Quantitative detection of human immunodeficiency virus type 1 (HIV-1) viral load by SYBR green real-time RT-PCR technique in HIV-1 seropositive patients

HIV-1 viral load represents a basic marker for evaluation of the rate and severity of HIV-1 related disease and to monitor the effectiveness of treatment. An SYBR green-based real-time RT-PCR (SYBR green real-time RT-PCR) revealed by Light Cycler technology was evaluated for quantitation of HIV-1 RNA viral load in plasma of HIV-1 seropositive patients. The performance of the SYBR green real-time PCR was assessed on 56 HIV-1 seropositive patients under highly active retroviral therapy (HAART) and 25 blood donors. The results demonstrated that this technique detected 50 HIV-1 RNA copies per millilitre of plasma. Moreover, we compared real-time RT-PCR with the b-DNA technique considered widely a reference technique for HIV-1 RNA viral load measurement. The parallel quantitative analysis of HIV-1 positive samples showed a high correlation (r=0.908) between the two methods. Although b-DNA and the real-time-based method gave similar sensitivity, the assay determined quantitatively HIV-1 RNA copies in 4 out of 16 samples shown as undetectable by b-DNA. The SYBR green real-time RT-PCR represents a good alternative to b-DNA assay in HIV-1 viral load determination especially during the monitoring of HAART treatment.     

Quantitative assay for group M (subtype A-H) and group O HIV-1 RNA detection in plasma

A quantitative HIV-1 test is described based on a competitive RT-PCR assay combined with a sandwich hybridization as a detection system. The internal RNA standard (IS) was designed specifically to be competitive during the amplification and during the hybridization step. Sample viral load determination was carried out with one RT-PCR in the presence of 10(3) IS copies. The HIV-1 copy number was calculated by reference to an external standard curve performed on known and increasing amounts of the reference HIV-1 (Ref HIV-1) RNA co-amplified with a constant amount of the IS RNA. The assay had a linear range from 10(1) to 10(6) HIV-1 copies. HIV-1 strains belonging to the different subtypes from group M, but also group O, were all detected. Absolute quantification of purified HIV-1 RNA copies gave identical results as the AMPLICOR HIV-1 Monitor assay. The quantification of patient's samples was evaluated according to different criteria such as dynamic range, sensitivity, efficacy of material recovery, reproducibility and convenience of sample handling. The microplate format of the assay combined with the colorimetric detection provides a convenient tool and fulfills the requirement for routine molecular diagnostic laboratories.     

Diagnostic testing for HIV type 1 RNA in seronegative blood

We studied the feasibility of routine diagnostic testing for HIV-1 RNA at a publicly funded testing site. HIV-1 RNA was determined with a commercial polymerase chain reaction assay in pooled seronegative blood samples submitted for HIV testing to a public health laboratory. Recovery of HIV-1 RNA from the samples was estimated as at least 8% of viral RNA that was found in freshly prepared plasma. We estimated that screening for HIV-1 RNA in serum pools would result in the identification of blood specimens from more than 95% of acutely infected patients. The frequency of HIV-1 RNA in seronegative blood samples was estimated to be between 19 and 601 per 10(6) submitted specimens. The ratio of HIV-1 RNA positive and seronegative samples to specimens with HIV-1 antibodies confirmed by Western blot was estimated to be between 0.2% and 6.6%. The reagent costs for identifying 1 HIV-infected blood sample were 10-fold higher with the commercially available HIV-1 RNA assay compared with the HIV antibody enzyme-linked immunosorbent assay. Diagnostic testing for HIV-1 RNA may be warranted in high-risk populations since acutely infected patients may benefit most from anti-retroviral therapy and are thought to contribute disproportionately to the HIV epidemic.     

Detection of Colorado Tick Fever viral RNA in acute human serum samples by a quantitative real-time RT-PCR assay

A quantitative real-time RT-PCR assay for the detection of Colorado Tick Fever (CTF) viral RNA in human clinical samples is presented. The sensitivity of this assay has been shown to be greater than that of the isolation of virus in Vero cells by standard plaque assay in a direct comparison. The specificity of the CTF quantitative real-time RT-PCR assay was determined by the exclusive detection of CTF viral RNAs when applied to a diverse panel of CTF viral isolates and reference strain agents known to circulate in areas of CTF virus transmission. Lastly, the quantitative real-time RT-PCR assay demonstrated exceptional sensitivity for the detection of CTF viral RNA in acute human serum. The quantitative real-time RT-PCR assay is efficient, sensitive and specific and as such is useful for the detection of CTF viral RNA in the diagnostic or research laboratory.     

Competitive polymerase chain reaction assay for quantitation of HIV-1 DNA and RNA.

A quantitative PCR assay for the detection of HIV-1 nucleic acids is described. The assay is based on a competitive internal standard nucleic acid which can be discriminated from target sequences by the presence of a new restriction enzyme site. The method was used to quantitate plasmid molecules containing HIV-1 sequences, HIV-1 DNA and HIV-1 RNA purified from HIV-1-infected tissue culture cells as well as HIV-1 DNA present in the peripheral blood mononuclear cells of an AIDS patient. The assay will be valuable for assessing viral load in AIDS patients and for the study of viral gene expression.     

