Xenobiotics and cyt p450 by dr rajender
drrajenarya
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Feb 24, 2015
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About This Presentation
metabolism of xenobiotis, drugs, medicine, carcinogen generation by enzymes like cyt p450 mono oxigenases, prostaglandin synthase ect. alcohol metabolism, toxin metabolism, definition of genobiotics, biotransformation, detoxification. effects on health
Slide Content
Xenobiotics Metabolism
CYP450
Dr. Rajender Kumar
P.G. Biochemistry
Pt. B.D.S.P.G.I.M.S. Rohtak
CYP450
Dr. Rajender Kumar
P.G. Biochemistry
Pt. B.D.S.P.G.I.M.S. Rohtak
Introduction
A xenobiotic is a foreign chemical substance found
within an organism that is not normally, naturally
produced by or expected to be present within that
organism. It can also cover substances which are
present in much higher concentrations than are usual
Examples- Drugs, food additives, pollutants,
insecticides, chemical carcinogens etc
They enter body mainly with food or as medications
Three principal entries: intestine, lungs, skin
A xenobiotic is a foreign chemical substance found
within an organism that is not normally, naturally
produced by or expected to be present within that
organism. It can also cover substances which are
present in much higher concentrations than are usual
Examples- Drugs, food additives, pollutants,
insecticides, chemical carcinogens etc
They enter body mainly with food or as medications
Three principal entries: intestine, lungs, skin
Entry of xenobiotic into cells
•Simple diffusion – lipophilic substances, depends on
concetration gradient (liver – freely permeable, big pores
in cell membrane, most affected in poisoning)
•Facilitated diffusion – transporters
•Active transport – primary, secondary
•Endocytosis
•xenobiotics structurally similar with physiological
substrates can utilize all available transport systems
•Simple diffusion – lipophilic substances, depends on
concetration gradient (liver – freely permeable, big pores
in cell membrane, most affected in poisoning)
•Facilitated diffusion – transporters
•Active transport – primary, secondary
•Endocytosis
•xenobiotics structurally similar with physiological
substrates can utilize all available transport systems
Excretion of xenobiotics from cell
•primary active transport – needs energy: ATP hydrolysis
•special ATP-ases called ABC (ATP binding cassettes)
localized in cell membranes, export xenobiotics from
cells into ECF
•MRP (multidrug resistance proteins) – in increased
expresion, they cause the resistance towards medicines
•primary active transport – needs energy: ATP hydrolysis
•special ATP-ases called ABC (ATP binding cassettes)
localized in cell membranes, export xenobiotics from
cells into ECF
•MRP (multidrug resistance proteins) – in increased
expresion, they cause the resistance towards medicines
Excretion of xenobiotics from body
•chemically modified (more polar) xenobiotics are
excreted by urine, bile, stool, or sweat
•volatile substance by lungs
•excretion into human milk
•intestinal deconjugation and reabsorption
sometimes occur - enterohepatic circulation
•chemically modified (more polar) xenobiotics are
excreted by urine, bile, stool, or sweat
•volatile substance by lungs
•excretion into human milk
•intestinal deconjugation and reabsorption
sometimes occur - enterohepatic circulation
Biotransformation and detoxification
Biotransformation is Conversion of lipophilic to water-
soluble chemicals catalyzed by enzymes in the liver
and other tissues
In most cases, biotransformation lessens the toxicity
of xenobiotics
The term “detoxification” is sometimes used for
many of the reactions involved in the metabolism of
xenobiotics
Biotransformation is Conversion of lipophilic to water-
soluble chemicals catalyzed by enzymes in the liver
and other tissues
In most cases, biotransformation lessens the toxicity
of xenobiotics
The term “detoxification” is sometimes used for
many of the reactions involved in the metabolism of
xenobiotics
Increasingly humans are subjected to exposure to various
foreign chemicals xenobiotics. Knowledge of the metabolism of
xenobiotics is basic to a rational understanding of
pharmacology and therapeutics
pharmacy
toxicology
management of cancer, and drug addiction
All these areas involve administration of, or exposure to,
xenobiotics
Biomedical importance
foreign chemicals xenobiotics. Knowledge of the metabolism of
xenobiotics is basic to a rational understanding of
pharmacology and therapeutics
pharmacy
toxicology
management of cancer, and drug addiction
All these areas involve administration of, or exposure to,
xenobiotics
Biomedical importance
1. facilitates excretion: Converts lipophilic to
hydrophilic compounds
2. Detoxification/inactivation: converts
chemicals to less toxic forms
3. Metabolic activation: converts chemicals to
more toxic active forms or converts inactive
