Dorien de Jong

Increased fitness of drug resistant HIV-1 protease as a result of acquisition of compensatory mutations during suboptimal therapy.

OBJECTIVE It is thought as a consequence of continuous replication, HIV-1 has acquired an optimal fitness state and that suboptimal antiretroviral therapy selects for drug resistant variants which show impaired fitness in the absence of the drug. In this paper we studied the evolution and fitness of viral populations appearing in a patient who received protease monotherapy. METHODS Two factors contributing to fitness, drug resistance and protease catalytic activity, were studied at the enzymatic and virological level. RESULTS The first drug resistant viral variants that were selected in vivo harboured one to three protease substitutions. These mutants showed reduced protease activity and consequently a reduction in viral replication capacity. During continued in vivo replication of these viruses in the presence of the drug, novel variants harbouring additional substitutions in the viral protease appeared. These variants did not display any further increase in drug resistance but demonstrated clearly increased protease activity. Consequently the replication capacity of these viruses was raised to a level at which they replicated better than the original wild-type virus. CONCLUSION This study indicates that the viral population in the patient does not have to represent the fittest possible variants, and thus antiretroviral therapy may drive the viral population first through a lower fitness level and then to a higher fitness level.

A Novel Substrate-Based HIV-1 Protease Inhibitor Drug Resistance Mechanism

Background HIV protease inhibitor (PI) therapy results in the rapid selection of drug resistant viral variants harbouring one or two substitutions in the viral protease. To combat PI resistance development, two approaches have been developed. The first is to increase the level of PI in the plasma of the patient, and the second is to develop novel PI with high potency against the known PI-resistant HIV protease variants. Both approaches share the requirement for a considerable increase in the number of protease mutations to lead to clinical resistance, thereby increasing the genetic barrier. We investigated whether HIV could yet again find a way to become less susceptible to these novel inhibitors. Methods and Findings We have performed in vitro selection experiments using a novel PI with an increased genetic barrier (RO033-4649) and demonstrated selection of three viruses 4- to 8-fold resistant to all PI compared to wild type. These PI-resistant viruses did not have a single substitution in the viral protease. Full genomic sequencing revealed the presence of NC/p1 cleavage site substitutions in the viral Gag polyprotein (K436E and/or I437T/V) in all three resistant viruses. These changes, when introduced in a reference strain, conferred PI resistance. The mechanism leading to PI resistance is enhancement of the processing efficiency of the altered substrate by wild-type protease. Analysis of genotypic and phenotypic resistance profiles of 28,000 clinical isolates demonstrated the presence of these NC/p1 cleavage site mutations in some clinical samples (codon 431 substitutions in 13%, codon 436 substitutions in 8%, and codon 437 substitutions in 10%). Moreover, these cleavage site substitutions were highly significantly associated with reduced susceptibility to PI in clinical isolates lacking primary protease mutations. Furthermore, we used data from a clinical trial (NARVAL, ANRS 088) to demonstrate that these NC/p1 cleavage site changes are associated with virological failure during PI therapy. Conclusions HIV can use an alternative mechanism to become resistant to PI by changing the substrate instead of the protease. Further studies are required to determine to what extent cleavage site mutations may explain virological failure during PI therapy.

Lamivudine-Resistant Human Immunodeficiency Virus Type 1 Variants (184V) Require Multiple Amino Acid Changes to Become Co-Resistant to Zidovudine In Vivo

Exposure of human immunodeficiency virus to the nucleoside analogue lamivudine (3TC) rapidly selects for resistant variants with a valine at codon 184 (M184V) in the catalytic site of reverse transcriptase. In vitro, 184V demonstrated increased enzyme fidelity and suppressed zidovudine resistance. Clinical trials demonstrated that 3TC-zidovudine combination therapy results in a strong and sustained antiviral response. To investigate the role of 184V on in vivo virus evolution, the effect of zidovudine addition in 3TC-pretreated patients harboring 184V was studied. In vivo, no significant change in fidelity was observed with 184V, shown by generation of the classical pattern of zidovudine mutations. Of interest, in contrast to zidovudine monotherapy, in which just one substitution is sufficient for in vivo development of significant zidovudine resistance, multiple substitutions are required for the same level of zidovudine resistance in strains harboring 184V. This need for multiple substitutions may be one of the mechanisms explaining the sustained antiretroviral response of the 3TC-zidovudine combination.

Transient relapses ("blips") of plasma HIV RNA levels during HAART are associated with drug resistance.

