Transcript Document

Pharmacogenomics:
Basics and its applications
Dr. C.Adithan
Pharmacogenomic Laboratory
Department of Pharmacology
JIPMER, Pondicherry
Outline of the talk:
Pharmacogenomics:

Definition

Polymorphism

SNP

Consequences of Polymorphism

Therapeutic importance

Bio-informatics
Present Scenario in drug therapy

Optimal therapy for major illness: Still elusive

Schizophrenia: 30 % do not respond

Hypertension: 27 % adequately controlled

ADR: 1 lakh patients die every year in USA

Cost of drug development : $ 500 – 700 million
for each drug …… 80% fails in clinical trial
This can be improved by
 At
Giving the right drug
Right Dose
 To the Right Patient
 At the Right Time
Patient specific selection of medication and their dosage
PHARMACOGENOMICS
Right Drug
Right Gene
Individualized medicine
Pharmacogenetics: Study of the
effect of variation in a single gene
Pharmacogenomics: Study of the
effect of variation in multiple genes
DNA sequence of all human beings is 99.9% identical

Our DNAs differ by 0.1%.

Does it make a difference ?
Yes
0.1% difference translates into 3 million
separate “spelling” differences in a
genome of 3 billion bases
What is Genetic Polymorphism?
A genetic polymorphism is any
mutant or variant gene that
occurs with a frequency of more
than 1% in the normal population
POLYMORPHISMS
SNP
• Missense
• Nonsense
• Silent
• Frameshift
• Splice site
INSERTIONS
DELETIONS
• Missense
• Nonsense
• Frameshift
• Missense
• Nonsense
• Frameshift
Single nucleotide polymorphisms (SNP)
……..G G T A A C T T G …...
……..G G C A A C T T G …...

Most common, Incidence 1 per 300 - 600bp
10q24.2
Chromosome
Example:
Nucleotide position 430
CYP2C9
gene
5’
C A G C
T G C A A C T
3’
CYP2C9*1
CYP2C9*2
Normal
Decreased
enzyme
enzyme
activity
activity
Consequences of polymorphisms
Drug metabolism
Disease
susceptibility
Drug transport
Polymorphisms
Adverse Drug
Reaction
Receptor
sensitivity
Responders/
Non-responders
DRUG METABOLISM
Molecular mechanisms that can alter drug metabolism
Primary CYP Enzymes in Drug Metabolism
% of total enzyme
% of drugs metabolised
1A2
5%
1A2
19%
2C9
2C19
19%
3A4/5
42%
2C9
2C19
26%
2E1
10%
3A4/5
51%
2D6
24%
2D6
3%
2E1
1%
Phase - I enzymes known to have
polymorphism





CYP2C9: Phenytoin, warfarin, NSAIDs etc
CYP2C19: Omeprazole, proguanil, diazepam
CYP2D6: More than 60 drugs
CYP2E1: Ethanol
CYP1A6: Nicotine
Mutant alleles of Phase I enzymes
CYP 450
gene
Mutant Alleles
CYP2C9*1
*2, *3, *4, *5, *6
CYP2C19*1
*2, *3, *4, *5,
*6, *7, *8
CYP2D6*1
*1XN, *2XN,
*3,*4,*5, *6
*9,*10,*17
Substrates
Warfarin, losartan
phenytoin, tolbutamide
Proguanil, Imipramine,
Ritonavir, nelfinavir,
cyclophosphamide
Clonidine, codeine,
promethazine,
propranolol, clozapine,
fluoxetine, haloperidol,
amitriptyline
Red: Absent; Blue: Reduced; Green: Increased activity
Phase II enzymes known to have
polymorphism





NAT2: Isoniazid, hydralazine,
GST: D-Penicillamine
TPMT: Azathioprine, 6-MP
Pseudocholinesterase: Succinyl choline
UGT1A1: Irinotecan
Mutant alleles of Phase II enzymes
Gene
NAT2
GST
TPMT
UGT1A1
Mutant Alleles
*2, *3, *5, *6,*7,
*10,*14
M1A/B, P1
M1 null, T1 null
Substrates
Isoniazid, hydralazine,
D-penicillamine
*1,*2,*3A,C, *4-*8 Azathioprine, 6-MP
*28
Irinotecan
Red: Absent; Blue: Reduced;
Potential consequences of polymorphic
drug metabolism







Extended pharmacological effect
Adverse drug reactions
Drug toxicity
Increased effective dose
Lack of prodrug activation
Metabolism by alternative, deleterious
pathways
Exacerbated drug-drug interactions
CYP2D6 – Implications for Poor metabolisers

Decreased elimination of parent compound.
Beta blockers: metoprolol, timolol
Antidepressants: nortriptyline, clomipramine

