TY - JOUR
T1 - Geographic and Temporal Trends in the Molecular Epidemiology and Genetic Mechanisms of Transmitted HIV-1 Drug Resistance
T2 - An Individual-Patient- and Sequence-Level Meta-Analysis
AU - Rhee, Soo Yon
AU - Blanco, Jose Luis
AU - Jordan, Michael R.
AU - Taylor, Jonathan
AU - Lemey, Philippe
AU - Varghese, Vici
AU - Hamers, Raph L.
AU - Bertagnolio, Silvia
AU - de Wit, Tobias F Rinke
AU - Aghokeng, Avelin F.
AU - Albert, Jan
AU - Avi, Radko
AU - Avila-Rios, Santiago
AU - Bessong, Pascal O.
AU - Brooks, James I.
AU - Boucher, Charles A B
AU - Brumme, Zabrina L.
AU - Busch, Michael P.
AU - Bussmann, Hermann
AU - Chaix, Marie Laure
AU - Chin, Bum Sik
AU - D’Aquin, Toni T.
AU - De Gascun, Cillian F.
AU - Derache, Anne
AU - Descamps, Diane
AU - Deshpande, Alaka K.
AU - Djoko, Cyrille F.
AU - Eshleman, Susan H.
AU - Fleury, Herve
AU - Frange, Pierre
AU - Fujisaki, Seiichiro
AU - Harrigan, P. Richard
AU - Hattori, Junko
AU - Holguin, Africa
AU - Hunt, Gillian M.
AU - Ichimura, Hiroshi
AU - Kaleebu, Pontiano
AU - Katzenstein, David
AU - Kiertiburanakul, Sasisopin
AU - Kim, Jerome H.
AU - Kim, Sung Soon
AU - Li, Yanpeng
AU - Lutsar, Irja
AU - Morris, Lynn
AU - Ndembi, Nicaise
AU - NG, Kee Peng
AU - Paranjape, Ramesh S.
AU - Peeters, Martine
AU - Poljak, Mario
AU - Price, Matt A.
AU - Ragonnet-Cronin, Manon L.
AU - Reyes-Terán, Gustavo
AU - Rolland, Morgane
AU - Sirivichayakul, Sunee
AU - Smith, Davey M.
AU - Soares, Marcelo A.
AU - Soriano, Vincent V.
AU - Ssemwanga, Deogratius
AU - Stanojevic, Maja
AU - Stefani, Mariane A.
AU - Sugiura, Wataru
AU - Sungkanuparph, Somnuek
AU - Tanuri, Amilcar
AU - Tee, Kok Keng
AU - Truong, Hong Ha M
AU - van de Vijver, David A M C
AU - Vidal, Nicole
AU - Yang, Chunfu
AU - Yang, Rongge
AU - Yebra, Gonzalo
AU - Ioannidis, John P A
AU - Vandamme, Anne Mieke
AU - Shafer, Robert W.
N1 - PMID: 25849352
WOS:000354825700001
PY - 2015/4/1
Y1 - 2015/4/1
N2 - Regional and subtype-specific mutational patterns of HIV-1 transmitted drug resistance (TDR) are essential for informing first-line antiretroviral (ARV) therapy guidelines and designing diagnostic assays for use in regions where standard genotypic resistance testing is not affordable. We sought to understand the molecular epidemiology of TDR and to identify the HIV-1 drug-resistance mutations responsible for TDR in different regions and virus subtypes.We reviewed all GenBank submissions of HIV-1 reverse transcriptase sequences with or without protease and identified 287 studies published between March 1, 2000, and December 31, 2013, with more than 25 recently or chronically infected ARV-naïve individuals. These studies comprised 50,870 individuals from 111 countries. Each set of study sequences was analyzed for phylogenetic clustering and the presence of 93 surveillance drug-resistance mutations (SDRMs). The median overall TDR prevalence in sub-Saharan Africa (SSA), south/southeast Asia (SSEA), upper-income Asian countries, Latin America/Caribbean, Europe, and North America was 2.8%, 2.9%, 5.6%, 7.6%, 9.4%, and 11.5%, respectively. In SSA, there was a yearly 1.09-fold (95% CI: 1.05–1.14) increase in odds of TDR since national ARV scale-up attributable to an increase in non-nucleoside reverse transcriptase inhibitor (NNRTI) resistance. The odds of NNRTI-associated TDR also increased in Latin America/Caribbean (odds ratio [OR] = 1.16; 95% CI: 1.06–1.25), North America (OR = 1.19; 95% CI: 1.12–1.26), Europe (OR = 1.07; 95% CI: 1.01–1.13), and upper-income Asian countries (OR = 1.33; 95% CI: 1.12–1.55). In SSEA, there was no significant change in the odds of TDR since national ARV scale-up (OR = 0.97; 95% CI: 0.92–1.02). An analysis limited to sequences with mixtures at less than 0.5% of their nucleotide positions—a proxy for recent infection—yielded trends comparable to those obtained using the complete dataset. Four NNRTI SDRMs—K101E, K103N, Y181C, and G190A—accounted for >80% of NNRTI-associated TDR in all regions and subtypes. Sixteen nucleoside reverse transcriptase inhibitor (NRTI) SDRMs accounted for >69% of NRTI-associated TDR in all regions and subtypes. In SSA and SSEA, 89% of NNRTI SDRMs were associated with high-level resistance to nevirapine or efavirenz, whereas only 27% of NRTI SDRMs were associated with high-level resistance to zidovudine, lamivudine, tenofovir, or abacavir. Of 763 viruses with TDR in SSA and SSEA, 725 (95%) were genetically dissimilar; 38 (5%) formed 19 sequence pairs. Inherent limitations of this study are that some cohorts may not represent the broader regional population and that studies were heterogeneous with respect to duration of infection prior to sampling.Most TDR strains in SSA and SSEA arose independently, suggesting that ARV regimens with a high genetic barrier to resistance combined with improved patient adherence may mitigate TDR increases by reducing the generation of new ARV-resistant strains. A small number of NNRTI-resistance mutations were responsible for most cases of high-level resistance, suggesting that inexpensive point-mutation assays to detect these mutations may be useful for pre-therapy screening in regions with high levels of TDR. In the context of a public health approach to ARV therapy, a reliable point-of-care genotypic resistance test could identify which patients should receive standard first-line therapy and which should receive a protease-inhibitor-containing regimen.
