Muscle Physiology Midterm 2

Question 1

Why is it important to study metabolism in a course on muscle?

Answer 1

To perform mechanical work (muscle contraction) during exercise, energy is required. Skeletal muscle is capable of enormous increases in force and velocity and consequently the rate of ATP utilization can change dramatically. Metabolic demand can increase more than 100 fold in a very short time

Question 2

What is the problem with metabolic demand in muscles increasing over 100 fold in a very short time?

Answer 2

The concentration of ATP is low and can only sustain maximal muscle contraction for about 2-3 seconds. Approx 90-100 lbs. of ATP would be need to perform all metabolic reactions during one day of hard labour. Therefore, we need not only a lot of ATP daily but we need to produce ATP at various rates depending on work/exercise intensity. Muscle must be equipped with metabolic mechanisms to meet varaible energy requirements to maintain work

Question 3

What is bioenergetics?

Answer 3

The study of how energy is generated in the cell; refers to the metabolic process of converting foodstuff (substrate) into ATP

Question 4

Three energy systems in muscle?

Answer 4

High energy phosphate transfer (transfer of a phosphate group to ADP to regenerate ATP). Glycolysis (degradation of glucose or glycogen (glycogenolysis). Oxidative phosphorylation (complete combustion of fats or carbohydrates)

Question 5

Anaerobic pathways?

Answer 5

Do NOT involve oxygen; HEPT and glycolysis

Question 6

Aerobic pathways?

Answer 6

Requires oxygen; oxidative phosphorylation

Question 7

Ammonium?

Answer 7

NH4+

Question 8

Ammonia?

Answer 8

NH3+

Question 9

How many high energy bonds does an ATP have?

Answer 9

2

Question 10

How many high energy bonds does an ADP have?

Answer 10

1

Question 11

How many high energy bonds does and AMP have?

Answer 11

NONE, but can be broken down into other things

Question 12

If a reaction is closer to equilibrium, how much energy is produced?

Answer 12

Not very much

Question 13

What happens to the the energy release as the reaction moves further from equilibrium?

Answer 13

More energy is released

Question 14

Is there more ATP or PCr stored in muscle?

Answer 14

More Pcr (3-4x more)

Question 15

ATPase reaction?

Answer 15

ATP + H2O —> ADP + Pi + H+ + Energy

Question 16

How many kcal/mol ATP?

Answer 16

7.3

Question 17

Creatine kinase reaction?

Answer 17

ADP + PCr + H+ –> ATP + Cr

Question 18

Adenylate kinase reaction?

Answer 18

ADP + ADP –> ATP + AMP

Question 19

AMP deaminase reaction?

Answer 19

AMP –> IMP + NH3

Question 20

Does PCr have a high or low capacity for producing ATP?

Answer 20

LOW CAPACITY because stores are limited in the muscle

Question 21

Does an ATPase or creatine kinase have a higher power for producing ATP?

Answer 21

Creatine kinase activity is higher that ATPase activity in the cell…replenishes ATP rapidly as it is hydrolyzed. The reaction is near equilibrium, therefore, all you need is a very small decrease in [ATP] to start the reaction going to the right.

Question 22

How does creatine kinase help buffer pH?

Answer 22

Uses an H+ in its reaction

Question 23

Why is the creatine kinase reaction so rapid?

Answer 23

The reaction is near equilibrium, therefore, as you need is a very small decrease in [ATP] to start the reaction going to the right (making ATP and Cr)

Question 24

How many isoforms of creatine kinase are there?

Answer 24

2…mitochondrial and cystolic

Question 25

What does mitochondrial creatine kinase do?

Answer 25

Adds a phosphate from ATP to creatine, resulting in ADP and Creatine Phosphate. Creatine phosphate is shuttled into the cytosol.

Question 26

What does cystolic creatine kinase do?

Answer 26

Removes phosphate from creatine phosphate and adds it to ADP to make ATP and Creatine. Creatine is shuttled back into mitochondria

Question 27

Where can Creatine be obtained from?

Answer 27

Made in the liver or obtained from meat/supplementation

Question 28

What does creatine supplementation do?

Answer 28

Increases both free CR and PCr stores

Question 29

Creatine supplementation has shown increases in what types of activities?

Answer 29

Short duration (less than 30 seconds), high intensity exercise (mainly cycling) Little positive effects on running and swimming (water retention from kindey metabolizing it); these activities typically use glycolysis and oxidative phosphorylation because they are longer duration

Question 30

What provides the fastest source of ATP to ATPases in muscle?

Answer 30

Stored ATP (no reaction involved. PCr is fast, but there is 1 reaction, so not as fast)

Question 31

Why is the adenylate kinase reaction important during very intense exercise?

Answer 31

1. Increases the [ATP] (ATP hydrolysis is very rapid, so the [ADP] increases rapidly) 2. Helps keep [ADP] low to maintain high free energy for the hydrolysis of ATP and to minimize fatigue 3. Increase the [AMP] which is useful for activating other metabolic pathways (glycolysis and oxidative phosphorylation)

Question 32

Why is it important to keep [ADP] low?

Answer 32

[ADP] influences the rate of ATP hydroylsis and the amount of energy that can be extracted from an ATP, in order to keep ATP hydrolysis moving quickly and efficiently, the [ADP] must be kept low

Question 33

How does the increase of [ADP] cause fatigue?

Answer 33

Increased [ADP] slows the rate of ADP release from the myosin head, which causes a decrease in the rate of the power stroke, therefore decreasing force output

Question 34

How does the increase in [AMP] from the adenylate kinase reaction stimulate other metabolic pathways?

Answer 34

An increase in [AMP] tells the cell that the [ATP] is decreasing and the only way the cell is making ATP is by using ADP. The [AMP] increase tells the cell it needs another way to make ATP, so it increases activation of glycolysis and oxidative phosphorylation

Question 35

Why is the AMP demaminase reaction important during very intense exercise?

Answer 35

Helps to keep the [AMP] low, which will keep the adenylate kinase reaction moving to the right, therefore, ultimately prevents [ADP] buildup (maintains high [ATP]/[ADP])

Question 36

What activates AMP deaminase?

Answer 36

Low pH …very low activity at rest

Question 37

Why is the reduction of the ammonia molecule to ammonium ion important in the AMP deaminase reaction?

Answer 37

Effectively removes H+ to help buffer pH, and the ammonium ion also known to stimulate glycolysis

Question 38

How many reactions in anaerobic glycolysis?

Answer 38

11 reactions

Question 39

Reaction of glycogen in anaerobic glycolysis?

Answer 39

Glycogen + 3 ADP + 3 Pi —> 2 lactate + 2 H+ + 3 ATP

Question 40

Reaction of glucose in anaerobic glycolysis?

Answer 40

Glucose + 2 ADP + 2 Pi —> 2 Lactate + 2 H+ + ATP

Question 41

What is the primary carbohydrate used in anaerobic glycolysis in skeletal muscle?

Answer 41

Glycogen

Question 42

What can glycolysis use as a source of fuel?

Answer 42

Only carbs

Question 43

2 sources of glucose in body?

Answer 43

Glucose found in blood and ECF, and glycogen stored in liver and muscle

Question 44

What is glycogen?

Answer 44

Molecule made from many glucose molecules joined together to form a compact, highly branched, spherical structure

Question 45

What enzyme makes glycogen?

Answer 45

Glycogen synthase

Question 46

Where are most glyocogen granules stored in the muscle cell?

Answer 46

Near the mitochondria…can be used to make ATP in aerobic respiration

Question 47

What can influence glycogen concentrations in the liver and muscle?

Answer 47

DIET!

Question 48

What type of power does anaerobic glycolysis have in producing ATP?

Answer 48

Medium power…a large amount of ATP can be generated per unit time, because of the high activity of enzymes in the pathway

Question 49

Why can’t anaerobic glycolysis be used for more than 3-5 hours?

Answer 49

Capacity of the system is limited by the availability of substrates (i.e. muscle glycogen) and buildup of lactic acid (H+ causes acidosis)

Question 50

What type of capacity does anaerobic glycolysis have for producing ATP?

Answer 50

Moderate capacity…lactic acidosis and/or glycogen depletion will ultimately limit work intensity (fatigue)

Question 51

2 phases of anaerobic glycolysis?

Answer 51

Energy investment stage and energy generation phase

Question 52

How many ATP are required in the inergy investment stage of glycolysis?

