Japan Perspective on PGt/PGx in the Drug Development and Approval Process J. Azuma M.D. Osaka University, Osaka, JAPAN OSAKA UNIVERSITY Non responder Disease Asthma Drug Class Non responder (%) β2 adrenergic agonist 5-LO, LTD4 Cancer Various (breast,lung,brain) Depression SSRIs, Tricyclics, MAOs Diabetes Duodenal ulcer Hyperlipidemia 4〜75 70〜100 20〜40 Sulfonylurea, Biguanides, 50〜75 Glitazones H2 antagonists, 20〜70 Proton pump inhibitors HMGCoA reductase, 30〜75 Resins, Niacin 2 Pharmacogenomics eds. Kalow, Tyndale, Meyer (p17, Marcel Dekker, May 2001) Paradox of Modern Drug Development ● ● Clinical trials provide evidence of efficacy and safety at usual doses in populations Physicians treat individual patients who can vary widely in their response to drug therapy 3 Lawrence J. Lesko; International Pharmacogenomics Symposium Tokyo, Japan April 25, 2003 Overview of Talk Treatment of tuberculosis with isoniazid and rifampicin Treatment of chronic heart failure with β-adrenergic receptor blockers Japan Pharmacogenomics Consortium (JPGC) Pharmacogenetics (PGx)-Pharmacoeconomics (PEx) Working Group Pharmacogenome Tip Top Inc. (P-TipTop) 4 Treatment of Pulmonary Tuberculosis • Approximately 20% of the patients treated with Rifampicin and INA develop hepatotoxicity. • Metabolic enzyme of INH is NAT2. • Rifampicin strongly induces many drug metabolizing enzymes. 5 Metabolic pathways of isoniazid NAT2 Acetylation CONHNHCOCH3 N Acetylisoniazid Hydrolysis NH2NHCOCH3 Acetylhydrazine (AcHz) NAT2 (NHCOCH3)2 Diacetylhydrazine CONHNH2 N Isoniazid (INH) Rifampicin Enzyme induction Hydrolysis COOH N Acetylation NAT2 Isonicotinyl glycine NH2NH2 Hydrazine (Hz) Hepatotoxic 6 Mutation of N-acetyltransferase 2 T→C G→A 111 191 A→C 434 A→C G→A 341 499 759 C→T 803 A→G 845 A→C * ** * * * * * * **** 190 282 C→T C→T 481 590 857 C→T G→A G→A SNPs 7 Frequency of the NAT2 genotypes in patients Genotype n % NAT2*4 / *4 46 40.3 RA type (40.3%) NAT2*4 NAT2*4 NAT2*4 NAT2*5 NAT2*5 NAT2*5 NAT2*6 NAT2*6 NAT2*7 4 34 15 3.5 29.8 13.2 IA type (46.5%) 0 2 0 7 4 2 0.0 1.8 0.0 6.1 3.5 1.8 114 100.0 / / / / / / / / / *5 *6 *7 *5 *6 *7 *6 *7 *7 SA type (13.2%) 8 Incidence of INH-Rifampicin (RFP) induced hepatotoxicity and NAT2 genotype Total (n=114) RA type (n=46) IA type (n=53) * SA type * (n=15) 0 20 40 60 80 Incidence (%) normal 100 * P<0.01 hepatotoxicity criteria: serum AST and/or ALT > 1.5 x upper limits of normal and 2 x before administration. 9 Plasma concentration (mM) Trough plasma concentration of INH and hydrazine metabolites in relation to NAT2 gene polymorphisms 8 * * * * * * 6 RA (n=29) IA (n=31) SA (n= 7) *p < 0.05 vs RA & IA mean±SD 4 2 0 INH AcHz Hz 10 Hydrazine induced cytotoxicity on HepG2 cells *5 M KpnⅠ *6 *7 TaqⅠ BamHⅠ 1 2 3 4 5 6 7 8 9 10 111213 Genotype of HepG2 NAT2 *5/ *6 ( slow acetylator ) Culture : MEM/Earle’s salt (10% FBS) 5% CO2 -95% Air 37 °C Stimulus : Hz, AcHz Incubation time : 48 hour 2,6,10 : w/w 3,7,11 : w/m 4,8,12 : m/m 5,9,13 : HepG2 Assay : AST, ALT, and LDH leakage Cell proliferation 11 Toxic effects of hydrazine on HepG2 cells 100 50 0 Cont AcHz Hz * ALT Enzyme leakage into the medium ( IU/L ) * Ratio to the nontreated control (%) Cell proliferation 20 10 0 Cont 0.3 mM 0.1 mM Mean±S.E. (n=12) Incu. 48h AcHz Hz 0.3 mM 0.1 mM *P < 0.05 12 Serum aminotransferase (IU/L) Case in SA type Case 1(female 69years) 350 300 drug monitoring AST