drug to its active form
Purpose of Biotransformation
hydrophilic compounds
2. Detoxification/inactivation: converts
chemicals to less toxic forms
3. Metabolic activation: converts chemicals to
more toxic active forms or converts inactive
drug to its active form
Purpose of Biotransformation
Sites of biotransformation
•Liver
– Primary site! Rich in enzymes
– Acts on endogenous and exogenous compounds
•Extrahepatic metabolism sites
–Intestinal wall
•Sulfate conjugation
•Esterase and lipases - important in prodrug
metabolism
–Lungs, kidney, placenta, brain, skin, adrenal glands
•Liver
– Primary site! Rich in enzymes
– Acts on endogenous and exogenous compounds
•Extrahepatic metabolism sites
–Intestinal wall
•Sulfate conjugation
•Esterase and lipases - important in prodrug
metabolism
–Lungs, kidney, placenta, brain, skin, adrenal glands
Metabolism of Xenobiotics
phase 1
1. Hydroxylation
Monooxygenases or cytochrome P450s
Hydroxylation may terminate the action of a drug
2. deamination, dehalogenation,
desulfuration, epoxidation,
peroxygenation, and reduction, hydrolysis
•Purpose
–Introduction of polar functional groups in a molecules
♣ Increase a molecule’s polarity
♣ Does provide a site for phase II metabolism
phase 1
1. Hydroxylation
Monooxygenases or cytochrome P450s
Hydroxylation may terminate the action of a drug
2. deamination, dehalogenation,
desulfuration, epoxidation,
peroxygenation, and reduction, hydrolysis
•Purpose
–Introduction of polar functional groups in a molecules
♣ Increase a molecule’s polarity
♣ Does provide a site for phase II metabolism
Metabolism of Xenobiotics
Phase 2
conjugation with
glucuronic acid,
sulfate,
acetate,
glutathione,
methyl
or certain amino acids,
The overall purpose of phases II of metabolism of
xenobiotics is to increase their water solubility
(polarity) and thus excretion from the body
Phase 2
conjugation with
glucuronic acid,
sulfate,
acetate,
glutathione,
methyl
or certain amino acids,
The overall purpose of phases II of metabolism of
xenobiotics is to increase their water solubility
(polarity) and thus excretion from the body
Xenobiotic-Metabolizing Enzymes
(XME)
Phase 1
•Cytochromes P450
•Flavin Containing Monooxygenase
•Epoxide Hydrolase
•Alcohol /Aldehyde Dehydrogenases
•Monoamine Oxidases
•Xanthine oxidase
Phase 2 “Transferases”
Sulfotransferases (ST)
UDP-glucuronosyltransferases (UGT)
Glutathione S-transferases (GST)
(XME)
Phase 1
•Cytochromes P450
•Flavin Containing Monooxygenase
•Epoxide Hydrolase
•Alcohol /Aldehyde Dehydrogenases
•Monoamine Oxidases
•Xanthine oxidase
Phase 2 “Transferases”
Sulfotransferases (ST)
UDP-glucuronosyltransferases (UGT)
Glutathione S-transferases (GST)
Cytochrome P450
•superfamily of heme enzymes (many isoforms) can
catalyze different reaction types, mainly hydroxylation
•Human:18 families, 43 subfamilies, 57 sequenced genes
•can be induced and inhibited
•occur in most tissues (except of muscles and erythrocytes)
•the highest amount in the liver (ER)
•exhibit genetic polymorphism (atypical biotransformations)
•Nomencleature:
CYP1A2
family subfamily
individual member of that
subfamily
•superfamily of heme enzymes (many isoforms) can
catalyze different reaction types, mainly hydroxylation
•Human:18 families, 43 subfamilies, 57 sequenced genes
•can be induced and inhibited
•occur in most tissues (except of muscles and erythrocytes)
•the highest amount in the liver (ER)
•exhibit genetic polymorphism (atypical biotransformations)
•Nomencleature:
CYP1A2
family subfamily
individual member of that
subfamily
Location of Cytochrome P450
•They are present in highest amount in liver and small
intestine but are probably present in all tissues
•In liver and most other tissues, they are present mainly
in the membranes of the smooth endoplasmic
reticulum
•In the adrenal, they are found in mitochondria as well
as in the endoplasmic reticulum
•The various hydroxylases present in that organ play an
important role in cholesterol and steroid biosynthesis
Cytochrome P450
intestine but are probably present in all tissues
•In liver and most other tissues, they are present mainly
in the membranes of the smooth endoplasmic
reticulum
•In the adrenal, they are found in mitochondria as well
as in the endoplasmic reticulum
•The various hydroxylases present in that organ play an
important role in cholesterol and steroid biosynthesis
Cytochrome P450
•At least six isoforms of cytochrome P450 are
present in the endoplasmic reticulum of human liver,
•acting on both xenobiotics and endogenous compounds
•P450 metabolizes certain widely used solvents and also
components found in tobacco smoke, many of which are
established carcinogens
•Most isoforms of cytochrome P450 are inducible
•Induction of cytochrome P450 has important clinical
implications, since it is a biochemical mechanism of
drug interaction
Cytochrome P450
present in the endoplasmic reticulum of human liver,
