Glycolysis & Gluconeogenesis

Question 1

Glycolysis def

Answer 1

Breakdown of Glucose to 2 Pyruvate

Question 2

Function of glycolysis

Answer 2

Produce energy in the form form of ATP

Question 3

NADH in the cytoplasm is worth how many ATP

Answer 3

2

Question 4

NADH in the mitochondria is worth how many ATP

Answer 4

3

Question 5

Where does glycolysis occur?

Answer 5

Common in Prokaryotic and Eukaryotic Cells:

1) Occurs in cytosol of cytoplasm
- anaerobic conditions->fermentation producing lactic acid or ethanol
- aerobic conditions-> aerobic respiration in mitochondria (Krebs cycle)
2) ALL TISSUE

Question 6

Net Production of ATP in Glycolysis

Answer 6

6 ATP

Question 7

Hexokinase

Answer 7

Glycolysis
Glucose-> Glucose 6 Phosphate
-Phosphoryl transfer at the expense of ATP
-phosphorylation of glucose traps inside cell, because there aren’t any transporters that can transport phosphorylate glucose
-cofactor- Divalent Cation (Mg2+ or Mn2+)
-Exergonic
-Irreversible Rxn

Regulation:
Allosteric regulated by: Glucose 6-Phosphate inhibits(feedback inhibition)

Hormonal Regulation:
Stimulated in the fed state by hormone insulin
Inhibited in the fasting state by hormone glucagon

Broad Substrate Specificity-phosphorylates many hexoses

Question 8

When Hexokinase binds to Glucose

Answer 8

causes conformation change (cleft closing) in hexokinase

• Active site around glucose becomes more nonpolar which favors donation of gamma phosphate
• Excludes water from active site, which prevents hydrolysis of gamma phosphate by H20

Example of Induced Fit

Substrate Induced Fit Cleft closing is a general feature of kinases

Question 9

Hexokinase vs Glucokinase

Answer 9

Hexokinase:
Low Km=High Affinity for glucose
Km<0.1 mM which permits efficient metabolism of glucose

Glucokinase:

• AKA hexokinase D or type IV
• found in adult kidney and liver and senses glucose levels
• High Km=Low affinity for glucose, allowing brain and muscles to have first call on glucose

Question 10

Phosphohexose Isomerase

Answer 10

Glycolysis
Or Phosphoglucose Isomerase
Glucose 6-Phosphate-> Fructose 6-Phosphate

1) Reaction Type: Isomerization- conversion of aldose C-1 to Ketose C-2
2) Helper Molecules: NONE
3) Exergonic
4) Reversible Reaction
5) No regulation

Question 11

Phosphofructose Kinase-1

Answer 11

Glycolysis
Fructose 6-Phosphate-> Frucose 1,6-Bisphosphate
MOST IMPORTANT CONTROL POINT OF METABOLISM

1) Reaction Type: Phosphoryl Transfer At the expense of ATP
2) No helper molecules
3) Exergonic
4) Irreversible

REGULATED:
Allosteric: regulated by energy charge
-Stimulated by Fructose 2,6 Bisphosphate and AMP
-Inhibited by ATP, citrate, and H+

Question 12

Phosphofructose Kinase-2 (PFK-2)

Answer 12

synthesis of Fructose 2,6 Bisphosphate which stimulates PFK1 in glycolysis and inactivates gluconeogenesis

Question 13

Adenylate Kinase

Answer 13

ADP +ADP -> ATP + AMP
salvages ATP from two ADP molecules
-primary reason AMP represents “low energy” charge

Question 14

Aldolase A

Answer 14

Glycolysis
Fructose 1,6-Bisphosphate-> DHAP and Glyceraldehyde 3-Phosphate

1) Reaction Type: Aldol Cleavage
2) Helper molecules: NONE
3) Exergonic
4) Reversible
5) NOT REGULATED

Question 15

Triose Phosphate Isomerase

Answer 15

Glycolysis **
Dihyroxyacetone Phosphate Glyceraldehye 3-Phosphate
at equilibrium 96% exist in DHAP 4% GAP

1) Reaction Type: Isomerization
2) Helper Molecules: NONE
3) ENDERGONIC
4) Reversible

NOT REGULATED

Question 16

Phosphoglyceraldehyde Dehdyrogenase

Answer 16

Glycolysis
OR Glyceraldehyde 3-Phosphate Dehydrogenase
Glyceraldehyde 3-Phosphate-> 1,3-Bisphosphoglycerate