Answer 52

Up to 2 ATP

Question 53

What does the energy generation phase produce in glycolysis?

Answer 53

ATP, NADH, and pyruvate or lactate

Question 54

What enzyme is used to add a phosphate to glycogen?

Answer 54

Phosphorylase

Question 55

What enzyme adds a phosphate from ATP to glucose to form Glucose-6-Phosphate?

Answer 55

Hexokinase

Question 56

What enzyme adds a phosphate to fructose-6-phosphate to make fructose-1,3-bisphosphate?

Answer 56

Phosphofructokinase

Question 57

How many ATP are invested in the energy investment stage of glycolysis for a glucose molecule?

Answer 57

2 (1 to make G-6-P via hexokinase and another to make F-1,6-BP via PFK)

Question 58

How many ATP are invested in the energy investment stage of glycolysis for a glycogen molecule?

Answer 58

1 (to make F-1,6-BP via PFK)

Question 59

How many isoforms of creatine kinase are there?

Answer 59

2…mitochondrial and cystolic

Question 60

What does mitochondrial creatine kinase do?

Answer 60

Adds a phosphate from ATP to creatine, resulting in ADP and Creatine Phosphate. Creatine phosphate is shuttled into the cytosol.

Question 61

What does cystolic creatine kinase do?

Answer 61

Removes phosphate from creatine phosphate and adds it to ADP to make ATP and Creatine. Creatine is shuttled back into mitochondria

Question 62

Where can Creatine be obtained from?

Answer 62

Made in the liver or obtained from meat/supplementation

Question 63

What does creatine supplementation do?

Answer 63

Increases both free CR and PCr stores

Question 64

Creatine supplementation has shown increases in what types of activities?

Answer 64

Short duration (less than 30 seconds), high intensity exercise (mainly cycling) Little positive effects on running and swimming (water retention from kindey metabolizing it); these activities typically use glycolysis and oxidative phosphorylation because they are longer duration

Question 65

Mechanisms of creatine supplementation?

Answer 65

Delay PCr depletion, increased ATP turnover (make ATP quicker because there is more creatine around), decreasing reliance on glycolysis (lactate formation), and decreases recovery time

Question 66

What provides the fastest source of ATP to ATPases in muscle?

Answer 66

Stored ATP (no reaction involved. PCr is fast, but there is 1 reaction, so not as fast)

Question 67

Why is the adenylate kinase reaction important during very intense exercise?

Answer 67

1. Increases the [ATP] (ATP hydrolysis is very rapid, so the [ADP] increases rapidly) 2. Helps keep [ADP] low to maintain high free energy for the hydrolysis of ATP and to minimize fatigue 3. Increase the [AMP] which is useful for activating other metabolic pathways (glycolysis and oxidative phosphorylation)

Question 68

Why is it important to keep [ADP] low?

Answer 68

[ADP] influences the rate of ATP hydroylsis and the amount of energy that can be extracted from an ATP, in order to keep ATP hydrolysis moving quickly and efficiently, the [ADP] must be kept low

Question 69

How does the increase of [ADP] cause fatigue?

Answer 69

Increased [ADP] slows the rate of ADP release from the myosin head, which causes a decrease in the rate of the power stroke, therefore decreasing force output

Question 70

How does the increase in [AMP] from the adenylate kinase reaction stimulate other metabolic pathways?

Answer 70

An increase in [AMP] tells the cell that the [ATP] is decreasing and the only way the cell is making ATP is by using ADP. The [AMP] increase tells the cell it needs another way to make ATP, so it increases activation of glycolysis and oxidative phosphorylation

Question 71

Why is the AMP demaminase reaction important during very intense exercise?

Answer 71

Helps to keep the [AMP] low, which will keep the adenylate kinase reaction moving to the right, therefore, ultimately prevents [ADP] buildup (maintains high [ATP]/[ADP])

Question 72

What activates AMP deaminase?

Answer 72

Low pH …very low activity at rest

Question 73

Why is the reduction of the ammonia molecule to ammonium ion important in the AMP deaminase reaction?

Answer 73

Effectively removes H+ to help buffer pH, and the ammonium ion also known to stimulate glycolysis

Question 74

How many reactions in anaerobic glycolysis?

Answer 74

11 reactions

Question 75

Reaction of glycogen in anaerobic glycolysis?

Answer 75

Glycogen + 3 ADP + 3 Pi —> 2 lactate + 2 H+ + 3 ATP

Question 76

Reaction of glucose in anaerobic glycolysis?

Answer 76

Glucose + 2 ADP + 2 Pi —> 2 Lactate + 2 H+ + ATP

Question 77

What is the primary carbohydrate used in anaerobic glycolysis in skeletal muscle?

Answer 77

Glycogen

Question 78

What can glycolysis use as a source of fuel?

Answer 78

Only carbs

Question 79

2 sources of glucose in body?

Answer 79

Glucose found in blood and ECF, and glycogen stored in liver and muscle

Question 80

What is glycogen?

Answer 80

Molecule made from many glucose molecules joined together to form a compact, highly branched, spherical structure

Question 81

What enzyme makes glycogen?

Answer 81

Glycogen synthase

Question 82

Where are most glyocogen granules stored in the muscle cell?

Answer 82

Near the mitochondria…can be used to make ATP in aerobic respiration

Question 83

What can influence glycogen concentrations in the liver and muscle?

Answer 83

DIET!

Question 84

What type of power does anaerobic glycolysis have in producing ATP?

Answer 84

Medium power…a large amount of ATP can be generated per unit time, because of the high activity of enzymes in the pathway

Question 85

Why can’t anaerobic glycolysis be used for more than 3-5 hours?

Answer 85

Capacity of the system is limited by the availability of substrates (i.e. muscle glycogen) and buildup of lactic acid (H+ causes acidosis)

Question 86

What type of capacity does anaerobic glycolysis have for producing ATP?

Answer 86

Moderate capacity…lactic acidosis and/or glycogen depletion will ultimately limit work intensity (fatigue)

Question 87

2 phases of anaerobic glycolysis?

Answer 87

Energy investment stage and energy generation phase

Question 88

How many ATP are required in the inergy investment stage of glycolysis?

Answer 88

Up to 2 ATP

Question 89

What does the energy generation phase produce in glycolysis?

Answer 89

ATP, NADH, and pyruvate or lactate

Question 90

What enzyme is used to add a phosphate to glycogen?

Answer 90

Phosphorylase

Question 91

What enzyme adds a phosphate from ATP to glucose to form Glucose-6-Phosphate?

Answer 91

Hexokinase

Question 92

What enzyme adds a phosphate to fructose-6-phosphate to make fructose-1,3-bisphosphate?

Answer 92

Phosphofructokinase

Question 93

How many ATP are invested in the energy investment stage of glycolysis for a glucose molecule?

Answer 93

2 (1 to make G-6-P via hexokinase and another to make F-1,6-BP via PFK)

Question 94

How many ATP are invested in the energy investment stage of glycolysis for a glycogen molecule?

Answer 94

1 (to make F-1,6-BP via PFK)

Question 95

Why is the creatine kinase reaction so rapid?

Answer 95

The reaction is near equilibrium, therefore, as you need is a very small decrease in [ATP] to start the reaction going to the right (making ATP and Cr)

Question 96

How many isoforms of creatine kinase are there?

Answer 96

2…mitochondrial and cystolic

Question 97

What does mitochondrial creatine kinase do?

Answer 97

Adds a phosphate from ATP to creatine, resulting in ADP and Creatine Phosphate. Creatine phosphate is shuttled into the cytosol.

Question 98

What does cystolic creatine kinase do?

Answer 98

Removes phosphate from creatine phosphate and adds it to ADP to make ATP and Creatine. Creatine is shuttled back into mitochondria

Question 99

Where can Creatine be obtained from?

Answer 99

Made in the liver or obtained from meat/supplementation

Question 100

What does creatine supplementation do?

Answer 100

Increases both free CR and PCr stores

Question 101

Creatine supplementation has shown increases in what types of activities?

Answer 101

Short duration (less than 30 seconds), high intensity exercise (mainly cycling) Little positive effects on running and swimming (water retention from kindey metabolizing it); these activities typically use glycolysis and oxidative phosphorylation because they are longer duration

Question 102

Mechanisms of creatine supplementation?

