(L3) - Carbohydrate Metabolism

Question 1

What cell types exclusively use glucose as their fuel source?

Answer 1

-RBCs -Brain (non-starvation)

Question 2

What enzyme is used for cells that lack mitochondria?

Answer 2

LACTATE

• critical for RBC that lack a mitochondria as they can replenish their NAD supply
• also important in cells that are in overworked muscles that lack O2

Question 3

What is the net yield of glycolysis per molecule of glucose? L3 S13 LO1

Answer 3

-2 ATP -2 NADH -2 Pyruvate

Question 4

What are the different types of glucose transporters, where are they found and what are their affinities? L3 S10-11 LO1

Answer 4

GLUT1: -found in all cells; especially high in RBCs and brain -high affinity (Km: 1mM)

GLUT2: -found in liver and pancreas -low specificity (Km: 10mM)

GLUT3: -found in neurons -high affinity (Km: 1mM)

-Glut 1-3 do passive transport

GLUT4: -found in skeletal muscle, adipose tissue, and heart -intermediate affinity (Km: 5mM) -INSULIN REGULATED vesicle fusion

Question 5

Explain glut 4 placement

Answer 5

-insulin signaling causes the fusion of vesciles with the plasma membrane and placement and insertion of the transporter in the membrane.

Question 6

What is the first phase of glycolysis and what occurs during it?

Answer 6

Investment -use 2 ATP to trap glucose Net reaction: Glucose + 2 ATP -> fructose 1,6-BP

Question 7

What does hexokinase do? L3 S14 LO1

Answer 7

Converts glucose to glucose 6-P using ATP Found in all cells

Inhibited by glucose-6P (feedback inhibition)

Question 8

What does glucokinase do? L3 S14 LO1

Answer 8

Converts glucose to glucose 6-P using ATP Found only in the liver and pancreas

No feedback inhibition by glucose 6-P

• stimulated by: Glucose, F-1-P, insulin
• inhibited by: glucagon and F-6-P

Question 9

What does phosphofructokinase do? L3 S14 Describe its regulation step by F2,6 bp.

Answer 9

RATE LIMITING Converts fructose 6-P to fructose. 1,6-BP Inhibited by ATP and citrate. And stimulated by AMP and F 2,6 BIS phosphate.

Question 10

What is the second phase of glycolysis and what occurs during it? L3 S15 LO1

Answer 10

Splitting -goes from 1 6C molecule to 2 3C molecules Net reaction: -Fructose 1,6-BP -> 2 Glyceraldehyde 3-P

Question 11

What does aldolase do? L3 S15 LO1

Answer 11

Splits fructose 1,6-BP into DHAP and G3P

Question 12

What does triose phosphate isomerase do? L3 S15

Answer 12

Interconverts DHAP and G3P

Glyceraldehyde 3 Phosphate is used in next step of glycolysis

Question 13

What is the third phase of glycolysis and what occurs during it? L3 S16 LO1

Answer 13

Recoup/payoff -4ATP and 2NADH are generated -pyruvate is generated

Net reaction: -2 G3P + 4 ADP + 2 NAD+ -> 2 Pyruvate + 4 ATP + 2 NADH

Question 14

What does glyceraldehyde 3-P dehydrogenase do? L3 S16 LO1

Answer 14

Converts G3P to 1,3-BPG Generates NADH

Question 15

What does phosphoglycerate kinase do? L3 S16 LO1

Answer 15

Converts 1,3-BPG to 3-phosphoglycerate Generates ATP

Question 16

What does pyruvate kinase do? L3 S16 LO1

Answer 16

Converts phosphoenolpyruvate to pyruvate Generate ATP

• Activated by F1,6BP and insulin
• Inhibited by ATP, Alanine, and glucagon
• Glycolysis is inhibited
• Phosphoenolpyruvate (PEP) enters gluconeogenesis
• High insulin: stimulates protein phosphatase, dephosphorylation of PK to activate it
• High glucagon: cAMP activates PKA, phosphorylation, PK inhibited.

