PPP
- no ____ is directly consumed or produced in the cycle
ATP
1. Consists of
a. _________
- oxidation of glucose by the pentose phosphate pathway generates ______
- 1st stage of the pentose phosphate pathway
b. _________
- interconversion reactions can function in several different directions
- 2nd and 3rd stages of the pentose phosphate pathway
2. Carbon 1 of Glucose 6-Phosphate
released as ______
3. Rate and Direction of the Reactions
- determined by
a. Irreversible Oxidative Reactions
- oxidation of glucose by the pentose phosphate pathway generates NADPH
b. Reversible Sugar-Phosphate Interconversions
released as CO2
a. Supply of intermediates
b. Demand for intermediates
A. Functions
1. Source of _____
- produces __ _____ for each glucose 6-phosphate molecule entering the oxidative part of the
pathway
a. _____
- as a reducing equivalent for _____ / _____ (the premier antioxidant system in the cell)
- for _____ and _____ biosynthesis
2. Source of _____
- shunts G6P to form _____ for _____ synthesis
3. Route for Use of Ingested _____
- and for their conversion to _____ ( _____ ) and _____
( _____ )
1. Source of NADPH
- produces 2 NADPH for each glucose 6-phosphate molecule entering the oxidative part of the
a. NADPH
- as a reducing equivalent for GSH/GSSG (the premier antioxidant system in the cell)
- for steroid and fatty acid biosynthesis
2. Source of Ribose 5-Phosphate
- shunts G6P to form ribulose-5-phosphate for nucleotide synthesis
3. Route for Use of Ingested Pentoses
- and for their conversion to fructose 6-phosphate (F6P) and glyceraldehyde 3-phosphate (G3P)
B. Location
1. In ______
a. ______ - active in fatty acid synthesis
b. ______
- active in fatty acid synthesis
c. ______
d. ______
- active in NADPH-dependent synthesis of steroids
e. ______
- require NADPH to keep glutathione reduced
2. Within ______
- ______
1. In Tissues
a. Liver - active in fatty acid synthesis
b. Mammary Glands
c. Adipose Tissue
d. Adrenal Cortex
e. Erythrocytes
2. Within Cells
- cytoplasm
FIRST STAGE of the PENTOSE PHOSPHATE PATHWAY (IRREVERSIBLE OXIDATIVE REACTIONS)
1. Consists of 3 Reactions
-> formation of:
c. ______ molecules of _________ (for each glucose 6-phosphate oxidized)
2. Important in the
a. _________, _________
-> fatty acid biosynthesis
-> NADPH-dependent steroids synthesis
c. _________ -> NADPH requirement to keep glutathione reduced -> membrane integrity
a. Ribulose 5-phosphate
b. CO2
c. 2 molecules of NADPH (for each glucose 6-phosphate oxidized)
a. Liver, Lactating Mammary Glands
b. Adrenal Cortex
c. RBCs -> NADPH requirement to keep glutathione reduced -> membrane integrity
A. Dehydrogenation of Glucose 6-Phosphate
- PPP is regulated primarily at this step
1. Enzyme
- glucose 6-phosphate dehydrogenase (G6PD)
2. Irreversible Reaction
- glucose 6-phosphate oxidation -> 6 phosphogluconolactone (6-phosphoglucono-δ-lactone)
3. Coenzyme
- NADP+ reduced to NADPH
4. NADPH
- potent competitive inhibitor of the enzyme
- high NADPH/NADP+ -> enzyme activity inhibition
a. Increased NADPH Demand
-> decreased NADPH/NADP+ -> increased glucose 6-phosphate dehydrogenase activity
-> increased flux through the cycle
5. Insulin
- enhances glucose 6-phosphate dehydrogenase gene expression -> flux through the pathway increases in well-fed state
B. 6-Phosphogluconolactone Hydrolysis and Ribulose 5-Phosphate Formation
1. 6-Phosphogluconolactone Hydrolase/Lactonase
- hydrolyze the lactone (cyclic ester) of 6-phosphogluconolactone to 6-phosphogluconate
- irreversible reaction
- not rate-limiting
2. 6-Phosphogluconate Dehydrogenase
- catalyzes oxidative decarboxylation of 6-phosphogluconate by NADP+
- irreversible
a. Products
i. Pentose sugar-phosphate (ribulose 5-phosphate)
ii. CO2 (from carbon of glucose)
iii. 2nd molecule of NADPH
FIRST STAGE of the PENTOSE PHOSPHATE PATHWAY REVERSIBLE NONOXIDATIVE REACTIONS
1. Occurrence
- in all cell types synthesizing
- nucleotides
- nucleic acids
2. Interconversions
- of 3-, 4-, 5-, 6-, and 7-carbon sugars
3. Ribulose 5-Phosphate Conversion to
a. Ribose 5-Phosphate
b. Intermediates of Glycolysis
- fructose 6-phosphate
- glyceraldehyde 3-phosphate
4. Control
- primarily by the availability of intermediates