Decreased prodrug activation:
Codeine, encainide

Decreased elimination of active metabolite:
imipramine

Decreased elimination of parent compound & active
metabolite:
Amitriptyline & nortriptyline
CYP2D6 Vs Starting dose of nortriptyline
Normal CYP2D6 : 150 mg/day
Mutant CYP2D6 : 10-20 mg/day
CYP2C9 Vs Phenytoin maintenance dose
Genotype
CYP2C9 *1/*1
CYP2C9 *1/*2
CYP2C9 *2/*3
Mean dose (mg/d)
314 mg/d
193 mg/d
150 mg/d
Why diazepam metabolism is slower in
Asians compared to Caucasians?
Because Asians have high frequency of mutant alleles CYP2C19
Genotype
Allele
Diazepam t1/2
EM
CYP2C19 *1/*1
20 hours
PM
CYP2C19 *2/*2
84 hours
CYP2C19 Vs Treatment of H.Pylori
Omeprazole 20 mg/day and amoxicillin 2gm/day
Genotype
Allele
Cure rate
Wild type
CYP2C19 *1/*1
29 %
Htz Mutant
CYP2C19 *1/*2
60 %
Hmz Mutant
CYP2C19 *2/*2
100 %
Due to higher concentration of omeprazole
DRUG TRANSPORTERS
 There are 7 different ABC transporters
 MDR1 is important among them.
MDR1 encodes a P-glycoprotein that
mediates ATP-dependent efflux of drugs.
Expressions of P-glycoprotein in different tissues
Molecular genetics of MDR1/ P-gp
•
•
•
•
•
Gene : MDR1
Gene symbol: ABCB1
Chromosome location: 7q21.1
No of Exons : 28
No of SNP detected : 29
Exon 19 SNP
- Intron
9 SNP
- Promoter 1 SNP
-
Polymorphism in Exon 26 (C3435T), Exon 21(G2677T/A)
significantly affect P-gp expression
Allele frequencies of MDR1 exon 26, 21 polymorphism in
Various ethnic populations
Sl No
Population
3435
C
T
2677
G
T
A
1.
Caucasian
48% 52% 55% 42% 03%
2.
Africans
81% 19% ND
3.
Orientals
55% 45% 41% 45% 14%
4.
Indians
38% 62% 33% 61% 06%
ND
ND
ND- Not Done
Substrates of P-glycoprotein
Category
Substrates of P-gp
Anti-cancer agents
Actinomycin D, Vincristine,etc
Cardiac drugs
Digoxin, Quinidine etc
HIV protease inhibitors
Ritonavir, Indinavir etc
Immunosuppressants
Cyclosporine A, tacrolimus etc
Antibiotics
Erythromycin,levofloxacin etc
Lipid lowering agents
Lovastatin, Atorvastatin etc
RECEPTOR SENSITIVITY
Receptor
Sensitivity/Effect
1 receptor gene
Arg389Gly
Subjects with Gly 389 have reduced
sensitivity to beta-blockers
Subjects with Gly 49 have increased
Ser49Gly
sensitivity to beta-blockers
2 receptor gene
Response to salbutamol is 5.3 fold
Arg16Gly
lower in Gly16 asthmatics.
Subjects with Glu27 have strong
Gln27Glu
resistance to beta 2 agonists
RESPONDERS &
NON-RESPONDERS
Disease
Asthma
Atherosclerosis
Smoking
cessation
Gene and
Allele/
Polymorphism Genotype
ALOX5
Promoter region
CETP
TaqIB
CYP2B6
C1459T
mut
B2/B2
Gln27Glu
Respond poorly to
antileukotriene
treatment with ABT761
Poor response to
treatment with
pravastatin
TT
Greater craving for
cigarettes and
higher relapse rates
Glu27
Better response to
carvedilol treatment
2 AR gene
Heart failure
Effect
ADVERSE DRUG REACTIONS
CYP2C9 polymorphism and phenytoin toxicity
Ataxia, nystagmus, drowsiness, gingival hyperplasia grade II
Phenytoin dose = 300 mg/day
Plasma phenytoin level =33.2 µg/ml
Genotype : CYP2C9*3/*3
This girl may develop side effects to
 Warfarin
 Acenocoumarol
 Losartan
 Irbesartan
 Glipizde
 Glibenclamide
 Tolbutamide
 Ibuprofen
 Flurbiprofen
 Diclofenac
All are metabolised by CYP2C9 enzyme
CYP2C9 and ADR of Warfarin
Subjects who are carriers of at least one
mutant allele (*2 or *3) are 4 times more
susceptible to bleeding complications
in spite of low dose administration
TPMT polymorphism induced ADR
 Patients
having TPMT*2, *3A and *3C
alleles have low enzyme activity
 They
are at risk for excessive toxicity,
especially fatal myelosuppression,
even at standard dose of azathioprine,
mercaptopurine and thioguanine
DISEASE SUSCEPTIBILITY
Genetic polymorphism & disease susceptibility
Disease
Gene
Polymorphism
Allele/
Genotype
AGT
M235T
T allele
 BP
ACE
ACEI/D
DD
 risk
AT1R
A1166C
C
 risk
β1 AR
Arg389Gly
Arg389
 risk
CETP
TaqIB
B2/B2
 risk
Hypertension
Atherosclerosis
Effect
Disease
Acute MI
Alzheimer’s
disease
Cancer
Gene
Allele/
Genotype
Effect
CYP2C9
eNOS
*3
T786C
susceptibility to AMI.
ApoE
ε2
ε 4/ ε4
Reduced risk
Poor prognosis
GST
M1 Null
T1 Null
NAT
NAT2 *10
 susceptibility to lung
and bladder cancer
 susceptibility to
colorectal cancer
Bio-informatics in Pharmacogenomics
Designing PCR-RFLP experiment (a method of genotyping):
Steps involved in PCR-RFLP are:
DNA extraction
PCR – amplification of specific sequence
Restriction digestion of amplified product
Electrophoresis of digested product- genotype
Validation of genotype - sequencing
Bio-informatics tools used
1.
Retrieval of genomic sequences
2.
Identification of site of mutation on gene of interest
3.
Design of PCR primers
4.
Selection of the restriction endonucleases
5.
PCR method validation by sequencing
6.
Analysis and comparisons of electropherograms
Retrieval of genomic sequence:
Nucleic acid databases:

GenBank (NIH Genetic Sequence Database)
http://www.ncbi.nlm.nih.gov

EMBL – Europe’s primary nucleotide sequence
resource in collaboration with GenBank and DDBJ
http://www.ebi.ac.uk/embl/

DNA Data Bank of Japan
http://www.ddbj.nig.ac.jp/
Identification of site of mutation

CYP allele nomenclature committee
http://imm.ki.se/cyp/

UCSC Genome Browser
http://www.genome.ucsc.edu/

Ensembl Genome Browser
http://www.ensembl.org/

Vega Genome Browser
http://vega.sanger.ac.uk/
Designing primers for PCR
Free interactive primer design tools:

Primer3
http://frodo.wi.mit.edu/cgi-bin/primer3/primer3_www.cgi

WebPrimer
http://seq.yeastgenome.org/cgi-bin/web-primer

GeneFisher
http://bibiserv.techfak.uni-bielefeld.de/genefisher/

SNPBox
http://www.snpbox.org
Selection of restriction enzyme

NEB Cutter
http://tools.neb.com/NEBcutter2/index.php

Restriction Mapper
http://www.restrictionmapper.org/

WebCutter
http://firstmarket.com/cutter/cut2.html
Analysis of Electropherogram

Chromas
http://www.technelysium.com.au/chromas_lite.html

Finch TV
http://geospiza.com/finchtv/

BioEdit
http://www.mbio.ncsu.edu/BioEdit/page2.html
What next ?
Patient requires Treatment
Examination by the Physician
Genomic testing
Traditional investigations
EXPERT SYSTEM
Decision making by Physician, assisted by an Expert
System (interactive interpretation)
Prescribes individualized drug treatment
..And what many thought would not
happen has already happened
Basel, 25 June 2003
Roche Diagnostics Launches the
AmpliChip CYP450 in the US, the
World’s First Pharmacogenomic
Microarray for Clinical Applications
Personalized Medication
in the Future
Gene Chip Analysis
SMART CARD
Person’s name
Xenobio
GeneChip
GENOME
(Confidential)
In the future (? years), doctors will be able to select the
best drug to treat your disease and the appropriate dose
based on knowledge of your specific genetic makeup!
“Here
is my
sequence”
DNA from 5ml of blood
ONGOING / FUTURE PROJECTS
• Epilepsy (CYP2C9,C19, and MDR1)
• Upper-aerodigestive cancers
(GSTM1,GSTT1,GSTP1, CYP1A1 and CYP2E1)
• Coronary heart disease
(ApoE, eNOS, CETP and CYP2C8,C9,J2)
• Hypertension
(M235T, ACEI/D, T174M, A1166C, Arg389Gly,
Glu298Asp)
Collaborating Departments





Medicine
Cardiology
Neurology
Radiotherapy
ENT





Surgery
Psychiatry
CTVS
Tuberculosis
Biochemistry
Thank You
Patient requires Treatment
Examination by the Physician
Traditional
investigations
Genomic testing
EXPERT SYSTEM
Decision making by Physician, assisted by an
Expert System (interactive interpretation)
Prescribes individualized drug treatment