Question 17

What are the regulated steps of glycolysis? L3 S19 LO1

Answer 17

-hexokinase/glucokinase -phosphofructokinase-1 -pyruvate kinase

Question 18

How is hexokinase/glucokinase regulated? L3 S20-21 LO1

Answer 18

Hexokinase is inhibited by G6P Glucokinase is minimally affected by G6P

Question 19

How is PFK-1 regulated? L3 S22-23 LO1

Answer 19

• High insulin/low glucagon: activate protein phosphatases –> dephosphorylate PFK-2/FBPase-2 (triggers kinase activity), producing F2,6BP which activates PFK-1
• High glucagon/low insulin: induces high [cAMP], activate protein kinase A, phosphorylates PFK-2/FBPase-2 (triggers phosphorylation activity), reduces PFK-1 activity.

Question 20

• How is pyruvate kinase regulated? L3 S25 LO1

Answer 20

Activated by F1,6BP and insulin (activation of phosphatases)

Inhibited by ATP, alanine and glucagon (activation of PKA)

Question 21

What is Tarui disease? L3 S24 LO1

Answer 21

GSD VII Deficiency in PFK-1 (rate limiting enzyme of glycolysis). Causes hemolytic anemia and high bilirubin and jaundice.

Question 22

What are the possible fates of G6P? L3 S27-28

Answer 22

• Glycolysis (pyruvate)
• Glycogen synthesis (glycogen (convert to G-1-P) )
• galatose matabolism ((convert to G-1-P))
• Pentosephosphate pathway (ribose)

Question 23

Glycolysis steps

Answer 23

1) Glucose + ATP –> G-6-P + ADP + H+ via hexokinase or glucokinase
IRR

3) f-6-p + atp –> fructose 1,6 bisohspate + ADP + H+ via PFK1
RLS IRR

6) Glyceraldehyde 3 phosphate + Pi + NAD –> 1,3 bisphosphoglycerate + NADH + H+ via glycerate 3 phosphate dehydrogenase
7) 1,3 bisphosphoglycerate + ADP –> 3 phosphoglycerate + ATP

via phosphoglycerate kinase

10 PEP + ADP –> pyruvate + ATP
by pyruvate kinase
IRR

Question 24

Hexokinase vs Glucokinase

Answer 24

hexokinase is (↓ Km) but ↓ capacity (↓ Vmax) in almost all tissues, substrate is glucose and other sugars, inhibited by g-6-p

glucokinase is ↓ affinity but ↑ Vmax, pancreatic β-cells and liver, substrate is glucose only, weakly inhibited by G-6-P

Question 25

How do defects in glycolysis affect RBCs? L3 S31-32 LO1

Answer 25

Glycolysis is only means of ATP production for RBCs Failure of glycolysis leads to hemolytic anemia.

Question 26

What is Fanconi-Bickel syndrome? L3 S37 LO1

Answer 26

Mutation in GLUT2 transporter (liver and pancreatic β cells

• Unable to take up glucose, fructose and galactose
• autosomal recessive

Question 27

gluconeogenesis steps

Answer 27

1) Pyruvate + 2 CO2 + 2 ATP + 2 H2O –> OAA + ADP + Pi + 2H+ via pyruvate carboxylase
- in mitochondria

3) OAA + GTP <–> PEP + GDP + CO2 via Phosphoenolpyruvate carboxykinase (PEPCK)

(THESE STEPS BYPASS PK)

5) 3 PHOSPHOGLYCERATE + ATP <–> 1,3 bisphosphglycerate + ADP via phosphoglycerate kianse
6) 1,3 bisphosphoglycerate + NADH + H+ <—> G-3-P + NAD+ VIA glyceraldehyde dehydrogenase
9) fructose 1,6 bisphosphate + H20 –> F-6-P via fructose 1,6 bisphosphatase

(bypass step 3)

10) g-6-p to glucose via glucose 6 phosphatase

Question 28

What factors regulate glycolysis and gluconeogenesis? L3 S44 LO2

Answer 28

• High energy signals (ATP, glucagon) inhibit glycolysis and stimulate gluconeogenensis
• Low energy signals (ADP/AMP, insulin) stimulate glycolysis and inhibit gluconeogenesis

Question 29

What does pyruvate carboxylase do? How is it regulated, and what cofator is needed with it?