ALT 250 200 150 100 NAT2*6/*6 (SA type) 50 0 0 10 20 30 40 50 60 70 80 INH (mg/day) 400 100 RFP 90 Day 200 発疹のため投与中止 (mg/day) 450 検出菌数 (蛍光法) 2+ 450 300 1+ ± 13 INH concentration (mg/mL) Plasma INH concentration-time profile observed in patient of case1 7 6 400mg/day 200mg/day 5 Reduced 4 3 2 1 0 0 5 10 15 Time after administration (hr) 14 Cases in RA type Case 5 (male 62years) Poor Response INH 400mg/day (po) +RFP+SM Cured INH 400mg/day(po) +200mg/day(inhalation) +RFP+SM INH conc. (mg/mL) : NAT2*4/*4 (RA type) 3 Case 5 2 Mean of RA type (400 mg/day) 1 0 5 10 15 Time after administration (hr) 15 INH-RFP induced hepatotoxicity INH+RFP slow acetylator intermediate acetylator rapid acetylator (SA type) (IA type) (RA type) Liver Toxicity Chenge regimen Delayed Continue Increase dose Cured 16 RFP:rifampicin Plasma INH concentration-time profile INH concentration (mg/mL) Patients (n ):114 10 Sparse plasma (n ):278 (1 – 4 points/person) 1 Dose: INH 200 mg at steady state 0.1 0.01 0.001 0 Same dose but different plasma concentrations RA type IA type SA type Therapeutic range 5 10 15 Time after administration (hr) Minimal inhibitory concentration17(MIC) Simulation of dose adjustment of INH based on NAT2 genotype (preliminary) INH conc. (mg/mL) Present Simulated 3.0 Css max 0.2 min 0 12 24 hr All types 200 mg x 2 /day 0 12 24 hr RA-type 500 mg x 2 /day I A-type 250 mg x 2 /day SA-type 100 mg x 2 /day 18 Trough plasma concentration of INH in relation to NAT2 genotype Japan Europe & USA 400 mg/day (8 mg/kg/day) 300 mg/day (5 mg/kg/day) Frequency of slow acetylator (SA-type) Japanese Caucasians 10 % 50 % Trough conc. of INH (mg/mL) Standard dose of INH 10 n=60 1 MIC 0.05-0.2 mg/mL 0.1 RA-type IA-type IA-type + HT SA-type + HT 0.01 0.001 0 2 4 6 Dose (mg/kg) 8 HT: hepatotoxicity 19 Benefit ◆ Decrease the incidence of drug-induced hepatotoxicity ◆ Inprove therapeutic effect ◆ Decrease the incidence of drug resistance in Micobacterium tuberculosis ◆ Decrease of relapse rate of pulmonary tubercurosis ◆ Effect on pharmacoeconomics〈t.b.〉 Newly diagnosed patients in Japan = about 40,000 persons/year Incidence of drug-induced hepatotoxicity in Slow acetylator (about 10% of Japanese) =100%(about 4,000 persons/year ) Increase on the cost for remedy followed by drug-induced hepatotoxicity (/year) 20,000 yen(1day)×60 days×4,000 persons=4.8 billion yen? Cost for NAT2 genotyping ~10,000 yen(1time) × 40,000 persons = ~0.4 billion yen 4.4 billion yen 20 Clinical trial for genotype based chemotherapy against pulmonary tuberculosis ◆ Multi-center prospective randomized clinical trial ◆ Rationalized dosing of isoniazid based on NAT2 gene polymorphism ◆ Safety, Efficacy, Pharmacoeconomics Patients with pulmonary tuberculosis NAT2 Gene chip NAT2 genotyping RA-type IA-type SA-type 21 Clinical trials for β-blocker therapy in chronic heart failure NYHA Mortality US Carvedilol carvedilol II~III -65% CIVIS II bisoprolol III -34% MERIT-HF metoprolol II~III -34% COPERNICUS carvedilol IV -35% 22 Individual Difference in β-blocker Effect β-bloker(79cases) %FS ±3% %FS (33例:41.8%) (41例:51.9%) Responder ; improvement of 3 % in the fractional shortening (5例:6.3%) (%) 25 Before 20 21.7 After 19.3 15 14.9 10 15.0 12.2 11.8 5 0 Responder Non-responder Bad-responder For Individualized Medications Genotyping 23 β1AR Polymorphism Ser49Gly Arg389Gly 24 J Mol Med 2000;78:87-93. Adrenergic