Population-based nanopore sequencing of the HIV-1 pangenome to identify drug resistance mutations.

HIV-1 drug resistance genotypic tests have primarily been performed by Sanger sequencing of gene segments encoding different drug target proteins. Since the number of targets has increased with the addition of a new class of antiretroviral drugs, a simple high-throughput system for assessing nucleotide sequences throughout the HIV-1 genome is required. Here, we developed a new solution using nanopore sequencing of viral pangenomes amplified by PCR. Benchmark tests using HIV-1 molecular clones demonstrated an accuracy of up to 99.9%. In addition, validation tests of our protocol in 106 clinical samples demonstrated high concordance of drug resistance and tropism genotypes (92.5% and 98.1%, respectively) between the nanopore sequencing-based results and archived clinical determinations made based on Sanger sequencing data. These results suggest that our new approach will be a powerful solution for the comprehensive survey of HIV-1 drug resistance mutations in clinical settings.

Nanopore Sequencing for Characterization of HIV-1 Recombinant Forms.

High genetic diversity, including the emergence of recombinant forms (RFs), is one of the most prominent features of human immunodeficiency virus type 1 (HIV-1). Conventional detection of HIV-1 RFs requires pretreatments, i.e., cloning or single-genome amplification, to distinguish them from dual- or multiple-infection variants. However, these processes are time-consuming and labor-intensive. Here, we constructed a new nanopore sequencing-based platform that enables us to obtain distinctive genetic information for intersubtype RFs and dual-infection HIV-1 variants by using amplicons of HIV-1 near-full-length genomes or two overlapping half-length genome fragments. Repeated benchmark tests of HIV-1 proviral DNA revealed consensus sequence inference with a reduced error rate, allowing us to obtain sufficiently accurate sequence data. In addition, we applied the platform for sequence analyses of 9 clinical samples with suspected HIV-1 RF infection or dual infection according to Sanger sequencing-based genotyping tests for HIV-1 drug resistance. For each RF infection case, replicated analyses involving our nanopore sequencing-based platform consistently produced long consecutive analogous consensus sequences with mosaic genomic structures consisting of two different subtypes. In contrast, we detected multiple heterologous sequences in each dual-infection case. These results demonstrate that our new nanopore sequencing platform is applicable to identify the full-length HIV-1 genome structure of intersubtype RFs as well as dual-infection heterologous HIV-1. Since the genetic diversity of HIV-1 continues to gradually increase, this system will help accelerate full-length genome analysis and molecular epidemiological surveillance for HIV-1. IMPORTANCE HIV-1 is characterized by large genetic differences, including HIV-1 recombinant forms (RFs). Conventional genetic analyses require time-consuming pretreatments, i.e., cloning or single-genome amplification, to distinguish RFs from dual- or multiple-infection cases. In this study, we developed a new analytical system for HIV-1 sequence data obtained by nanopore sequencing. The error rate of this method was reduced to ~0.06%. We applied this system for sequence analyses of 9 clinical samples with suspected HIV-1 RF infection or dual infection, which were extracted from 373 cases of HIV patients based on our retrospective analysis of HIV-1 drug resistance genotyping test results. We found that our new nanopore sequencing platform is applicable to identify the full-length HIV-1 genome structure of intersubtype RFs as well as dual-infection heterologous HIV-1. Our protocol will be useful for epidemiological surveillance to examine HIV-1 transmission as well as for genotypic tests of HIV-1 drug resistance in clinical settings.

Evaluation of the Geenius HIV 1/2 confirmatory assay for HIV-2 samples isolated in Japan.

BACKGROUND: Although the number of HIV-2-infected individuals is quite low in Japan, at least three groups of HIV-2 (A, B and CRF01_AB) have been detected thus far. In particular, CRF01_AB HIV-2 cases have been found only in limited areas, Cote d'Ivoire and Japan. Here, we demonstrate that Geenius HIV 1/2 Confirmatory Assay (Geenius, Bio-Rad Laboratories) is able to detect HIV-2 samples, including groups A, B and CRF01_AB, isolated in Japan. STUDY DESIGN: A total of 57 plasma samples, including three panels (Ⅰ: HIV-2-positive samples [n=9], Ⅱ: HIV-1 infection with HIV-2 antibody cross-reactivity samples [n=37], and Ⅲ: HIV negative with biological false-positive HIV-2 samples [n=11]) were tested by Geenius. RESULTS: Geenius determined Panel I to be "HIV-2 positive with/without HIV-1 cross-reactivity (n=4, respectively)", including HIV-2 group A and CRF01_AB. In the case with HIV-2 group B, all bands were detected, resulting in a Geenius interpretation of "HIV positive untypable". Geenius classified Panels II and III as "HIV-1 positive (n=37)" or "HIV negative (n=9)", "HIV indeterminate (n=1)" and "HIV-2 indeterminate (n=1)", suggesting 95.8% HIV-2 differentiation by Geenius. CONCLUSIONS: With Geenius, there were fewer false-positives for HIV-1/-2 negativity and fewer cross-reactions with HIV-2 among HIV-1-positive samples. Additionally, the assay could detect HIV-2 genetic group CRF01_AB. Geenius can be expected to be a useful diagnostic tool that is an alternative to conventional Western blotting.

