Regulation of glycogen metabolism

Question 1

Where’s glycogen stored?

Answer 1

Primarily found in liver (10% of weight) and muscle (1-2% wt)

Question 2

In what forms is glycogen stored?

Answer 2

Stored in granules:

• α-rosettes containing 20-40 β- particles
• β-particle contains 55k glu with 2k non-reducing ends

Question 3

How fast is glycogen depleted?

Answer 3

Depleted after 12-24h fasting in liver and 1h of strenuous exercise in muscle

Question 4

Why is glycogen is stored in far smaller amounts compared to fat?

Answer 4

It has high affinity for water-> bulky

Question 5

Which tissues/organs store glycogen?

Answer 5

Astrocytes, heart, adipose tissue store glycogen

Question 6

What does glycogenesis start with?

Answer 6

With UDP-glucose- precursor

It’s a sugar nucleotide

Question 7

Where does glycogenesis take place?

Answer 7

Can take place in any cells; but predominant in liver

Question 8

What has to be done to a precursor for glycogen chin to be made?
Why?

Answer 8

For glycogen chain to be synthesized, the precursor sugar has to be charged
Charged with nucleotide UDP
Charge is important for incorporation of glucose into the glycogen chain

Question 9

What is needed to charge glycogen precursor?

Answer 9

For charging to happen, NDP-sugar pyrophosphorylase is needed. Pro means 2

Question 10

How’s glycogen precursor charged?

Answer 10

NDP-sugar pyrophosphorylase uses glucose with phosphate on it and NTP (uracil triphosphate)
Condensation reaction occurs between a nucleoside triphosphate (NTP) and a sugar phosphate.
The negatively charged oxygen on the sugar phosphate serves as a nucleophile, attacking the aphosphate of the nucleoside triphosphate and displacing pyrophosphate-> 2 phosphate groups are removed- > UDP glucose is formed

Question 11

How is the reaction of charging glycogen precursor pulled forward?

Answer 11

The reaction is pulled in the forward direction by the hydrolysis of PPi into individual inorganic phosphate groups

Question 12

Net formula for charging glycerol precursors

Answer 12

Sugar phosphate + NTP-> NDP-sugar +2Pi

Question 13

What are the enzymes that are required to make glycogen?

Answer 13

• NDP-glucose pyrophosphorylase charges glycogen precursor
• Glycogenin starts polymerization process of NDP-sugar and also acts as a primer
• Glycogen synthase further extends glycogen chain. BAsically continues the work of glycogenin
• Glycogen branching enzyme (amylo (1->4) to (1->6) transglycosylase): makes α1->6 bonds bonds
  found at the branch points of glycogen

Question 14

What’s glycogenin?

Answer 14

It’s a protein that is both a primer on which new chains are assembled and the enzyme that catalyzes polymerization

Question 15

What are the steps of making glycogen

Answer 15

1. UDP-glucose pyrophosphorylase adds a NTP group to a sugar, charging it and forming an NDP-sugar- activation
2. Glycogenin acts as a primer and accepts glucose from UDP-Glc. Glucose residue is transferred from UDP-glucose to the hydroxyl group of Tyr of glycogenin glucosyltransferase activity
3. The new chain is extended by the sequential addition of seven more glucose residues, each derived from UDP-glucose. This is catalyzed by chain-extending activity of glycogenin
4. Glycogen synthase takes
   over, which promotes the transfer of the glucose residue from UDP-glucose to a nonreducing end of a branched glycogen molecule . Forms 1-4 bonds
   Glycogenin remains buried within the β particle, covalently attached to the single reducing end of the glycogen molecule

Question 16

How is glucose residue attached to glycogenin

Answer 16

Through glycosyl transferase activity- the hydroxyl group of Tyr on UDP-glucose attack Tyr of glycogenin resulting in a glycosylated Tyr residue
Then by glycogen synthase

Question 17

How’s 1->4 glycosidic link formed?

Answer 17

After Tyr residue of glycogenin was glycosylated, the C-1 of another UDP-glucose molecule is now attacked by the C-4 hydroxyl group of the terminal glucose, and this sequence repeats 6 times to form a glycogen molecule of six to eight glucose residues attached by (1->4) glycosidic linkages.
4th carbon of last glucose attacks first carbon of incoming glucose

Question 18

What bond does glycogen synthase form?

Answer 18

1->4 glycosidic linkages

Question 19

What are the 4 phases of glycogen synthesis?

Answer 19

Step 1: Formation of UDP-glucose (NDP-sugarpyrophosphorylase)
Step 2: Initial short chain synthesis (Glycogenin)
Step 3: Elongation (Glycogen synthase)
Step 4: Branching (Glycogen-branching enzyme)

Question 20

What are the enzymes of glycogenolysis?

