Impact of human leukocyte antigen-B*51-restricted cytotoxic T-lymphocyte pressure on mutation patterns of nonnucleoside reverse transcriptase inhibitor resistance

Rilpivirine resistance mutation E138K in HIV-1 reverse transcriptase predisposed by prevalent polymorphic mutations

BACKGROUND

Rilpivirine is listed as a recommended or alternative key drug in the current ART guidelines. E138K in HIV-1 reverse transcriptase (RT) is a primary mutation in resistance to rilpivirine, although in vitro experiments showed it confers only <3-fold resistance. An unidentified mechanism could amplify resistance to rilpivirine conferred by E138K.

OBJECTIVES

The objective of this study was to reveal the mechanism amplifying rilpivirine resistance conferred by E138K.

PATIENTS AND METHODS

HIV-1 RT sequences were compared in patients who failed rilpivirine-containing ART virologically. The effects of mutations commonly identified with E138K on rilpivirine susceptibility were analysed by using recombinant HIV-1 variants.

RESULTS

Rilpivirine-containing ART was introduced in 162 HIV-1-infected patients at the outpatient clinic of the AIDS Clinical Center (National Center for Global Health and Medicine, Tokyo, Japan) between May 2012 and June 2015. Virological treatment failure occurred in six of these patients. E138K emerged in three patients while other rilpivirine resistance mutations emerged in the other three patients. I135T/L were identified in only three patients with E138K and existed before the introduction of rilpivirine-containing ART. Analysis of recombinant HIV-1 variants indicated that E138K conferred low-level rilpivirine resistance and that coexistence of I135T/L with E138K amplified the resistance.

CONCLUSIONS

I135T/L, escape mutations from HLA-B*51/52-restricted cytotoxic T lymphocytes, which are prevalent in Japan, may predispose HIV-1 to harbour E138K upon failure of rilpivirine-containing ART. The mutation patterns of drug resistance may vary due to baseline polymorphic mutations.

Raltegravir and elvitegravir-resistance mutation E92Q affects HLA-B*40:02-restricted HIV-1-specific CTL recognition

Interplay between drug-resistance mutations in CTL epitopes and HIV-1-specific CTLs may influence the control of HIV-1 viremia. However, the effect of integrase inhibitor (INI)-resistance mutations on the CTL recognition has not been reported. We here investigated the effect of a raltegravir and elvitegravir-resistance mutation (E92Q) on HLA-B*40:02-restricted Int92-102 (EL11: ETGQETAYFLL)-specific CTLs. EL11-specific CTLs recognized E92Q peptide-pulsed and E92Q mutant virus-infected cells less effectively than EL11 peptide-pulsed and wild-type virus-infected cells, respectively. Ex vivo ELISpot analysis showed no induction of E92Q-specific T cells in chronically HIV-1-infected individuals. Thus, we demonstrated that EL11-specific CTL recognition was affected by the INI-resistance mutation.

Effect of mutations at position E138 in HIV-1 reverse transcriptase and their interactions with the M184I mutation on defining patterns of resistance to nonnucleoside reverse transcriptase inhibitors rilpivirine and etravirine

Impacts of mutations at position E138 (A/G/K/Q/R/V) alone or in combination with M184I in HIV-1 reverse transcriptase (RT) were investigated. We also determined why E138K is the most prevalent nonnucleoside reverse transcriptase inhibitor mutation in patients failing rilpivirine (RPV) therapy. Recombinant RT enzymes and viruses containing each of the above-mentioned mutations were generated, and drug susceptibility was assayed. Each of the E138A/G/K/Q/R mutations, alone or in combination with M184I, resulted in decreased susceptibility to RPV and etravirine (ETR). The maximum decrease in susceptibility to RPV was observed for E138/R/Q/G by both recombinant RT assay and cell-based assays. E138Q/R-containing enzymes and viruses also showed the most marked decrease in susceptibility to ETR by both assays. The addition of M184I to the E138 mutations did not significantly change the levels of diminution in drug susceptibility. These findings indicate that E138R caused the highest level of loss of susceptibility to both RPV and ETR, and, accordingly, E138R should be recognized as an ETR resistance-associated mutation. The E138K/Q/R mutations can compensate for M184I in regard to both enzymatic fitness and viral replication capacity. The favored emergence of E138K over other mutations at position E138, together with M184I, is not due to an advantage in either the level of drug resistance or viral replication capacity but may reflect the fact that E138R and E138Q require two distinct mutations to occur, one of which is a disfavorable G-to-C mutation, whereas E138K requires only a single favorable G-to-A hypermutation. Of course, other factors may also affect the concept of barrier to resistance.

Influence of HAART on alternative reading frame immune responses over the course of HIV-1 infection

Background

Translational errors can result in bypassing of the main viral protein reading frames and the production of alternate reading frame (ARF) or cryptic peptides. Within HIV, there are many such ARFs in both sense and the antisense directions of transcription. These ARFs have the potential to generate immunogenic peptides called cryptic epitopes (CE). Both antiretroviral drug therapy and the immune system exert a mutational pressure on HIV-1. Immune pressure exerted by ARF CD8⁺ T cells on the virus has already been observed in vitro. HAART has also been described to select HIV-1 variants for drug escape mutations. Since the mutational pressure exerted on one location of the HIV-1 genome can potentially affect the 3 reading frames, we hypothesized that ARF responses would be affected by this drug pressure in vivo.

