glycogen

Question 1

Energy sources during exercise over time

Answer 1

1) ATP + creatine phosphate
2) anaerobic glycolysis of muscle glycogen
3) Anaerobic oxidation of muscle glycopgen, liver glycogen, plasma glucose
4) Aerobic oxisation of plasma FFA and plasma tissue triglycerides.

Question 2

Enzymes needed for glycogen synthesis

Answer 2

glycogen synthase: adds glucosyl units in an alpha 1,4 linkage

Branching enzymes ads glucosyl units in an alpha 1,6 linkage

Question 3

Enymes required for glycogen degradation

Answer 3

glycogen phosphorylase- removed glucosyl units from alpha 1,4 linkage

debranching enzyme- transferase and alpha 1,6-glucosidase

Question 4

Phosphorylase a regulators

Answer 4

Phosphorylase a is the phosphorylated and active form that causes degradation of glycogen.

activators: cAMP, PI, Ca2+. cause activation of PKA which P and activates phos a. glucagon
inhibitors: insulin, ATP

when glucose and ATP levels are high (necrosis, inflammation, liver injury) tney can bind directly to the phosphorylated form and inactivate it.

Question 5

phosphorylase b regulators

Answer 5

inactive form that promotes glycogen synthesis. it is dephosphorylated

Activators: insulin

inhibitors: cAMP

AMP can bind directly to the b enzyme, causing a conformational change an activate from b to a form. regardless of phosphorylation status

Question 6

glycogen synthase a

Answer 6

this is the active dephosphorylated form. glyccogen synthesis

promotors: insulin
inhibitors: cAMP

Question 7

glycogen synthase b

Answer 7

this is the inactive phosphorylated form. no glycogen formation.

promotors: cAMP, PKA, calmodulin dependent protein kinase, PKC, caesin kinase, glucose-6-phosphate, glucagon
inhibitors: glycogen synthase kinase 3, insulin

under certain circumstances like pathological GSD, when glucose-6-P is high it directly binds to the b forms causing a conformational change to activate it.

Question 8

Fasted state phophorylase and synthase

Answer 8

Phosphorylase a: P, active, glucagon, relaxed, glycogen degradation, high affinity to glycogen. inhibited by high glucose and ATP

Synthase b: P, inactive, glucagon, tight, substrate is UDP glucose, low affinity to substrate. inhibited by G-6-P which promotes synthesis of glycogen.

Question 9

Fed state phosphorylase and synthase

Answer 9

Phosphorylase b: dephosphorylated, inactive form. low affinity to substrate, won’t degrade glycogen. promoted by insulin. inativated during high energy levels. when energy levels drop, have high AMP, activated form promoted for glycogen degradation.

Synthase a: dephosphorylated, active form. promotes glyocogen synthesis. promoted by insulin.

Question 10

Effects of cAMP in liver

Answer 10

1) promotes glycogen degradation
2) inhibits glycolysis
3) inhibits glycogen synthesis

all promoted by glucagon

Question 11

Effects of cAMP in heart and muscle

Answer 11

only activated by epi not glucagon

1) promotes glycogen degradation
2) Activates glycolysis
3) inhibits glycogen synthesis

Question 12

PI in the liver

Answer 12

Epi activates this pathway

1) IP3 increases calcium
2) Ca2+ activates a Ca2+ depdendent PK
3) DAG activates PKC

stimulation of glycogenolysis by alpha agonists. inhibition of glycogen formation

Question 13

Ca2+ in the muscle

Answer 13

pathway activated by nerve impulses on an AcH receptor, causes depolarization and release of Ca+.

Ca 2+ causes glycogen degradation. forma lactate

Question 14

insulin in muscle cells

Answer 14

activates kinase mediated signaling cascade. causes uptake of glucose by GLUT 4. Promoted glycogen formation and inhibits glycolysis

Question 15

Insuline in liver cells

Answer 15

kinase mediated signaling causes uptake of glucose. promotes glycogen formation and inhibits glycolysis.

Question 16

defective glycogen synthase

Answer 16

affects liver

decreased glycogen

cause hypoglycemia, post prandial lactic aceidemia, and fasting ketosis.