•acting on both xenobiotics and endogenous compounds
•P450 metabolizes certain widely used solvents and also
components found in tobacco smoke, many of which are
established carcinogens
•Most isoforms of cytochrome P450 are inducible
•Induction of cytochrome P450 has important clinical
implications, since it is a biochemical mechanism of
drug interaction
Cytochrome P450
Certain isoforms of cytochrome P450 (eg, CYP1A1) are
particularly involved in the metabolism of polycyclic
aromatic hydrocarbons (PAHs) and related
molecules
for this reason they were formerly called aromatic
hydrocarbon hydroxylases (AHHs)
This enzyme is important in the metabolism of PAHs
and in carcinogenesis produced by these agents
Cytochrome P450
particularly involved in the metabolism of polycyclic
aromatic hydrocarbons (PAHs) and related
molecules
for this reason they were formerly called aromatic
hydrocarbon hydroxylases (AHHs)
This enzyme is important in the metabolism of PAHs
and in carcinogenesis produced by these agents
Cytochrome P450
Certain cytochrome P450s exist in polymorphic forms
(genetic isoforms), some of which exhibit low catalytic
activity
CYP2A6 involved in the metabolism of nicotine to conitine,
three alleles have been identified, a wild type and two null
or inactive alleles
Individuals with the null alleles, who have impaired
metabolism of nicotine, are apparently protected against
becoming tobacco- dependent smokers
because their blood and brain concentrations of nicotine
remain elevated longer
It has been speculated that inhibiting CYP2A6 may be a
novel way to help prevent and to treat smoking
Cytochrome P450
(genetic isoforms), some of which exhibit low catalytic
activity
CYP2A6 involved in the metabolism of nicotine to conitine,
three alleles have been identified, a wild type and two null
or inactive alleles
Individuals with the null alleles, who have impaired
metabolism of nicotine, are apparently protected against
becoming tobacco- dependent smokers
because their blood and brain concentrations of nicotine
remain elevated longer
It has been speculated that inhibiting CYP2A6 may be a
novel way to help prevent and to treat smoking
Cytochrome P450
•some xenobiotics induce the synthesis of CYP – the
metabolic capacity of CYP is enhanced
• if administered inducer + drug, both metabolized by the
same CYP isoform and drug is metabolized faster, drug
is less effective
•some xenobiotics inhibit CYP
•the most common isoform CYP3A4 metabolizes more
than 120 different pharmaceutical drugs
•inhibitors of CYP3A4 are e.g. macrolide antibiotics,
grapefruit (furanocoumarins), ketoconazole
• if administered inhibitor + drug, increased drug level,
overdosing , side effects
Inducers and inhibitors of CYP450
metabolic capacity of CYP is enhanced
• if administered inducer + drug, both metabolized by the
same CYP isoform and drug is metabolized faster, drug
is less effective
•some xenobiotics inhibit CYP
•the most common isoform CYP3A4 metabolizes more
than 120 different pharmaceutical drugs
•inhibitors of CYP3A4 are e.g. macrolide antibiotics,
grapefruit (furanocoumarins), ketoconazole
• if administered inhibitor + drug, increased drug level,
overdosing , side effects
Inducers and inhibitors of CYP450
cytochrome P450 contains three cofactors and two enzymes:
• NADPH+H+, FAD, heme
• NADPH:CYP reductase (separates 2 H 2 e- + 2H+) and
cytochrome P-450 hydroxylase
Lipids are also components of the cytochrome P450 system
The preferred lipid is phosphatidylcholine, which is the major
lipid found in membranes of the endoplasmic reticulum
Components of cytochrome P450
• NADPH+H+, FAD, heme
• NADPH:CYP reductase (separates 2 H 2 e- + 2H+) and
cytochrome P-450 hydroxylase
Lipids are also components of the cytochrome P450 system
The preferred lipid is phosphatidylcholine, which is the major
lipid found in membranes of the endoplasmic reticulum
Components of cytochrome P450
Mechanism of CYP hydroxylation
The formation of hydroxyl group
monooxygenase: one O atom from O
2
molecule is
incorporated into substrate between C and H (R-H → R-OH )
The second O atom + 2H from NADPH+H
+
give water
R-H + O
2
+ NADPH + H
+
→ R-OH + H
2
O + NADP
+
2 e
-
+ 2 H
+
The formation of hydroxyl group
monooxygenase: one O atom from O
2
molecule is
incorporated into substrate between C and H (R-H → R-OH )
The second O atom + 2H from NADPH+H
+
give water
R-H + O
2
+ NADPH + H
+
→ R-OH + H
2
O + NADP
+
2 e
-
+ 2 H
+
Mechanism of CYP hydroxylation
PHASE I REACTIONS
•Hydroxylation is the chief reaction involved
•The responsible enzymes are called monooxygenases
and cytochrome P450s
•Hydroxylation by CYP450 occurs in endogenous and
exogenous substrates
•Endoplasmic reticulum: squalene, cholesterol, bile
acids, FA desaturation, prostaglandins, xenobiotics
•Mitochondria: steroidal hormones
hydroxylation
•The responsible enzymes are called monooxygenases
and cytochrome P450s