5. TPP - required in the transketolase reaction
a. Other TPP-Requiring Enzymes
i. Pyruvate Decarboxylase
- of the pyruvate dehydrogenase complex
ii. α-Ketoglutarate Dehydrogenase
- of the TCA cycle
iii. Branched-Chain α-Keto Acid Dehydrogenase
- of branched-chain amino acid metabolism
A. Conversion of Pentose Phosphate to Intermediates of Glycolysis
- cells that carry out reductive biosynthetic reactions -> greater need for NADPH (than for ribose
5-phosphate) -> transketolase (transfers 2-carbon units), transaldolase (transfers 3-carbon units)
convert ribulose 5-phosphate to glyceraldehyde 3-phosphate and fructose 6-phosphate ->
glycolysis
B. Formation of Ribose 5-Phosphate from Intermediates of Glycolysis
- under conditions where demand for pentoses (for nucleotide and nucleic acid synthesis) > NADPH need
-> ribose 5-phosphate synthesis from glyceraldehyde 3-phosphate and fructose 6-phosphate
SECOND STAGE of the PENTOSE PHOSPHATE PATHWAY (REVERSIBLE OXIDATIVE
REACTIONS)
A. Ribulose 5-Phosphate to Ribose 5-Phosphate and Xylulose 5-Phosphate
- both products are formed by isomerization of ribulose 5-phosphate
1. Enzymes
a. Phosphopentose Isomerase (Ribulose-5-Phosphate Isomerase)
- converts ribulose 5-phosphate to ribose-5-phosphate
- ribose-5-phosphate can be used to produce nucleosides for RNA and DNA synthesis
b. Phosphopentose Epimerase (Ribulose-5-Phosphate Epimerase)
THIRD STAGE of the PENTOSE PHOSPHATE PATHWAY (REVERSIBLE OXIDATIVE REACTIONS)
- 3 five-carbon sugars are converted to 2 fructose-6-phosphate and 1 glyceraldehyde-3-phosphate
A. Ribose 5-Phosphate and Xylulose 5-Phosphate to Sedoheptulose 7-Phosphate and G3P
1. Reaction
- 2-carbon unit is transferred from a ketose (xylulose 5-phosphate) to an aldose (ribose 5-
phosphate) -> seven-carbon sugar sedoheptulose-7-phosphate and glyceraldehyde-3-
phosphate
2. Enzyme
- transketolase (requires TPP as cofactor)
3. Wernicke-Korsakoff Syndrome
a. Cause
- results from chronic thiamine deficiency -> reduced transketolase activity ->
clinical manifestations of this syndrome
b. Defective Transketolase Activity
- exhibiting reduced affinity to TPP (other TPP-dependent enzymes in these patients
appear to be normal)
c. Symptoms
- weakness or paralysis
- impaired mental function
B. Sedoheptulose 7-Phosphate and G3P to Erythrose 4-Phosphate and F6P
- 3-carbon unit is transferred from sedoheptulose 5-phosphate to G3P -> fructose-6-phosphate and
the four-carbon sugar erythrose-4-phosphate
- transaldolase (requires no cofactor)
C. Xylulose 5-Phosphate and Erythrose 4-Phosphate to F6P and G3P
- TPP-dependent transketolase
SUMMARY of REACTIONS (STOICHIOMETRY)
3G6P + 6NADP+
-> 2F6P + 3CO2 + G3P + 6NADPH + 6H+
REGULATION of the PATHWAY
A. Rate of the Glucose-6-Phosphate Dehydrogenase (G6PD) Reaction
- regulate the flux of glucose-6-phosphate
- controlled by the availability of its substrate NADP+
so that the pathway flux increases in response to
increasing levels of NADP+
(which indicates increased cellular demand for NADPH)
B. NADP+
- cellular concentration is the major factor
- availability regulates the rate-limiting G6PD reaction
USES of NADPH
A. Reductive Biosynthesis
- part of the energy of glucose 6-phosphate is conserved in NADPH
1. NADPH
- high-energy molecule (part of the energy of glucose 6-phosphate is conserved in NADPH)
- electrons are destined for use in reductive biosynthesis of macromolecules (of fatty acids and
steroids -> anabolism)
- cells keep the [NADP+
]/[NADPH] ratio near 0.01 (which favors reductive biosynthesis)
2. NADH
- used in oxidative metabolism (catabolism)
- cells keep the [NAD+
]/[NADH] ratio near 1000 (which favors metabolite oxidation)
B. Reduction of H2O2
1. H2O2 - one of a family of reactive oxygen species
- formed from partial reduction of molecular O2
- formed continuously
- as by-product of aerobic metabolism
- through reactions with drugs and environmental toxins
- diminished levels of antioxidants -> oxidative stress
highly reactive -> damage to
- DNA
- proteins
- unsaturated lipids -> cell death
- reactive oxygen intermediates are implicated in
- reperfusion injury
- cancer
- inflammatory disease