Answer 29

Converts pyruvate to oxaloacetate

- stimulated by acetyl CoA and cortisol

-inhibted by ADP

• it is a mitochondrial enzyme and is ATP and Co2 dependent
• requires a Biotin cofactor

Question 30

How do you get OAA out of the mitochondria?

Answer 30

–Mitochondrial membrane impermeable to oxaloacetate (OAA)

–OAA reduced to malate by mitochondrial malate dehydrogenase

–Malate transported to cytoplasm via malate shuttle

–Re-oxidized to OAA by cytosolic malate dehydrogenase

Question 31

What does phsophoenolpyruvate carboxykinase do? L3 S47 LO2 What is it regulated by?

Answer 31

Converts oxaloacetate to PEP using GTP

regulated by: trancription activated by cortisol, glucagon, and thyronine

Question 32

What does fructose 1,6-bisphosphatase do? L3 S47 LO2

Answer 32

RATE LIMITING Converts fructose 1,6-bisphosphatase to fructose 6-P

• stimulated by citrate and cortisol
• inhibited by AMP F,2,6BP

Question 33

What does glucose 6-phosphatase do? Where is it found? What regulates it?

Answer 33

Dephosphorylates G6P to glucose ONLY found in liver, kidneys, SI, and pancreas.

-stimulated by cortisol

Question 34

What is GLUT7? L3 S48 LO2

Answer 34

• Removes glucose from the ER after being produced by glucose 6-phosphatase
• Explained:
  
  • glucose 6-phosphatase, is located in the lumen of the endoplasmic reticulum
  • -Glucose 6-phosphatase has 3 subunits: a catalytic unit, a glucose 6-phosphate and Pi antiporter, and a glucose transporter (GLUT7)
  • -Glucose 6-phosphate cleaved to form glucose. Then it is is transported into the ER by the G6P transporter, and glucose transported back to the cytoplasm by the GLUT 7

Question 35

What is the Cori cycle? L2 S49 LO2

Answer 35

Links the lactate produced from anaerobic glycolysis in RBC and exercising muscle to gluconeogenesis in liver.

It does two things:

• Prevents lactate accumulation
• Regenerates glucose

Question 36

What is Von Gierke disease? L3 S54 L2

Answer 36

GSD1a Deficiency in glucose 6-phosphatase

-Results in inefficient release of glucose from the liver and build of of stored glycogen in liver

Question 37

What is the significance of fructose metabolism on glycolysis? L3 S63 LO3

Answer 37

Fructose enters glycolysis as G3P, after rate limiting step. High consumption of fructose is linked to obesity because of this.

Question 38

What is the significance of galactosemia? L3 S65 LO3

Answer 38

Deficiency in glucose 1P uridyltransferase (GALT): classical

• Leads to accumulation of galactitol
• Classic galactosemia: Failure to thrive,

Deficiency in Galactokinase

•Nonclassical variant (Type II): Leads to accumulation of galactose and galactitol in blood and urine

-accumulation of galactitol in lens of eyes leads to cataracts

Question 39

What is the rate limiting step of the PPP? L3 S69-70 LO4

Answer 39

Glucose 6-phosphate dehydrognase

Question 40

What is the first step of the PPP? L3 S68 LO4

Answer 40

Oxidative phase Contains rate limiting step Produces NADPH and ribulose 6-phosphate

Question 41

What is the second step of the PPP? L3 S68 LO4

Answer 41

Non-oxidative Products shunt to glycolysis/gluconeogenesis or nucleotide synthesis

Question 42

What are the main products of PPP and what are they used for? L3 S73 LO4

Answer 42

Ribose 5-P: -used in nucleotide synthesis NADPH: -Used as a reducing agent in anabolic reactions

Question 43

How do fed and fasting states regulate glycogenesis and glycogenolysis? L3 S87 LO5

Answer 43

Fed state: -high insulin and glucose -trigger dephosphorylation of glycogen synthase (activating) and glycogen phosphorylase (inactivating) Starving state: -high glucagon, low glucose -triggers phosphorylation of glycogen synthase (inactivating) and glycogen phosphorylase (activating)

Question 44

Explain how gluokinase is regulated

Answer 44

• F6P production promotes it to be translocated to the nucleus and is sequestered by GK regulatory protein
• glucose and fuctose 1 phosphate will promote disociation and then it is transolcated back into the cytoplasm
• insulin induces synthesis of GK and glucagon inhibits synthesis.

