Glycogen

Question 1

Glucose is preferred energy source for…

Answer 1

Brain and RBC

Question 2

Where is glucose obtained from?

Answer 2

Diet
GNG
Glycogen storage

Question 3

Dietary intake of glucose

Answer 3

• sporadic
• dependent on diet content
• not always a reliable source

Question 4

GNG glucose supply

Answer 4

• can provide sustained synthesis of glucose

- is somewhat slow in responding to falling blood glucose levels

Question 5

Glycogen storage supply of glucose

Answer 5

-mechanisms for storing a supply of glucose in a rapidly metabolized form

Question 6

Places you can find glycogen

Answer 6

• virtually any cell is capable of containing glycogen, but it VERY SMALL AMOUNTS
• Skeletal muscle(uses it as own fuel source, cannot exit into the blood stream)
• Liver(releases it into the blood to maintain blood glucose levels)

Question 7

Glycogen distribution in liver

Answer 7

• 100g

- 10% of the fresh weight of an adult well fed liver

Question 8

Glycogen distribution in skeletal muscle

Answer 8

• 400g

- 1-2% of the fresh weight of resting muscle

Question 9

Water and glycogen

Answer 9

• glycogen storage is associated with water storage
• water has 5X the weight of glycogen
• your weight can vary significantly based on the amount of glycogen you have stored

Question 10

degradation of glucose (liver and muscle cells)

Answer 10

• liver: when not getting glucose from diet, glycogen is degraded to glucose and released from liver and kidney(very small amount from kidney)
• muscle:in exercising muscle, glycogen is degraded to provide that tissue with energy
• glycogen serves as a glucose source in the gap between the fall of glucose levels after a meal and the onset of GNG(few hours)

Question 11

Glycogen structure

Answer 11

• HIGHLY branched polysaccharide made EXCLUSIVELY from alpha D glucose
• 10-40,000 glucose molecules per one glycogen
• primary bond is alpha 1-4 linkage(linear)
• every 8-10 glucosyl residues, there is a branch with alpha 1-6 linkage

Question 12

Discrete cytoplasmic granules

Answer 12

• beta particles
• associated with ALL the enzymes necessary for degradation and synthesis of glycogen
• all enzymes are associated all the time

Question 13

Step 1: Synthesis of Uridine diphosphate glucose

Answer 13

1. alpha D glucose —>glucose 6P SUPER FAST
2. glucose 6P—>Glucose 1P
3. UTP—->UDP
4. UDP glucose (highly energetic carrier to transport glucose)
   - if sufficient energy, it will save glucose for later
   - highly exergonic(drives the rest of synthesis)

Question 14

Step 2: Synthesis of a primer to initiate glycogen Synthesis

Answer 14

1. glycogen synthase CANNOT add UDP-glucose to a single glucose molecule, it can only ELONGATE primers
2. no primers? glycogenin serves as primer

Question 15

Glycogenin

Answer 15

• protein that can serve as primer if there are no primers available
• specific tyrosine residue serves as attachment point for glycogen synthesis
• catalyzes(acts as enzyme) the attachment reaction and the attachment for the next few UDP-glucose molecules via 1-4 glycosidic bonds
• after it binds 4, its a primer so glycogen synthase can take over

Question 16

Step 3: elongation of glycogen chains

Answer 16

Enzyme: glycogen synthase

• elongates existing primers
• transfers UDP-glucose to NON REDUCING end of primer
• forms alpha 1-4 bonds ONLY between UDP and primer
• rate limiting

Question 17

Step 4: Formation of branches

Answer 17

Enzyme: branching enzyme

• removes chain of 6-8 glucosyl residues from the end of glycogen chain(breaks 1-4 bond)
• attaches it to non terminal glucosyl residue by 1-6 bond
• functions as 4:6 transferase

Question 18

Why are branches important?

