Glycolysis. The conversion of glucose to pyruvate to yield 2ATP molecules 10 enzymatic steps...
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Transcript of Glycolysis. The conversion of glucose to pyruvate to yield 2ATP molecules 10 enzymatic steps...
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Glycolysis
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Glycolysis
The conversion of glucose to pyruvate to yield 2ATP molecules•10 enzymatic steps•Chemical interconversion steps•Mechanisms of enzyme conversion and intermediates•Energetics of conversions•Mechanisms controlling the Flux of metabolites
through the pathway
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Pathway overview1. Add phosphoryl groups to activate glucose.
2. Convert the phosphorylated intermediates into high energy phosphate compounds.
3. Couple the transfer of the phosphate to ADP to form ATP.
Stage I A preparatory stage in which glucose is phosphorylated and cleaved to yield two molecules of glyceraldehyde-3-phosphate - uses two ATPs
Stage II glyceraldehyde-3-phosphate is converted to pyruvate with the concomitant generation of four ATPs-net profit is 2ATPs per glucose.
Glucose + 2NAD+ + 2ADP +2Pi 2NADH + 2pyruvate + 2ATP + 2H2O + 4H+
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Oxidizing power of NAD+ must be recycled
1. Under anaerobic conditions in muscle NADH reduces pyruvate to lactate (homolactic fermentation).
2. Under anaerobic conditions in yeast, pyruvate is decarboxylated to yield CO2 and acetaldehyde and the latter is reduced by NADH to ethanol and NAD+ is regenerated (alcoholic fermentation).
3. Under aerobic conditions, the mitochondrial oxidation of each NADH to NAD+ yields three ATPs
NADH produced must be converted back to NAD+
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Hexokinase
Isozymes: Enzymes that catalyze the same reaction but are different in their kinetic behavior
Tissue specific
Glucokinase- Liver controls blood glucose levels.
Hexokinase in muscle - allosteric inhibition by ATP
Hexokinase in brain - NO allosteric inhibition by ATP
O
OH
H
OH
OHH
CH2OH
HH
OH H
OH
OH
H
OH
H
OHH
OH
CH2OPO32-
H+ ATP + ADP + H+
Glucose Glucose-6-phosphate
Mg++
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Hexokinase reaction mechanism is RANDOM Bi-Bi
Glucose ATP ADP Glu-6-PO4
When ATP binds to hexokinase without glucose it does not hydrolyze ATP. WHY?
The binding of glucose elicits a structural change that puts the enzyme in the correct position for hydrolysis of ATP.
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The enzyme movement places the ATP in close proximity to C6H2OH group of glucose and excludes
water from the active site.
There is a 40,000 fold increase in ATP hydrolysis upon binding xylose which cannot be phosphorylated!
O
OH
H
OH
OHH
H
H
-D-Xylose
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Yeast hexokinase, two lobes are gray and green. Binding of glucose (purple) causes a large conformational change. A substrate induced conformational change that prevents the unwanted hydrolysis of ATP.