1) Reaction type:
Phosphorylation coupled to oxidation of aldehyde to carboxylic acid at the expense of NAD+
2) Helper molecule-coenzyme-NAD+
3)Exergonic
4) Reversible
5) NOT REGULATED

Question 17

3-Bisphosphoglycerate Kinase

Answer 17

Glycolysis **
OR Phosphoglycerate Kinase
1,3 Bisphosphoglycerate -> 3-Phosphoglycerate

1) Reaction Type: Transfer of Phosphoryl group from 1,3-BPG to ADP to regenerate ATP since 1,3-BPG has higher phosphoryl potential than ATP
* SUBSTRATE LEVEL PHOSPHORYLATION
2) Helper Molecules-NONE
3) ENDERGONIC
4) REVERSIBLE-unusal for kinases
5) NOT REGULATED

Question 18

Phosphoglyceromutase

Answer 18

Glycolysis **
OR Phosphoglycerate Mutase
3-Phosphoglycerate-> 2-phosphoglycerate

1) Reaction type-Phosphoryl shift from C3 to C2
2) Helper Molecules-NONE
3) Endergonic
4) Reversible
5) NOT REGULATED

Question 19

Enolase

Answer 19

Glycolysis
2-phosphoglycerate-> Phosphoenolpyruvate

1) Reaction type-dehydration
2) Helper molecules; NONE
3) Exergonic
4) reversible
5) NOT REGULATED

Question 20

Pyruvate Kinase

Answer 20

Glycolysis (LAST STEP)
PEP-> Pyruvate

1) Reaction Type: Phosphoryl Transfer from PEP to ADP to regenerate to ATP since PEP has higher phosphorylation potential than ATP
2) Helper Molecules-NONE
3) Exergonic
4) Irreversible

REGULATED:
Allosterically regulated:
-Stimulated by Fructose 1,6-BP in feedforward stimulation
-Inhibited by ATP and Alanine

IN LIVER:
-inactivated by cAMP dependent Protein Kinase A; low blood glucose=increase glucagon which pyruvate kinase is phosphorylated and inactivated

Question 21

Pyruvate Kinase Deficiency in RBCs

Answer 21

RBC lack mitochondria thus lack Pyruvate oxidation, Krebs cycle, and Electron Transport chain Thus depends on glycolysis for ATP production

PK deficiency causes change in shape of RBC due to insufficient energy production causing chronic hemolytic fever

Question 22

3 fates of pyruvate post glycolysis

Answer 22

Fermentation:

• anaerobic conditions
• cytoplasm
  1) Lactic acid-higher eukaryotes
  2) ethanol-microorganisms

Pyruvate Oxidation

• aerobic conditions
• matrix of mitochondria

Question 23

Pyruvate: Ethanol Fate

Answer 23

Fermentation-anerobic conditions
-occurs in cytoplasm

Pyruvate-> Acetaldehyde + CO2
-Enzyme: Pyruvate Decarboxylase 
Reaction type: decarboxylation
-Helper Molecule: Prosthetic group-Thiamine pyrophosphate 
-Reversible
-Exergonic

Acetaldehyde-> Ethanol
Enzyme: Alcohol dehydrogenase 
Reaction type: oxidation
Helper molecule- Zn2+-cofactor; NADH coenzyme
exergonic
REGENERATE NAD+

Question 24

Pyruvate: Lactate Fate

Answer 24

Pyruvate-> Lactate

Enzyme: Lactate dehydrogenase

Question 25

Lactate + Exercise

Answer 25

formation of lactate reduces pH potentially leading to cramps
-lactate diffuses into blood and can be used to make glucose in liver

Question 26

Lactate + Heart

Answer 26

Heart gathers lactate from blood and converts to pyruvate

Question 27

Rossmann Folds

Answer 27

NAD+ binding site are similar in:

• Glyceraldehdye 3-phosphate dehydrogenase
• Lactate Dehydrogenase
• Alcohol Dehydrogenase

Composed of:

• 4 alpha helixes
• 6 parallel beta strands

Question 28

In the liver, Glycolysis is involved in:

Answer 28

• maintenance of blood glucose levels
• synthesizes glycogen to store glucose when glucose concentration is high
• generates intermediates for biosynthesis

Question 29

Glycolysis Regulation: resting muscles

Answer 29

Glycolysis is inhibited by High Energy

Resting muscles have High Energy Charge (ATP/AMP)

• ATP binds Allosterically to PFK-1 and PK and inhibiting enzymes function
• inhibition of PFK-1 and PK leads to increase in G 6-P concentration and binds to allosteric site on hexokinase inhibiting it’s function