Answer 102

Delay PCr depletion, increased ATP turnover (make ATP quicker because there is more creatine around), decreasing reliance on glycolysis (lactate formation), and decreases recovery time

Question 103

What provides the fastest source of ATP to ATPases in muscle?

Answer 103

Stored ATP (no reaction involved. PCr is fast, but there is 1 reaction, so not as fast)

Question 104

Why is the adenylate kinase reaction important during very intense exercise?

Answer 104

1. Increases the [ATP] (ATP hydrolysis is very rapid, so the [ADP] increases rapidly) 2. Helps keep [ADP] low to maintain high free energy for the hydrolysis of ATP and to minimize fatigue 3. Increase the [AMP] which is useful for activating other metabolic pathways (glycolysis and oxidative phosphorylation)

Question 105

Why is it important to keep [ADP] low?

Answer 105

[ADP] influences the rate of ATP hydroylsis and the amount of energy that can be extracted from an ATP, in order to keep ATP hydrolysis moving quickly and efficiently, the [ADP] must be kept low

Question 106

How does the increase of [ADP] cause fatigue?

Answer 106

Increased [ADP] slows the rate of ADP release from the myosin head, which causes a decrease in the rate of the power stroke, therefore decreasing force output

Question 107

How does the increase in [AMP] from the adenylate kinase reaction stimulate other metabolic pathways?

Answer 107

An increase in [AMP] tells the cell that the [ATP] is decreasing and the only way the cell is making ATP is by using ADP. The [AMP] increase tells the cell it needs another way to make ATP, so it increases activation of glycolysis and oxidative phosphorylation

Question 108

Why is the AMP demaminase reaction important during very intense exercise?

Answer 108

Helps to keep the [AMP] low, which will keep the adenylate kinase reaction moving to the right, therefore, ultimately prevents [ADP] buildup (maintains high [ATP]/[ADP])

Question 109

What activates AMP deaminase?

Answer 109

Low pH …very low activity at rest

Question 110

Why is the reduction of the ammonia molecule to ammonium ion important in the AMP deaminase reaction?

Answer 110

Effectively removes H+ to help buffer pH, and the ammonium ion also known to stimulate glycolysis

Question 111

How many reactions in anaerobic glycolysis?

Answer 111

11 reactions

Question 112

Reaction of glycogen in anaerobic glycolysis?

Answer 112

Glycogen + 3 ADP + 3 Pi —> 2 lactate + 2 H+ + 3 ATP

Question 113

Reaction of glucose in anaerobic glycolysis?

Answer 113

Glucose + 2 ADP + 2 Pi —> 2 Lactate + 2 H+ + ATP

Question 114

What is the primary carbohydrate used in anaerobic glycolysis in skeletal muscle?

Answer 114

Glycogen

Question 115

What can glycolysis use as a source of fuel?

Answer 115

Only carbs

Question 116

2 sources of glucose in body?

Answer 116

Glucose found in blood and ECF, and glycogen stored in liver and muscle

Question 117

What is glycogen?

Answer 117

Molecule made from many glucose molecules joined together to form a compact, highly branched, spherical structure

Question 118

What enzyme makes glycogen?

Answer 118

Glycogen synthase

Question 119

Where are most glyocogen granules stored in the muscle cell?

Answer 119

Near the mitochondria…can be used to make ATP in aerobic respiration

Question 120

What can influence glycogen concentrations in the liver and muscle?

Answer 120

DIET!

Question 121

What type of power does anaerobic glycolysis have in producing ATP?

Answer 121

Medium power…a large amount of ATP can be generated per unit time, because of the high activity of enzymes in the pathway

Question 122

Why can’t anaerobic glycolysis be used for more than 3-5 hours?

Answer 122

Capacity of the system is limited by the availability of substrates (i.e. muscle glycogen) and buildup of lactic acid (H+ causes acidosis)

Question 123

What type of capacity does anaerobic glycolysis have for producing ATP?

Answer 123

Moderate capacity…lactic acidosis and/or glycogen depletion will ultimately limit work intensity (fatigue)

Question 124

2 phases of anaerobic glycolysis?

Answer 124

Energy investment stage and energy generation phase

Question 125

How many ATP are required in the inergy investment stage of glycolysis?

Answer 125

Up to 2 ATP

Question 126

What does the energy generation phase produce in glycolysis?

Answer 126

ATP, NADH, and pyruvate or lactate

Question 127

What enzyme is used to add a phosphate to glycogen?

Answer 127

Phosphorylase

Question 128

What enzyme adds a phosphate from ATP to glucose to form Glucose-6-Phosphate?

Answer 128

Hexokinase

Question 129

What enzyme adds a phosphate to fructose-6-phosphate to make fructose-1,3-bisphosphate?

Answer 129

Phosphofructokinase

Question 130

How many ATP are invested in the energy investment stage of glycolysis for a glucose molecule?

Answer 130

2 (1 to make G-6-P via hexokinase and another to make F-1,6-BP via PFK)

Question 131

How many ATP are invested in the energy investment stage of glycolysis for a glycogen molecule?

Answer 131

1 (to make F-1,6-BP via PFK)

Question 132

Why is the creatine kinase reaction so rapid?

Answer 132

The reaction is near equilibrium, therefore, as you need is a very small decrease in [ATP] to start the reaction going to the right (making ATP and Cr)

Question 133

How many isoforms of creatine kinase are there?

Answer 133

2…mitochondrial and cystolic

Question 134

What does mitochondrial creatine kinase do?

Answer 134

Adds a phosphate from ATP to creatine, resulting in ADP and Creatine Phosphate. Creatine phosphate is shuttled into the cytosol.

Question 135

What does cystolic creatine kinase do?

Answer 135

Removes phosphate from creatine phosphate and adds it to ADP to make ATP and Creatine. Creatine is shuttled back into mitochondria

Question 136

Where can Creatine be obtained from?

Answer 136

Made in the liver or obtained from meat/supplementation

Question 137

What does creatine supplementation do?

Answer 137

Increases both free CR and PCr stores

Question 138

Creatine supplementation has shown increases in what types of activities?

Answer 138

Short duration (less than 30 seconds), high intensity exercise (mainly cycling) Little positive effects on running and swimming (water retention from kindey metabolizing it); these activities typically use glycolysis and oxidative phosphorylation because they are longer duration

Question 139

Mechanisms of creatine supplementation?

Answer 139

Delay PCr depletion, increased ATP turnover (make ATP quicker because there is more creatine around), decreasing reliance on glycolysis (lactate formation), and decreases recovery time

Question 140

What provides the fastest source of ATP to ATPases in muscle?

Answer 140

Stored ATP (no reaction involved. PCr is fast, but there is 1 reaction, so not as fast)

Question 141

Why is the adenylate kinase reaction important during very intense exercise?

Answer 141

1. Increases the [ATP] (ATP hydrolysis is very rapid, so the [ADP] increases rapidly) 2. Helps keep [ADP] low to maintain high free energy for the hydrolysis of ATP and to minimize fatigue 3. Increase the [AMP] which is useful for activating other metabolic pathways (glycolysis and oxidative phosphorylation)

Question 142

Why is it important to keep [ADP] low?

Answer 142

[ADP] influences the rate of ATP hydroylsis and the amount of energy that can be extracted from an ATP, in order to keep ATP hydrolysis moving quickly and efficiently, the [ADP] must be kept low

Question 143

How does the increase of [ADP] cause fatigue?

Answer 143

Increased [ADP] slows the rate of ADP release from the myosin head, which causes a decrease in the rate of the power stroke, therefore decreasing force output

Question 144

How does the increase in [AMP] from the adenylate kinase reaction stimulate other metabolic pathways?

Answer 144

An increase in [AMP] tells the cell that the [ATP] is decreasing and the only way the cell is making ATP is by using ADP. The [AMP] increase tells the cell it needs another way to make ATP, so it increases activation of glycolysis and oxidative phosphorylation

Question 145

Why is the AMP demaminase reaction important during very intense exercise?

Answer 145

Helps to keep the [AMP] low, which will keep the adenylate kinase reaction moving to the right, therefore, ultimately prevents [ADP] buildup (maintains high [ATP]/[ADP])

Question 146

What activates AMP deaminase?

Answer 146

Low pH …very low activity at rest

Question 147

Why is the reduction of the ammonia molecule to ammonium ion important in the AMP deaminase reaction?