Introduction: In a large number of patients on HAART who achieved plasma HIV RNA levels below the limit of detection (50 copies/ml), transient relapses of HIV RNA levels (“blips”) are observed. Objective: To determine whether relapses of plasma HIV RNA during HAART are associated with development of drug resistance. Methods: Plasma samples from 15 patients with a transient viral load relapse during HAART were studied. All regimens contained lamivudine (3TC). We used an ultrasensitive sequence approach to analyze the presence of drug resistance mutations during the relapse. Results: The median plasma HIV RNA load of the relapse was 76 copies/ml (range 50‐1239). In 11 of 15 cases, a genotype of HIV could be obtained. Mutations in the RT and protease gene conferring resistance to one or more drugs were observed in 8 of 11 patients, 6 of whom had the M184V substitution. During a median follow‐up of 27 months after the relapse, plasma HIV RNA levels remained undetectable in 13 of 15 patients. Conclusions: Plasma HIV RNA blips during HAART can be associated with selection of drug‐resistant HIV. This indicates that viral replication may occur during HAART, probably caused by a temporary decrease in active drug concentrations. A blip containing only wild‐type virus is not necessarily caused by viral replication. In this situation the raise of HIV RNA could also originate from release of wild‐type viruses, caused by activation of the latent virus reservoir. Independent of the mechanism, blips did not preclude successful inhibition of viral replication during 2‐year follow‐up in the majority of these cases.

Ninety-nine is not enough: molecular characterization of inhibitor-resistant human immunodeficiency virus type 1 protease mutants with insertions in the flap region

ABSTRACT While the selection of amino acid insertions in human immunodeficiency virus (HIV) reverse transcriptase (RT) is a known mechanism of resistance against RT inhibitors, very few reports on the selection of insertions in the protease (PR) coding region have been published. It is still unclear whether these insertions impact protease inhibitor (PI) resistance and/or viral replication capacity. We show that the prevalence of insertions, especially between amino acids 30 to 41 of HIV type 1 (HIV-1) PR, has increased in recent years. We identified amino acid insertions at positions 33 and 35 of the PR of HIV-1-infected patients who had undergone prolonged treatment with PIs, and we characterized the contribution of these insertions to viral resistance. We prepared the corresponding mutated, recombinant PR variants with or without insertions at positions 33 and 35 and characterized them in terms of enzyme kinetics and crystal structures. We also engineered the corresponding recombinant viruses and analyzed the PR susceptibility and replication capacity by recombinant virus assay. Both in vitro methods confirmed that the amino acid insertions at positions 33 and 35 contribute to the viral resistance to most of the tested PIs. The structural analysis revealed local structural rearrangements in the flap region and in the substrate binding pockets. The enlargement of the PR substrate binding site together with impaired flap dynamics could account for the weaker inhibitor binding by the insertion mutants. Amino acid insertions in the vicinity of the binding cleft therefore represent a novel mechanism of HIV resistance development.

Persistence of HIV-1 Variants with Multiple Protease Inhibitor (PI)-Resistance Mutations in the Absence of PI Therapy Can Be Explained by Compensatory Fixation

OBJECTIVE To investigate the mechanism explaining the persistence of human immunodeficiency virus (HIV) type 1 variants with multiple protease inhibitor (PI)-resistance mutations in the absence of PI therapy. METHODS Longitudinal genotypic analyses were performed on sequential samples obtained from 2 HIV-1-infected patients who had stopped PI therapy for 4 years. Replication capacity (RC) was determined using recombinant viruses. Subsequently, the effect that changing individual protease mutations back to wild type has on RC was analyzed. RESULTS We observed prolonged persistence (up to 4 years) of viruses with multiple protease mutations after PI therapy was stopped, despite the fact that the RC of the viruses was severely reduced. Forcing the virus to evolve toward wild type by changing individual protease mutations to wild type was unsuccessful, because all variants displayed a decreased RC in comparison with that of their predecessors. CONCLUSIONS We propose compensatory fixation as a mechanism for the in vivo persistence of variants with multiple PI-resistance mutations in the absence of PI therapy. Viruses with multiple PI mutations have (partially) compensated for the initial loss in RC. Therefore, reversion of a single mutation causes a (further) reduction in RC and, as a consequence, the route to wild type is blocked.

HIV-1 can persist in aged memory CD4+ T lymphocytes with minimal signs of evolution after 8.3 years of effective highly active antiretroviral therapy.