Receptor Polymorphisms β1 AR Codon Amino acid change Function change (in vitro) 49 Ser→Gly Increased down regulation 389 Arg→Gly Decreased G-protein coupling 16 Arg→Gly Increased down regulation 27 Gln→Glu Decreased down regulation deletion Reduced agonist binding and decreased G-protein coupling β2 AR α2c AR 322-325 25 Drug metabolizing enzymes for β-blocker β-blocker metoprolol bisoprolol carvedilol Drug metabolizing enzymes CYP2D6 CYP2D6/3A4/1A2 26 Effect of CYP2D6*10 allele on PK of S-metoprolol Concentration in plasma (nM) 500 CYP2D6*10/*10 400 300 200 100 2D6*1/*1 0 0 2 4 6 8 10 12 14 Time (hr) Clin Pharmacol Ther 1999 ; 65 : 402-407 27 Chronic Heart Failure βbloker responder non-responder CAUSE Plasma Concentration of β blocker Function of Target Molecules of β blocker Polymorphisms Drug Metabolizing Enzyme Polymorphisms AR and Target Molecules 28 β1AR Ser49Gly and Risk in CHF △ Ser49 homozygotes without b-blockers (n=63) ▲ Gly49 variant without b-blockers (n=28) ☆ Ser49 homozygotes with b-blockers (n=59) Risk of end-point (%) 60 ★ Gly49 variant with b-blockers (n=33) △ p = 0.12 40 ☆ ▲ p = 0.016 20 0 ★ effective β-blocker is more in Patients with Gly allele 0 1 2 3 4 5 Follow-up (years) Increased down regulation Eur Heart J 2000;21:1853-8. 29 β2 adrenergic receptor polymorphism Ratio of Responders Gln/Gln Gln/Glu 26% Glu/Glu 62% Responder; Improved LVEF by 10% Improved FS by 5% Gln27Glu is a potential determinant for the response to carvedilol in heart failure Decreased down regulation 30 Kaye, DM, et al Pharmacogenetics (2003) 13;379-382 Heart failure and Polymorphism of α2c AR α2CDel322-325 2A Decreased Function in vitro α2C Sympathetic nerve α2c AR Del322-325 Allele frequency Norepinephrine 1 CHF healthy Bleck 0.62 0.41 White 0.11 0.04 Yellow ??? ??? Cardiac-cell membrane 2 3 (2002,10 β1Arg389Gly Increased Function in vitro These two polymorphism of receptors act synergistically to increase the risk of heart failure in black. reported) Japanese ? 31 N Engl J Med (2002) 347, 1135-42 Allelic frequency of adrenergic receptor polymorphisms in healthy and CHF 0.7 Allelic frequency 0.6 CHF (n = 36) Healthy (n = 96‐101) Allelic frequency of α2c AR Del322325 in healthy Japanese is 0.14. 0.5 0.4 Black and White:CHF>Healthy 0.3 0.2 0.1 0 Ser49Gly Arg389Gly β1 AR Arg16Gly Gln27Glu β2 AR α2c Del α2c AR 32 Allelic frequency of adrenergic receptor polymorphisms in Responder and non-Responder 0.7 Allelic frequency 0.6 Responder (n=21) non-Responder (n=13) 0.5 0.4 Responder: improvement of 3% in the fractional shortening 0.3 0.2 0.1 0 Ser49Gly Arg389Gly Arg16Gly Gln27Glu α2c Del β1 AR β2 AR α2c AR 33 Scientific Basis for Using PGt to Rationalize Dosing Top 27 drugs frequently cited in ADR reports 59% (16/27) metabolized by at least one enzyme having poor metabolizer (PM) genotype 38% (11/27) metabolized by CYP 2D6 mainly drugs acting on CNS and cardiovascular systems Phillips et al, JAMA, 286 (18), 2001, 2270-2279 34 Summary of CYP2D6 activity Japanese Caucasians activity Genotype phenotype Low PM 1%> IM EM UM High Mainly (CYP2D6*5 ) *10/ PM gene (about 3%) *10/*10 (about 15%) hetEM: wt / PM gene wt /*10 phenotype PM 5-10% *3,*4,*5 etc ??? ( *2 with -1584CG SNP) EM wt / wt (wild type) Ultra Rapid (low frequency) Genotype hetEM: wt / PM gene wt / wt (wild type) UM Ultra Rapid (ethnic difference) Multiple active genes 35 Clinical