Answer 147

Effectively removes H+ to help buffer pH, and the ammonium ion also known to stimulate glycolysis

Question 148

How many reactions in anaerobic glycolysis?

Answer 148

11 reactions

Question 149

Reaction of glycogen in anaerobic glycolysis?

Answer 149

Glycogen + 3 ADP + 3 Pi —> 2 lactate + 2 H+ + 3 ATP

Question 150

Reaction of glucose in anaerobic glycolysis?

Answer 150

Glucose + 2 ADP + 2 Pi —> 2 Lactate + 2 H+ + ATP

Question 151

What is the primary carbohydrate used in anaerobic glycolysis in skeletal muscle?

Answer 151

Glycogen

Question 152

What can glycolysis use as a source of fuel?

Answer 152

Only carbs

Question 153

2 sources of glucose in body?

Answer 153

Glucose found in blood and ECF, and glycogen stored in liver and muscle

Question 154

What is glycogen?

Answer 154

Molecule made from many glucose molecules joined together to form a compact, highly branched, spherical structure

Question 155

What enzyme makes glycogen?

Answer 155

Glycogen synthase

Question 156

Where are most glyocogen granules stored in the muscle cell?

Answer 156

Near the mitochondria…can be used to make ATP in aerobic respiration

Question 157

What can influence glycogen concentrations in the liver and muscle?

Answer 157

DIET!

Question 158

What type of power does anaerobic glycolysis have in producing ATP?

Answer 158

Medium power…a large amount of ATP can be generated per unit time, because of the high activity of enzymes in the pathway

Question 159

Why can’t anaerobic glycolysis be used for more than 3-5 hours?

Answer 159

Capacity of the system is limited by the availability of substrates (i.e. muscle glycogen) and buildup of lactic acid (H+ causes acidosis)

Question 160

What type of capacity does anaerobic glycolysis have for producing ATP?

Answer 160

Moderate capacity…lactic acidosis and/or glycogen depletion will ultimately limit work intensity (fatigue)

Question 161

2 phases of anaerobic glycolysis?

Answer 161

Energy investment stage and energy generation phase

Question 162

How many ATP are required in the inergy investment stage of glycolysis?

Answer 162

Up to 2 ATP

Question 163

What does the energy generation phase produce in glycolysis?

Answer 163

ATP, NADH, and pyruvate or lactate

Question 164

What enzyme is used to add a phosphate to glycogen?

Answer 164

Phosphorylase

Question 165

What enzyme adds a phosphate from ATP to glucose to form Glucose-6-Phosphate?

Answer 165

Hexokinase

Question 166

What enzyme adds a phosphate to fructose-6-phosphate to make fructose-1,3-bisphosphate?

Answer 166

Phosphofructokinase

Question 167

How many ATP are invested in the energy investment stage of glycolysis for a glucose molecule?

Answer 167

2 (1 to make G-6-P via hexokinase and another to make F-1,6-BP via PFK)

Question 168

How many ATP are invested in the energy investment stage of glycolysis for a glycogen molecule?

Answer 168

1 (to make F-1,6-BP via PFK)

Question 169

The AMP Deaminase reaction is important because?

Answer 169

Stimulates glycolysis (NH4+ does), helps buffer pH (NH3 accepts H+), and indirectly helps maintain low ADP

Question 170

The first reaction that utilizes ATP in glycolysis if blood glucose is used as a substrate is catalyzed by what enzyme?

Answer 170

Hexokinase

Question 171

Why is the buildup of H+ a safety mechanism?

Answer 171

Tells the muscle to slow down/ stop contraction before mechanical damage occurs

Question 172

How is ATP formed during glycolysis?

Answer 172

Substrate level phosphorylation

Question 173

What causes the production of lactic acid?

Answer 173

When oxygen is not available in the mitochondria to accept H+ (and electrons) from Nadh produced in glycolysis, H+ and electrons from NADH are accepted by pyruvic acid to form lactic acidd

Question 174

What enzyme is responsible for the conversion of pyruvic acid to lactic acid?

Answer 174

Lactate Dehydrogenase

Question 175

What is the conversion of pyruvic acid to lactic acid important?

Answer 175

Allows anaerobic glycolysis to continue by maintaining a high NAD/NADH ratio (the redox potential). If the NADH/NAD ratio increases, GAPDH reaction slows/stops = no more glycolysis = no more ATP

Question 176

How many ATP does a glucose molecule produce?

Answer 176

32 ATP

Question 177

How many ATP does palmitic acid produce?

Answer 177

106 ATP

Question 178

What is aerobic/oxidative metabolism?

Answer 178

The complete combustion of fatty acids (from fat cells or in muscle cells), carbs (blood glucose and liver/muscle glycogen), and to a limited extent, protein, in the presence of oxygen

Question 179

What type of capacity for producing ATP does the aerobic pathway have?

Answer 179

Large capacity because of the continuous supply of ATP to large fat and glycogen stores

Question 180

What type of power for producing ATP does the oxidative pathway have?

Answer 180

Low-moderate pathway because ATP regeneration is relatively low and is limited by oxygen supply (VO2 max)

Question 181

What is oxidative phosphorylation?

Answer 181

The formation of ATP from ADP and Pi in association with electron transfer from fuel substrates to coenzymes to oxygen

Question 182

Why are aerobic pathways slower at ATP resynthesis than anaerobic pathways?

Answer 182

Location of the substrate (liver glycogen has to be transported) and there are more steps/enzymes in oxidative phosphorylation versus HEPT and glycolysis

Question 183

What is the Krebs cycle?

Answer 183

Completes the oxidation of substrates and produces NADH or FADH2 to enter the ETC

Question 184

What is the electron transport chain?

Answer 184

Electrons removed from NADH and FADH2 are passed along a series of carriers to produce ATP…H+ from NADH and FADH2 are accepted by O2 to form water.

Question 185

What are the three stages of oxidative metabolism?

Answer 185

1. Formation of Acetyl-CoA from CHO (pyruvate) or fats (fatty acids) 2. Oxidation of acetyl groups in Krebs cycle to form NADH and FADH2 3. Oxidation of NADH and FADH2 in ETC to form ATP from ADP and Pi

Question 186

What enzyme is responsible for the conversion of pyruvate (3C) to acetyl CoA (2C)?

Answer 186

Pyruvate dehydrogenase…a NADH and a CO2 are produced in this reaction

Question 187

In the beta-oxidation pathway, fatty acyl-CoA is split into?

Answer 187

2C acetyl groups that enter the Kreb’s Cycle

Question 188

When an acetyl group is cleaved in beta oxidation what is produced?

Answer 188

1 NADH and 1 FADH2 are produced

Question 189

How many acetyl CoA, NADH, and FADH2 are produced from a 16 carbon fatty acid?

Answer 189

8 acetyl CoA, 7 NADH and 7 FADH2

Question 190

How many ATP are used to uptake a fatty acid into the cell?

Answer 190

2 ATP

Question 191

Where are fat droplets located in the muscle?

Answer 191

Located near mitochondria

Question 192

What two Krebs cycle enzymes are measured in the muscle cell as a measure of oxidative potential?

Answer 192

Citrate synthase and succinate dehydrogenase

Question 193

How many H+ are moved across the membrane for every NADH molecule?

Answer 193

10 H+

Question 194

What ETC complexes pump hydrogen molecules?

Answer 194

1, 3, and 4

Question 195

What drives the formation of ATP in the ETC chain?

Answer 195

Flow of H+ from the intermembrane space through ATP synthase to the matrix down their concentration gradient

Question 196

How does ATP synthase make ATP?

Answer 196

H+ binding to the enzymes causes a confirmational shape change, which results in the formation of ATP from ADP and Pi

Question 197

How many H+ are needed to make one ATP?

Answer 197

4 H+

Question 198

How many ATP per NADH??

Answer 198

2.5 ATP

Question 199

How many ATP per FADH2?

Answer 199

1.5 ATP

Question 200

How many ATP from one glucose?

Answer 200

32 ATP

Question 201

What is respiration efficiency?

Answer 201

Efficieny of converting energy from foodstuff into biologically usable energy (ie ATP)

Question 202

Respiration efficiency of aerobic respiration?

Answer 202

34%, with the remaining 66% of the free energy being released as heat

Question 203

How do UCP increase BMR?