Background:Patients on long-term highly active antiretroviral therapy (HAART) were studied to determine persistence, drug resistance development, and evolution of HIV-1 proviral DNA. Methods:Peripheral blood mononuclear cells were obtained by large volume blood drawn (500 mL) from 8 clinically successfully treated patients who had received uninterrupted HAART for up to 8.9 years. HIV-1 load was determined by Taqman real-time polymerase chain reaction. Drug resistance mutations were determined by sequencing and ultrasensitive, allele-specific, reverse transcriptase (RT)-polymerase chain reaction. Results:HIV-1 DNA load was significantly higher in aged memory (CD45RO+ CD57+) when compared with memory (CD45RO+ CD57−) and naive (CD27+ CD45RO−) CD4+ T cells after HAART. Sequencing revealed no major drug resistance mutations in protease in all patients and appearance of resistance mutations in RT in just 1 patient. In 1 of 5 patients with undetectable viremia during treatment, RT M184 substitutions were detected. Phylogenetic analysis showed short genetic distances between patient sequences. Conclusions:During long-term HAART, HIV-1 is able to persist in terminally differentiated CD4+ T cells as proviral DNA. Viral evolution was restricted, and in 80% of the patients with undetectable viremia, no sign of viral replication could be detected.

An increase in viral replicative capacity drives the evolution of protease inhibitor-resistant human immunodeficiency virus type 1 in the absence of drugs.

Summary: Little is known about the factors which drive the evolution of protease inhibitor-resistant human immunodeficiency virus type-1 in the absence of drugs. To examine if viral replicative capacity (RC) is an important determinant, we performed in vitro evolution experiments in the absence of drugs with a unique panel of 6 drug-resistant human immunodeficiency virus type-1 recombinant protease variants with a range of different RC. The experiments revealed that an increase in viral RC was indeed an important determinant of evolution. Initial protease inhibitor-resistant viruses with only a few protease mutations and a lowered RC evolved into viruses with an increased RC, either by reversion of primary resistance mutations or by the acquisition of compensatory mutations. For these viruses with a lowered RC, higher fitness peaks are most likely available in the sequence space. Evolution of these viruses in the absence of drugs will therefore drive them to new fitness peaks. In contrast, viruses with an RC comparable to wild type or even higher than wild type did not show any evolution. In the case of these viruses, it is not so likely that higher fitness peaks are present within the sequence space, and therefore, these variants will persist in the absence of drug pressure.

A combinational CRISPR/Cas9 gene-editing approach can halt HIV replication and prevent viral escape

HIV presents one of the highest evolutionary rates ever detected and combination antiretroviral therapy is needed to overcome the plasticity of the virus population and control viral replication. Conventional treatments lack the ability to clear the latent reservoir, which remains the major obstacle towards a cure. Novel strategies, such as CRISPR/Cas9 gRNA-based genome-editing, can permanently disrupt the HIV genome. However, HIV genome-editing may accelerate viral escape, questioning the feasibility of the approach. Here, we demonstrate that CRISPR/Cas9 targeting of single HIV loci, only partially inhibits HIV replication and facilitates rapid viral escape at the target site. A combinatorial approach of two strong gRNAs targeting different regions of the HIV genome can completely abrogate viral replication and prevent viral escape. Our data shows that the accelerating effect of gene-editing on viral escape can be overcome and as such gene-editing may provide a future alternative for control of HIV-infection.

Maraviroc is able to inhibit dual-R5 viruses in a dual/mixed HIV-1-infected patient

OBJECTIVES Maraviroc is the first licensed chemokine co-receptor 5 (CCR5) co-receptor antagonist in clinical practice. It is currently being used in patients harbouring exclusively CCR5-tropic virus. The objective of the study was to investigate the impact of maraviroc on viruses with different co-receptor preferences in a patient with a dual/mixed (D/M) infection. METHODS We present a case report of an HIV-1 patient infected with a D/M virus population. Co-receptor tropism was determined by phenotypic and genotypic tests. Biological clones from pre- and post-maraviroc therapy were generated. Tropism of these infectious clones was investigated in U373-MAGI cells expressing CD4+ CCR5+ or CD4+ CXCR4+. Maraviroc susceptibility and viral replication were determined using donor peripheral blood mononuclear cells (PBMCs). RESULTS In-depth clonal genotypic analysis revealed the presence of both R5-tropic variants and X4-tropic viruses before the start of maraviroc. During maraviroc therapy all R5-predicted viruses were suppressed. Phenotypic analyses revealed that all biological clones before maraviroc therapy could infect both CCR5- and CXCR4-bearing U373-MAGI cells, demonstrating dual tropism. The baseline biological clones preferentially infected the CCR5 cell line and were fully susceptible to maraviroc in PBMCs (dual-R5). In contrast, during maraviroc therapy the dual-R5-tropic viruses were replaced by more X4-tropic viruses (dual-X4), which could not be inhibited by maraviroc. CONCLUSIONS This case report demonstrates that dual-tropic viruses, capable of using both co-receptors in phenotypic assays, can be inhibited by maraviroc if they have a CCR5 co-receptor preference in vivo.