Question 45

Defects in glycolytic enzymes cause what?

Answer 45

Ineffecctive glycoysis, most defects will cause hemolytic anemia bc RBC do not have mitochondrias.

-failure of Glycolysis will disrupt ion gradients powered by ATP which reduces cell viability that will edstroy and then cause hemolytic anemia.

Question 46

Hemolytic anemia

Question 47

Decribe the effect of the brain and glucose

Answer 47

• Brain cells are particularly dependent on glucose because glucose is the preferred fuel for neurons and one of the only fuel molecule that can cross the blood brain barrier (BBB).
• during fasting and mild starvation you will start gluconeogensis
• during extreme starvation brain cells will start making ketone bodies for fuel (beta hydroxybutyrate)

Question 48

what are clinical markers for hemolytic anemia?

Answer 48

• elevated lactate dehyrogenase in plasma and unconjugated bilirubin
• caused as ATP dependent ion pumps are not working thus Na builds up which causes swelling and lysis

Question 49

Gluconeogenesis occurs where?

Answer 49

occurs in liver, kidney, and SI

-precursors are lactate, AA, and glycerol

Question 50

List the precursors of gluconeogenesis

Answer 50

• fructose
• galactose
• glycogen
• glycerol
• propionate
• lactate
• alanine
• amino acids except leucine and lysine

(FGGGPLA)

Question 51

F1,6 bisphosphatase deficiency

Answer 51

• Similar to Tarui disease in glycolysis
• Presents in infancy or early childhood
• Hypoglycemia, lactic acidosis, ketosis, apnea, hyperventilation (after fructose, glycerol or sorbitol)

Question 52

Describe the absorption of fructose, galactose and glucose

Answer 52

• Fructose uptake is by GLUT 5
• glucose and galactose uptake is by SGLT 1 VIA SECONDARY ACTIVE TRANSPORT

-glut 2 will then transport all three into the blood and glut 5 will just transfer fructose again

Question 53

Polyol Pathway

Answer 53

2 step pathway that produces glucose to fructose (how sperm makes fructose because it relies on that)

• Glucose reduced to sorbitol by Aldose reductase (NADPH –> NADP+)
• Sorbitol oxidized to fructose by Sorbitol dehydrogenase (NAD –> NADH)

Question 54

Decribe Sx of Sorbitol accumulation

Answer 54

• Cells that lack sorbitol dehydrogenase (kidneys, retina, Schwann cells) can accumulate sorbitol, which triggers water influx and causes swelling.
• Manifests as retinopathy, cataracts and peripheral neuropathy

Question 55

Fructose metabolism steps

Answer 55

1) fructose —> F-6-P (ENTERS GLYCOLYSIS) via hexokinase
1. a) fructose + ATP –> F-1-P + adp via fructokinase

2) f-1-p –> Glyceraldehyde and DHAP
via aldose B (found in liver) (deficiency is called heridtary fructose intolerance)

…. feed into triacylglyceol synthesis

Question 56

Why is fructose metabolism faster?

Answer 56

• Bypasses rate limiting step of glycolysis
• Due to absence of PFK-1
• They feed into glycolysis at an un checked fashion
• the excess a-coa will be convereted into FA causing obesity
• liver will also accumulate FA resulting in fatty liver

Question 57

Galactose metabolism

Answer 57

1) Galactose can turn into galataciol via aldose reducatse
1. a) Galatose + ATP –> Galatose 1 phosphate + ADP via galatokinase
2) galatose 1-p + udp glucose —> Glucose 1 p + udp galatose via Glucose 1P uridyltransferase (GALT)

Question 58

What is the RLS of galatose metabolism

Answer 58

glucose 1P uridyltransferase (GALT)

Question 59

What does a defiecieny of aldose B cause?