•Hydroxylation by CYP450 occurs in endogenous and
exogenous substrates
•Endoplasmic reticulum: squalene, cholesterol, bile
acids, FA desaturation, prostaglandins, xenobiotics
•Mitochondria: steroidal hormones
hydroxylation
Example of hyroxylation
Flavin-containing Monooxygenase
•FAD-containing monooxygenases
(FMO) oxidize nucleophilic
nitrogen, sulfur and phosphorus
heteroatoms of a variety of
xenobiotics
• FMO’s are not inducible and are
constitutively expressed
•Can be inhibited by other
substrates
• Located in microsomal fraction of
liver, kidney, and lung
FMO
FAD
FMO
FADH
2
NADP
+
FMO
FADHOOH
NADP
+
FMO
FADHOH
NADP
+
NADPH
+ H
+
O
2
X
XO
NADP
+
H2O
FADHOOH is 4a-hydroperoxyflavin
FADHOH is 4a-hydroxyflavin
FMO
FAD
•FAD-containing monooxygenases
(FMO) oxidize nucleophilic
nitrogen, sulfur and phosphorus
heteroatoms of a variety of
xenobiotics
• FMO’s are not inducible and are
constitutively expressed
•Can be inhibited by other
substrates
• Located in microsomal fraction of
liver, kidney, and lung
FMO
FAD
FMO
FADH
2
NADP
+
FMO
FADHOOH
NADP
+
FMO
FADHOH
NADP
+
NADPH
+ H
+
O
2
X
XO
NADP
+
H2O
FADHOOH is 4a-hydroperoxyflavin
FADHOH is 4a-hydroxyflavin
FMO
FAD
FMO Example Reactions
N
N
CH
3
N
N
CH
3
excretion
nicotine
O
N
O
CH
3
H
N
O
CH3
OH
nicotine-1'-N-oxide
2-acetylaminofluorene (2-AAF)
caricnogen
N-hydroxy-2-AAF
FMO
FMO
N
N
CH
3
N
N
CH
3
excretion
nicotine
O
N
O
CH
3
H
N
O
CH3
OH
nicotine-1'-N-oxide
2-acetylaminofluorene (2-AAF)
caricnogen
N-hydroxy-2-AAF
FMO
FMO
Epoxides are highly reactive and mutagenic or carcinogenic
can form during Phase I (CYP/COX)
Epoxide hydrolase converting them into much less reactive
dihydrodiols
There are 5 distinct forms of EH in mammals:
1. Microsomal epoxide hydrolase (mEH)
2. Soluble epoxide hydrolase (sEH)
3. Cholesterol epoxide hydrolase
4. LTA4 hydrolase
5. Hepoxilin hydrolase
mEH and sEH hydrolyze xenobiotic epoxides while the latter 3
hydrolases act on endogenous substrates
Epoxides
can form during Phase I (CYP/COX)
Epoxide hydrolase converting them into much less reactive
dihydrodiols
There are 5 distinct forms of EH in mammals:
1. Microsomal epoxide hydrolase (mEH)
2. Soluble epoxide hydrolase (sEH)
3. Cholesterol epoxide hydrolase
4. LTA4 hydrolase
5. Hepoxilin hydrolase
mEH and sEH hydrolyze xenobiotic epoxides while the latter 3
hydrolases act on endogenous substrates
Epoxides
Hydrolysis in plasma by esterases (suxamethonium
by cholinesterase)
Alcohol and aldehyde dehydrogenase in liver
cytosolic (ethanol)
Monoamine oxidase in mitochondria (tyramine,
noradrenaline, dopamine, amines)
Xanthine oxidase (6-mercaptopurine, uric acid
production)
Enzymes for particular substrates (tyrosine
hydroxylase, dopa-decarboxylase etc.)
Other (non-microsomal) Phase I reactions
by cholinesterase)
Alcohol and aldehyde dehydrogenase in liver
cytosolic (ethanol)
Monoamine oxidase in mitochondria (tyramine,
noradrenaline, dopamine, amines)
Xanthine oxidase (6-mercaptopurine, uric acid
production)
Enzymes for particular substrates (tyrosine
hydroxylase, dopa-decarboxylase etc.)
Other (non-microsomal) Phase I reactions
RCH
2
NH
2
+O
2
+H
2
O
2
RCHO+NH
3+H
2O
•MAO catalyze the oxidative deamination of monoamines
•Oxygen is used to remove an amine group from a molecule,
resulting in the corresponding aldehyde and ammonia
• MAO are found bound to the outer membrane of
mitochondria in most cell types in the body
•They belong to protein family of flavin containing amine
oxidoreductases
Non-Microsomal Oxidation Reactions
2
NH
2
+O
2
+H
2
O
2
RCHO+NH
3+H
2O
•MAO catalyze the oxidative deamination of monoamines
•Oxygen is used to remove an amine group from a molecule,
resulting in the corresponding aldehyde and ammonia
• MAO are found bound to the outer membrane of
mitochondria in most cell types in the body
•They belong to protein family of flavin containing amine
oxidoreductases
Non-Microsomal Oxidation Reactions
Hydrolytic Reactions
R
1
R
2
Name Susceptibility
to Hydrolysis
CO Ester Highest
CSThioester
OOCarbonate
CN Amide
ONCarbamate
NN Ureide Lowest
Naming carbonyl - heteroatom groups
Hydrolyzes (adds water to) esters and amides and their
isosteres
Enzymes: Non-microsomal hydrolases
however amide hydrolysis appears to be mediated by liver
microsomal amidases, esterases, deacylases
R
1CR
2
O
d-
d+
O CH
3
CO
2
H
O
OH
CO
2
H
CH
3
O
OH
ASA
Acetylsalicylic Acid
esterase
R
1
R
2
Name Susceptibility
to Hydrolysis
CO Ester Highest
CSThioester
OOCarbonate
CN Amide
ONCarbamate
NN Ureide Lowest
Naming carbonyl - heteroatom groups
Hydrolyzes (adds water to) esters and amides and their
isosteres
Enzymes: Non-microsomal hydrolases
however amide hydrolysis appears to be mediated by liver
microsomal amidases, esterases, deacylases
R
1CR
2
O
d-
d+
O CH
3
CO
2
H
O
OH
CO
2
H
CH
3
O
OH
ASA
Acetylsalicylic Acid
esterase
PHASE II REACTIONS
CONJUGATIONS
CONJUGATIONS
Glucuronidation
•most frequent conjugation reaction.