Specific mutations in the HIV-1 G-tract of the 3'-polypurine tract cause resistance to integrase strand transfer inhibitors.

BACKGROUND: In vitro selection experiments identified viruses resistant to integrase strand transfer inhibitors (INSTIs) carrying mutations in the G-tract (six guanosines) of the 3'-polypurine tract (3'-PPT). A clinical study also reported that mutations in the 3'-PPT were observed in a patient receiving dolutegravir monotherapy. However, recombinant viruses with the 3'-PPT mutations that were found in the clinical study were recently shown to be susceptible to INSTIs. OBJECTIVES: To identify the specific mutation(s) in the G-tract of the 3'-PPT for acquiring INSTI resistance, we constructed infectious clones bearing single or multiple mutations and systematically characterized the susceptibility of these clones to both first- and second-generation INSTIs. METHODS: The infectious clones were tested for their infectivity and susceptibility to INSTIs in a single-cycle assay using TZM-bl cells. RESULTS: A single mutation of thymidine (T) at the fifth position (GGG GTG) in the G-tract of the 3'-PPT had no effect on INSTI resistance. A double mutation, cytidine (C) or 'T' at the second position and 'T' at the fifth position (GCG GTG and GTG GTG), increased resistance to INSTIs, with the appearance of a plateau in the maximal percentage inhibition (MPI) of the dose-response curves, consistent with a non-competitive mechanism of inhibition. CONCLUSIONS: Mutations at the second and fifth positions in the G-tract of the 3'-PPT may result in complex resistance mechanism(s), rather than simply affecting INSTI binding at the IN active site.

Pre-treatment and acquired HIV drug resistance in Dar es Salaam, Tanzania in the era of tenofovir and routine viral load monitoring.

OBJECTIVES: We investigated the prevalence and patterns of pre-treatment and acquired HIV drug resistance mutations (DRMs) in Tanzania as a 'treat all' strategy, virological monitoring and the progressive increase in usage of tenofovir are being implemented in HIV treatment programmes. METHODS: Viral RNA was isolated from plasma of 60 ART-naive and 166 treated-but-viraemic (>400 copies/mL) HIV-1-infected adults attending a care and treatment clinic at Muhimbili National Hospital, Dar es Salaam, Tanzania, between June and October 2017. Viral genes encoding protease and reverse transcriptase were amplified by PCR and directly sequenced. RESULTS: Viral genotyping of successfully amplified samples revealed pre-treatment DRMs in 14/47 (29.8%) ART-naive subjects. Of these, 7/47 (14.9%) harboured mutations that confer high-level resistance to at least one drug of the default first-line regimen. In treated-but-viraemic subjects, DRMs were found in 100/111 (90%), where DRMs against NNRTI, NRTI and PI were observed in 95/100 (95%), 92/100 (92%) and 13/100 (13%), respectively. Tenofovir-resistance mutations K65R and K70G/E or ≥3 thymidine analogue resistance mutations including M41L and L210W were found in 18/36 (50%) subjects on a tenofovir-containing regimen at failure. Four patients harboured multiple DRMs, which can confer resistance to all available ART regimens in Tanzania. CONCLUSIONS: Taken together, pre-treatment and acquired DRMs were highly prevalent, which represents a major risk for the efficacy of ART programmes in Tanzania. Availability of a newer generation of antiretroviral drugs with a higher genetic barrier to resistance and robust treatment monitoring is warranted for effective and sustainable HIV treatment.

Impact of HIV-1 Integrase L74F and V75I Mutations in a Clinical Isolate on Resistance to Second-Generation Integrase Strand Transfer Inhibitors.