Answer 59

hereditary fructose intolerance

Question 60

What is cateracts caused by?

Answer 60

Cataract is the clouding of the normally clear lens of the eye.

If the transferase is not active in the lens of the eye, the presence of aldose reductase causes the accumulating galactose to be reduced to galactitol.

Question 61

PPP overview

Answer 61

–Produces no energy

–Produces the sugar for DNA and RNA formation

–Oxidation of G6P to Ribulose 5-P

–Reduction of NADP+ to NADPH

–Irreversible oxidative step (catabolic) and

–reversible non-oxidative step (anabolic)

Question 62

PPP – Oxidative Phase

Answer 62

–2 enzymatic steps, produce 2 NADPH and 1 CO2

1) G6P dehydrogenase: rate-limiting step, reduces NADP+ to NADPH, oxidizes G6P to 6-phosphoglucono-δ-lactone

(inhibited by NADPH)

2. Form ribulose 5P via 6-Phosphogluconate dehydrogenase (decarboxylation):
   - Reduces NADP+ to NADPH
   - Removes a carbon and forms CO2

Question 63

G6PD deficiency

Answer 63

affects a significant population, particularly those of African descent. Presentation of hemolytic anemia when NADPH need is elevated (infection, oxidizing medications).

Question 64

What does NADPH help for

Answer 64

regenerating an antioxidant

–NADPH regenerates glutathione (G-SH), an important antioxidant, detoxifies H2O2 with glutathione reductase

Question 65

PPP – Non-oxidative Phase

Answer 65

• A series of reversible reactions
• End products shunt to glycolytic, gluconeogenic or nucleotide synthesis pathways
• this is where ribose can be formed

Question 66

When different metabolites are needed from the PPP what happen?

Answer 66

• high demand of Ribose 5P: ox phase is favored to produce ribulose 5 phosphate
• high demand for NADPH non ox products channeled into gluconeogensis for re entry into PPP

Question 67

Glycogen structure

Answer 67

.Glucose molecules within chain linked together via α-1,4 glycosidic bonds

• Branch points formed via α-1,6 glycosidic bonds between glucose monomers of separate chains
• Non-reducing ends each contain a terminal glucose with a free hydroxyl group at Carbon 4
• Reducing end consists of glucose monomer connected to a protein called glycogenin
• Glycogenin creates a short glycogen polymer on itself and serves as a primer for glycogen synthesis
• Glycogen is degraded and extended from non-reducing end.

Question 68

Glycogen is stored in

Answer 68

liver and muslces as granules. The granules contain enzymes needed for glycogen metabolism.

Question 69

Functions of glycogen

Answer 69

• Liver glycogen - regulates blood glucose levels: In liver Glu-1-P converted to Glu-6-P by an epimerase and then to Glu by glucose-6-phosphatase. Free glucose released into blood stream.
• Muscle glycogen - provides reservoir of fuel (glucose) for physical activity, as there is NO G-6-P phopspatase. Muscles use it to generate energy via glycolysis and the TCA cycle.

Question 70

Glycogenesis steps

Answer 70

1. Trapping and Activation of Glucose: Glucokinase/hexokinase in cytosol of hepatocytes and muscle makes glucose to glucose-6-phosphate

• Phosphoglucomutase then reversibly isomerizes glucose-6-phosphate to glucose-1-phosphate
• Uridine diphosphate(UDP)-glucose pyrophosphorylase then transfers the glucose-1-phosphate to uridine triphosphate (UTP) which generates UDP-glucose (active form of glucose)

2) elongation: Glycogen synthase (rate limiting enzyme). Catalyzes transfer of glucose from UDP-glucose to non-reducing end of glycogen chain. Forms α-1,4 glycosidic bonds between glucose molecules
3) Branching of glycogen chains:

When glycogen chain reaches 11 residues, a fragment of the chain (about 7 residues long) is broken off at an α -1, 4 link and reattached elsewhere via α -1, 6 link by glucosyl (4:6) transferase.

Question 71

Why is glycogen branched?

Answer 71

•Branching increases solubility of glycogen and increases number of terminal non-reducing ends.