Development and evaluation of a real-time RT-PCR assay for quantification of cell-free human immunodeficiency virus type 2 using a Brome Mosaic Virus internal control

Quantification of cell-free virus in plasma is important for monitoring disease progression and for assessing the response to antiretroviral therapy in both human immunodeficiency type 1 and type 2 (HIV-1, HIV-2) infections. Although commercial assays suitable for HIV-1 quantification have been used for more than a decade, no commercial assays are yet available for the measurement of cell-free HIV-2. We have therefore developed a novel real-time RT-PCR assay which, unlike previously described 'in house' assays, incorporates a Brome Mosaic Virus (BMV) internal control to minimise the risk of generating false-negative or falsely low results due to unrecognised problems with viral RNA purification, cDNA synthesis or PCR amplification. The assay has a dynamic range of >5 log10, detects the clinically important HIV-2 subtypes A and B with high sensitivity and shows no cross reactivity with HIV-1. The 95% detection limit is approximately 100 HIV-2 RNA copies/ml and both the inter-assay and intra-assay variability are low (CV% at 1.8 x 10(5) copies/ml, 13.3% and 5.7%, respectively). Overall, plasma HIV-2 RNA was detected in 38% of 167 unselected HIV-2 antibody-positive samples analysed over a 2 year period. The assay described provides an ideal system for studying viral replication in HIV-2 infected patients and for monitoring antiretroviral therapy.     

Detection and quantitation of human immunodeficiency virus type-1 particles by confocal microscopy

A method is described to visualise directly human immunodeficiency virus type-1 (HIV-1) particles. HIV-1 containing samples were adsorbed onto a plastic surface and doubly labeled with antibodies specific for viral proteins and sensitive nucleic acids dyes. Laser scanning confocal microscopy detected co-localization of viral proteins and nucleic acids, thus allowing specific identification of HIV. Using this technique, we have quantified eight different HIV-1 sub-types and three HIV-1 groups in tissue culture supernatants from infected peripheral blood mononuclear cells (PBMCs). Confocal counts correlated well with electron microscopy (EM) counts and HIV-1 RNA loads as determined by quantitative PCR. Confocal microscopy may prove to be a simple alternative to electron microscopy for virus identification and quantitation.     

Performance of the automated Abbott RealTime HIV-1 assay on a genetically diverse panel of specimens from Brazil

The combination of automated sample preparation and real-time RT-PCR for measurement of HIV-1 viral load has the potential to significantly enhance throughput, reduce operator-associated error, and increase assay sensitivity and dynamic range. In this study, RNA was extracted from the plasma of 91 HIV-1 seropositive Brazilian blood donors using the Abbott m2000sp automated sample preparation system. Viral loads measured using the RealTime HIV-1 (RealTime HIV-1) assay and the Abbott m2000rt instrument were compared to values obtained in the LCx HIV RNA quantitative assay. Subtype was determined for 89 of 91 specimens by sequence/phylogenetic analysis of three genomic regions: gag p24, pol integrase, and env gp41. The panel included 69 subtype B, 1 C, 2 F, and 17 recombinant strains. Eighty-seven specimens were quantified by both assays. Two specimens were quantified only in RealTime HIV-1. Two additional specimens below the detection limit of both assays were also negative on PCR amplification. Viral load results were highly correlated, and good agreement was observed between assays with 90% of values within 0.5 log(10)copies/ml. The RealTime HIV-1 assay and m2000 system offer the advantages of automation while providing reliable quantification of diverse HIV strains.     

Diagnosing acute HIV infection: The performance of quantitative HIV-1 RNA testing (viral load) in the 2014 laboratory testing algorithm

New recommendations for laboratory diagnosis of HIV infection in the United States were published in 2014. The updated testing algorithm includes a qualitative HIV-1 RNA assay to resolve discordant immunoassay results and to identify acute HIV-1 infection (AHI). The qualitative HIV-1 RNA assay is not widely available; therefore, we evaluated the performance of a more widely available quantitative HIV-1 RNA assay, viral load, for diagnosing AHI. We determined that quantitative viral loads consistently distinguished AHI from a false-positive immunoassay result. Among 100 study participants with AHI and a viral load result, the estimated geometric mean viral load was 1,377,793 copies/mL.     