Answer 20

1. Glycogen phosphorylase
2. Glycogen debranching enzyme
3. Phosphoglucomutase

Question 21

What does Glycogen phosphorylase depend on?

Answer 21

Glycogen phosphorylase depends on Pyridoxal phosphate cofactor

Question 22

What does glycogen phosphorylase do?

Answer 22

Glycogen phosphorylase catalyzes the reaction in which an (1->4) glycosidic linkage between two glucose residues at a non-reducing end of glycogen (extreme end) undergoes attack by inorganic phosphate (Pi), removing the terminal glucose residue as -D-glucose 1-phosphate. This phosphorolysis reaction is repetitive; the enzyme removes successive glucose residues until it reaches the fourth glucose unit from a branch point
Breaks 1->4 bond

Question 23

What’s special about glucose phosphate produced during glycogen phosphorylase catalyzed reaction?

Answer 23

D-glucose 1-phosphate is produced which isn’t very useful- usually should be G6P
As it is phosphorylated it cannot leave the cell and enter the metabolic pathways as the phosphate is on the wrong carbon

Question 24

How does glycogenolysis occur at a branch?

Answer 24

When glycogen phosphorylase arrives to a branch, each of each contains about 4 glucose units, it reaches its limit
After a debranching enzyme comes in
Has 2 functions:
- Glycosyl transferase function- shifts a block of 3 glucose units out of 4 that are left to one other branch- using 1->4 linkage> Creates new longer glycogen chain with only one glucose sticking out in 1->6 linkage
- Glucosidase function- debranching enzymes releases oen last left-over glucose as free glucose by the debranching enzyme’s (1->6) glucosidase activity. This glucose is not phosphorylated

Question 25

How is D-glucose 1-phosphate produced by glucogenolysis made useful again?

Answer 25

Phosphoglucomutaseconverts it into G6P

Question 26

How does glycogen synthase work?

Answer 26

Glycogen synthase requires an existing short chain created by glycogenin- continues work of glycogenin
Requires a UDP glucose; creates 1,4-glycosidic bond
4th carbon of last glucose attacks first carbon of incoming glucose

Question 27

Which type of bond does glycogen synthase create?

Answer 27

1-> 4 glycosidic bond

Question 28

What’s glycogen branching enzyme?

Answer 28

An enzyme that creates branches
Breaks a 1->4 bond between 4th and 5th carbon in glycogen core are bring is too a first glucose unit. creating a new non-reducing end and a 1-> 6 linkage

Question 29

Glycogen branching enzyme can only work from _th glucose onwards only from a core or a branch

Answer 29

Glycogen branching enzyme can only work from 5th glucose onwards only from a core or a branch

Question 30

What does glycogen branching enzyme increase?

Answer 30

Water solubility
Number of non-reducing ends->more ends, more glucose synthesizing/ glycogen lysing enzymes can attack glycogen to make more glucose

Question 31

What’s the other name for glycogen branching enzyme?

Answer 31

Amylo (1-4) to (1-6) transglycosylase

Question 32

What are the 4 step of gluconeogenesis?

Answer 32

vStep 1: Formation of UDP-glucose (NDP-sugarpyrophosphorylase)
vStep 2: Initial short chain synthesis (Glycogenin)
vStep 3: Elongation (Glycogen synthase)
vStep 4: Branching (Glycogen-branching enzyme)

Question 33

What are the enzymes of glycogenolysis?

Answer 33

1. Glycogen phosphorylase
2. Glycogen debranching enzyme
3. Phosphoglucomutase

Question 34

What does Glycogen phosphorylase depend on?

Answer 34

Glycogen phosphorylase depends on Pyridoxal phosphate cofactor

Question 35

What’s the function of Glycogen phosphorylase?

Answer 35

Glycogen phosphorylase catalyzes the reaction in which an (1->4) glycosidic linkage between two glucose residues at a nonreducing end of glycogen (extreme end) undergoes attack by inorganic phosphate (Pi), removing the terminal glucose residue as -D-glucose 1-phosphate. This phosphorolysis reaction is repetitive; the enzyme removes successive glucose residues until it reaches the fourth glucose unit from a branch point

Question 36

What kind of bond does glycogen phosphorylase break?

Answer 36

1->4

Question 37

What is the stop point of glycogen phosphorylase?

Answer 37

When it reaches a branch

Question 38

What’s the downside of glucose phosphate produced by glycogen phosphorylase?

Answer 38

It produces glucose 1-phosphate which As it is phosphorylated it cannot leave the cell and enter the metabolic pathways as it has a phosphate attached to a wrong carbon

Question 39

How does glycogenolysis occur at a branch?