•UDP-glucuronic acid (UDPGA) is the glucuronyl donor
•UDP-glucuronyl transferases (UGT), present in both the
endoplasmic reticulum(ER) and cytosol, are the catalysts
•Molecules such as 2-acetylaminofluorene (a carcinogen),
aniline, benzoic acid, meprobamate (a tranquilizer),
phenol, and many steroids are excreted as glucuronides
•The glucuronide may be attached to oxygen, nitrogen,
or sulfur groups of the substrates
•most frequent conjugation reaction.
•UDP-glucuronic acid (UDPGA) is the glucuronyl donor
•UDP-glucuronyl transferases (UGT), present in both the
endoplasmic reticulum(ER) and cytosol, are the catalysts
•Molecules such as 2-acetylaminofluorene (a carcinogen),
aniline, benzoic acid, meprobamate (a tranquilizer),
phenol, and many steroids are excreted as glucuronides
•The glucuronide may be attached to oxygen, nitrogen,
or sulfur groups of the substrates
Glucuronidation
Some alcohols, arylamines, and phenols are sulfated
other biologic sulfation reactions are sulfation of steroids,
glycosaminoglycans, glycolipids, and glycoproteins
The sulfate donor is adenosine 3-phosphate-5-
phosphosulfate (PAPS)
Leads to inactive water-soluble metabolites
Sulfation
other biologic sulfation reactions are sulfation of steroids,
glycosaminoglycans, glycolipids, and glycoproteins
The sulfate donor is adenosine 3-phosphate-5-
phosphosulfate (PAPS)
Leads to inactive water-soluble metabolites
Sulfation
Glutathione (γ-glutamyl-cysteinylglycine) is a tripeptide
consisting of glutamic acid, cysteine, and glycine
It detoxify electrophilic chemicals
Conjugation with Glutathione
consisting of glutamic acid, cysteine, and glycine
It detoxify electrophilic chemicals
Conjugation with Glutathione
The glutamyl and glycinyl groups belonging to
glutathione are removed by specific Enzymes
acetyl group (donated by acetyl- CoA) is added to the
amino group of the remaining cysteinyl moiety
The resulting compound is a mercapturic acid, a
conjugate of L acetylcysteine, which is then excreted in the
urine
Mechanism Conjugation with Glutathione
glutathione are removed by specific Enzymes
acetyl group (donated by acetyl- CoA) is added to the
amino group of the remaining cysteinyl moiety
The resulting compound is a mercapturic acid, a
conjugate of L acetylcysteine, which is then excreted in the
urine
Mechanism Conjugation with Glutathione
Reaction catalyzed by acetyltransferases present in the
cytosol of various tissues, particularly liver
Important for drugs with primary amino groups
The drug isoniazid, used in the treatment of tuberculosis,
is subject to acetylation
Acetylation does NOT increase water solubility
Causes Detoxification or termination of drug activity
Acetylation
isoniazid
cytosol of various tissues, particularly liver
Important for drugs with primary amino groups
The drug isoniazid, used in the treatment of tuberculosis,
is subject to acetylation
Acetylation does NOT increase water solubility
Causes Detoxification or termination of drug activity
Acetylation
isoniazid
A few xenobiotics are subject to methylation by
methyltransferases
S-adenosylmethionine is methyl donor
Key for biosynthesis of many compounds Important in the
inactivation of physiologically active biogenic amines
neurotransmitters norepinephrine, dopamine, serotonin,
histamine
Minor pathway in the metabolism of drugs
Methylation does NOT increase water solubility
Most methylated products are inactive
Methylation
methyltransferases
S-adenosylmethionine is methyl donor
Key for biosynthesis of many compounds Important in the
inactivation of physiologically active biogenic amines
neurotransmitters norepinephrine, dopamine, serotonin,
histamine
Minor pathway in the metabolism of drugs
Methylation does NOT increase water solubility
Most methylated products are inactive
Methylation
• with glycine, taurine
• xenobiotics with -COOH groups are the substrates
• endogenous example: conjugated bile acids
Approximately 76% of aspirin is metabolized through amino
acid conjugation
Salicyluric acid, the glycine conjugate of salicyclic acid, is
the main metabolite of aspirin
Conjugation with amino acids