Evaluation of the Abbott Real-Time HIV-1 quantitative assay with dried blood spot specimens

The Abbott Real-Time HIV-1 assay was evaluated for its performance in quantification of human immunodeficiency virus type 1 (HIV-1) RNA in dried blood spot (DBS) samples. In total, 169 blood samples with detectable plasma HIV-1 RNA were used to extract RNA from paired DBS and liquid plasma samples, using the automated Abbott m Sample Preparation System (m2000sp). HIV-1 RNA was then quantitated by the m2000rt RealTime analyser. RNA samples suitable for real-time PCR were obtained from all but one (99.4%) of the DBS samples and HIV-1 RNA was detected in 163/168 (97.0%) samples. The correlation between HIV-1 RNA values measured in paired DBS and plasma samples was very high ( r  = 0.882), with 78.5% and 99.4% of cases differing by <0.5 and 1.0 log, respectively. Retesting of DBS replicates following 6 months of storage at 2–8°C showed no loss of HIV-1 RNA in a subset of 89 samples. The feasibility of DBS testing coupled with automated sample processing, and the use of a latest-generation FDA-approved real-time PCR-based system, represents an encouraging first step for viral load measurement in reference centres in developing countries where access to antiretroviral therapy is expanding.     

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.     

Plasma RNA viral load in human immunodeficiency virus type 2 subtype A and subtype B infections

Human immunodeficiency virus type 2 (HIV-2) is much less pathogenic than HIV-1, and HIV-2 infection is associated with plasma viral loads significantly lower than those found in HIV-1 infection. We have developed a real-time quantitative PCR method for measuring the HIV-2 RNA load that covers the range of genetic diversity of HIV-2 isolates and that detects extremely low viral loads. Samples from 49 patients were studied. Proviral DNA was first detected and quantified. The strains that were detected were then genotyped: 21 patients were infected with HIV-2 subtype A and 15 patients were infected with HIV-2 subtype B; 1 patient was infected with a highly divergent strain. Env PCR failed for the remaining 12 patients, so subtypes could not be determined. For viral RNA quantification, a stock of HIV-2 strain NIHZ, which was counted by electron microscopy, was used as the standard. Several primer sets targeting the highly conserved gag region were evaluated. Various primer combinations failed to amplify subtype B strains. With the final primer pair selected, which detected both subtype A and subtype B strains, the sensitivity of the assay was 100% at a viral load of 250 copies/ml and 66% at a viral load of 125 copies/ml. We found a correlation between the CD4(+)-cell count, the clinical stage, and the plasma HIV-2 RNA level. The median plasma HIV-2 RNA value for the 33 asymptomatic patients was 2.14 log(10), whereas it was 3.1 log(10) for the 16 patients with AIDS (P < 0.01). Proviral DNA was detectable in 18 symptom-free patients with high CD4(+)-cell counts, in whom viral RNA was undetectable.     

Quantitation of human immunodeficiency virus type 1 RNA in cell free seminal plasma: comparison of NASBA with Amplicor reverse transcription-PCR amplification and correlation with quantitative culture

Human immunodeficiency virus type 1 (HIV-1) is transmitted by infected males in semen. However, the inoculum required for infection is unknown. The ability to collect such information will rely on the availability of reliable quantitative assays of HIV-1 in semen. We examined the comparative performance of NASBA^™ and Amplicor Monitor^™ RT-PCR in quantifying HIV-1 RNA in cell free seminal plasma from seropositive men and correlated the results obtained with viral titres measured by a seminal cell quantitative microculture (QMC) assay. Of samples analysed, 68% and 56% by both NASBA and RT-PCR contained measurable HIV-1 RNA, respectively. Amplification inhibition frequently affected RT-PCR but not NASBA. Excluding samples with complete RT-PCR inhibition, there was 90% qualitative concordance and a strong positive correlation (r = 0.86) of RNA levels measured by the two methods. Comparison of the concentration of HIV-1 RNA in seminal plasma samples, as measured by NASBA, with QMC viral titres indicated that RNA levels probably reflect the infectiousness of whole semen. NASBA is a reliable technique for quantitating HIV-1 RNA in seminal plasma and should become a valuable tool in the study of factors that influence the sexual transmission of HIV.     

A novel RealTime HIV-1 Qualitative assay for the detection of HIV-1 nucleic acids in dried blood spots and plasma

Abbott RealTime HIV-1 Qualitative is an in vitro real-time PCR assay for detecting HIV-1 nucleic acids in human plasma and dried blood spots (DBS). The assay was designed to be used in diagnosis of HIV-1 infections in pediatric and adult patients, with an emphasis on the applicability in resource-limited settings. Use of DBS facilitates specimen collection from remote areas and transportation to testing laboratories. Small sample input requirement facilitates testing of specimens with limited collection volume. The Abbott RealTime HIV-1 Qualitative assay is capable of detecting HIV-1 group M subtypes A-H, group O and group N samples. HIV-1 virus concentrations detected with 95% probability were 80 copies/mL of plasma using the plasma protocol, and 2469 copies/mL of whole blood using the DBS protocol. The assay detected HIV-1 infection in 13 seroconversion panels an average 10.5 days earlier than an HIV-1 antibody test and 4.9 days earlier than a p24 antigen test. For specimens collected from 6 weeks to 18 months old infants born to HIV-1 positive mothers, assay results using both the DBS and plasma protocols agreed well with the Roche Amplicor HIV-1 DNA Test version 1.5 (95.5% agreement for DBS and 97.8% agreement for plasma).