- aging
- protective mechanisms of the cell
2. Enzymes that Catalyze Antioxidant Reactions
a. Glutathione Peroxidase
- selenium-requiring
- converts reduced glutathione (tripeptide thiol, ->-glutamylcysteinylglycine) -> oxidized
glutathione -> glutathione reductase using NADPH as a source of reducing
electrons -> regeneration of reduced glutathione
- chemically detoxify H2O2
i. RBCs - totally dependent on HMP pathway for NADPH supply
- glucose 6-phosphate dehydrogenase defect -> decreased NADPH levels -> nonreduction of oxidized glutathione -> H2O2 accumulation -> membrane instability -> lysis
b. Superoxide Dismutase
c. Catalase
3. Antioxidant Chemicals
- detoxify oxygen intermediates
- correlated with
- reduced risk for certain types of cancers
- reduced frequency of other chronic health problems
(- clinical trials with antioxidants as dietary supplements have failed to show clear
beneficial effects)
a. Ascorbic Acid (Vitamin C)
b. Vitamin E
c. B-Carotene
- dietary supplementation -> rate of lung cancer in smokers increased rather thandecreased
C. Cytochrome P450 Monooxygenase System
1. Functions
- major pathway for the hydroxylation of aromatic and aliphatic compounds (steroids, alcohol,
drugs, other compounds)
- detoxify drugs and other compounds -> converting to soluble form -> renal excretion
2. Monooxygenases (Mixed Function Oxidases)
- incorporate one atom from molecular oxygen into a substrate (creating a hydroxyl group)
- the other atom reduced to water
- provides the reducing equivalents
- a supply of NADPH is critical for the liver microsomal cytochrome P450
monooxygenase system
b. Overall Reaction Catalyzed by a Cytochrome P450 Enzyme
4. Mitochondrial Cytochrome P450 Monooxygenase System
- participate in hydroxylation of steroids -> more water soluble
a. Placenta, Ovaries, Testes, Adrenal Cortex
- hormone-producing tissues
- hydroxylate intermediates in the conversion of cholesterol to steroid hormones
b. Liver - uses the system in bile acid synthesis
c. Kidney
- uses the system to hydroxylate 25-hydroxycholecalciferol (vitamin D) -> biologically
active 1, 25- hydroxylated form
5. Microsomal Cytochrome P450 Monooxygenase System
- associated with the endoplasmic reticulum membranes particularly in the liver
a. Detoxification of Foreign Compounds (Xenobiotics)
i. Drugs
ii. Pollutants
- petroleum products
- carcinogens
- pesticides
b. Purposes of the Modification
i. Activate or inactivate a drug
ii. Make a toxic compound more soluble -> excretion in the urine or feces
c. New Hydroxyl Group
- serve as site for conjugation with a polar compound (glucuronic acid) -> increased
solubility
D. Phagocytosis by WBCs (Neutrophils, Macrophages, Monocytes)
1. Phagocytosis
- ingestion by receptor-mediated endocytosis of
- microorganisms
- foreign particles
- cellular debris
- by - neutrophils
- macrophages (monocytes)
2. Bacterial Killing Mechanisms
a. Oxygen-Dependent Mechanisms
i. Myeloperoxidase (MPO) System
- most potent of the bactericidal mechanisms
ii. Other Systems
- involving the generation of oxygen-derived free radicals
b. Oxygen-Independent Systems
- utilize pH changes in the phagolysosome and lysosomal enzymes destruction of
pathogens
3. Mechanism
- invading bacterium -> recognized by the immune system -> attacked by antibodies -> binding to
a receptor on a phagocytic cell -> phagocytosis -> internalization of the microorganism
-> NADPH oxidase (WBC cell membrane) -> conversion of molecular O2 to
superoxide (respiratory burst - rapid oxygen consumption accompanying superoxide
formation) -> converted to H2O2 by superoxide dismutase (SOD) -> addition of
chloride ions -> hypochlorous acid (HOCl) formation -> bacterial killing
a. Excess H2O2
- neutralized by
- catalase
- glutathione peroxidase
4. NADPH Oxidase
- hormonally regulated complex enzyme
- subunits contain
- cytochrome
- flavin coenzymes
- electrons move from NADPH to O2 via FAD and heme -> generate O2
-
5. Genetic Deficiencies of NADPH Oxidase -> Chronic Granulomatosis
a. Chronic Granulomatosis
- severe, persistent chronic pyogenic infections
- formation of granulomas (nodular areas of inflammation) that sequester the bacteria
that were not destroyed
