Gluconeogenesis

Question 1

What is gluconeogenesis?

Answer 1

Net formation of glucose from pyruvate

Question 2

Gluconeogenic enzymes

Answer 2

• Glucose 6 phosphatase
• Fructose-1,6 bisphosphatase
• Pyruvate carboxylase and PEP carboxylase

Question 3

Location of first bypass (Pyruvate carboxylase+ATP)

Answer 3

Mitochondria

Question 4

Pyruvate carboxylase

Answer 4

Dissolved CO2 present in the bloodstream and within cells as bicarbonate ions are used
Enzyme contains biotin covalently bound to lysine residue
Other cofactors: Mg++, K+ and ATP

Question 5

Intermediate in Step 1

Answer 5

Oxaloacetate exits mitochondria– after it is converted to aspartate– via the malate-aspartate shuttle.

In cytosol, it converts back to oxaloacetate

Question 6

Other molecules can be gluconeogenic?

Answer 6

yes. Cytosolic oxaloacetate from other sources (for example, breakdown of amino acids in the cytosol) can be gluconeogenic

Question 7

Location of PEP carboxylase (+GTP)?

Answer 7

Primarily in the cytosol

Question 8

Requirements of PEPCK?

Answer 8

Mn++, K+, and GTP

Question 9

Fructose-1,6-bisphosphate

• Stimulators vs Inhibitors
• When does it operate?

Answer 9

• ALlosteric inhibitors: Fructose-2,6 bisphosphate
• Stimulators: ATP and citrate
• Operates effctively in resting muscle when [ATP] is high and [ADP, AMP] are low

Question 10

Glucose-6-phosphate

Answer 10

-Converts glucose-6-phosphate to glucose

Question 11

If ATP/ADP is high, oxaloacetate is used for…

If ATP/ADP is low, oxaloacetate is used for…

Answer 11

If ATP/ADP is high, oxaloacetate is used for gluconeogenesis

If ATP/ADP is low, oxaloacetate is used for… TCA cycle

Question 12

Activation of pyruvate carboxylase

Answer 12

Activated in the presence of Acetyl CoA

Question 13

Primary site for gluconeogenesis

Answer 13

Liver

Question 14

All the steps of gluconeogenesis occurs in the cytoplasm except…

Answer 14

Transformation of pyruvate to oxoaloacetate— occurs in the mitochondria

Question 15

Glucose-6-phosphate

Answer 15

• Located in the lumen of the endoplasmic reticulum
• Present in liver, kidney medulla
• Absent in other tissues, especially the CNS and erythrocytes where glucose is the primary fuel

Question 16

Allosteric stimulator of gluconeogenesis

Answer 16

ATP, citrate, acetyl CoA

Question 17

Fatty acids and gluconeogenesis

Answer 17

Fatty acid oxidation provides energy for gluconeogenesis

-During “fasting state”- blood glucose drops, liver can metabolize triglycerides thus providing acetyl CoA and ATP

Question 18

Glucogenic and metabolic intermediates

Answer 18

Glucogenic metabolites supply carbon for gluconeogenesis

• Carbohydrates if conerted to glycolytic intermediates
• Almost all amino acids when degraded, they yield TCA intermedoates
• some TCA intemediates– alpha ketoglutarate, succinyl CoA, oxaloacetate

Question 19

Lactic Acidosis

Answer 19

blood lactate level exceeds 2mM. Lactic Acid diffuses into the bloodstream
-Failure of gluconeogenesis,

Question 20

Cori cycle between erythrocytes and liver

Answer 20

In erythrocytes, pyruvate is converted to lactate by lactate dehydrogease
-Lactate is transported to the liver, where it is converted to pyruvate by LDH and used for gluconeogenesis

Question 21

Metabolism of Ethanol

Answer 21

Inhibits Glucogenesis

Ethanol ->Acetaldehyde ->Acetate+ NADH

• catalyzed by aldehyde dehydrogenase in the mitochondrial matrix
• acetate can be converted to acetyl-coA by thiokinase

