First case of mother-to-infant HIV type 1 group O transmission and evolution of C2V3 sequences in the infected child. French HIV Pediatric Cohort Study Group

Novel Time-Resolved Fluorescence Europium Nanoparticle Immunoassay for Detection of Human Immunodeficiency Virus-1 Group O Viruses Using Microplate and Microchip Platforms

Accurate detection and quantification of HIV-1 group O viruses have been challenging for currently available HIV assays. We have developed a novel time-resolved fluorescence (TRF) europium nanoparticle immunoassay for HIV-1 group O detection using a conventional microplate enzyme-linked immunosorbent assay (ELISA) and a microchip platform. We screened several antibodies for optimal reactivity with several HIV-1 group O strains and identified antibodies that can detect all the strains of HIV-1 group O that were available for testing. The antibodies were used to develop a conventional ELISA format assay and an in-house developed europium nanoparticle-based assay for sensitivity. The method was evaluated on both microwell plate and microchip platforms. We identified two specific and sensitive antibodies among the six we screened. The antibodies, C65691 and ANT-152, were able to quantify 15 and detect all 17 group O viruses, respectively, as they were broadly cross-reactive with all HIV-1 group O strains and yielded better signals compared with other antibodies. We have developed a sensitive assay that reflects the actual viral load in group O samples by using an appropriate combination of p24 antibodies that enhance group O detection and a highly sensitive TRF-based europium nanoparticle for detection. The combination of ANT-152 and C65690M in the ratio 3:1 was able to give significantly higher signals in our europium-based assay compared with using any single antibody.

Non-M variants of human immunodeficiency virus type 1

The AIDS pandemic that started in the early 1980s is due to human immunodeficiency virus type 1 (HIV-1) group M (HIV-M), but apart from this major group, many divergent variants have been described (HIV-1 groups N, O, and P and HIV-2). The four HIV-1 groups arose from independent cross-species transmission of the simian immunodeficiency viruses (SIVs) SIVcpz, infecting chimpanzees, and SIVgor, infecting gorillas. This, together with human adaptation, accounts for their genomic, phylogenetic, and virological specificities. Nevertheless, the natural course of non-M HIV infection seems similar to that of HIV-M. The virological monitoring of infected patients is now possible with commercial kits, but their therapeutic management remains complex. All non-M variants were principally described for patients linked to Cameroon, where HIV-O accounts for 1% of all HIV infections; only 15 cases of HIV-N infection and 2 HIV-P infections have been reported. Despite improvements in our knowledge, many fascinating questions remain concerning the origin, genetic evolution, and slow spread of these variants. Other variants may already exist or may arise in the future, calling for close surveillance. This review provides a comprehensive, up-to-date summary of the current knowledge on these pathogens, including the historical background of their discovery; the latest advances in the comprehension of their origin and spread; and clinical, therapeutic, and laboratory aspects that may be useful for the management and the treatment of patients infected with these divergent viruses.

A new real-time quantitative PCR for diagnosis and monitoring of HIV-1 group O infection

The correct diagnosis and monitoring of HIV-1 group O (HIV-O) infection are essential for appropriate patient management, for the prevention of mother-to-child transmission, and for the detection of dual HIV-M/HIV-O infections. HIV-O RNA quantification is currently possible with two commercial kits (from Abbott and Roche), which quantify HIV-M and HIV-O strains indifferently; therefore, they cannot be used for the specific identification of HIV-O infection. We designed a new real-time quantitative reverse transcription PCR (RT-qPCR assay) (INT-O), which we compared with our previous version, LTR-O, and with the Abbott RealTime HIV-1 kit. Specificity was assessed with 27 HIV-1 group M strains and the prototype strain of group P. Clinical performances were analyzed by using 198 stored plasma samples, representative of HIV-O genetic diversity. Analytical sensitivity, repeatability, and reproducibility were also determined. The detection limit of the INT-O assay was 40 copies/ml, and its specificity was 100%. The repeatability and reproducibility were excellent. Analysis of clinical samples showed a good correlation between the INT-O and LTR-O assays (r = 0.8240), with an improvement of analytical sensitivity. A good correlation was also obtained between the INT-O and Abbott assays (r = 0.8599) but with significantly higher values (0.19 logs) for the INT-O method, due to marked underquantifications for some patients. These results showed that HIV-O genetic diversity still has an impact on RNA quantification. The new assay, INT-O, allows both the specific diagnosis of HIV-O infection and the quantification of diverse HIV-O strains. Its detection limit is equivalent to that of commercial kits. This assay is cheap and suitable for use in areas in which strains of HIV-1 groups M and O cocirculate.