A novel HIV-1 integrase mutation pattern, L74F V75I, which conferred resistance to first-generation integrase strand transfer inhibitors (INSTIs), was identified in a clinical case with virological failure under a raltegravir-based regimen. Addition of L74F V75I to N155H or G140S Q148H increased resistance levels to the second-generation INSTIs dolutegravir (>385- and 100-fold, respectively) and cabotegravir (153- and 197-fold, respectively). These findings are important for the development of an accurate system for interpretation of INSTI resistance and the rational design of next-generation INSTIs.

HIV-1 CRF01_AE and Subtype B Transmission Networks Crossover: A New AE/B Recombinant Identified in Japan.

The major circulating HIV-1 strains in Japan have been subtype B (B) followed by CRF01_AE (AE) in newly diagnosed HIV/AIDS cases. These two subtypes have distinct epidemiological characteristics; B predominates in men who have sex with men, while AE is observed mostly in heterosexuals engaging in high-risk sex. However, transmission networks of these two high-risk populations appear to be crossing over and diffusing. Here we report the emergence of previously unidentified HIV-1 AE/B recombinants in Japan. We initially identified 13 cases with discordant subtyping results with AE (gag MA)/B (pol PR-RT)/AE (env C2V3) by molecular phylogenetic analysis of 1,070 cases who visited Nagoya Medical Center from 1997 to 2012. Genetic characterization of full-length sequences demonstrated that they shared an identical recombinant structure, and was designated as CRF69_01B by the Los Alamos HIV National Laboratory. By reviewing gag, pol, and env sequences collected in the Japanese Drug Resistance HIV-1 Surveillance Network, we found five other CRF69_01B probable cases from different areas in Japan, suggesting that the strain is transmitted widely throughout the country. The time of the most recent common ancestor analyses estimated that CRF69_01B emerged between 1991 and 1995, soon after AE was introduced from neighboring countries in the mid-1990s. Understanding the current epidemic strains is important for the diagnosis and treatment of HIV/AIDS, as well as for the development of globally effective HIV vaccines.

A Novel Drug-Resistant HIV-1 Circulating Recombinant Form CRF76_01B Identified by Near Full-Length Genome Analysis.

HIV-1 CRF01_AE and subtype B (B) have dominated and their different circulating recombinant forms (CRFs) have emerged in East and Southeast Asian countries. Here, we report a novel drug-resistant HIV-1 CRF. Five independent recombinant specimens exhibiting discordant subtype results for the gag, pol, and env sequences were isolated. These recombinants had the CRF01_AE (gag p17)/B (pol PR-RT and IN)/CRF01_AE (env C2-V3) pattern similar to CRF69_01B. Sequence analysis of four near full-length HIV-1 genomes revealed a unique phylogenetic cluster distinct from previously reported CRFs. Of the four recombinants, three shared an identical mosaic structure including seven breakpoints in the gag, pol, vif, and env regions, designated CRF76_01B. The one remaining recombinant had additional recombination breakpoints in the vpu region and exhibited another unique recombinant form composed of CRF76_01B and B. These findings provide important insight into the transmission dynamics of HIV-1 in Asia that may be important for its effective prevention.

Natural polymorphism S119R of HIV-1 integrase enhances primary INSTI resistance.

Integrase strand transfer inhibitors (INSTIs), which block proviral DNA integration into the host chromosome, are clinically effective against HIV-1 isolates exhibiting resistance to other classes of antiretroviral agents. Although naturally occurring amino acid variation has been less frequently observed in the integrase region, the functional constraints of this variation on primary INSTI resistance-associated mutations are not fully understood. In the present study, we focused on the S119G/R/P/T (S119X) polymorphisms, which are frequently observed in HIV-1 sequences derived from clinical specimens (naïve, n=458, 26%). The frequency of the S119X polymorphism together with Q148H/R (n=8, 63%) or N155H (n=12, 83%) was relatively high compared with that of naïve group. Our in vitro assays revealed that S119G/P/T alone exerted no effect on the susceptibility to INSTIs, whereas S119R enhanced the level of INSTI resistance induced by well-known INSTI resistance-associated mutations (Y143C, Q148H or N155H). Notably, the S119R polymorphism contributed to a significant (5.9-fold) increase in dolutegravir resistance caused by G140S/Q148H. Analysis of two cases of virological failure during raltegravir-based therapy showed that the accumulation and the rapid evolution of primary INSTI resistance-associated mutations coincided with the S119R mutation. These data highlight the role of the S119X polymorphism in INSTI resistance, and this polymorphism might be linked to the potential treatment outcome with INSTI-based therapy.