Question 17

Type I: Von Gierke disease

Answer 17

Glucose-6-phosphatase deficiency (translocase or enzyme).

affects the liver and kidney

increased normal glycogen

causes enlarged liver, failure to thrive, severe hypoglycemia, hyperuricemia, gouty arthiritis, hyperlipidemia (high fasting levels of fatty acid in the blood), mental retardation, lactic acidosis

Question 18

Type II: Pompe Disease

Answer 18

defective 1,4 glucosidase (lysosomal acid maltase)

affects all organs

Massive in crease in normal structure glycogen

causes cardiorespiratory failure, death usually before age 2

Question 19

Type III: Cori disease

Answer 19

defective glycogen debranaching enzyme

affects muscle and liver.

increased short outer glycogen

like vongierke but milder.

Question 20

Type IV: Anderson’s disease

Answer 20

defective glycogen branching enzyme.

affects the liver and the spleen

Decreased normal amount of glycogen with long branches.

Progressive cirrhosis of liver. Liver failure causes death before age 2.

Question 21

Type V: McArdler disease

Answer 21

defective phosphorylase.

effects muscle

moderate amount of normal structure

limited ability to perform strenous exercise, painful muscle cramps

Question 22

Type VI: Hers disease

Answer 22

deficient phosphorylase

affects the liver

increased amount of glycogen

Like Type 1 but milder

Question 23

Type VII: Tarui disease

Answer 23

deficient PFK-1

affects the liver

increased amount of glycogen

Like V

Question 24

Type VIII

Answer 24

Deficient phosphorylase b kinase

affects the liver

increased amount of normal structure glycogen

mild liver enlargement and mild hypoglycemia

Question 25

How does glucagon and epi inhibit glycolysis?

Answer 25

inhibits PFK-2 which leads to decreased F2,6BP, which leads to decreaes activity of PFK-1

Inhibits pyruvate kinase

Question 26

How does glucagon and epi activate gluconeogenesis in liver

Answer 26

Inhibits PFK-2 which decreases F26BP which increases activity of F16BP

inhibits PK which inhibits glycolysis and promotes gluconeogenesis

Question 27

How does glucagon inhibit glycogen synthesis

Answer 27

inhibits glycogen synthase

Question 28

How does glucagon activate glycogenolysis

Answer 28

activates glycogen phosphorylase

activates phosphorylase kinase

Question 29

How do glucagon and epi promote glucose homeostasis

Answer 29

raise BGL

promote hepatic glucneo

promote hepatic glycogen degradation

block hepatic utilization of glucose

inhibit hepatic glycolysis

inhibit hepatic glycogen synthesis

Question 30

What are the end products of pentose phosphate pathway and what can the be used for

Answer 30

Used in red blood cells

NADPH- lipid biosynthesis

Ribose-5-phosphate- used in synthesis of DNA, RNAm CoA, ATP, etc

intermediates can be further metabolized by glycolysis.

Question 31

What is the rate limiting enzyme in the pentose phosphate pathway?

Answer 31

Glucose-6-phosphate dehydrogenase

Question 32

What occurs in people who have a deficiency in the glucose-6-phosphate dehydrogenase enzyme?

Answer 32

can lead to drug induced hemolytic anemia

red blood cells cannot maintain adequate amounts of reduces NADPH, which is required to reduce glutathione and prevent oxidative damage in the red blood cell. increased reactive oxygen species and cannot detoxify H2O2

Question 33

Symptoms of glucose-6-phosphate dehydrogenase deficiency

Answer 33

X- linked pattern of inheritance

increased billiruin

decreased hemoglobin

increased hemolytic anemia.

Question 34

Intermediates of glycolysis that are generated by the pentose phosphate pathway

Answer 34

Glyceraldehyde-3-phosphate

Fructose-6-phosphate

Question 35

Enzymes activated by cAMP-dependent phosphrylation

Answer 35

phosphorylase kinase

glycogen phosphorylase

Question 36

enzymes inhibited by cAMP depdendent phosphorylation

Answer 36

glycogen synthase

pyruvate kinase

Question 37

enzymes indirectly inhibited by cAMP-dependent phosphorylation

Answer 37

PFK-1

Question 38

enzymes indirectly stimulated by cAMP-dependent phosphorylation

Answer 38

fructose 1,6 bisphosphatase

Question 39

enzymes inhibited by phosphorylation that is not cAMP depdendent

Answer 39

pyruvate dehydrogenase