme b, the central iron atom is either oxidized (Fe3+) or reduced (Fe2+)

Question 85

Where does Complex III transfers the electrons?

Answer 85

From ubiquinol to cytochrome c.

2 e- from QH2 reduce two molecules of cytochrome c.

Question 86

How many protons are pumped into the intermembrane space in Complex III?

Answer 86

4 protons (H+)
2 from QH2 in the first round and 2 from QH2 in the second round.

Question 87

What is another name for Complex IV?

Answer 87

Cytochrome a + a3
Complex IV oxidizes cytochrome c and reduced O2.
It also generates H2O.

Question 88

How many electrons and protons are donated or translocated in Complex IV?

Answer 88

For every 2 e- donated by cytochrome c, 2 H+ are translocated to the intermembrane space.

Question 89

How many protons are generated in Complex I-IV?

Answer 89

10 H+ total
Complex I = 4 H+
Complex III = 4 H+
Complex IV = 2 H+

Question 90

What is the chemiosmotic theory?

Answer 90

The imbalance of protons represents a source of free energy, also called a protonmotive force, that can drive the activity of an ATP synthase.

Question 91

What is the protein that taps the electrochemical proton gradient to phosphorylate ADP?

Answer 91

ATP synthase (Complex V)

Question 92

In Complex V, what is F1 and F0 responsible for?

Answer 92

F1 is responsible for synthesis of ATP

F0 is responsible for the transport of H+ to the matrix side.

Question 93

Describe the different parts of the ATP Synthase

Answer 93

a is located in the intermembrane space and does not move
b is the peripheral stalk located in the matrix
c is the ring that moves (8 total)
gamma, epsilon and delta are the central stalk and gamma will rotate
alpha and beta are the subunits; there are 3 alpha and 3 beta that alternate their order

Question 94

Explain how ATP synthase works

Answer 94

ATP synthase rotates as it translocates protons.
H+ binds to a c subunit.
The c subunit moves away from the a subunit.
As a new c subunit reaches the a subunit, a proton is released.
ONE ROTATION OF THE RING TRANSLOCATES 8 PROTONS.

Question 95

What is the ATP translocase protein?

Answer 95

A transport system used to move ATP from the matrix to the cytosol.
It moves ATP from the matrix to the cytosol and ADP from the cytosol to the matrix.
A symport protein permits simultaneous movement of Pi and H+.

Question 96

What are the three conformational changes the beta subunit undergo?

Answer 96

The beta-subunit takes ADP + Pi and releases ATP.
Loose: bind ADP and Pi
Tight: form ATP
Open: release ATP

Question 97

What is the conversion between NADH & ATP and QH2 & ATP?

Answer 97

1 NADH = 2.5 ATP

1 QH2 = 1.5 ATP

Question 98

What are the four unique enzymes found in gluconeogenesis and not in glycolysis?

Answer 98

Pyruvate carboxylase
Phosphoenolpyruvate carboxykinase
Fructose bisphosphatase
Glucose-6-phosphatase