Question 30

Glycolysis Regulation: Contracting Muscles

Answer 30

Glycolysis is stimulated by Low Energy

Contracting Muscles utilize existing ATP (converting it to ADP and AMP) reducing the energy charge of surrounding tissue

• AMP displaces ATP from allosteric site of PFK-1 stimulating PFK-1 to produce Fructose 1,6-BP which feedforward stimulation of PK
• as PFK-1 is activated G 6-P conc is reduced thus activating Hexokinase

Question 31

Glycolysis Regulation: Liver

Answer 31

Glycolysis CAN NOT FERMENT thus no Lactate, which means H+ (protons) have no effect on regulation ofPFK1

Utilizes Glucokinase isozyme of Hexokinase, with High Km thus lower affinity for glucose-allows Brain and muscles to have first. all

Allosteric Regulation

1) PFK2 Produces Fructose 2,6 bisphosphate which stimulates PFK1 to produce Fructose 1,6-BP to feedforward and stimulates PK (SAME AS MUSCLES)
2) PK is also stimulated by alanine

Inhibition:
High energy Charge (ATP) inhibits PFK-1 and PK
and Citrate from Krebs cycle also inhibits PFK1

Question 32

Glucose Transport

Answer 32

Sodium monosaccharide cotransport system

• transports glucose AGAINST conc gradient
• requires energy from sodium/potassium ATPase pump

Question 33

GLUT

Answer 33

Sodium independent facilitate diffusion(transport) of glucose down its concentration gradient across the Plasma membrane
-14 different isoforms of GLUTS
composed of 
-single polypeptide-500 amino acids
-12 transmembrane  alpha helix structres
-tissue specific pattern of expression

Question 34

Glycolysis in cancer cells

Answer 34

In cancer cels, glycolysis often functions anaerobically (Fementation), even in the presence of oxygen

• Called anaerobic glycolysis or “Warburg Effect”
• Medicine-capitiliazes on this with testing for cancer

Question 35

Glucogneogenesis Def

Answer 35

New synthesis of glucose

2 Types;
Anabolic-synthesis from noncarbohydrate precursors
Conversion-from other carbohydrates (C5 and C6)

Question 36

Where does gluconeogenesis occur?

Answer 36

LIVER AND KIDNEY

• During an overnight fast, gluconeogenesis occurs in the liver (90%) and kidney (10%)
• extended fast, the kidney takes over a larger percentage of gluconeogenesis (40%)

Question 37

Glucose Requirements per day

Answer 37

Human Adults= 160g/day (24 hrs)

-brain requires 120g of that 160g per day

Question 38

Glycogen stores in humans

Answer 38

Glycogen stores= 190g of glucose

-once glycogen stores are depleted, glucose is produced by gluconeogenesis

Question 39

Potential Substrates for Gluconeogenesis

Answer 39

1) Lactate
2) Pyruvate
3) Glycerol-from catabolism of triacylglycerol
- animals DO NOT convert fatty acids to glucose
4) Alpha Ketoacids-from catabolism of glucogenic amino acids

Question 40

Gluconeogenesis: Glycerol Substrate

Answer 40

Glycerol Source:
Hydrolysis of Triacylglycerols of adipose tissues, but Glycerol Kinase is not found in adipose tissues. Therefore Glycerol inters bloodstream and travels to liver

Once in liver:

• Glycerol is phosphorylated to Glycerol Phosphate at the expense of ATP Gamma Phosphate; catalyzed by Glycerol Kinase
• Glycerol Phosphate is then oxidized to Dihydroxyacetone Phosphate at the expense of NAD+ to NADH; catalyzed by Glycerol Phosphate dehydrogenase

Question 41

Gluconeogenesis: Lactate Substrate

Answer 41

CORI CYCLE:

• Lactate is formed in skeletal muscles and tissues lacking mitochondria during strenuous exercise
• lactate diffuses into blood and carried to liver
• Lactate diffuses into liver where it is used to synthesize glucose

Question 42

Source of Amino Acids in Gluconeogenesis

Answer 42

During a fast, amino acids come from hydrolysis of tissue proteins

Question 43

Gluconeogenesis: Pyruvate Substrate

Answer 43

ONLY IN LIVER AND KIDNEY:

