Figure 173Degradation of glucose via the glycolytic pathway' All steps occur in the cytosol' All enz

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Figure 17-3 Degradation of glucose via the
glycolytic pathway. All steps occur in the
cytosol.All enzymes are homodimers or
homotetramers!
Page 584
Buchner!!!
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Figure 17-5a Conformation changes in yeast
hexokinase on binding glucose. (a) Space-filling
model of a subunit of free hexokinase. (b)
Space-filling model of a subunit of free
hexokinase in complex with glucose (purple). (8
? movement!!!)
This same change in conformation is observed for
ALL kinases! It also accounts for the fact
that water cannot be used for hydrolysis of ATP
unless we fool the enzyme by using xylose
instead of glc.
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Page 586
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Phosphoglucose isomerase (PGI)
pKs for active site 6.7 and 9.3 (determined by
rate vs. pH) Which aas??
Actually Glu (!!!) and His with stabilization of
His by a Glu (remember the ser protease
mechanism!)
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Figure 17-7 Base-catalyzed isomerization of
glucose, mannose, and fructose.
NOT produced by PGI!
Page 588
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Figure 17-6 Reaction mechanism of phosphoglucose
isomerase.
General Acid/Base Catalysis
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RATE DETERMINING STEP OF GLYCOLYSIS!
Phosphofructokinase (PFK)
Works exactly like HK.
Inhibited by hi ATP or citrate
Activated by AMP even in the presence of hi
ATP.
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Figure 17-8 Mechanism for base-catalyzed aldol
cleavage.
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Transition state analogs like 2-phosphoglycolate
inhibit the enzyme
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Figure 17-9 Enzymatic mechanism of Class I
aldolase.
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Proof for the formation of the Schiff base
Enzyme-Substrate Complex trapped by reduction of
DHAP with NaBH4 followed by hydrolysis (p.
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Figure 16-10 Mechanism of aldoseketose
isomerization.
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Figure 17-10 Proposed enzymatic mechanism of the
TIM reaction General Acid Catalysis.
pKs 6.5 and 9.5 Like PGI But pK1 is for GLU!
Normal pk?
4.1
Glu?Asp ? activity by 1000!
Reaction rate is diffusion limited!!
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GAP DH
Start of energy producing phase of glycolysis
Production of the first hi energy molecule.
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Figure 13-2The structures and reaction of
nicotinamide-adenine dinucleotide (NAD) and
nicotinamide adenine dinucleotide phosphate
(NADP).
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Figure 17-13a Some reactions employed in
elucidating the enzymatic mechanism of GAPDH. (a)
The reaction of iodoacetate with an active site
Cys residue. (b) Quantitative tritium transfer
from substrate to NAD.
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32Pi also incorporated
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Figure 17-14 Enzymatic mechanism of
glyceraldehyde-3 phosphate dehydrogenase.
?Go 6.7 kJ!
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Figure 17-15 Space-filling model of yeast
phosphoglycerate kinase showing its deeply
clefted bilobal structure.
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Figure 17-16 Mechanism of the PGK reaction.
?Go -12.1 kJ
?Go -49.4 kJ!
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Phosphoglucomutase--PGM
Mutases move functional groups 3PG?2PG
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Figure 17-17 The active site region of yeast
phosphoglycerate mutase (dephospho form) showing
the substrate, 3-phosphoglycerate, and some of
the side chains that approach it.
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Figure 17-18 Proposed reaction mechanism for
phospho-glycerate mutase.
Phosphorylated active site
Bisphospho- intermediate.
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Figure 17-19 The pathway for the synthesis and
degradation of 2,3-BPG in erythrocytes is a
detour from the glycolytic pathway.
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Figure 17-20 The oxygen-saturation curves of
hemoglobin (red) in normal erythrocytes and those
from patients with hexokinase (green) and
pyruvate kinase deficiencies (purple).
?BPG
? BPG
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Figure 17-21 Proposed reaction mechanism of
enolase.
F- binds Pi Mg2 Potent inhibitor
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Figure 17-22 Mechanism of the reaction catalyzed
by pyruvate kinase.
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Figure 17-23 The active site region of porcine H4
LDH in complex with S-lac-NAD, a covalent adduct
of lactate and NAD.
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Figure 17-24 Reaction mechanism of lactate
dehydrogenase.
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Figure 17-25 The two reactions of alcoholic
fermentation.
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Figure 17-26 Thiamine pyrophosphate.
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Figure 17-27 Reaction mechanism of pyruvate
decarboxylase.
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Figure 17-29 The formation of the active ylid
form of TPP in the pyruvate decarboxylase
reaction.
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Figure 17-30 The reaction mechanism of alcohol
dehydrogenase involves direct hydride transfer of
the pro-R hydrogen of NADH to the re face of
acetaldehyde.
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Table 17-2 Some Effectors of the Nonequilibrium
Enzymes of Glycolysis.
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Figure 17-32a X-Ray structure of PFK. (a) A
ribbon diagram showing two subunits of the
tetrameric E. coli protein.
Mg2
F6P
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ATP
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Figure 17-33 PFK activity versus F6P
concentration.
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Figure 17-35 Metabolism of fructose.
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Figure 17-36 Metabolism of galactose.
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Figure 17-37 Metabolism of mannose.
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Figure 17-31 Schematic diagram of the plasmid
constructed to control the amount of citrate
synthase produced by E. coli.
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Alfonse, Biochemistry makes my head hurt!!
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