significances of polymorphisms in β-blocker therapy against Chronic Heart Failure Mega trial of β-Blocker Treatment in Japanese Patients with Chronic Heart Failure (J-CHF) Patient: NYHA II or III EF<40%, 1500 patients (multicenter, 300 hospitals) Drug:Carvedilol (2.5mg、5mg、20mg/day) Endpoint:Mortality, Cardiovascular death, Mobility Surrogate Marker : Cardiac function Sub analysis : Genotyping Directed by A Kitabatake MD, PhD (Hokkaido University) Supported by Japanese Circulation Society 36 Potential Use of PGx in Drug Development Pharmacogenomics: systemic genomic analysis in populations of treated subjects to identify variants that predict drug response including the occurrence of adverse reactions Cause of Disease Drug Discovery By 2010 New Drug Targets New Biomarkers Differential Diagnosis Drug Therapy By 2005 Rationalize Dosing Drug Selection By 2008 Class of Drugs Lawrence J. Lesko International Pharmacogenomics Symposium 37 Tokyo, Japan April 25, 2003 Overview of Talk Treatment of tuberculosis with isoniazid and rifampicin Treatment of heart failure with βadrenergic receptor blockers Japan Pharmacogenomic Consortium (JPGC) Pharmacogenetics (PGx)-Pharmacoeconomics (PEx) Working Group Pharmacogenome Tip Top Inc. (P-TipTop) 38 JPGC Outline (Japan Pharmaco-genomics Consortium) Rep. Fujisawa Yukio JPGC Background Perspective ・Globalized competition ・Genomic, ‘tailor-made’ medicine to be realized with Pharmaco-genomics/genetics evolution Urgent Need to create a better climate for performing quality clinical trials on pharmacogenomics/genetics (PG) in drug development as well as in post-marketing Collaboration among pharmaceutical companies to solve problems and develop techniques 40 Participating companies Otsuka Pharmaceutical Co., Ltd. Sanwa Kagaku Kenkyusho Co., Ltd. Shionogi & Co., Ltd. Sumitomo Pharmaceuticals Senju Pharmaceutical Co., Ltd. Dainippon Pharmaceutical Co., Ltd. Takara Bio Inc. Takeda Chemical Industries, Ltd. Tanabe Seiyaku Co., Ltd. Fujisawa Pharmaceutical Co., Ltd. *as 41 of Sep., 2003 Research Points Foundations and Standardization ● ● ● ● ● Technological requirements for PG trials Correlation analysis method between clinical and genetic data Method of selecting genes targeted for analysis Standards of ethical review and personal information management Analysis of PG trial data and construction of useful database for clinical evaluation ● Analytic engineering to utilize the database Pilot study on clinical pharmacology ● Clinical trial to verify a hypothesized relation between marketed 42 drug and genetic polymorphism JPGC Action Plan 2003 Jun. Sep. 2004 Dec. Mar. Jun. 2005 Sep. Dec. Mar. Jun. Founded on Jul.14 WG-II Plan to perform a test study on clinical pharmacology WG-III Building a common DB as well as study DB on CP* *Clinical Pharmacology=CP 43 PG Clinical study support center WG-I Ethical matters, PG trial groundwork & internal standard CIOMS The Council for International Organizations of Medical Sciences • Established by WHO and UNESCO in 1949 • Activities : – Bioethics – Health Policy, Ethics and Human Values - An International Dialogue – Drug Development and Use • • • • • • Safety requirements for the use of drugs Assessment, monitoring and reporting of adverse drug reactions Reporting and terminology of adverse drug reactions Ethical criteria for drug promotion Surveillance and assessment