Answer 203

They uncouple the H+ flow from the IMS to the matrix, so no ATP is made, only heat is produced, Body wants to keep high [H+], therefore, it burns more foodstuffs to make FADH2 and NADH to keep pumping e- for the ETC to continue to make ATP

Question 204

Why are metabolic systems in muscle so tightly coordinated and controlled?

Answer 204

To maintain ATP homeostasis even when ATP utilization increases 200 fold

Question 205

5 basic ways metabolic control occurs in muscle?

Answer 205

1. Mass action (increase substrate = increase product) 2. Allosteric control (inc. or dec. a pathway) 3, Enzymatic activation-deactivation by phosphorylation processes 4. Cellular compartmentalization 5. Substrate control

Question 206

What is a rate limiting enzyme?

Answer 206

Enzymes that determine the rate of flux of a metabolic pathway and are therefore usually highly controlled. ANything that gets past a rate limiting enzyme will become product.

Question 207

Name 5 sources that provide ATP for the muscle cell?

Answer 207

1. Creatine phosphate 2. Glucose 3. Stored ATP 4. Adenylate Kinase 5. Anaerobic glycolysis

Question 208

Activators of phosphorylase?

Answer 208

Pi, AMP, and IMP…all are by-products of ATP utilization, their buildup tells cell that there may not be enough stored ATP or Pc to keep contraction going, so other pathway must start or become more activated.

Question 209

Inhibitors of phosphorylase?

Answer 209

G-6-P and ATP

Question 210

Why is G-6-P an inhibitor of phosphorylase?

Answer 210

Increase in its concentration tells the cell that it isn’t being used to make ATP or glucose is being used to make G6P, so glycogen is not needed/

Question 211

What activates phosphorylase?

Answer 211

Ca2+ and epinephrine through phosphorylation processes via PHOSPHORYLASE KINASE

Question 212

What is phosphorylase “a”?

Answer 212

More active form or phosphorylase, phosphorylated form, physiologically active

Question 213

What is phosphorylase “b”?

Answer 213

Unphosphorylated form of phosphorylase, main form at rest, inactive in the absence of AMP

Question 214

At the onset of ecercise, what phosphorylase form is used?

Answer 214

At the onset of exercise, phos “b” –> phos “a” but then most of phos “a” converts back to phos “b” later in exercise, however, phos “b” mroe active during exercise than at rest due to allosteric activation by Pi, AMP, and IMP

Question 215

What is the best example of a rate limiting metabolic enzyme?

Answer 215

PFK is probably the best example of a rate limiting metabolic enzyme such that flux through glcolytic reactions that take place downstream of PFK is determined simply by mass action

Question 216

Activators of PFK?

Answer 216

Pi, ADP, AMP, IMP, increased pH

Question 217

Inhibitors of PFK?

Answer 217

Citrate, ATP, decrease in pH

Question 218

Why is citrate an allosteric inhibitor of PFK?

Answer 218

If its concentration is increased, it means it isn’t being used OR it’s being produced by some other pathwa (like aerobic) so no point in activating glycolysis. As soon as its concentration decreases, PFK is stimulated to make pyruvate, which cna make ACetyl CoA and then ATP

Question 219

Why is decreased pH an inhibitor of PFK?

Answer 219

It can cause the buildup of lactic acid, so if pH is already low, we don’t want to decrease it further by completing this reaction/

Question 220

The control of what enzyme causes control of glycolysis?

Answer 220

PFK, not phosphorylase

Question 221

What form of PDH is active?

Answer 221

Dephosphorylated

Question 222

What form of PDH is inactive?

Answer 222

Phosphorylated

Question 223

What controls the forms of PDH?

Answer 223

Phosphorylation-dephosphorylation processes

Question 224

Activators of phosphatase in the control of PDH?

Answer 224

Mg2+ and Ca2+

Question 225

Inhibitors of kinase in the control of PDH?

Answer 225

Pyruvate, increased mitochondria NAD+/NADH, decreased ATP/ADP and decreased Acetyl CoA/CoA

Question 226

What activates PDH?

Answer 226

Activators of phosphatase and inhibitors of kinase

Question 227

How does ATP synthase make ATP?

Answer 227

H+ binding to the enzymes causes a confirmational shape change, which results in the formation of ATP from ADP and Pi

Question 228

How many H+ are needed to make one ATP?

Answer 228

4 H+

Question 229

How many ATP per NADH??

Answer 229

2.5 ATP

Question 230

How many ATP per FADH2?

Answer 230

1.5 ATP

Question 231

How many ATP from one glucose?

Answer 231

32 ATP

Question 232

What is respiration efficiency?

Answer 232

Efficieny of converting energy from foodstuff into biologically usable energy (ie ATP)

Question 233

Respiration efficiency of aerobic respiration?

Answer 233

34%, with the remaining 66% of the free energy being released as heat

Question 234

How do UCP increase BMR?

Answer 234

They uncouple the H+ flow from the IMS to the matrix, so no ATP is made, only heat is produced, Body wants to keep high [H+], therefore, it burns more foodstuffs to make FADH2 and NADH to keep pumping e- for the ETC to continue to make ATP

Question 235

Why are metabolic systems in muscle so tightly coordinated and controlled?

Answer 235

To maintain ATP homeostasis even when ATP utilization increases 200 fold

Question 236

5 basic ways metabolic control occurs in muscle?

Answer 236

1. Mass action (increase substrate = increase product) 2. Allosteric control (inc. or dec. a pathway) 3, Enzymatic activation-deactivation by phosphorylation processes 4. Cellular compartmentalization 5. Substrate control

Question 237

What is a rate limiting enzyme?

Answer 237

Enzymes that determine the rate of flux of a metabolic pathway and are therefore usually highly controlled. ANything that gets past a rate limiting enzyme will become product.

Question 238

Name 5 sources that provide ATP for the muscle cell?

Answer 238

1. Creatine phosphate 2. Glucose 3. Stored ATP 4. Adenylate Kinase 5. Anaerobic glycolysis

Question 239

Activators of phosphorylase?

Answer 239

Pi, AMP, and IMP…all are by-products of ATP utilization, their buildup tells cell that there may not be enough stored ATP or Pc to keep contraction going, so other pathway must start or become more activated.

Question 240

Inhibitors of phosphorylase?

Answer 240

G-6-P and ATP

Question 241

Why is G-6-P an inhibitor of phosphorylase?

Answer 241

Increase in its concentration tells the cell that it isn’t being used to make ATP or glucose is being used to make G6P, so glycogen is not needed/

Question 242

What activates phosphorylase?

Answer 242

Ca2+ and epinephrine through phosphorylation processes via PHOSPHORYLASE KINASE

Question 243

What is phosphorylase “a”?

Answer 243

More active form or phosphorylase, phosphorylated form, physiologically active

Question 244

What is phosphorylase “b”?

Answer 244

Unphosphorylated form of phosphorylase, main form at rest, inactive in the absence of AMP

Question 245

At the onset of ecercise, what phosphorylase form is used?

Answer 245

At the onset of exercise, phos “b” –> phos “a” but then most of phos “a” converts back to phos “b” later in exercise, however, phos “b” mroe active during exercise than at rest due to allosteric activation by Pi, AMP, and IMP

Question 246

What is the best example of a rate limiting metabolic enzyme?

Answer 246

PFK is probably the best example of a rate limiting metabolic enzyme such that flux through glcolytic reactions that take place downstream of PFK is determined simply by mass action

Question 247

Activators of PFK?

Answer 247

Pi, ADP, AMP, IMP, increased pH

Question 248

Inhibitors of PFK?

Answer 248

Citrate, ATP, decrease in pH

Question 249

Why is citrate an allosteric inhibitor of PFK?

Answer 249

If its concentration is increased, it means it isn’t being used OR it’s being produced by some other pathwa (like aerobic) so no point in activating glycolysis. As soon as its concentration decreases, PFK is stimulated to make pyruvate, which cna make ACetyl CoA and then ATP

Question 250

Why is decreased pH an inhibitor of PFK?

Answer 250

It can cause the buildup of lactic acid, so if pH is already low, we don’t want to decrease it further by completing this reaction/

Question 251

The control of what enzyme causes control of glycolysis?

Answer 251

PFK, not phosphorylase

Question 252

What form of PDH is active?

Answer 252

Dephosphorylated

Question 253

What form of PDH is inactive?