An 11-Year Surveillance of HIV Type 1 Subtypes in Nagoya, Japan.

Abstract To monitor active HIV-1 transmission in Nagoya, Japan, we have been determining the subtypes of HIV-1 infecting therapy-naive individuals who have newly visited the Nagoya Medical Center since 1997. The subtypes were determined by phylogenetic analyses using the base sequences in three regions of the HIV-1 genes including gag p17, pol protease (PR) and reverse transcriptase (RT), and env C2V3. Almost all HIV-1 subtypes from 1997 to 2007 and 93% of all HIV-1 isolates in 2007 were subtype B. HIV-1 subtypes A, C, D, and F have been detected sporadically since 1997, almost all in Africans and South Americans. The first detected circulating recombinant form (CRF ) was CRF01_AE (11-year average annual detection rate, 7.7%). Only two cases of CRF02_AG were detected in 2006. A unique recombinant form (URF ) was first detected in 1998 and the total number of URFs reached 25 by year 2007 (average annual detection rate, 4.7%). Eleven of these 25 were detected from 2000 to 2005 and had subtypes AE/B/AE as determined by base sequencing of the gag p17, pol PR and RT, and env C2V3 genes (average annual detection rate, 3.7%). Unique subtype B has been detected in six cases since 2006. All 17 of these patients were Japanese. Other recombinant HIV-1s have been detected intermittently in eight cases since 1998. During the 11-year surveillance, most HIV-1s in Nagoya, Japan were of subtype B. We expect that subtype B HIV-1 will continue to predominate for the next several years. Active recombination between subtype B and CRF01_AE HIV-1 and its transmission were also shown.

Analysis of near full-length genomic sequences of drug-resistant HIV-1 spreading among therapy-naïve individuals in Nagoya, Japan: amino acid mutations associated with viral replication activity.

We analyzed a total of 12 near full-length genomes of drug-resistant HIV-1 spreading among therapy-naïve individuals in Nagoya, Japan. Genomes comprised seven protease inhibitor (PI)-resistant viruses possessing an M46I (n = 6) or L90M mutation (n = 1) and five non-nucleoside reverse transcriptase inhibitor-resistant viruses possessing a K103N mutation. All 12 viruses conserved both an H87Q mutation in the cyclophilin A-binding site of Gag p24 (capsid) and a T23N mutation in the cysteine-rich domain of Tat protein. PI-resistant viruses commonly possessed two cleavage site mutations in the p6(Pol)/protease of Pol polyprotein (F48L in p6(Pol)) and the anchor/core domains of Nef protein (L57V). These amino acid mutations represent candidates for enhancing replication activity of drug-resistant viruses and supporting expansion of such viruses in therapy-naïve individuals.

Trend of drug-resistant HIV type 1 emergence among therapy-naive patients in Nagoya, Japan: an 8-year surveillance from 1999 to 2006.

We studied the emergence of drug-resistant human immunodeficiency virus type 1 (HIV-1) with major amino acid mutations in 402 therapy-naive patients at Nagoya Medical Center, Japan, between 1999 and 2006. The mean prevalence of drug-resistant HIV-1 was 6.7% (range, 2.3-10.0%; n = 27). HIV-1 variants with protease inhibitor (PI)-resistant mutations alone were most frequently found (3.5%, n = 14), followed by those with nonnucleoside reverse transcriptase inhibitor (NNRTI)-resistant mutations alone (1.7%, n = 7). Variants with nucleoside reverse transcriptase inhibitor (NRTI)-resistant mutations alone were sporadically found (1.0%, n = 4). A variant possessing both NRTI- and PI-resistant mutations was detected in one patient (0.2%) and a variant possessing both NNRTI- and PI-resistant mutations was identified in another patient (0.2%). In addition, another 17 variants (4.2%, n = 17) with only 215-revertant mutations (T215C/D/G/L/S) that can easily reconvert to the nucleoside analogue-associated mutation of T215Y/F were found. The 402 viruses were phylogenetically analyzed, revealing three independent clusters comprising PI-resistant variants with the M46I or L90M mutation, NNRTI-resistant variants with the K103N mutation, and 215-revertant variants. The PI-resistant and 215-revertant strains have been spreading since 2000, and the NNRTI-resistant strain has started spreading since 2003. The nature of the epidemic and information for successfully blocking the spread of drug-resistant HIV-1 were clarified in this study.