Question 22

Thiokinase

Answer 22

used to convert actetate to Acetyl-CoA during metabolism of ethanol

Acyl CoA synth Synthetase

Question 23

Effects of ethanol metabolism on liver metabolism

Answer 23

Accumulation of NADH within hepatocytes
-Decreased liver NAD+ inhibits both gluconeogenesis from lactate, and fatty acid oxidation (both require NAD+ and produce NADH)

Result in increase in ratio of lactate/pyruvate (shifted to lactic acidosis)

• Also increase in malate/oxaloacetate ratio
• Because fatty acid oxidation is inhibited, triglyceride fats accumulate in the lier

Question 24

What is glycogen metabolism?

Answer 24

Storage form of glucose that is

• osmotically stable, as compared to free glucose
• can be quickly mobilized
• can be used for energy generation even in the absence of oxygen

Question 25

Glycogen synthesis is poceeded by:

Answer 25

“Activation” of glucose to form UDP-glucose which is then utilized to couple glucose residues to a growing glycogen polymer

Question 26

Glycogen synthase

Answer 26

Adds glucose residues from UDP-glucose ot the growing polymer, to form glycogen

-C1 end of the incoming glycogen rsidue reacts with C-4 of a glucose residue already on the chain, forming a alpha 1,4glycosidic linkage

Glycogen granule begins with the addition of a molecule of glucose (from UDP-glucose) to the carrier protein glycogenin using a specific glucose transferase enzyme
This takes place immediately after glycogenin protein synthesis
Glycogenin, acting as an enzyme, then appears to self-catalyze the addition of six or seven more glucose units.

Glycogen synthase continues to add glucose residues to hte glycoside chain which is on the glycogenin molecule. When the alpha 1,4-glycoside (amylose) chain reaches at least 11 residues, it then becomes a substrate for the branching enzyme, which removes a block of six or seven glucose residues and transfers it to a neighboring chain in an alpha 1,-6 glycosidic linkage

Question 27

UDP-glucose synthesis

Answer 27

Glucose -> Glucose-6-phosphate (using hexokinase)

Glucose-6-Phosphate -> Glucose-1-phosphate (using phosphoglucomutase)

glucose-1-P +UTP -> UDP-glucose + PPi (pyrophosphate)

Question 28

Glycogenolysis

Answer 28

Accomplished by the action of the enzyme glycogen phosphorylase, which cleaves 1,4-glycosiic bond by phosphorolysis, beginning at the C-6 ends of the glucose, releasing glucose 1-phosphate

Question 29

What activates glycogenolysis

Answer 29

The reaction is activated allosterically by AMP and in glucose and ATP

Question 30

Phosphoglucomutase

Answer 30

Glucose-1-P is converted to glucose-6-P by phospoglucomutase and may enter the glycolytic pahtway or be de-phosphorylated (in liver)

Also changes Glucose-1-phosphate to glucose-6P

Question 31

Debranching enzyme

Answer 31

Transfers 4 glucose residues from each branch to an adjacent branch, the enzyme can then remove the residue at the branch point by hydrolysis, releasing glucose

Question 32

Glyconeolysis in muscles

Answer 32

In muscles, the object of glycogenolysis is production of glucose-6-phosphate for immediate use in the production of ATP.

Question 33

Glyconeolysis in the liver

Answer 33

In the liver, the action of glucose-6-phosphatase can lead to the release of glucose into the bloodstream in order to maintain adequate blood glucose concentration

Question 34

Glycogen phosphorylase

Answer 34

Enzyme

Catalytic site contains pyridoxal phosphate (Vitamin B6)

Phosphorylated by phosphorylase kinase

Glycogen phosporylase is activated through phosphorylation by the enzyme phosporylase kinase (the active, phosphorylated form is phosporylase a)

The dephospho-form (phosphorylase b) is inactive

Question 35

What is an allosteric inhibitor of glycogen phosphorylase?