• xenobiotics with -COOH groups are the substrates
• endogenous example: conjugated bile acids
Approximately 76% of aspirin is metabolized through amino
acid conjugation
Salicyluric acid, the glycine conjugate of salicyclic acid, is
the main metabolite of aspirin
Conjugation with amino acids
Peroxidases
RH+O
2
PHS
R-OOH+X or XH
PHS
MOx
LOx
ROH+XO or X
R-OOH+carcinogen
PHS
MOx
LOx
active carcinogen
(ie. aflatoxin)
1. Prostaglandin H synthase (PHS, COX1,2) (brain, lung,
kidney, GI tract, urinary bladder)
2. Myeloperoxidase (MOx) (leukocytes)
3. Lactoperoxidase (LOx) (mammary gland)
Most oxidative biotransformations require reduced cofactors
NADPH and NADH, except for peroxidases that couple the
reduction of hydrogen peroxide and lipid hydroperoxides to
the oxidation of other substrates called cooxidation
RH+O
2
PHS
R-OOH+X or XH
PHS
MOx
LOx
ROH+XO or X
R-OOH+carcinogen
PHS
MOx
LOx
active carcinogen
(ie. aflatoxin)
1. Prostaglandin H synthase (PHS, COX1,2) (brain, lung,
kidney, GI tract, urinary bladder)
2. Myeloperoxidase (MOx) (leukocytes)
3. Lactoperoxidase (LOx) (mammary gland)
Most oxidative biotransformations require reduced cofactors
NADPH and NADH, except for peroxidases that couple the
reduction of hydrogen peroxide and lipid hydroperoxides to
the oxidation of other substrates called cooxidation
Prostaglandin H synthase
COOH
arachidonic acid
O2+O
2
O
O
COOH
OOH
PGG2
cyclooxygenase
peroxidase
X or 2XH
XO or 2X + H2O
O
O
COOH
OH
PGH
2
prostacyclinthromboxane A
2prostaglandins
(PGD
2
, PGE
2
)
PHS (COX) has two catalytic activities:
1. a cyclooxygenase (COX) that converts
arachidonic acid to the cyclic endoperoxide-
hydroperoxide PGG
2
)
2. a peroxidase (that converts the
hydroperoxide to the corresponding alcohol
PGH
2
) which can result in the oxidation of
xenobiotics
3. COX-2 inhibitors include aspirin and ibuprofin
PHS can bioactivate carcinogens such as β-
napthylamine, a bladder carcinogen
NH
2
PHS
NH
DNA
damage
COOH
arachidonic acid
O2+O
2
O
O
COOH
OOH
PGG2
cyclooxygenase
peroxidase
X or 2XH
XO or 2X + H2O
O
O
COOH
OH
PGH
2
prostacyclinthromboxane A
2prostaglandins
(PGD
2
, PGE
2
)
PHS (COX) has two catalytic activities:
1. a cyclooxygenase (COX) that converts
arachidonic acid to the cyclic endoperoxide-
hydroperoxide PGG
2
)
2. a peroxidase (that converts the
hydroperoxide to the corresponding alcohol
PGH
2
) which can result in the oxidation of
xenobiotics
3. COX-2 inhibitors include aspirin and ibuprofin
PHS can bioactivate carcinogens such as β-
napthylamine, a bladder carcinogen
NH
2
PHS
NH
DNA
damage
Activation of prodrugs
CARCINOGENS
PAHs formed by:
- incomplete combustion of organic matter such as coal,
wood, oil, petrol and diesel
- coke production, vehicle and aircraft exhaust
- smoking cigarettes
- charbroiled meats
PAHs are also found in natural fuel deposits
A few PAHs are used to produce medicine, dyes, plastics, &
pesticides
Natural sources of PAHs include volcanoes and natural fires
Examples include Benzo(a)pyrene and Benzo(b)fluoranthene
PAH in environment
- incomplete combustion of organic matter such as coal,
wood, oil, petrol and diesel
- coke production, vehicle and aircraft exhaust
- smoking cigarettes
- charbroiled meats
PAHs are also found in natural fuel deposits
A few PAHs are used to produce medicine, dyes, plastics, &
pesticides
Natural sources of PAHs include volcanoes and natural fires
Examples include Benzo(a)pyrene and Benzo(b)fluoranthene
PAH in environment
- radicals formed by pyrolysis of hydrocarbons between
500 and 800ºC in zone of flame with insufficient O
2
- C1 and C2 fragments combine in reducing atmosphere
to form condensed aromatics
- on cooling, PAHs condense onto existing particles –
their distribution reflects their differing thermodynamic
stability in O
2
deficient flame
Mechanism of formation during combustion
Source %
Heating, power production51
Industrial producers 20
Incineration & open burning28
Vehicles 1
B(a)P in foodstuffsμg/kg
Charcoal broiled steak 8
Margarine 1-36
Sausages 4-50
Roasted coffee 1-13
Toast 0.5
500 and 800ºC in zone of flame with insufficient O
2
- C1 and C2 fragments combine in reducing atmosphere