[Specific diagnosis and follow-up of HIV-1 group O infection: RES-O data]

INTRODUCTION

HIV-1 group O (HIV-O), mainly found in Cameroon, has a very high genetic diversity with consequences on the diagnosis and treatment of patients, requiring the development of specific tools.

OBJECTIVE

We present the currently available tools for the specific detection of HIV-O and its therapeutic monitoring, and the first RES-O data, a French network for the identification and monitoring of patients infected by HIV-O.

METHOD

The diagnosis of infection was confirmed by group-specific envelope serotyping. The viral load was assessed by a specific technique, LTR-O, developed in the laboratory and compared to the nonspecific kit RealTime HIV-1 (Abbott). The sequencing of antiretroviral target regions (Protease, Reverse Transcriptase (RT), Integrase and Gp41), was performed by specific primers. The analysis of resistance mutations was performed with the ANRS algorithm used for HIV-M.

RESULTS

HIV-O infection was confirmed for 117 patients. Measuring viral load showed the two techniques were equivalent, but with a tendency to under-quantification for the Abbott technique greater than 1 log for 5% of samples. 70 to 100% of the studied strains had at least 10 mutations in the Protease, four 4 in the RT, and one in Gp41, resulting in a natural genotypic resistance to some anti-retroviral molecules.

DISCUSSION

The diagnosis and monitoring of HIV-O infection is now possible. However, the impact of this variant's natural polymorphism on response to treatment remains undocumented.

Diagnosis and monitoring of HIV-1 group O-infected patients in Cameroun

OBJECTIVE

To define a routine algorithm for the specific diagnosis and complete follow-up of HIV-1 group O (HIV-O) infections in Cameroun.

METHODS

During 18 months, samples referred to Centre Pasteur du Cameroun for HIV testing or viral monitoring were screened for HIV-O infection with an in-house serotyping assay. HIV-O viral load was quantified by real-time polymerase chain reaction in the LTR gene and resistance genotyping was performed on pol and env sequences.

RESULTS

Of the 7030 samples tested, 78 HIV-O infections (1.1%) were identified, including 7 M and O dually seroreactive samples (9%). All treatment-naive patients and 59% of the patients receiving HAART had detectable viral loads. Analysis of pol sequences from 15 treatment-naive patients revealed a high number of polymorphisms in the protease region, with natural residues implicated in genotypic resistance to tipranavir and saquinavir for HIV-1 group M according to the Agence Nationale de Recherches sur le Sida et les Hépatites virales algorithm. Six patients (40%) harbored the 181C mutation conferring natural resistance to nonnucleoside reverse transcriptase inhibitors. Among antiretroviral-treated patients, major resistance mutations described for HIV-1 group M were found.

CONCLUSIONS

HIV-O prevalence remains relatively low in Cameroun. The cocirculation of groups M and O in this country leads to replicative dual infections. HIV-O-infected patients in this region can now benefit from effective and specific tools for a complete monitoring of infection. However, further studies are needed to understand long-term response to antiretrovirals of these complex variants.

Synonymous substitution rates predict HIV disease progression as a result of underlying replication dynamics

Upon HIV transmission, some patients develop AIDS in only a few months, while others remain disease free for 20 or more years. This variation in the rate of disease progression is poorly understood and has been attributed to host genetics, host immune responses, co-infection, viral genetics, and adaptation. Here, we develop a new “relaxed-clock” phylogenetic method to estimate absolute rates of synonymous and nonsynonymous substitution through time. We identify an unexpected association between the synonymous substitution rate of HIV and disease progression parameters. Since immune activation is the major determinant of HIV disease progression, we propose that this process can also determine viral generation times, by creating favourable conditions for HIV replication. These conclusions may apply more generally to HIV evolution, since we also observed an overall low synonymous substitution rate for HIV-2, which is known to be less pathogenic than HIV-1 and capable of tempering the detrimental effects of immune activation. Humoral immune responses, on the other hand, are the major determinant of nonsynonymous rate changes through time in the envelope gene, and our relaxed-clock estimates support a decrease in selective pressure as a consequence of immune system collapse.

During the clinical course of HIV infection, an asymptomatic phase always precedes the acquired immunodeficiency syndrome (AIDS). The duration of this asymptomatic phase is highly variable among patients and reflects the rate at which the immune system gradually deteriorates. Although humoral and cell-mediated immune responses are mounted against HIV, continuous replication and adaptation allows the virus to escape host immune responses. To gain a better understanding of the role of viral evolution in disease progression, we developed a new computational technique that can estimate changes in the absolute rates of synonymous and nonsynonymous divergence through time from molecular sequences. Using this type of evolutionary inference, we have identified a previously unknown association between the “silent” evolutionary rate of HIV and the rate of disease progression in infected individuals. This finding demonstrates that cellular immune processes, which are already known to determine HIV pathogenesis, also determine viral replication rates and therefore impose important constraints on HIV evolution.