AB - Regional and subtype-specific mutational patterns of HIV-1 transmitted drug resistance (TDR) are essential for informing first-line antiretroviral (ARV) therapy guidelines and designing diagnostic assays for use in regions where standard genotypic resistance testing is not affordable. We sought to understand the molecular epidemiology of TDR and to identify the HIV-1 drug-resistance mutations responsible for TDR in different regions and virus subtypes.We reviewed all GenBank submissions of HIV-1 reverse transcriptase sequences with or without protease and identified 287 studies published between March 1, 2000, and December 31, 2013, with more than 25 recently or chronically infected ARV-naïve individuals. These studies comprised 50,870 individuals from 111 countries. Each set of study sequences was analyzed for phylogenetic clustering and the presence of 93 surveillance drug-resistance mutations (SDRMs). The median overall TDR prevalence in sub-Saharan Africa (SSA), south/southeast Asia (SSEA), upper-income Asian countries, Latin America/Caribbean, Europe, and North America was 2.8%, 2.9%, 5.6%, 7.6%, 9.4%, and 11.5%, respectively. In SSA, there was a yearly 1.09-fold (95% CI: 1.05–1.14) increase in odds of TDR since national ARV scale-up attributable to an increase in non-nucleoside reverse transcriptase inhibitor (NNRTI) resistance. The odds of NNRTI-associated TDR also increased in Latin America/Caribbean (odds ratio [OR] = 1.16; 95% CI: 1.06–1.25), North America (OR = 1.19; 95% CI: 1.12–1.26), Europe (OR = 1.07; 95% CI: 1.01–1.13), and upper-income Asian countries (OR = 1.33; 95% CI: 1.12–1.55). In SSEA, there was no significant change in the odds of TDR since national ARV scale-up (OR = 0.97; 95% CI: 0.92–1.02). An analysis limited to sequences with mixtures at less than 0.5% of their nucleotide positions—a proxy for recent infection—yielded trends comparable to those obtained using the complete dataset. Four NNRTI SDRMs—K101E, K103N, Y181C, and G190A—accounted for >80% of NNRTI-associated TDR in all regions and subtypes. Sixteen nucleoside reverse transcriptase inhibitor (NRTI) SDRMs accounted for >69% of NRTI-associated TDR in all regions and subtypes. In SSA and SSEA, 89% of NNRTI SDRMs were associated with high-level resistance to nevirapine or efavirenz, whereas only 27% of NRTI SDRMs were associated with high-level resistance to zidovudine, lamivudine, tenofovir, or abacavir. Of 763 viruses with TDR in SSA and SSEA, 725 (95%) were genetically dissimilar; 38 (5%) formed 19 sequence pairs. Inherent limitations of this study are that some cohorts may not represent the broader regional population and that studies were heterogeneous with respect to duration of infection prior to sampling.Most TDR strains in SSA and SSEA arose independently, suggesting that ARV regimens with a high genetic barrier to resistance combined with improved patient adherence may mitigate TDR increases by reducing the generation of new ARV-resistant strains. A small number of NNRTI-resistance mutations were responsible for most cases of high-level resistance, suggesting that inexpensive point-mutation assays to detect these mutations may be useful for pre-therapy screening in regions with high levels of TDR. In the context of a public health approach to ARV therapy, a reliable point-of-care genotypic resistance test could identify which patients should receive standard first-line therapy and which should receive a protease-inhibitor-containing regimen.
UR - http://www.scopus.com/inward/record.url?scp=84930531525&partnerID=8YFLogxK
U2 - 10.1371/journal.pmed.1001810
DO - 10.1371/journal.pmed.1001810
M3 - Article
C2 - 25849352
AN - SCOPUS:84930531525
SN - 1549-1277
VL - 12
JO - PLoS Medicine
JF - PLoS Medicine
IS - 4
M1 - e1001810
ER -