G6PD DEFICIENCY
- most common disease-producing abnormality in humans
- highest prevalence in the
- Middle East
- tropical Africa
- Asia
- parts of the Mediterranean
- inherited disease (X-linked) characterized by hemolytic anemia due to inability to detoxify oxidizing
agents
- family of deficiencies caused by >400 different mutations in the gene coding for G6PD
- some cause clinical symptoms
- shortened life span of patient due to complications of from chronic hemolysis
- increased resistance to falciparum malaria
A. Role of G6PD in RBCs
- decreased G6PD activity -> impaired NADPH formation increases the sensitivity of red blood cells to
oxidative stress -> failure to maintain adequate amount of reduced glutathione -> impaired
detoxification of free radicals and peroxides -> diminished stability -> hemolysis
1. Glutathione
- help maintain the reduced state of sulfhydryl groups of proteins (hemoglobin)
- oxidation of sulfhydryl groups -> protein denaturation -> form insoluble
masses (Heinz bodies) -> attach to RBC membranes
- additional membrane protein oxidation -> rigid and nondeformable RBCs ->
removed from the circulation by macrophages (liver, spleen)
- all cells are affected but most severe in RBCs
- PPP provides the only means of NADPH generation in RBCs
- RBCs are devoid of nucleus and ribosomes -> cannot renew supply of enzymes
- other tissues have alternative sources of NADPH (NADP+ dependent malate dehydrogenases)
B. Precipitating Factors in G6PD Deficiency
- most individuals who have inherited 1 of the many G6PD mutations do not show clinical manifestations
- some patients with G6PD deficiency develop hemolytic anemia if they
- are treated with oxidant drugs
- ingest fava beans
- contract a severe infection
1. Oxidant Drugs
a. Antibiotics
- sulfamethoxazole
- chloramphenicol
b. Antimalarials
- primaquine
c. Antipyretics
- acetanilid
- aspirin
d. Nitrofurans
2. Favism
- G6PD deficiency exacerbated (hemolytic effect) by consumption of fava beans usually within
24-48 hours after consumption
- not observed in all patients with G6PD deficiency
- all patients with favism have G6PD deficiency
- Mediterranean variant of G6PD deficiency is particularly susceptible
a. Fava Bean
- dietary staple in Mediterranean region
3. Infection
- most common precipitating factor of hemolysis in G6PD deficiency
- infection -> inflammatory response -> generation of free radicals in macrophages -> diffuse
into RBCs -> oxidative damage
4. Neonatal Jaundice
- from impaired hepatic catabolism or increased bilirubin production
- 1-4 days after birth
- may be severe
C. Properties of the Variant Enzyme
1. Some Mutations
- do not disrupt the structure of the enzyme’s active site -> no effect on enzymatic activity
2. Mutant Enzymes
- show altered kinetic properties
a. Decreased catalytic activity
b. Decreased stability
c. Alteration of binding affinity for NADP+
, NADPH, or glucose 6-phosphate
3. Severity of the Disease
- correlates with the amount of residual enzyme activity in the RBCs
Severity of the Disease Table
4. G6PD A-
- prototype of the moderate (class III) form of the disease
- RBCs contain unstable but kinetically normal G6PD with most of the enzyme activity present in
the reticulocytes and younger RBCs (oldest RBCs contain the lowest level of enzyme
activity -> preferentially removed in hemolytic episode)
5. G6PD Mediterranean
- prototype of the more severe (class II) deficiency
- enzyme shows normal stability but scarcely detectable activity
6. Class I Mutations
- often associated with chronic nonspherocytic anemia (occurs even in the absence of oxidative
stress)
D. Molecular Biology of G6PD
1. Mutations
- cloning and G6PD gene and sequencing of its complimentary DNA -> identification of
mutations (most are missense point mutations in the coding region of the gene) that
cause G6PD deficiency
a. G6PD A-
, G6PD Mediterranean
- have mutant enzymes that differ from the normal variant by a single amino acid
b. Locations
i. Clustered Near the Carboxyl Ends of the Enzyme
- cause nonspherocytic hemolytic anemia
ii. Amino End of the Enzyme
- cause milder forms
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