Methodology/Principal findings

In this study we identified new ARFs derived from sense and antisense transcription of HIV-1. Many of these ARFs are detectable in circulating viral proteins. They are predominantly found in the HIV-1 env nucleotide region. We measured T cell responses to 199 HIV-1 CE encoded within 13 sense and 34 antisense HIV-1 ARFs. We were able to observe that these ARF responses are more frequent and of greater magnitude in chronically infected individuals compared to acutely infected patients, and in patients on HAART, the breadth of ARF responses increased.

Conclusions/Significance

These results have implications for vaccine design and unveil the existence of potential new epitopes that could be included as vaccine targets.

[Bioinformatics studies on drug resistance against anti-HIV-1 drugs]

More than 20 drugs have been available for anti-HIV-1 treatment in Japan. Combination therapy with these drugs dramatically decreases in morbidity and mortality of AIDS. However, due to high mutation rate of HIV-1, treatment with ineffective drugs toward patients infected with HIV-1 causes accumulation of mutations in the virus, and emergence of drug resistant viruses. Thus, to achieve appropriate application of the drugs toward the respective patients living with HIV-1, methods for predicting the level of drug-resistance using viral sequence information has been developed on the basis of bioinformatics. Furthermore, ultra-deep sequencing by next-generation sequencer whose data analysis is also based on bioinformatics, or in silico structural modeling have been achieved to understand drug resistant mechanisms. In this review, I overview the bioinformatics studies about drug resistance against anti-HIV-1 drugs.

[Structural mechanism of immune evasion of HIV-1 gp120 by genomic, computational, and experimental science]

The third variable region (V3) of the human immunodeficiency virus type 1 (HIV-1) envelope gp120 subunit participates in determination of viral infection co-receptor tropism and host humoral immune responses. Positive charge of the V3 plays a key role in determining viral co-receptor tropism. In our previous papers, we showed a key role of the V3's net positive charge in the immunological escape and co-receptor tropism evolution in vivo. On the other hand, the several papers suggested that trimeric gp120s are protected from immune system by occlusion on the oligomer, by mutational variation, by carbohydrate masking and by conformational masking. If we can reveal the mechanism of neutralization escape, we expect that we will regulate the neutralization of HIV-1. In this review, we will overview the structural mechanism of neutralization escape of HIV-1 gp120 examined by computational science. The computational sciences for virology can provide more valuable information in combination with genomic and experimental science.

Influence of major HIV-1 protease inhibitor resistance mutations on CTL recognition

BACKGROUND

HIV-1 protease is subjected to dual selection pressure exerted by protease inhibitors (PIs) and cytotoxic T lymphocytes (CTL). Recently, we identified KMIGGIGGF (KF9) as a HLA-B*1501-restricted CTL epitope, including several major PI resistance mutations (M46I/L, I47A/V, G48V, I50V). To assess potential interactions between KF9-specific CTL and emergence of these important resistance mutations, we studied CTL recognition of the mutations and analyzed protease sequences in an HLA-I–typed patient cohort.

METHODS

CTL recognition of KF9 and resistance mutations in KF9 were studied in 38 HLA-B*1501-positive HIV-1–infected patients using variant KF9 peptides in interferon-g enzyme-linked immunospot assays. Protease sequences were analyzed in 302 HLA-I–typed HIV-1–infected patients.

RESULTS

G48V abolished KF9 recognition by CTL in all patients. Furthermore, M46I, I47A, and I50V could impair or abolish CTL recognition in many patients. In contrast, M46L and I47V showed good CTL recognition in nearly all patients. HIV-1 protease sequence analysis showed no statistical correlation between the occurrence of resistance mutations in KF9 and HLA-B*1501. Viral load in patients failing therapy with KF9 mutations was significantly lower in HLA-B*1501-positive patients in comparison with HLA-B*1501-negative patients.

CONCLUSIONS

PI mutations, G48V, M46I, and I47A, can abrogate CTL recognition, indicating potential interactions between development of drug resistance and CTL response. However, we could not find evidence that development of these PI mutations is influenced by KF9-specific CTL.

Characterization of the E138K resistance mutation in HIV-1 reverse transcriptase conferring susceptibility to etravirine in B and non-B HIV-1 subtypes

We have selected for resistance to etravirine (ETR) and efavirenz (EFV) in tissue culture using three subtype B, three subtype C, and two CRF02_AG clinical isolates, grown in cord blood mononuclear cells. Genotypic analysis was performed at baseline and at various weeks of selection. Phenotypic resistance in regard to ETR, EFV, and nevirapine (NVP) was evaluated at weeks 25 to 30 for all ETR-selected viruses and in viral clones that contained specific resistance mutations that were inserted by site-directed mutagenesis into pNL-4.3 and AG plasmids. The results show that ETR selected mutations at positions V90I, K101Q, E138K, V179D/E/F, Y181C, V189I, G190E, H221H/Y, and M230L and that E138K was the first of these to emerge in most instances. The time to the emergence of resistance was longer in the case of ETR (18 weeks) compared to EFV (11 weeks), and no differences in the patterns of emergent mutations could be documented between the B and non-B subtypes. Viral clones containing E138K displayed low-level phenotypic resistance to ETR (3.8-fold) and modestly impaired replication capacity (2-fold) compared to wild-type virus. ETR-selected virus showed a high degree of cross-resistance to NVP but not to EFV. We identified K101Q, E138K, V179E, V189I, G190E, and H221Y as mutations not included among the 17 currently recognized resistance-associated mutations for ETR.