of drug safety data from clinical trials Pharmacogenetics and Pharmacoeconomics – International Nomenclature of Diseases 44 CIOMS Working Group on Pharmacogenetics and Pharmacoeconomics • Membership: Academia (3), drug regulatory agencies (14) and the pharmaceutical industry (13) –University of Tokyo, MHLW, Yamanouchi • Targets: Terminology, impact, cost, regulation, ethics etc. of pharmacogenomics and pharmacogenetics • Pharmacoeconomic issues in Pharmacogenetics –Database relating Pharmacogenetics –Regulatory Perspectives CIOMSが作成するレポートは、国際的な強制力は持たないもの –Pharmacogenetics: Unresolved Issues and Barriers to Progress の、ICH等を通じて各国の医薬品行政に影響を及ぼす可能性が強 –Ethical Issues 45 いので、その動向に注意する必要がある。 –Progress reports regarding pharmacogenetics Rational Use of Pharmacogenomics in Drug Development and Regulation Aim: Develop ethical, social and economical infrastructure for appropriate use of pharmacogenetics and pharmacogenomics Scope: examine and analyze efforts of regulatory authorities and industries relating to pharmacogenetics and pharmacogenomics and establish its proper use in drug development and clinical practice. Schedule: FY2003 - FY2005 (3 years-term) Budget: 6 million yen (FY2003) Supporter: Ministry of Health, Labor and Welfare Project Leader: Tsutani, Kiichiro (Tokyo University) Participant: Junichi Azuma (Osaka University), Tohru Masui (National Institute of Health Sciences), Hiroshi Gushima (Kurume University), Mieko Tamaoki (Yamanouchi Pharmaceutical) 46 Pharmacogenomic trails in our laboratory approved by the ethical committee in Osaka University Category Heart failure Title 心不全の個別治療のためのゲノム解析に関する臨床研究 Asthma ロイコトリエン拮抗薬ブラングカストにおける薬効の個体差の解明 Tuberculosis 薬効ゲノム情報に基づく結核治療の個別適正化プロジェクト Depression 精神疾患患者に対する個別化適正薬物投与のための薬物感受性遺伝 子に関する研究 Arteriosclerosis ホモシステインを標的とした動脈硬化治療法の確立 Adverse event 小児におけるアセトアミノフェン副作用発現の個人差の解明 Drug metabolism Smoking Cohort Study New Genotyping System 日本人健康男性志願者におけるチトクロムP450を介した薬物代謝能 の検討を目的とした臨床薬理試験 有効な禁煙指導を行うための遺伝子多型の解析 離島における薬物応答性遺伝子多型に関する情報の体系的収集と解 析の試み 新規遺伝子解析システムによる遺伝子多型判定法の開発 47 PGt/PGx Clinical Study on going and conducted so far Number of protocol Collaborate with Originals or support Units CYP2D6 10 Agent Unit for Phase I trial other metabolic enzyme 3 Agent Unit for Phase I trial other metabolic enzyme 2 no Unit for Phase I trial Tuberculosis In progress (Agent) Public Hospital Heart Failure In progress (Agent) University hospital(Multiple trial) Depression In progress (Agent) University hospital Asthma In progress (Agent) Public Hospital Diabetes In progress Public Hospital Cohort study In progress Local clinic 48 Have genetic testing aided drug development ??? Case 1 Dose-dependency :Inconsistency of plasma concentration was observed in dose escalation. → We could explain this phenomenon by different number of the subjects with decreased CYP450 activity enrolled at different dose groups. (→ Go forward) Case 2 Bio-equivalence Study → We could complete our goal by enrolling small number of subjects genotyped as same before the trial, for additional formula application or generic drug development. Case 3 Undesirable contribution of genetic factor → The finding suggested that the candidate compound should be changed positively to a backup derivative in an early stage. Case 4 Suggestive in vitro data of contribution polymorphic CYP450 → We could not find the contribution of the genotypes in vivo on the