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21 - HIV and Antiretroviral Therapy

from II - Therapeutic Areas

Published online by Cambridge University Press:  05 June 2012

By
Amalio Telenti
Edited by
Russ B. Altman ,
David Flockhart  and
David B. Goldstein
Russ B. Altman
Affiliation:
Stanford University, California
David Flockhart
Affiliation:
Indiana University
David B. Goldstein
Affiliation:
Duke University, North Carolina
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Summary

Basic Concepts in HIV Therapeutics

Considerable progress has been made during the past twenty years in the development of effective treatment against HIV-1, the agent of AIDS. Today, there are more than twenty agents commercialized that target various steps in the viral life cycle (Figure 21.1). These drugs, used in combination, inhibit two or more steps of the viral cycle: viral entry (fusion inhibitors, coreceptor antagonists), reverse transcription (nucleoside analog and nonnucleoside inhibitors), integration into the host genome (anti-integrases), and viral polyprotein processing (protease inhibitors). The need for combination antiretroviral therapy (ART) is determined by the ease of viral escape from the selective pressure when confronted with single antiretroviral agents. The ability to escape from drug pressure is, in turn, the result of rapid mutation rates due to a viral polymerase (the reverse transcriptase) that lacks proofreading activity.

HIV treatment is highly standardized, with defined criteria for its initiation and detailed knowledge on comparative efficacy (1). Decisions to initiate ART are primarily based on the degree of immunosuppression (generally defined by the numbers of CD4+ T cells – the target of HIV-1 – in blood), with additional consideration given to the levels of viral replication (defined by the level of viremia – viral genome copy numbers per milliliter), and the presence of clinical symptoms. In the absence of treatment, most individuals infected with HIV-1 will have progression of immunosuppression, leading to AIDS-related opportunistic infections and cancer. Individuals progress to AIDS over a mean of eight years after infection; however, rates of progression are highly variable among individuals.

Type
Chapter
Information
Principles of Pharmacogenetics and Pharmacogenomics , pp. 238 - 248
Publisher: Cambridge University Press
Print publication year: 2012