What activates glycogen phosphorylase?

Answer 35

Glucose inhibits

AMP phosphorylates

Question 36

Phosphorylase kinase

Answer 36

-large, multi-submit complex of the form alpha4, beta4, gamma4, delta4)

gamma subunit has catalytic activity

Others are regulatory subunits, which contain sites for phosphorylation

alpha and beta phosphorylated by protein kinase a

Question 37

Glucagon/epinephrine, insulin and glycogenolysis

Answer 37

Glucagon and epinephrine, which raise the level of cAMP promotes glycogenolysis

Insulin activates protein phosphatase, leading to a a decrease in cAMP, and inhibiting glycogen phosphorylase

Question 38

Regulation of glycogen synthase– G6P and phosporylation

Answer 38

G6P is an allosteric activator of glycogen synthase

GS isozyme is expressed in specific tissue:
-Muscle, kidney, intestinal mucosa
G6P is an allosteric activator of glycogen synthase

Regulated by phosphorylation

• The phosphorylated form is known as a synthase b, and is less active. Very sensitive to Glu-6-P
• stimulated by many kinases, including glycogen synthase kinase-3 and protein kinase a
• aided by glucagon and messenger molecules, cyclic AMP, calcium, diacylglycerol

Dephospho form, synthase a, is fully ctive and is less sensitive to Glu-6-P
-stimulated by insulin

Question 39

Glycogen degredation

Answer 39

Stimulated by glucagon and epinephrine

Question 40

Cyclin AMP

Answer 40

Activates protein kinase A, which results in the phosphorylation (and activation) of glycogen
phosphorylase as well as phosphorylation (and inactivation) of glycogen synthase. The overall result is
the mobilization of glucose. When the glucose concentration rises sufficiently, the phosphoprotein
phosphatase(s) cause dephosphorylation of regulatory enzymes and the process is reversed. (Here the
action of insulin comes into play.) Thus, at high glucose concentration in liver and in muscle (and
some other tissues), glycogen may be synthesized.

Question 41

Glycogen is primarily stored

Answer 41

In liver and muscle

Question 42

Glycogen granule consists of:

Answer 42

Glucose linked to carrier protein glycogenin by glucose transferase

Question 43

Where are glycogen granules made?

Answer 43

In the ER

Question 44

What activates G-6-Phosphotase?

Answer 44

Fructose-6-Phosphate

Question 45

Phosphoglucomutase

Answer 45

Converts Glucose-1-P to glucose-6-P

Question 46

Lactose is hydrolized in

Answer 46

The small intestine

Question 47

Fructose is broken down in

Answer 47

the liver

Question 48

Fructose is transferred by

Answer 48

GLUT-4

Question 49

Lactose is transported by

Answer 49

GLUT-2

Question 50

Galatose is phosphorylated by

Answer 50

lactokinase

Question 51

Galactose is channeled into glucose metabolism in the following steps:

Answer 51

Galactose 1-P
UDP-Galactose
UDP-Glucose
Glucose-1-P
Glucose-6-P

Question 52

Galactosemia

Answer 52

Results from deficiencyof galactos uridyl transferase

can lead to high blood levl of galactose

liver failure

Question 53

Galactisol

Answer 53

Lack of galactokinase causes accumulation of galactose, which can be reduced to galactisol. Accumulation of galactisol in the lens may lead to early cataract formation

Question 54

Sorbitals and diabetes

Answer 54

in tissues of diabetic individuals aldose reductase is induced by elevated glucose level and production of sorbitol can exceed the capacity of sorbitol dehydrogenase.
- Accumulation of sorbitol crystals in some tissues causes pathology: especially in the eye (lens) and kidney (glomerulus)
- Reduction of galactose to galactitol by aldose reductase may produce
similar pathology in individuals with galactosemia