level of plasma concentration(→ Go forward safely) 49 Application of PGx/PGt providing tailored medicines for individuals Creation of database for pharmacogenetic knowledge Bood samples (I.D.) Clinical trials /Treatments based on genetic variation Patients (I.D.) Genotyping Published Evidence New Evidence from research institute Patent obtaining Data Bank on Genetic Variation Genetic Information Center (I.D.) ・Process information ・Bioinformatics ・Expect pharmacokinetics/ adverse effects in vivo ・Simulate response in silico New Drug Discovery & Development Personalized Medication Doctors Pharmacists IT Network right treatment for the right patient at the right time. 50 薬効ゲノム情報(株) 51 Tasks to be coped by JPGC Better Climate, Standardization ・Ethical system (in medical institutions and industries) ・IC・personal information, Sample storage ・Evaluation method on genomic data Know-how, Techniques ・Screening method of gene analysis ・Correlation analysis between genetic data and clinical information ・Finding SNPs with strong correlation /association Tasks ・ Establish Japan standard for PG study (trial) ・ Request cooperation from medical institutions and administration ・ Found a practical support center Corporate collaboration in working is indispensable! Japan (Internal) Consortium(JPG)founded 52 JPG Consortium Goal ● Improve the basic conditions and establish a Japan standard for promoting PG study in development and post-marketing The essential items on Informed Consent and an explanation Method of screening target genes Correlation analysis method・Clinical evaluation standard ● Found a support center to help companies in performing PG clinical studies with genetic analysis. Utilities for each member company to perform PG trials, including stored products of consortium activities 53 Organization General Meeting Steering Committee Advisory Board Working Group Secretariat Liaison Group Admin. Group Groundwork G. Domestic interchange Legal affairs Pilot Study G. International Public Relations Database Establishment G. Logistics 54 Concept on the use of JPGC products Standardization ・Storage of Data & Know-how Support &Promotion Univ. & Medical Institution Co. A Co. C Co. D Overseas Consortium Know-how introduction Use of the Institution Participation MoHLW JPGC Co. B PG study Support Center The more use, the better in quality and cost 55 TRI Utilization Use of TRI facilities, services and software for linkage analysis ● To build a frequency analysis database on healthy subjects ● To make the database more complete with the data from pilot studies ● To lay the foundation of the DB, based on the support center plan 56 Collaboration with TRI Consortium activities consist with the TRI’s goal & role: ・Build data foundation for Translational research from basic research to clinical or practical use ・Perform studies in cure and care field, including public relations about PG, SNPs study and their benefit to promote the Translational Research. 57 Drug Selection 個別化医療 Rationalize Dosing 診断 ゲ ノ ム 解 析 患者A × A遺伝子 治 療 法 薬剤X レスポンダー B遺伝子 Class of Drugs 匙加減 (質・量) 患者B × 治 癒 A遺伝子 B遺伝子 治 療 法 薬剤Y 治 癒 レスポンダー 58 Translation of PGx to Bedside Medicine: Predict Drug Response in Advance GCCCGCCTC GCCCACCTC 59 From McLeod and Evans, Ann Rev of Pharmacol and Toxicol, 2001: 41,101-121 DNA自動検査装置GenelyzerTMの開発 60
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