Answer 253

Phosphorylated

Question 254

What controls the forms of PDH?

Answer 254

Phosphorylation-dephosphorylation processes

Question 255

Activators of phosphatase in the control of PDH?

Answer 255

Mg2+ and Ca2+

Question 256

Inhibitors of kinase in the control of PDH?

Answer 256

Pyruvate, increased mitochondria NAD+/NADH, decreased ATP/ADP and decreased Acetyl CoA/CoA

Question 257

What activates PDH?

Answer 257

Activators of phosphatase and inhibitors of kinase

Question 258

What are activators of the PDH kinase…inactivate PDH?

Answer 258

Increased ATP/ADP and increased acetyl CoA/CoA

Question 259

Rate limiting enzyme of ATP-PC system?

Answer 259

Creatine Kinase

Question 260

Rate limiting enzyme of Krebs Cycle?

Answer 260

Isocitrate dehydrogenase

Question 261

Stimulators of isocitrate dehydrogenase?

Answer 261

ADP, Mito Ca2+, NAD

Question 262

Inhibitors of Isocitrate dehydrogenase?

Answer 262

ATP and NADH

Question 263

Rate limiting enzyme of ETC?

Answer 263

Cytochrome C oxidase

Question 264

Stimulators of Cytochrome C Oxidase?

Answer 264

ADP and Pi

Question 265

Inhibitors of cytochrome c oxidase?

Answer 265

ATP

Question 266

What causes activation of isocitrate dehydrogenase and other dehydrogenases in Krebs Cycle?

Answer 266

Mitochondrial Ca2+ binding directly to enzyme…not through phosphorylation processes

Question 267

The complete combustion of a glucosyl unit from glycogen would produce?

Answer 267

33 ATP

Question 268

Enzyme responsible for accepting an e_ from cytochrome c is?

Answer 268

Cytochrome C Oxidase (it is oxidizing cytochrome c)

Question 269

What does cellular comparmentalization do?

Answer 269

Has to with getting ATP to the sites where it is needed (i.e. ATPases) as quickly as possible (i.e. locating the sites of ATP production near the sites of ATP utilization)

Question 270

3 examples of compartmentalization in muscle?

Answer 270

1. Sarcolemmal mitochondira…supplies Na/K+ ATPase with ATP 2. SR-Glycogenolytic Complex 3. Cr Shuttle

Question 271

What is the purpose of the SE-Glycogenolytic complex?

Answer 271

Glycogen and glycolytic enzymes are attached to SR, so they supply SERCA with ATP, also helps with Ca2+ activation of phosphorylase

Question 272

How does the Cr Shuttle help with energy in the muscle cell?

Answer 272

ATP very slow to diffuse through cytoplasm, so Cr is a much faster way to get energy through muscle fibre

Question 273

Glucose transporter in muscle?

Answer 273

GLUT4

Question 274

Fatty acid transporter in muscle?

Answer 274

FAT and CD 36

Question 275

Lactate transporters in muscle?

Answer 275

MCT 1 (in) and MCT 4 (out)

Question 276

What are the 3 ways substrate transport is regulated in muscle?

Answer 276

1. Amount of available protein (gene regulation) 2. Protein localization (translocation) 3. Activity of transporter (allosteric)

Question 277

Why is it important to control substrate transport in muscle cells?

Answer 277

We want to have control over how much and what kind of substrate gets into cell during different activities

Question 278

What causes translocation of GLUT4 to sarcolemma?

Answer 278

Insulin and Exercise

Question 279

What is maximal exercise?

Answer 279

WOrk rate that would require energy production equivalent to VO2 max (short term intense)

Question 280

Submaximal high intensity exercise?

Answer 280

Work rate is greater than lactate threshold but less than 100% VO2 max (prolonged)

Question 281

What is supramaximal exercise?

Answer 281

Work rate that would require energy production greater than 100% VO2 max (short-term very intense)

Question 282

Submaximal steady state exercise?

Answer 282

Work rate is less than lactate threshold where 100% of the energy is supplied by aerobic metabolism

Question 283

Progressive (incremental) exercise?

Answer 283

Exercise that begins at a low work rate (intensity) and involves step (or ramp) increases in work rate until exhaustion (i.e. VO2 max test)

Question 284

When does oxygen consumption reach a steady state?

Answer 284

1-4 minutes into exercise

Question 285

What is the oxygen deficit?

Answer 285

Lag in oxygen uptake at the beginning of exercise. Suggests that anaerobic pathways contribute to total ATP production

Question 286

After steady state is reached, how is ATP requirement met?

Answer 286

Aerobically

Question 287

Before state state is reached, how is ATP produced?

Answer 287

Anaerobically because there is not sufficient oxygen supply to make ATP aerobically

Question 288

Which of the following is/are true regarding PDH?

Answer 288

1. inactive when phosphorylated 2. Activation of PDH kinase reduced PDH activity 3. Can be indirectly activated by Ca2+ 4. Inactive when ATP/ADP ratio is high

Question 289

A mitochondrial enzyme activated/stimulated by Ca2+?

Answer 289

Isocitrate dehydrogenase…NOT phosphorylase because it is NOT a mitochondrial enzyme, although it is activated by Ca2+

Question 290

What was “serial mobilization?”

Answer 290

Margaria in the 1960s thought that PCr provided immediate and only substrate for ATP synthesis in the first 10 seconds of exercise, and when PCr was depleted, glycolysis activated to provide a continued ATP supply

Question 291

Why is the “serial mobilization” idea not true?

Answer 291

Glycolysis is also immediately activated at the onset of exercise and blood flow increases and enzymes involved in oxidative phosphorylation are activated…All pathways are activated at the onset of exercise, but they may not all be fully activated.

Question 292

Equation for the total anaerobic ATP provision during intense exercise?

Answer 292

Change in PCr + (1.5 x change in Lactate) + (2 x change in ATP)

Question 293

Approximate contributions of anaerobic vs aerobic sources to total ATP production during high-intensity exercising lasting approx. 3 minutes?

Answer 293

80%/20% in initial 30 seconds. 45%/55% from 60-90 seconds. 30%/70% from 120 to 180 seconds.

Question 294

As exercise intensity increases, how does ATP provision/power change?

Answer 294

Greatly increases, too

Question 295

Why does IMP increase as a function of decrease in ATP during high-intensity exercise?

Answer 295

During high-intensity exercise, the adenylate kinase reaction is also activated, which means the AMP deaminase reaction will also be activated in order to keep the [ADP] low and the adenylate kinase reaction moving. Therefore, as ATP decreases due to utilization, IMP increases.

Question 296

For the total ATP provision due to the anaerobic system during high-intensity exercise, why is it 1.5 times lactate?

Answer 296

Because for every glucosyl unit that comes from glycogen (preferred substrate in muscle), 3 ATP are produced for every 2 lactate. Therefore, there is 1.5 lactates for every 1 ATP.

Question 297

In the equation for total anaerobic ATP provision during high-intensity exercise, why is the change in ATP multiplied by 2?

Answer 297

For every 1 ATP that is split by an ATPase, another one is regenerated due to the adenylate kinase reaction that is activated during high-intensity exercise.

Question 298

Oxygen deficit is…

Answer 298

1. The anaerobic portion of the total ATP used at the onset of exercise 2. Refers to the lag in oxygen at the onset of exercise 3. Is equivalent to the O2 needed to supply ATP aerobically

Question 299

What is excess post exercise oxygen consumption (EPOC)?

Answer 299

The elevated VO2 that occurs for several minutes immediately following exercise

Question 300

What is the “fast” portion of EPOC consist of?

Answer 300

20%…resynthesis of stored PCr and replacing the muscle and blood oxygen stores

Question 301

What does the “slow” portion of EPOC consist of?

Answer 301

80%…elevated body temperature and cathecholamines, conversion of lactic acid to glucose in the liver (gluconeogenesis), and elevated HR and ventilation (diaphragm) above resting values

Question 302

Once steady state is reached, how is ATP produced?

Answer 302

AEROBICALLY

Question 303

Why does elevated body temperature and catecholamines increase oxygen consumption?

Answer 303

The increase in temperature causes increased activation of enzymes and epipnephrine stimulates phosphorylase to breakdown glycogen, so oxygen is needed to take this glycogen and make ATP aerobically.