Plasma viral RNA assay in HIV-1 group O infection by real-time PCR

HIV-1 group O infections remains essentially restricted to central Africa, and particularly Cameroon, although isolated cases have been reported in Western countries. Genomic differences explain why commercial tests used to quantify HIV-1 group M plasma load are unsuitable for HIV-1 group O. This lack of a quantitative tool hinders the clinical management of HIV-O-infected patients. We have therefore developed a real-time PCR assay, based on LightCycler technology, to quantify HIV-1 group O RNA in plasma. The primers were selected in the LTR 3' region. Forty-eight plasma samples containing strains belonging to the different HIV-1 type O clades (O:A, O:B and O:C) were tested. RNA was quantifiable in 40 of these samples. RNA was always detected in samples from untreated patients, except for one patient infected by a highly divergent strain. The kinetics of plasma viral load were also examined in seven patients for whom clinical and immunologic follow-up data were available. HIV-1 group O plasma load was high in the absence of treatment and correlated negatively with the CD4 cell count. Serial samples obtained during treatment allowed us to compare viral load changes with immunologic outcome. Despite the high initial cost of acquiring the required cycling device, the per-sample cost of this real-time quantitative PCR assay for HIV-1 group O is low, making it suitable for use in endemic zones.

Phylogenetic analysis of 49 newly derived HIV-1 group O strains: high viral diversity but no group M-like subtype structure

We assess the genetic relationships between 49 HIV-1 group O strains from 24 and 25 patients living in Cameroon and France, respectively. Strains were sequenced in four genomic regions: gag (p24) and three env regions (C2-V3, gp41, and for 22 C2-gp41). In each of the genomic regions analyzed, the genetic diversity among the group O strains was higher than that exhibited by group M. We characterize three major group O phylogenetic clusters (O:A, O:B, and O:C) that comprised the same virus strains in each of the genomic regions analyzed. The majority of strains cluster in O:A, a cluster previously identified by analysis of pol and env sequences. Group O recombinants were also identified. Importantly, the distinction between these three major group O clades was weak compared to the strong clustering apparent in the global group M phylogenetic tree that led to the identification of subtypes. Thus, these clusters of group O viruses should not be considered as equivalent to the group M subtypes. This difference between the pattern of group O and the global group M diversity, both taking into account the pandemic status of the group M subtypes and the comparatively small number of group O-infected individuals (the majority being from Cameroon), indicates that the group O phylogeny primarily represents viral divergence in the Cameroon region, analogous to group M viral diversity present in the Democratic Republic of Congo.

Analysis of pol gene heterogeneity, viral quasispecies, and drug resistance in individuals infected with group O strains of human immunodeficiency virus type 1

Nucleotide sequences of the reverse transcriptase (RT) coding region have been compared in four new human immunodeficiency virus type 1 (HIV-1) group O isolates. Phylogenetic analysis of this pol region highlights a cluster of these four HIV-1 group O sequences with seven other group O isolates (5% intracluster nucleotide sequence diversity) similar to clusters classified as subtypes in HIV-1 group M (an average of 4.9% intrasubtype sequence diversity). Based on these analyses, this group O cluster has been designated subtype A-O. A longitudinal study of a heterosexual couple infected with group O (ESP1 and ESP2) allowed a detailed analysis of RT sequences (amino acids 28 to 219). Directed evolution and a slightly higher mutation frequency was observed in the RT sequences of patient ESP2, treated with antiretroviral drugs, than that from the untreated patient ESP1. Antiretroviral treatment also selected for specific substitutions, M184V and T215Y in the RT coding region, conferring resistance to 3'-dideoxy-3'-thiacytidine and zidovudine, respectively. A Gly98 to Glu RT substitution identified in the treated patient suggests a possible reversion of a nonnucleoside RT inhibitor-resistant phenotype. Using RT clones from this longitudinal study, both heteroduplex tracking assay and cloning-sequencing techniques were employed for an extensive genetic analysis of pol gene quasispecies. Amino acid substitutions (i.e., Phe-77 to Leu, Lys-101 to Glu, and Val-106 to Iso) associated with antiretroviral resistance were identified in RT clones from HIV-1 group O-infected patients not subjected to drug therapy or treated with unrelated drugs. Finally, phylogenetic relationships between RT clones of the treated ESP2 patient and those of the untreated ESP1 patient show how drug pressure can direct evolution of viral pol gene quasispecies independently of direct drug-resistant substitutions.