1) Pyruvate is carboxylated to Oxaloacetate by Pyruvate Carboxylase at the expense of ATP-> ADP
2) Oxaloacetate is unable to leave mitochondria, so is reduced to Malate at the expense of NADH oxidized to NAD+; catalyzed by Malate dehydrogenase (mt)
3) Malate travels to cytoplasm of cell and is oxidized to Oxaloacetate at the expense of NAD+ reduced to NADH; catalyzed by Malate Dehydrogenase (cytosol)
4) Oxaloacetate is then decarboxylated phosphorylated to PEP at the expense of GTP-> GDP;catalyzed by PEP carboxykinase (cytosol)

Question 44

Pyruvate Carboxylase

• Purpose?
• Found?
• Prosthetic Group
• Regulation

Answer 44

Produces Oxaloacetate from Pyruvate for gluconeogenesis and to replenish oxaloacetate as intermediate in Krebs cycle

Found in:

• liver and kidney cells
• Muscle cells only to replenish Oxaloacetate as Krebs cycle Intermediate

Prosthetic Group
-Biotin

Allosterically Regulated
Stimulated by Acetyl CoA

Question 45

Biotin

• function
• vit
• deficiency

Answer 45

Prosthetic Group of Pyruvate Carboxylase
-covalently attached to E amino group of lysine by amide bond called biotycin at this state

Function:
-Carries activated CO2 for carboxylation and carboxyl group transfer in certain enzymes of gluconeogensis and fatty acid synthesis

Vit-Biotin

Def
-rash about eye brows, muscle pain, fatigue (rare)

Question 46

PEP Carboxykinase

Answer 46

or PEP CK

Decarboxylates and phosphorylates oxaloacetate to phosphoenolpyruvate (PEP)

Question 47

Gluconeogenesis: Glycolysis step 3

Answer 47

ONLY IN LIVER AND KIDNEYS-Gluconeogenesis
Fructose 1,6-BP -> Fructose 6-Phosphate
Enzyme: Fructose 1,6-Bisphosphatase
-dephosphorylation of Fructose 1,6-BP

Regulated by:ENERGY CHARGE (OPPOSITE OF Glycolysis)

• inhibited by High AMP (OR LOW ENERGY CHARGE)
• inhibited by Fructose 2,6-BP

Question 48

Gluconeogenesis: Glycolysis Step 1

Answer 48

ONLY IN LIVER AND KIDNEYS-GLuconeogenesis
Muscles cells lack Glucose 6-P

For glucose 6-Phosphate to reach Glucose 6-Phosphatase must be transported to the Lumen of Endoplasmic Reticulum (ER)

1) Glucose 6-Phosphate (cytoplasm)-> Glucose 6-P (ER)
- enzyme=Glucose 6-Phosphatase translocate
2) Glucose 6-Phosphate (ER)-> Glucose
- once in lumen of ER Glucose 6-Phosphatase dephosphorylates to produce glucose

Question 49

REGULATION OF Gluconeogenesis

-Glucagon to stimulate gluconeogenesis

Answer 49

Glucagon is secreted by pancreatic islet and stimulates gluconeogenesis:

1) Lowering the conc of Fructose 2,6-BP
- activates fructose 1,6-Bisphosphatase (gluconeogenesis)
- inhibits PFK-1 (glycolysis)
2) Inhibits by Pyruvate Kinase by Phosphorylation
- glucagon elevates cAMP which stimulates cAMP-dependent protein kinase to phosphorylate PYRUVATE KINASE. PEP is then shifted to synthesis of glucose
3) Increasing Transcription of PEP carboxykinase gene

Question 50

Regulation of Gluconeogenesis

-Substrate Availability

Answer 50

• specific availability of glucogenic amino acids

- decresed conc of insulin favors mobilization of amino acids from muscle protein

Question 51

Regulation of Gluconeogenesis:

-Allosteric inhibitors/activators

Answer 51

Allosteric Activation of Acetyl-CoA
-fasting stimulates hepatic Pyruvate Carboxylase
Allosteric Inhibition by AMP

Question 52

Malignant Hyperthermia

Answer 52

Both glucose and glycolysis are running at high rates leading to uncontrolled hydrolysis of ATP which generates HEAT

Question 53

Substrate Cycles

Answer 53

Changes in rates of two opposing cycles can vastly increase the rate of production of the product “B”

• Allosteric effector
• Net flux increases or decreases

Question 54

Transcriptional Control by insulin/glucagon

Answer 54

Insulin release (fed state) stimulates the expression of PFK-1, PK, and the bifunctional enzyme (PFK2/FBPase2) stimulating glycolysis