Question 304

Why does the conversion of lactic acid to glucose contribute to the slow portion of EPOC?

Answer 304

Oxygen is needed to turn it back into glucose

Question 305

EPOC tends to be equal to the area of?

Answer 305

Oxygen deficit

Question 306

What is VO2 max?

Answer 306

The point at which no further increase in oxygen consumption occurs, even with increasing work rate

Question 307

Physiological factors influencing VO2 max?

Answer 307

Ability of cardiorespiratory system to deliver oxygen to muscles, and the ability of muscles to take up the oxygen and produce ATP aerobically

Question 308

Why do byproducts dramatically increase at higher work rates?

Answer 308

Because of increased ATP utilization

Question 309

What is the lactate threshold?

Answer 309

Work rate/point where there is a dramatic increase in blood lactate levels

Question 310

Where does OBLA (onset of blood lactate accumulation) occur?

Answer 310

4 mmol lactate/L

Question 311

What is the ventilatory breakpoint?

Answer 311

Point at which ventilation dramatically increases.

Question 312

What causes the ventilatory breakpoint?

Answer 312

Increased lactate at the muscle would lead to excess H+ and could decrease muscle and blood pH. Sodium bicar, a weak base, is used as a pH buffer, which forms sodium lactate and CARBONIC ACID. Carbonic acid readily dissociates into CO2 and water. Increased blood CO2 causes increased ventilation.

Question 313

How does low muscle oxygen contribute to the lactate threshold?

Answer 313

A decrease availability of )2 will slow down electron transport and lead to NADH accumulation in the mitochondrial matrix and cytosol, which will cause pyruvate to accept an H+ to regenerate NAD and allow glycolysis to continue. This leads to the formation of lactate, which leads to the lactate threshold.

Question 314

How does accelerated glycolysis lead to the lactate threshold?

Answer 314

Increased levels of ADP can stimulate PFK and glycolysis, which leads to lactate formation. Epinephrine levels will increase with exercise which will stimulate phosphorylase and glycolysis.=, leading to lactate formation.

Question 315

How does the recruitment of fast twitch fibres lead to lactate threshold?

Answer 315

Fast twitch fibres are activated at high intensities of exercise. Type IIx don’t have as many mitochondria, but are doing the same amount of absolute work as the aerobic Type I fibres, so they need to make the same amount of ATP. But they cannot produce it all aerobically. Therefore, it is make anarobically, which leads to accumulation of lactate.

Question 316

What causes the reduced rate of lactate removal that contributes to the lacate threshold?

Answer 316

As exercise intensity increases, bloodflow to the liver is diverged from the liver to the skeletal muscles. Less blood to liver = less lactate removal = more buildup in blood

Question 317

Sites of lactate removal during exercise?

Answer 317

The liver (Cori Cycle), the heart, resting slow twitch, and active slow twitch fibres

Question 318

5 different types of LDH isoforms?

Answer 318

M4, M3H1, M2H2, M1H3, H4

Question 319

Type of LDH isoform in Type II fibres?

Answer 319

M4

Question 320

Type of LDH isoform in Type I fibres and heart?

Answer 320

H4

Question 321

What does the M form of LDH isoform do?

Answer 321

Converts pyruvate —-> lactate

Question 322

What does the H form of LDH isoform do?

Answer 322

Convert lactate —–> pyruvate

Question 323

Red muscle would have what LDH isoform?

Answer 323

M4

Question 324

Why does light exercise increase lactate removal versus just sitting down for rest?

Answer 324

The H4 LDH isoform is found in Type I fibres, which are most active during low intensity exercise (35% VO2), therefore, exercising will increase lactate removal

Question 325

Explain 2 reasons why the recruitment of more FT fibres would contribute to lactate threshold?

Answer 325

1. Type II fibres are activated at higher intensities and primarily use glycolysis for ATP production, so more lactate production. 2. Type II fibres have M4 LDH isoform, which converts pyruvate to lactate, rather than lactate utilization

Question 326

Why is there a plateau in the concentrations of metabolites during prolonged exercise around 30 minutes?

Answer 326

Steady state is reached, so ATP is being produced aerobically. However, is intensity changes, there will be an increase in metabolites until steady state is reached again, if it can be reached.

Question 327

How is fuel utilization estimated during exercise?

Answer 327

The Respiratory Exchange Ration (RER)

Question 328

What is RER?

Answer 328

Ratio of VCO2 to VO2

Question 329

RER for 100% fat utilization?

Answer 329

0.7

Question 330

RER fro 50% CHO and 50% fat utilization?

Answer 330

0.85

Question 331

RER fro 100% CHO utilization?

Answer 331

1.0

Question 332

If steady state is not reached, why do VCO2 and VO2 NOT reflect O2 consumption and CO2 production at the cellular level?

Answer 332

At high intensities, when steady state is not achieved, CO2 is produced by hte buffering system. This “extra” CO2 will throw off RER, so values will be greater than 1.

Question 333

During low intensity exercise (<30% VO2 max) what is the primary fuel source?

Answer 333

Fats

Question 334

During high-intensity exercise (>70% VO2 max) what is the primary fuel source?

Answer 334

CHO

Question 335

What is the crossover concept?

Answer 335

Describes the shift from fat to CHO metabolism as exercise intensity increases

Question 336

What is the crossover concept due to?

Answer 336

1. Recruitment of fast muscle fibres (cannot utilize fat very well because so few mitochondria) 2. Increasing blood levels of epinephrine (stimulates glycolysis through activating phosphorylase)

Question 337

During prolonged exercise why is there a shift from CHO metabolism toward fat matabolism?

Answer 337

Increased rate of lipolysis (breakdown of TAGs into glycerol and FFAs)

Question 338

What stimulates increased lipolysis during prolonged exercise?

Answer 338

Rising blood levels of E, NE, and glucagon

Question 339

What inhibits lipolysis?

Answer 339

Insulin and blood lactic acid

Question 340

How does insulin lower lipolysis?

Answer 340

Insulin –> GLUT 4 translocation to sarcolemma –> inc. glucose uptake –> more glucose in muscle –> glucose used in glycolysis, so lipolysis is not necessary anymore

Question 341

How does lactic acid decrease lipolysis in the muscle?

Answer 341

Causes stimulation of pathway that converts FFA into TAGs, not breaking TAGs into glycerol and FFAs

Question 342

Sources of CHO and fat during prolonged exercise (60-75% VO2 max)?

Answer 342

Muscle glyocogen and muscle TAGs are used at first, then plasma FFA and blood glucose as exercise progressese (up to 4 hrs.) due to depletion of intramuscular energy stores.

Question 343

Metabolic fatigue is caused by?

Answer 343

1. Reduced energy supply (ATP and PCr) 2. Build-up of metabolic by-products (i.e. ADP, Pi, H+)

Question 344

3 metabolites that affect the cross bridge cycle?

Answer 344

Reduced pH, Increased Pi, Increased ADP

Question 345

What type of exercise results in greater and more rapid glycogen depletion?

Answer 345

High-intensity

Question 346

What type of exercise is associated with depleted muscle glycogen stores?

Answer 346

Prolonged sub-maximal exercise to exhaustion (<70% VO2 max)

Question 347

Where does H+ come from in the muscle?

Answer 347

Breakdown of ATP and anaerobic glycolysis

Question 348

What effect does decreased pH have on free energy release?

Answer 348

A decrease in pH brings the [reactants] and [products] of ATP utilization closer together, so LESS free energy is released per ATP molecule. This means more energy/ATP is needed to do the same amount of work, which leads to fatigue quicker.

Question 349

What effect does decreased pH have on Fmax and Vmax?

Answer 349

Decreased both in fast twitch and slow twitch muscle fibres

Question 350

What effect does Pi have on Fmax and Vmax?

Answer 350

Decreases both in slow, but only decreases Fmax in fast twich fibres (no change in Vmax).

Question 351

What effects does increased Pi have in the muscle?

Answer 351

Increased Pi reduces the rate of Pi release from myosin and therefore reduces strong binding and force goes down.

Question 352

What effect does increased ADP have in the muscle?

Answer 352

Increased ADP reduces the ADP release from myosin and therefore more corss-bridges are locked in strong binding and force goes up BUT sliding of filaments is slowed.

Question 353

Reduced pH leads to?

Answer 353

Lower Vmax and lower maximal isometric force (Po) (FT>ST)

Question 354

Increased Pi leads to?