Answer 39

glycogen phosphorylase stops working
Debranching enzyme comes in
Has 2 functions:
Glycosyl transferase function- shifts a block of 3 glucose units out of 4 that are left to one other branches- using 1->4 linkage> Creates new longer glycogen chain with only one glucose sticking out in 1->6 linkage
Glucosidase function- debranching enzymes releases glucose as free glucose left-over through debranching enzyme’s (1->6) glucosidase activity. This glucose is not phosphorylated

Question 40

How’s the problem of glucose 1-phosphate resolved?

Answer 40

Phosphoglucomutase transfers phosphate group from carbon 1 to carbon number 6
Doesn’t add phosphate group, just transfers

Question 41

Is Phosphoglucomutase activity reversible?

Answer 41

Its function is reversible- can convert glucose-1-phosphate back and forth to glucose-6-phosphate

Question 42

What’s the fate of G6P in muscles and liver after being produced by glycolysis

Answer 42

In muscles this glucose-6-phsophate is ready to do work
In liver- liver is not supposed to use glucose. It is supposed to release it, so when glycogen lysis occurs in the liver, the phosphate group needs to be removed from the glucose- Glucose-6-phosphatase

Question 43

What’s the function of glucose-6-phosphatase?

Answer 43

Removes a phosphate group from G6P so it can be released from liver into circulation

Question 44

What are the 3 forms of glucose phosphate that are interconvertible thanks to glucose-6-phosphatase

Answer 44

Glucose 1-phosphate
Glucose 6-phosphate
Glucose 1.6-bisphosphate (extra PO3 group is attached to Ser residue of glucose-6-phosphatase)

Question 45

Which GLUT transporter is expressed in liver and muscles

Answer 45

Liver -GLUT2

Muscles-GLUT4

Question 46

Is glucose 6-phosphatase expressed in muscles?

Answer 46

Glucose 6-phosphatase is not expressed in muscles

Question 47

How’s glucose 6-phosphate treated in the liver?

Answer 47

Glucose-6-phosphatase removes the phosphate group from glucose
from glucose 6- phosphate - it is converted to regular glucose and it is now able to pass through a glucose transporter - GLUT2

Question 48

What is the last enzyme of glycogenolysis?

Answer 48

Glucose-6-phosphatase

Question 49

Describe GLUT4 activity

Answer 49

GLUT4 that is present in the muscles s sensitive to insulin (insulin dependent). Insulin brings GLUT4 to the cell membrane- it is only available when insulin is present
GLUT4 doesn’t’ allow glucose to leave muscle cells into circulation. Glucose only enters the muscles

Question 50

What happens to glucose in regulation of glycogen metabolism when it needs to be stored?

Answer 50

• When glucose needs to be stored it is converted to glucose 6-phosphate by hexokinase
as it can then enter glycogen pathway

Question 51

Glucose 6-phosphate can always be mutated to __ by _ (irreversible/reversible)

Answer 51

Glucose 6-phosphate can always be mutated to glucose 1-phosphate by Phosphoglucomutase (reversible)

Question 52

UDP-glucose can be turned into _ using __ and __

Answer 52

UDP-glucose can be turned into glycogen using glycogenin, glycogen synthase and glycogen branching enzyme

Question 53

Glycogen can then be converted back to glucose 1-phosphate by __, __, and __

Answer 53

Glycogen can then be converted back to glucose 1-phosphate by glycogen phosphorylase, glycogen debranching enzyme, and phosphoglucomutase

Question 54

glucose 1-phosphate then can be converted to __ by __

Answer 54

glucose 1-phosphate then can be converted to glucose by glucose 6-phosphatase

Question 55

What is the function of Glycogen phosphorylase?

Answer 55

Glycogen phosphorylase converts glycogen to glucose 1-phosphate

Question 56

How’s glycogen phosphorylase regulated?

Answer 56

Its activity depends on whether or not its phosphorylated
Phosphorylated= more active. Non-phosphorylated=non-functional
There’s a specific kinase that phosphorylates phosphorylase- phosphorylase b kinase- increases activity of Glycogen phosphorylase
B kinase is activated by various ligands: cAMP, PKA, glucagon (GPCR)

Protein phosphatases (PP1) remove phosphates from target proteins -> inactivates Glycogen phosphorylase
PP1 is s

Question 57

What are the ligands of phosphorylase b kinase?

Answer 57

cAMP, PKA, glucagon (GPCR), epinephrin

Question 58

How’s glycogen phosphorylase affected in resting and contracting muscles?