to form condensed aromatics
- on cooling, PAHs condense onto existing particles –
their distribution reflects their differing thermodynamic
stability in O
2
deficient flame
Mechanism of formation during combustion
Source %
Heating, power production51
Industrial producers 20
Incineration & open burning28
Vehicles 1
B(a)P in foodstuffsμg/kg
Charcoal broiled steak 8
Margarine 1-36
Sausages 4-50
Roasted coffee 1-13
Toast 0.5
PAHs effects
•Some PAHs have been shown to be cancer causing
•Chronic Bronchitis
•Skin Problems
•Allergies
Fetus is at greater risk and susceptibility :
•Growth retardation
•Low birth weight
•Small head circumference
•Low IQ
•Damage DNA
•Disrupt endocrine systems, such as estrogen, thyroid, and
steroids
•Some PAHs have been shown to be cancer causing
•Chronic Bronchitis
•Skin Problems
•Allergies
Fetus is at greater risk and susceptibility :
•Growth retardation
•Low birth weight
•Small head circumference
•Low IQ
•Damage DNA
•Disrupt endocrine systems, such as estrogen, thyroid, and
steroids
CYP/PHS
O
EH
HO
OH
CYP/PHS
HO
OH
O
benzo[a]pyrene
(+) benzo[a]pyrene
7,8-oxide
(-) benzo[a]pyrene
7,8-dihydrodiol
(+) benzo[a]pyrene
7,8-dihydrodiol-9,10-epoxide
ULTIMATE CARCINOGEN
HN
N
N
N
O
HN
DNA
HO
OH
HO
BaP-N
2
-dG DNA adduct
DNA
GST/GSH
OH
GS
inactive (excreted)
O
CYP/PHS
OH
OH
inactive
Phase II
Phase II and
excretion
PAHs metabolites
O
EH
HO
OH
CYP/PHS
HO
OH
O
benzo[a]pyrene
(+) benzo[a]pyrene
7,8-oxide
(-) benzo[a]pyrene
7,8-dihydrodiol
(+) benzo[a]pyrene
7,8-dihydrodiol-9,10-epoxide
ULTIMATE CARCINOGEN
HN
N
N
N
O
HN
DNA
HO
OH
HO
BaP-N
2
-dG DNA adduct
DNA
GST/GSH
OH
GS
inactive (excreted)
O
CYP/PHS
OH
OH
inactive
Phase II
Phase II and
excretion
PAHs metabolites
•The first reaction is an epoxidation. With benzo(a)pyrene,
the product is the corresponding 7,8-epoxide that, in turn, is
subject of epoxide hydrolases to form stereoisomeric
dihydrodiols
•These are converted further to the 7,8-dihydrodiol-9,10-
epoxide. The terminal oxidase is cytochrome P-450
(CYP1A1). The diol epoxide can exist in 4 stereoisomeric
forms of which the key carcinogenic product is
benzo(a)pyrene-r-7,t-8-diol-t-9,10-epoxide
•PAH epoxides can then be conjugated with GSH. This
conjugation is regarded as a true detoxification reaction and
is mediated by glutathione transferase (GSTM1)
PAHs metabolites
the product is the corresponding 7,8-epoxide that, in turn, is
subject of epoxide hydrolases to form stereoisomeric
dihydrodiols
•These are converted further to the 7,8-dihydrodiol-9,10-
epoxide. The terminal oxidase is cytochrome P-450
(CYP1A1). The diol epoxide can exist in 4 stereoisomeric
forms of which the key carcinogenic product is
benzo(a)pyrene-r-7,t-8-diol-t-9,10-epoxide
•PAH epoxides can then be conjugated with GSH. This
conjugation is regarded as a true detoxification reaction and
is mediated by glutathione transferase (GSTM1)
PAHs metabolites
•The epoxides that are not conjugated with GSH are
converted into phenols and diols. These PAH
metabolites, however, are sometimes not sufficiently
polar to be excreted and are therefore conjugated with
glucuronic or sulfuric acids to enable excretion to
occur
•In addition to conjugation, the hydroxylated derivatives of
PAHs may undergo a number of oxidation and
hydroxylation reactions. These include the conversion
of phenols to phenol-epoxides and subsequently to
diphenols and triols, diols to tetrols and diol-epoxides,
and triols to triolepoxides and pentols
PAHs metabolites
converted into phenols and diols. These PAH
metabolites, however, are sometimes not sufficiently
polar to be excreted and are therefore conjugated with
glucuronic or sulfuric acids to enable excretion to
occur
•In addition to conjugation, the hydroxylated derivatives of
PAHs may undergo a number of oxidation and
hydroxylation reactions. These include the conversion
of phenols to phenol-epoxides and subsequently to
diphenols and triols, diols to tetrols and diol-epoxides,
and triols to triolepoxides and pentols
PAHs metabolites
Aflatoxin
Aflatoxins are naturally occurring mycotoxins that are produced
by many species of Aspergillus, a fungus.