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References

Hammer, SMSaag, MSSchechter, MTreatment for adult HIV infection: 2006 recommendations of the International AIDS Society-USA panelJAMA 2006 296 827Google Scholar
Haas, DWRibaudo, HJKim, RBPharmacogenetics of efavirenz and central nervous system side effects: an Adult AIDS Clinical Trials Group studyAIDS 2004 18 2391Google Scholar
Ward, BAGorski, JCJones, DRHall, SDFlockhart, DADesta, ZThe cytochrome P450 2B6 (CYP2B6) is the main catalyst of efavirenz primary and secondary metabolism: implication for HIV/AIDS therapy and utility of efavirenz as a substrate marker of CYP2B6 catalytic activityJ Pharmacol Exp Ther 2003 306 287Google Scholar
Telenti, AZanger, UMPharmacogenetics of anti-HIV drugsAnnu Rev Pharmacol Toxicol 2008 48 227Google Scholar
Frohlich, MHoffmann, MMBurhenne, JMikus, GWeiss, JHaefeli, WEAssociation of the CYP3A5 A6986G (CYP3A5*3) polymorphism with saquinavir pharmacokineticsBr J Clin Pharmacol 2004 58 443Google Scholar
Anderson, PLLamba, JAquilante, CLSchuetz, EFletcher, CVPharmacogenetic characteristics of indinavir, zidovudine, and lamivudine therapy in HIV-infected adults: a pilot studyJ Acquir Immune Defic Syndr 2006 42 441Google Scholar
Rotger, MCsajka, CTelenti, AGenetic, ethnic, and gender differences in the pharmacokinetics of antiretroviral agentsCurr HIV/AIDS Rep 2006 3 118Google Scholar
Rotger, MTegude, HColombo, SPredictive value of known and novel alleles of CYP2B6 for efavirenz plasma concentrations in HIV-infected individualsClin Pharmacol Ther 2007 81 557Google Scholar
Zukunft, JLang, TRichter, TA natural CYP2B6 TATA box polymorphism (-82T–> C) leading to enhanced transcription and relocation of the transcriptional start siteMol Pharmacol 2005 67 1772Google Scholar
di Iulio, JFayet, AArab-Alameddine, MIn vivo analysis of efavirenz metabolism in individuals with impaired CYP2A6 functionPharmacogenet Genomics 2009 19 300Google Scholar
Rotger, MColombo, SFurrer, HInfluence of CYP2B6 polymorphism on plasma and intracellular concentrations and toxicity of efavirenz and nevirapine in HIV-infected patientsPharmacogenetics Genomics 2005 15 1Google Scholar
Baedevan Dijk, PAHugen, PWVerweij-van Wissen, CPKoopmans, PPBurger, DMHekster, YAAnalysis of variation in plasma concentrations of nelfinavir and its active metabolite M8 in HIV-positive patientsAIDS 2001 15 991Google Scholar
Haas, DWSmeaton, LMShafer, RWPharmacogenetics of long-term responses to antiretroviral regimens containing efavirenz and/or nelfinavir: an Adult Aids Clinical Trials Group StudyJ Infect Dis 2005 192 1931Google Scholar
Kassahun, KMcIntosh, ICui, DMetabolism and disposition in humans of raltegravir (MK-0518), an anti-AIDS drug targeting the human immunodeficiency virus 1 integrase enzymeDrug Metab Dispos 2007 35 1657Google Scholar
Anderson, PLKakuda, TNLichtenstein, KAThe cellular pharmacology of nucleoside- and nucleotide-analogue reverse-transcriptase inhibitors and its relationship to clinical toxicitiesClin Infect Dis 2004 38 743Google Scholar
Fellay, JBoubaker, KLedergerber, BPrevalence of adverse events associated with potent antiretroviral treatment: Swiss HIV Cohort StudyLancet 2001 358 1322Google Scholar
Keiser, OFellay, JOpravil, MAdverse events to antiretrovirals in the Swiss HIV Cohort Study: impact on mortality and treatment modificationAntivir Ther 2007 12 1157Google Scholar
Rotger, MColombo, SFurrer, HInfluence of CYP2B6 polymorphism on plasma and intracellular concentrations and toxicity of efavirenz and nevirapine in HIV-infected patientsPharmacogenet Genomics 2005 15 1Google Scholar
Tarr, PETelenti, AToxicogenetics of antiretroviral therapy: genetic factors that contribute to metabolic complicationsAntivir Ther 2007 12 999Google Scholar
Rodondi, NDarioli, RRamelet, AAHigh risk for hyperlipidemia and the metabolic syndrome after an episode of hypertriglyceridemia during 13-cis retinoic acid therapy for acne: a pharmacogenetic studyAnn Intern Med 2002 136 582Google Scholar
Cutrell, AGHernandez, JEFleming, JWUpdated clinical risk factor analysis of suspected hypersensitivity reactions to abacavirAnn Pharmacother 2004 38 2171Google Scholar
Hetherington, SHughes, ARMosteller, MGenetic variations in HLA-B region and hypersensitivity reactions to abacavirLancet 2002 359 1121Google Scholar
Mallal, SNolan, DWitt, CAssociation between presence of HLA-B*5701, HLA- DR7, and HLA-DQ3 and hypersensitivity to HIV-1 reverse-transcriptase inhibitor abacavirLancet 2002 359 727Google Scholar
Rauch, ANolan, DMartin, AMcKinnon, EAlmeida, CMallal, SProspective genetic screening decreases the incidence of abacavir hypersensitivity reactions in the Western Australian HIV cohort studyClin Infect Dis 2006 43 99Google Scholar
Hughes, SHughes, ABrothers, CSpreen, WThorborn, DPREDICT-1 (CNA106030): the first powered, prospective trial of pharmacogenetic screening to reduce drug adverse eventsPharm Stat 2008 7 121Google Scholar
KimchiSarfaty, COh, JMKim, IWA “silent” polymorphism in the MDR1 gene changes substrate specificityScience 2007 315 525Google Scholar
Haas, DWBartlett, JAAndersen, JWPharmacogenetics of nevirapine-associated hepatotoxicity: an Adult AIDS Clinical Trials Group collaborationClin Infect Dis 2006 43 783Google Scholar
Fellay, JShianna, KVGe, DA whole-genome association study of major determinants for host control of HIV-1Science 2007 317 944Google Scholar
Loeuillet, CDeutsch, SCiuffi, AIn vitro whole-genome analysis identifies a susceptibility locus for HIV-1PLoS Biol 2008 6Google Scholar
McRae, AFByrne, EMZhao, ZZMontgomery, GWVisscher, PMPower and SNP tagging in whole mitochondrial genome association studiesGenome Res 2008 18 911Google Scholar
Pharoah, PDAntoniou, ACEaston, DFPonder, BAPolygenes, risk prediction, and targeted prevention of breast cancerN Engl J Med 2008 358 2796Google Scholar
Roujeau, JCStern, RSSevere adverse cutaneous reactions to drugsN Engl J Med 1994 331 1272Google Scholar
Nelson, MRBacanu, SAMosteller, MGenome-wide approaches to identify pharmacogenetic contributions to adverse drug reactionsPharmacogenomics J 2009 9 23Google Scholar
Nyakutira, CRoshammar, DChigutsa, EHigh prevalence of the CYP2B6 516G–>T(*6) variant and effect on the population pharmacokinetics of efavirenz in HIV/AIDS outpatients in ZimbabweEur J Clin Pharmacol 2008 64 357Google Scholar
Rotger, MTelenti, AOptimizing efavirenz treatment: CYP2B6 genotyping or therapeutic drug monitoringEur J Clin Pharmacol 2008 64 335Google Scholar
Telenti, AGoldstein, DBGenomics meets HIVNat Rev Microbiol 2006 4 9Google Scholar

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