Glucagon Release (fasting) stimulates expression of phosphoenolpyruvate carboxykinase, and fructose 1,6-bisphosphatase

Question 55

Bifunctional Enzyme of Glycolysis/gluconeogenesis

Answer 55

REGULATION OF GLYCOLYSIS/GLUCONEOGENESIS AT TRANSITION POINT-Fructose 2,6-Bisphosphate

PFK2 and FBPase2 reside on the same polypeptide
-regulation is by phosphorylation of serine in regulatory domain

Phosphorylation turns off the kinase activity/turning on the phosphatase activity (FBPase2) which reduced the concentration of Fructose 2,6-BP

Dephosphorylation turns on the kinase activity(PFK2)/turning off the phosphatase activity which increases the concentration of Fructose 2,6-BP

Question 56

Bifunctional Enzyme at Low glucose levels

Answer 56

1) glucagon triggers production of cAMP by adenylate cyclase
2) cAMP stimulates Protein Kinase A to phosphorylate the bifunctional enzyme
3) Phosphorylation stimulates FBPase2 activity and inhibits PFK2 activity
4) FBPase2 dephosphorylates C-2 of Fructose 2,6-Bisphosphate producing Fructose 6-Phosphate
5) Low Fructose 2,6-Bisphosphate concentration inhibits PFK-1 and favors gluconeogenesis

Question 57

Bifunctional enzyme at High Glucose Levels

Answer 57

1) insulin stimulates Phosphoprotein Phosphatase
2) Phosphoprotein Phosphatase dephosphorylates the bifunctional enzyme activating PFK2
3) PFK2 phosphorylates Fructose 6-Phosphate to Fructose 2,6Bisphosphate
4) Increase in Fructose 2,6-BP concentration stimulates PFK1 and favors glycolysis

Question 58

What other carbohydrates can be used in glycolysis

Answer 58

Fructose (2 entry points-depending on from other tissues or liver)
Galactose (1 entry point)

Question 59

Glycolysis: Fructose

Answer 59

Pathway In Liver:

1) Fructose-> Fructose 1-Phosphate at the expense of ATP-> ADP catalyzed by Fructose Kinase
2) Fructose 1-Phosphate-> DHAP + Glyceraldehyde; catalyzed by Fructose 1-Phosphate Aldolase
* *Glyceraldehyde needs to be phosphorylated
3) Glyceraldehye-> Glyceraldehyde 3-Phosphate at the expense of ATP-ADP; catalyzed by TRIOSE KINASE

Pathway in other tissues:
Fructose-> Fructose 6-Phosphate catalyzed by Hexokinase at the expense of ATP-> ADP

Question 60

Galactitol

Answer 60

Causes Cateracts

• galatosemia causes increased galactose concentration in the blood which can leads to increased concentration in some tissues
• In the eye its converted to Galactitol which causes cateracts

Question 61

Lactase Deficiency

Answer 61

Can lead to Lactose Intolerance
-Deficiency (reduction)

Microorganisms ferment lactose into lactic acid and methane and hydrogen gas

Question 62

Mechanism of Triose Phosphate Isomerase

Answer 62

DHAP GAP *want to form GAP
-contain amino acids Glu and His
enzyme approaches Kinetic Perfection

1) Glu (general base) abstracts proton from DHAP
- His (general acid) donates proton to C=O of DHAP (or C2)
2) Glu (general acid) donates to C2 (old C=O of DHAP)
- His (general base) abstracts proton from Hydroxyl of C1
3) Glu (negative) and His (positive) returns to original form

Question 63

Alcohol Dehydrogenase Active site

Answer 63

Zn2+ linked to:

• 2 S of Cyst
• N of His
• O of aldehyde of Acetaldehyde, which polarizes carbonyl group

NADH-transfers hydride to C of acetaldehyde

Question 64

Mechanism of Glyceraldehyde 3-phosphate dehydrogenase

Answer 64

Two processes:

• oxidation of aldehyde to carboxylic acid by NAD+ (-G)
• Joining of Carboxylic acid and orthophosphate (Pi) to form acyl phosphate (+G)
• steps are tightly coupled by covalent attachment of acid intermediate to enzyme by thioester bond

1) Cys reacts with aldehyde of GAP forming hemethioacetal
2) Hydride transferred from substrate (oxidized) to NAD+ reduced to NADH
- concomitantly a thioester is formed between substrate and enzyme
- His accepts proton
3) NADH is exchanged to NAD+
4) Orthophosphate (Pi) attaches thioester forming 1,3-BPG