They can be found on moldy peanuts, rice, corn and other crops.
Aflatoxin B1 is the most potent liver carcinogen.
Aspergillus fungus that procues aflatoxin Aspergillus fungus on corn
Aflatoxins are naturally occurring mycotoxins that are produced
by many species of Aspergillus, a fungus.
They can be found on moldy peanuts, rice, corn and other crops.
Aflatoxin B1 is the most potent liver carcinogen.
Aspergillus fungus that procues aflatoxin Aspergillus fungus on corn
O
O
O
O
O
OCH
3
*
*
isolated
e
-
-rich double bond
aflatoxin
O
O
O
O
O
OCH
3
*
*
O
ULTIMATE CARCINOGEN
CYP/PHS
DNA
NH
N
N
N
O
NH
2
DNA
O
O
O
O
O
OCH
3
HO
GST/GSH
O
O
O
O
O
OCH
3
*
*GS
OH
EH
inactive (excreted)
O
O
O
O
O
OCH
3
*
*HO
OH
*
*
AFB
1 N7-DNA
adduct
* electrophilic
some DNA activity
Epoxide hydrolase can detoxify aflatoxin-epoxide from binding to DNA, but still has some
mutagenic activity
Aflatoxin metabolism
O
O
O
O
OCH
3
*
*
isolated
e
-
-rich double bond
aflatoxin
O
O
O
O
O
OCH
3
*
*
O
ULTIMATE CARCINOGEN
CYP/PHS
DNA
NH
N
N
N
O
NH
2
DNA
O
O
O
O
O
OCH
3
HO
GST/GSH
O
O
O
O
O
OCH
3
*
*GS
OH
EH
inactive (excreted)
O
O
O
O
O
OCH
3
*
*HO
OH
*
*
AFB
1 N7-DNA
adduct
* electrophilic
some DNA activity
Epoxide hydrolase can detoxify aflatoxin-epoxide from binding to DNA, but still has some
mutagenic activity
Aflatoxin metabolism
N-Hydroxylation of AAF
N-Hydroxylation of AAF is the first metabolic step towards
the development of a carcinogenic agent
N-Hydroxylation of AAF is the first metabolic step towards
the development of a carcinogenic agent
Further Metabolism of N-HydroxyAAF Produces Cancer
N-HydroxyAAF undergoes phase II metabolism to the ultimate
carcingogen. The glucuronide pathway is also involved in
carcinogenesis
N-HydroxyAAF undergoes phase II metabolism to the ultimate
carcingogen. The glucuronide pathway is also involved in
carcinogenesis
Tobacco
•during cigarette burning?
• temperature about 900
o
C
• dried tobacco undergoes incomplete combustion
• nicotine partly passes to smoke, partly decomposes
•Nicotine: 0.9 mg/cig.
•Tar: 11 mg/cig.
Tobacco
• temperature about 900
o
C
• dried tobacco undergoes incomplete combustion
• nicotine partly passes to smoke, partly decomposes
•Nicotine: 0.9 mg/cig.
•Tar: 11 mg/cig.
Tobacco
Cigarette smoke contains
•free base of nicotine – binds to receptors in the brain
•CO – binds to hemoglobin to give carbonylhemoglobin
(tissue ischemia)
•nitrogen oxides – may generate reactive radical
species
•polycyclic aromatic hydrocarbons (PAH)(pyrene,
chrysene, benzo[a]pyrene …), main components of tar
•they can attack and damage DNA, carcinogens
•other substances (N2, CO2, HCN, CH4, esters …)
Tobacco
•free base of nicotine – binds to receptors in the brain
•CO – binds to hemoglobin to give carbonylhemoglobin
(tissue ischemia)
•nitrogen oxides – may generate reactive radical
species
•polycyclic aromatic hydrocarbons (PAH)(pyrene,
chrysene, benzo[a]pyrene …), main components of tar
•they can attack and damage DNA, carcinogens
•other substances (N2, CO2, HCN, CH4, esters …)
Tobacco
Toxic effects of xenobiotics
1.cell injury (cytotoxicity)
2.the reactive species of a xenobiotic may bind to a protein, altering
its antigenicity. The xenobiotic is said to act as a hapten
3.reactions of activated species of chemical carcinogens with DNA
are thought to be of great importance in chemical carcinogenesis
1.cell injury (cytotoxicity)
2.the reactive species of a xenobiotic may bind to a protein, altering
its antigenicity. The xenobiotic is said to act as a hapten
3.reactions of activated species of chemical carcinogens with DNA
are thought to be of great importance in chemical carcinogenesis
Factors that influence metabolism of
xenobiotics
•Age
–older people less efficient at metabolism
•Sex
–Linked to hormonal differences
•Heredity
–Genetic differences can influence amounts and
efficiency of metabolic enzymes
•Disease states
–Liver, cardiac, kidney disease
xenobiotics
•Age
–older people less efficient at metabolism
•Sex
–Linked to hormonal differences
•Heredity
–Genetic differences can influence amounts and
efficiency of metabolic enzymes
•Disease states
–Liver, cardiac, kidney disease
THANKS
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