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Phosphoglucose Isomerase
Uses an “ ene dione intermediate
1) Substrate binding
2) Acid attack by H2N-Lys opens the ring
3) Base unprotonated Glu abstracts proton from C2
4) Proton exchange
5) Ring closure
OH
CH2OH
H
OH H
HO
-2O3POCH2
HO
OH
OH
H
OH
OHH
OH
CH2OPO32-
HH
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Uncatalyzed isomerization of Glucose
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Phosphofructokinase
Fructose-6-PO4 Fructose-1,6-bisphosphate
1.) Rate limiting step in glycolysis
2.) Irreversible step, can not go the other way
3.) The control point for glycolysis
OH
CH2OH
H
OH H
HO
-2O3POCH2
HO
OH
CH2OPO3-2
H
OH H
HO
-2O3POCH2
HO+ ATP + ADP
Mg++
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Aldolase
CH2OPO3-2
C O
C
C
C
HHO
OHH
OHH
CH2OPO3-2
CH2OPO3-2
C O
C HHO
H
C OHH
CH2OPO3-2
H O
+
Dihydroxyacetone phosphate (DHAP)
Glyceraldehyde-3-phosphate (GAP)
Fructose -1,6-bisphosphate (FBP)
Aldol cleavage (retro aldol condensation)
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There are two classes of Aldolases
Class I animals and plants - Schiff base intermediate
Step 1 Substrate binding
Step 2 FBP carbonyl groups reacts with amino LYS to form iminium cation (Schiff base)
Step 3. C3-C4 bond cleavage resulting enamine and release of GAP
Step 4 protonation of the enamine to a iminium cation
Step 5 Hydrolysis of iminium cation to release DHAP
C14 NH
CH2OH
CH2OPO3-2
(CH2)4 Lys C14NH3
CH2OH
CH2OPO3-2
(CH2)4 LysH
+ NaBH4
+
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Class II enzymes are found in fungi and algae and do not form a Schiff base. A divalent cation usually a Zn+2 polarizes the carbonyl intermediate.
Probably the occurrence of two classes is a metabolic redundancy that many higher organisms replaced with the better mechanism.
CH2OPO3-2
C O
CHO
H
Zn2+
- HO H
C O Zn2+
CH2OPO32-
-
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Aldolase is very stereospecific
When condensing DHAP with GAP four possible products can form depending on the whether the pro-S or pro R hydrogen is removed on the C3 of DHAP and whether the re or si face of GAP is attacked.
CH2OPO32-
HHO
OHH
OHH
CH2OPO32-
O
CH2OPO32-
OHH
OHH
OHH
CH2OPO32-
O
D-Fructose 1,6 bisphosphate
D-Psicose1,6 bisphosphate
CH2OPO32-
HHO
HHO
OHH
CH2OPO32-
O
CH2OPO32-
OHH
HHO
OHH
CH2OPO32-
O
D-Tagatose1,6 bisphosphate
D-Sorbose1,6 bisphosphate
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Triosephosphate isomerase
DHAP GAP 96
110x7.4
DHAP
GAP K 2
eq
TIM is a perfect enzyme which its rate is diffusion controlled.
A rapid equilibrium allows GAP to be used and DHAP to replace the used GAP.
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TIM has an enediol intermediate
Transition state analogues Phosphoglycohydroxamate (A) and 2-phosphoglycolate (B) bind to TIM 155 and 100 times stronger than GAP of DHAP
H
C
O
CH2OPO32-
OHH C
CH2OPO32-
OHH
C
C
CH2OPO32-
O
OHH
HH OH
GAP enediol DHAP
CH2OPO32-
O-N
OH
C
O32-POH2C
O-H
HO
O32-POH2C
O-O
A. B.
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Glyceraldehyde-3-phosphate dehydrogenase
The first high-energy intermediate
Uses inorganic phosphate to create 1,3 bisphosphoglycerate
C
CH2OPO32-
OHH
HO
C
CH2OPO32-
OHH
OPO32-O
+ NAD+ + Pi + NADH
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Reactions used to elucidate GAPDH’s mechanism
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Mechanistic steps for GAPDH
1. GAP binds to enzyme.
2. The nucleophile SH attacks aldehyde to make a thiohemiacetal.
3. Thiohemiacetal undergoes oxidation to an acyl thioester by a direct transfer of electrons to NAD+ to form NADH.
4. NADH comes off and NAD+ comes on.
5. Thioester undergoes nucleophilic attack by Pi to form 1,3 BPG.
The acid anhydride of phosphate in a high energy phosphate intermediate
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Arsenate uncouples phosphate formation
C
CH2OPO32-
OHH
OOAs O
O
O
C
CH2OPO32-
OHH
O-O
As OO
O
O
C
CH2OPO32-
OHH
HO
+GAP DH
As OO
O
O
+
3PG