Answer 354

Reduces Po in FT and ST fibres (and Vmax only in ST fibers)

Question 355

Increased ADP leads to?

Answer 355

Reduced Vmax and Increased Po

Question 356

Why does an increase in Pi on reduced Vmax in ST fibres?

Answer 356

FT fibres hydrolyze ATP and release Pi so rapidly, that an increase in Pi doesn’t really affect Vmax

Question 357

Adaptations in aerobic/endurnace training depend on?

Answer 357

1. Genetics 2. Initial training status (greater gains in someone who starts program out of shae=pe)

Question 358

What is the general adaptatio to aerobic/endurnace training?

Answer 358

Improved metabolic control (“tight” as opposed to “loose” metabolic control)

Question 359

What is tight metabolic control?

Answer 359

Over a braod range of metabolic and work rates, the concentrations of PCr, Pi, ATP, ADP, AMP, and IMP show very minimal changes despite large increases in flux through actomyosin ATPases and mitochondrial ATP synthesis (phosphrylation potential remains high)

Question 360

What is loose metabolic control?

Answer 360

Over a braod range of metabolic and work rates, the concentrations of PCr, Pi, ATP, and ADP show large changes when large increases in flux occurs through actomyosin ATPases and mitochondrial ATP synthesis (phosphorylation potential shows large reductions)

Question 361

Metabolic response to exercise following training compared with sedentary?

Answer 361

1. Decreased glycolysis 2. Decreased CHO utilization 3. Decrease in net glycogen 4. Decrease in PCr hydrolysis 5. Decrease in ATP degradation products (i.e. ADP, Pi, AMP, IMP) 6. Increase in fat oxidation

Question 362

Why is there an increase in glycogen storage in muscle following training?

Answer 362

Increased levels of glycogen synthase enzyme as a result of the training/stimulus to muscle

Question 363

What are the 2 reasons for less glyocgen depletion following training?

Answer 363

1. Increased transport and utilizatoin of fat as fuel 2. Decreased translocation of GLUT 4 to sarcolemma at submaximal intensities (drop in glucose in muscle - increase in fat oxidation)

Question 364

Why are blood lactate levels reduced at a give intensity of exercise and and lactate threshold increased following training?

Answer 364

There is less lactate produced due to increased fat oxidation, and there is also an increased rate of lactate removal due to change in LDH isoform to H4 and more capillaries

Question 365

How does the decrease in ATP degradation products (ADP, Pi, AMP, IMP) account for a lower glycolytic rate?

Answer 365

These metabolites can allosterically activate or inihibt enzymes that control glycolysis. So, when their concentrations are decreased, there is less activation of glycolysis, so less lactate production, so less fatigue.

Question 366

Why do the concentrations of succinate dehydrogenase and citrate synthase increase due to prolonged endurance training?

Answer 366

Increased number and size of mitochondria

Question 367

2 factors that influence training adaptations?

Answer 367

1. Genetics 2. Initial training status

Question 368

Due to aerobic training, is there a complete lack of glycogen utilization as a fuel source?

Answer 368

NO

Question 369

What does a change in mitochondrial content mean?

Answer 369

There is either an increase in size or number of mitochondria, which increases the concentrations of aerobic enzymes = less lactate production

Question 370

Why do Type IIx fibres show a greater increase in citrate synthase activity in response to higher intensity training versus slow twitch who show no difference in CS activity in response to different training intensities?

Answer 370

Type IIx gain more michtochondrial content in response to high intensity training because they are only recruited at higher intensities. Therefore, at low intensities, they are not recruited, so no stress = no adaptations

Question 371

Know why more mitochondria following training leads to tighter metabolic control…

Answer 371

Less emphasis on glycolysis because more mitchondria = more fat oxidation. Less glycolysis = less lactate. More mitochondria = use pyruvate faster. More mitchondria = shuttle ADP and Pi into mitochondria quicker, so their concentrations in cytosol drop, so less stimulation of glycolysis and fatigue caused by their altering of the powerstroke and Pi’s interaction with calcium to form calcium percipitate. More mitochondria = takes up pyruvate and NADH quicker and uses them to make ATP aerobically

Question 372

How does the increased mitchondrial content in response to training increase the activation of aerobic energy at the onset of exercise?

Answer 372

More mitochondria = more sensitive to changes in [ADP, Pi, AMP, IMP], so increases activation of mitochondrial enzymes faster = aerobic metabolism occurs sooner = less lactate

Question 373

How does oxidation of plasma fatty acids decrease PFK activity/

Answer 373

The oxidation causes an increase in citrate, which is an allosteric inhibitor of PFK

Question 374

Ways in which glycolysis is regulated in response to tighter metabolic control?

Answer 374

1. Lack of glycoylsis causes a buildup of glucose in cell, which decreases its transport into the cell. 2. Decreased glycolysis+increased intracellular glucose = increase in G6P = decrease in phosphorylase activity 3. Increased G6P = decreased hexokinase activity 4. Increased acetyl Coa/CoA ratio, increased NADH/NAD+ ratio = decreased PDH 5. increased citrate from beta oxidation = decreased activity of PFK

Question 375

What is calcineurin, and how does it change fibre type/mitochondrial content?

Answer 375

Calcineurin is a Ca2+ regulated phosphatase that dephosphorylates nuclear factor of activated T-cells transcription factors. A second target of calcineurin is the transcriptional co-activator, peroxisome-proliferator-activated receptor gamma co-activator 1 (PGC-1). Activation of calcineurin in skeletal myocytes selectively up-regulates slow-fibre-specific gene promoters and PGC-1 expression. PGC-1 activates mitochondrial biogenesis.

Question 376

Adaptations to endurance training besides increased mitochondrial content, glyocgen synthase, etc.

Answer 376

1. increased muscle capillaries and myoglobin 2. Increased muscle TAG stores (because you are using fat more) and increaesd fat oxidation enzymes 3. Increase in MCT-slow and LDH H4 isoform 4. Increased VO2 max

Question 377

In Heritage family study, how much of the increase in VO2 max was influenced by genetics?

Answer 377

%

Question 378

How much of increase in VO2 max is a result of maternal genetics (mtDNA)?

Answer 378

30%

Question 379

Why does mtDNA influence VO2 so much?

Answer 379

Mitochondrial DNA that codes for proteins in ETC comes from maternal DNA

Question 380

What can explin the metabolic adaptations to short term training that occur before mitochondrial potential and increases in VO2 max?

Answer 380

Increased blood flow and VO2 kinetics at the onset of exercise during the non-steady state. Improvements may be due to increased vasodilation of arterioles.

Question 381

What are the 2 main factors that determine the ability for the muscle to adapt to strength/resistance training?

Answer 381

1. Overload 2. Specificity

Question 382

What is overload?

Answer 382

Muscle will increase its function and size when it is forced to contract at forces near their maximal output (loaded beyond point which normally loaded). Once significant improvements are made load applied to muscle must be progressively increased for adaptation to continue

Question 383

What is specificity?

Answer 383

Muscle will adapt specifically to the exercise stress placed on it.

Question 384

What is muscular strength?

Answer 384

Peak force developed during a maximum voluntary effort (depends on muscle length and velocity of contraction)

Question 385

Muscular power

Answer 385

The explosive aspect of strength defined as the rate at which mechanical work is performed

Question 386

Muscular endurance

Answer 386

ability to sustain repeated muscle actions (repetitions) or to sustain fixed static muscle actions for an extended period of time (max number of repetitions at a given % of 1 RM)

Question 387

Intensity, reps, and rest for power training

Answer 387

.85% 1 RM, 1-2 reps, 2-5 min

Question 388

Intensity, reps, and rest for strength

Answer 388

80-85% 1 RM, <6 reps, 2-5 min

Question 389

Intensity, reps, and rest for endurance

Answer 389

30-70% 1 RM, > 12, 0.5 min

Question 390

Intensity, reps, and rest for hypertrophy

Answer 390

70-85% 1 RM, 6-12, 1 min

Question 391

If training increases Vmax then peak power…

Answer 391

increases and occurs at higher velocity

Question 392

If training increases MVC then peak power…

Answer 392

increases and occurs at a lower velocity

Question 393

Strength training increases muscle strength/power by…

Answer 393

1. Neural adaptation 2. Increased muscle size (more actin and myosin)