Answer 18

1. increases solubility of glycogen

2. increases surface area to make more reducing ends for faster degradation and synthesis

Question 19

Glycogenolysis

Answer 19

-degradation of glycogen
-NOT A REVERSAL OF GLYCOGENESIS
-gets its own set of enzymes(still on beta particles)
-4 step pathway
Shortening of chain
removal of branches
glucose1P—->glucose 6P
glucose 6p—->glucose(ONLY IN LIVER)

Question 20

Step 1 of degradation: shortening of chain

Answer 20

Enzyme: glycogen phosphorylase

• rate limiting step
• tissue specific isoforms for liver, muscle, and brain
• cleaves alpha 1-4 bonds from ends of chains
• uses INORGANIC PI to cleave AND attach itself to glucose
• yields glucose 1P
• stops when chain is only 4 glucosyl units from branch point
• requires PLP(vitamin B6) as coenzyme

Question 21

Limit dextrins

Answer 21

• branch point

- once it is down to 4 units, it does not fit in active site of enzyme anymore, so shortening of chains done

Question 22

Step 2 of degradation: removal of branches

Answer 22

Enzyme: debranching enzyme

• single protein, 2 activities
  4: 4 transferase activity: removes 3 of the 4 glucosyl residues by breaking 1-4 bond and transfers the to end of another chain by 1-4 bond

1:6 glucosidase activity: removes remaining residue attached by 1-6 bond and creates free glucose!

Question 23

Step 3 of degradation: Conversion of Glucose 1P to glucose 6P

Answer 23

Enzyme: phosphoglucomutase

• forms intermediate glucose 1-6 bisphosphate
• activated by glucose 1-6 bisphosphate
• ser-phosphorylation allows to put another on, then release ser and you only have one P

Question 24

Step 4 of degradation: glucose 6P—> glucose

Answer 24

Enzyme: Glucose 6-phosphatase

• liver and kidney
• sometimes in beta pancreatic cells, but much less
• ER transmembrane with active site facing ER lumen
• complex (3 transporters and catalytic subunit)
• G6PT1,2,3 and G6Pase alpha or beta

Question 25

degradation in lysosomes

Answer 25

Enzyme: lysosomal alpha 1-4 glucosidase

• housekeeping gene(always expressed)
• regulated at the level of protein expression
• optimal pH=4.5(acidic)
• only 1-3% of glycogen
• purpose of this pathway is not understood, but when it is missing, it is no bueno

Question 26

regulation of glycogenesis and glycogenolysis in liver

Answer 26

• glycogenesis is up in well fed state

- glycogenolysis is up during fasting

Question 27

Regulation of glycogenesis and glycogenolysis in muscles

Answer 27

• glycogenesis is up at rest

- glycogenolysis is up during exercise

Question 28

Hormonal regulation

Answer 28

to meet the needs of the body as a whole

Question 29

Allosteric regulation

Answer 29

to meed the needs of a particular tissue only

Question 30

glycogen phosphorylase in liver

Answer 30

• activated by epinephrine and glucagon
• inactivated by insulin
• inactivated by glucose6P,glucose, and ATP

Question 31

glycogen phosphorylase in muscle

Answer 31

• activated by epinephrine, high AMP and Ca2+

- inhibited by insulin and high ATP and Glucose 6P

Question 32

Glycogen synthase in liver and muscles

Answer 32

• both activated by insulin and Glucose 6P
• muscle inhibited by epinephrine
• liver inhibited by epinephrine and glucagon

Question 33

Von Gierke

Answer 33

-deficient: glucose 6-phosphatase
-Location: liver and kidnet
-Features: fasting, lactic acidosis, hypoglycemia, glucose cannot leave cell(goes to synthesize fats)
Structure:normal

Question 34

Pompe

Answer 34

Deficient: Lysosomal alpha 1-4 glucosidase

• Location: can effect all cells
• Features: muscle weakness, death at 2, cardiomegaly
• Structure: glycogen like material in inclusions

Question 35

Cori

Answer 35

• Deficient: Branching enzyme
• location: yea idk
• Features: mild hyperglycemia, liver enlargement
• Structure: short outer branches, single glucose residue at outer branch

Question 36

Andersen

Answer 36

Deficient: Branching enzyme (super rare)

• Location: synthesis of glycogen
• Features: infantile hypotonia, cirrhosis, death at 2
• Structure: very few branches, less soluble

Question 37

Mcardle

Answer 37

• Deficiency: Muscle glycogen phosphorylase
• Location:muscles only.(liver isoform is still gucci)
• Features: muscle cramps, weakness, myoglobinuria
• Structure: normal

Question 38

Hers

Answer 38

• Deficiency: hepatic glycogen phosphorylase
• Location: liver only(muscle isoform is still gucci)
• Structure: Normal