Question 72

Glycogenolysis steps

Answer 72

1. Chain shortening (release of Glu-1-P)
   - Glycogen phosphorylase (GP) (rate limiting enzyme) catalyzes cleavage of glucose residues as a glucose-1-phosphate from non-reducing end of glycogen

–GP uses pyridoxal phosphate (vitamin B6) as cofactor

–Phosphorolysis continues till GP gets within 4 residues of α-1,6 linkage of a branch point.

2. Branch transfer and release of glucose: debranching enzyme uses its transferase (4:4) activity to transfer a block of 3 of the remaining 4 glucose to the non-reducing end of the main chain forming an α-1,4 bond.

Then the enzymes cleaves the α-1,6 bond of the single remaining glucoseresidue to release free glucose.

NET: Generates Glu-1-P and free Glu in a ratio of 10:1

Question 73

RLS for Glycogen metabolism

Answer 73

Glycogen synthase - the rate limiting step of synthes

–dephospho form active

–phospho form inactive

Glycogen phosphorylase - the rate limiting step of degradation

–dephospho form inactive

–phospho form active

Question 74

When is glycogenesis favored?

When is glycogenolysis favored?

Answer 74

Glycogenesis:

-High blood glucose, insulin, and cellular ATP levels

Glucogenolysis:

-during fasting state (low blood gluose and glucagon is high) or during exersice (high cellular calcium levels and aMP levels).

Question 75

Blood glucose levels

Answer 75

• normal: 70-100mg (fasting)
• < 140 fed
• pre dm (100-125 mg) fasting, >140 after eating
• DM 126 mg/dl, > 199mg (fed)

Question 76

Glycogen Storage Diseases

Answer 76

0, Vigra, pills, cause, a, massive, hardon

-VON GIERKES, POMPE, CORI, ANDERSONS, MCARDLES, HERS

Question 77

GSD 0:

Answer 77

• Deficiency in glycogen synthase
• Patients cannot synthesize and store glycogen
• Rely on glucose in diet
• Vulnerable to hypoglycemia when fasting (e.g., during sleep)
• Have muscle cramps due to lack of glycogen in muscle
• Need to eat frequently

Question 78

GSD1a/Von Gierke disease

Answer 78

-Deficiency in glucose 6-phosphatase

• Inefficient release of free glucose into the bloodstream by the liver following gluconeogenesis and glycogenolysis.
• Patients exhibit marked fasting hypoglycemia, lactic acidosis, hepatomegaly due to buildup of glycogen, hyperlipidemia.
• Mutations in catalytic site of glucose 6-phosphatase

Question 79

GSD II/Pompe Disease

Answer 79

Deficiency in Acid Maltase aka acid α -glucosidase

• Impairs lysosomal glycogenolysis resulting in accumulation of glycogen in lysosomes.
• Disrupts normal functioning of muscle and liver cells.
• Progressive muscle weakness (myopathy) in body including heart and skeletal muscle.

Question 80

GSD III/Cori Disease

Answer 80

Deficiency in α-1,6,-glucosidase (debranching enzyme).

• Patients possess glycogen molecules with large number of short branches.
• Light hypoglycemia and hepatomegaly.

Question 81

GSD IV/Andersen Disease

Answer 81

Deficiency in glucosyl (4:6) transferase (branching enzyme)

• Patients have long chain glycogen with fewer branches.
• Causes enlargement of liver and spleen, scarring of liver tissue (cirrhosis).
• Death by 5 years of age.

Question 82

GSD V/McArdle Disease

Answer 82

Deficiency in muscle glycogen phosphorylase

• Rate limiting step of glycogen breakdown
• Patients unable to supply muscles with enough glucose
• Exercise intolerance
• Patients recommended to reduce strenuous exercise

Question 83

Hers Disease

Answer 83

Deficiency in liver glycogen phosphorylase

• Prevents glycogen breakdown in liver, hence it accumulates in liver causing hepatomegaly.
• Low blood glucose levels.

Question 84

PPP is high in which cells?

Answer 84

• lactating mammary glands
• lung and liver
• phagocytic cells