Answer 58

In contracting muscles, where there’s a requirement of glucose for glycolysis Glycogen phosphorylase is active and phosphorylated
In resting muscles Glycogen phosphorylase is inactive and dephosphorylated - no glucose is required for glycolysis so it is stored

Question 59

Describe hormonal regulation of glycogenolysis in mycotes

Answer 59

Muscles
Ligand- epinephrine
Receptor- GPCR
GPCR+ligand-> cAMP->PKA-> phosphorylase kinase-> glucose 6-phosphate is released from glycogen-> glycolysis

Question 60

Describe hormonal regulation of glycogenolysis in Hepatocytes

Answer 60

Liver
Ligand- Glucagon
Receptor- GPCR
GPCR+ligand-> cAMP->PKA-> phosphorylase kinase-> glucose 6-phosphate is released from glycogen-> free glucose-> circulation

Question 61

What are the hormones that control glycogenolysis?

Answer 61

Liver- glucagon

Muscles- epinephrine

Question 62

What does function of glycogen synthase depend on?

Answer 62

Function of glycogen synthase depends on whether or not is phosphorylated
Phosphorylated= inactive
Dephosphorylated= active

Question 63

How does insulin affect glycogen synthase?

Answer 63

Insulin binding to its receptor activates a tyrosine protein kinase in the receptor, which phosphorylates insulin receptor substrate-1 (IRS-1).
The phosphotyrosine in this protein is then bound by PI-3K, which converts PIP2 in the membrane to PIP3.
A protein kinase (PDK-1) that is activated when bound to PIP3 activates a second protein kinase (PKB), which phosphorylates GSK3 inactivating it.
The inactivation of GSK3 allows phosphoprotein phosphatase 1 (PP1) to dephosphorylate and thus activate glycogen synthase.
In this way, insulin stimulates glycogen synthesis

Question 64

Which 2 substances activate glycogen synthase

Answer 64

Insulin and glucose/G-6-P stimulates dephosphorylation of glycogen synthase, activating it
Glucagon and epinephrine inhibits dephosphorylation of glyc

Question 65

Which 2 substances inactivate glycogen synthase

Answer 65

Glucagon and epinephrine inhibits dephosphorylation of glycogen synthase, inactivating it

Question 66

High blood glucose- events

Answer 66

High blood glucose results in insulin releases
In hepatocytes:
- Insulin inactivates GSK3, acting through a cascade and
activates a protein phosphatase, e.g PP1.
These two actions activate glycogen synthase.
PP1 also inactivates glycogen phosphorylase α and phosphorylase kinase by dephosphorylating both-> glycogen breakdown is stopped.
Glucose enters the hepatocyte through the high-capacity transporter GLUT2, always present in the plasma membrane-> increase in glucose blood concentration-> inreased expression of glycolytic enzymes (hexokinase II, PFK-1, pyruvate kinase). In cells where these enzymes are expressed, glycolysis increases.

Question 67

Low blood glucose events

Answer 67

The drop in blood glucose triggers the release of glucagon which is a GPCR ligand. It acts through cAMP, which, acting through a cascade activates PKA.
PKA mediates all the effects of glucagon. It phosphorylates phosphorylase
kinase, activating it and leading to the activation of glycogen phosphorylase-> increases glycogen breakdown. PKA phosphorylates glycogen synthase, inactivating it and blocking glycogen synthesis.
It phosphorylates PFK-2/FBPase-2, leading to a drop in the concentration of the regulator fructose
2,6-bisphosphate, which has the effect of inactivating the glycolytic enzyme PFK-1 and activating the gluconeogenic
enzyme FBPase-1-> glycolysis is stopped. PKA also phosphorylates and
inactivates the glycolytic enzyme pyruvate kinase-> glycolysis is stopped

Question 68

This release of glucose is possible only in liver and kidney, because other tissues lack __

Answer 68

This release of glucose is possible only in liver and kidney, because other tissues lack glucose 6-phosphatase

Question 69

Difference in the regulation of carbohydrate metabolism in liver and muscle.

Answer 69

In liver, either glucagon (indicating low blood glucose) or epinephrine (signaling the need to fight or flee) has the effect of maximizing the output of glucose into the bloodstream. In muscle, epinephrine increases glycogen breakdown and glycolysis, which
together provide fuel to produce the ATP needed for muscle contraction.

Question 70

Epinephrine and Glucagon GPCR signaling increases __ and __

Answer 70

Epinephrine and Glucagon GPCR signaling increases glycogenolysis and glucose release.

Question 71

In case of excess glucose, liver can use it for __

Answer 71

In case of excess glucose, liver can use it for glycolysis

Question 72

Describe pyruvate kinase specific for the liver

Answer 72

Pyruvate kinase L specific to liver is inactivated by phosphorylation. This doesn’t occur in the muscles-> a lot of glucose is created in the muscles from the pyruvate that is released

Question 73

How physiology of skeletal muscle differs from

that of liver that i simportant in metabolic regulation?

Answer 73

• Muscles lack glucagon receptor
• Muscle isoform Pyruvate kinase is not phosphorylated by PKA -> doesn’t become inactivated
• Muscle does not produce F26BP