Evaluation of a Benchtop HIV Ultradeep Pyrosequencing Drug Resistance Assay in the Clinical Laboratory

Avidor, Boaz; Girshengorn, Shirley; Matus, Natalia; Talio, Hadass; Achsanov, Svetlana; Zeldis, Irene; Fratty, Ilana S.; Katchman, Eugene; Brosh‐Nissimov, Tal; Hassin, David; Alon, Danny; Bentwich, Zvi; Yust, Israel; Amit, Sharon; Forer, Relly; Shultsman, Ina Vulih; Turner, Dan

doi:10.1128/jcm.02652-12

Cited by 33 publications

(21 citation statements)

References 27 publications

(40 reference statements)

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“…Using deep sequencing, a series of studies have demonstrated the ability to detect minority HIV drug resistant variants at levels as low as 0.1% to 1% of the virus population [26, 106, 158–162]. Most of these studies used the 454™ platform [106, 158, 159, 163, 164], but recently other deep sequencing technologies such as Illumina® [165] and Ion Torrent™ [162, 166] have proved to be useful in the identification of low-level drug resistant HIV variants. Deep sequencing has been used in HIV drug resistance surveillance [167, 168], to study transmission of HIV drug resistant viruses [101, 160, 169–175], and to evaluate the impact of minority variants on treatment efficacy [160, 176–183].…”

Section: Deep Sequencing In the Clinical Settingmentioning

confidence: 99%

Deep sequencing: Becoming a critical tool in clinical virology

Quiñones‐Mateu¹,

Ávila²,

Reyes‐Terán³

et al. 2014

Journal of Clinical Virology

116

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Population (Sanger) sequencing has been the standard method in basic and clinical DNA sequencing for almost 40 years; however, next-generation (deep) sequencing methodologies are now revolutionizing the field of genomics, and clinical virology is no exception. Deep sequencing is highly efficient, producing an enormous amount of information at low cost in a relatively short period of time. High-throughput sequencing techniques have enabled significant contributions to multiples areas in virology, including virus discovery and metagenomics (viromes), molecular epidemiology, pathogenesis, and studies of how viruses to escape the host immune system and antiviral pressures. In addition, new and more affordable deep sequencing-based assays are now being implemented in clinical laboratories. Here we review the use of the current deep sequencing platforms in virology, focusing on three of the most studied viruses: human immunodeficiency virus (HIV), hepatitis C virus (HCV), and influenza virus.

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Section: Deep Sequencing In the Clinical Settingmentioning

confidence: 99%

Deep sequencing: Becoming a critical tool in clinical virology

Quiñones‐Mateu¹,

Ávila²,

Reyes‐Terán³

et al. 2014

Journal of Clinical Virology

116

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“…The laboratory manipulations necessary for library generation are recognised as potential sources of artefactual recombination. Several papers have addressed the issue of minimising PCR artefacts [ 1 - 3 ] and there is growing interest in optimising RT-PCR techniques to enable accurate analysis of patient RNA virus load and early detection of the emergence of drug resistant quasi-species [ 3 - 6 ].…”

Section: Introductionmentioning

confidence: 99%

A general method to eliminate laboratory induced recombinants during massive, parallel sequencing of cDNA library

Waugh

Cromer²,

Grimm³

et al. 2015

Virol J

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BackgroundMassive, parallel sequencing is a potent tool for dissecting the regulation of biological processes by revealing the dynamics of the cellular RNA profile under different conditions. Similarly, massive, parallel sequencing can be used to reveal the complexity of viral quasispecies that are often found in the RNA virus infected host. However, the production of cDNA libraries for next-generation sequencing (NGS) necessitates the reverse transcription of RNA into cDNA and the amplification of the cDNA template using PCR, which may introduce artefact in the form of phantom nucleic acids species that can bias the composition and interpretation of original RNA profiles.MethodUsing HIV as a model we have characterised the major sources of error during the conversion of viral RNA to cDNA, namely excess RNA template and the RNaseH activity of the polymerase enzyme, reverse transcriptase. In addition we have analysed the effect of PCR cycle on detection of recombinants and assessed the contribution of transfection of highly similar plasmid DNA to the formation of recombinant species during the production of our control viruses.ResultsWe have identified RNA template concentrations, RNaseH activity of reverse transcriptase, and PCR conditions as key parameters that must be carefully optimised to minimise chimeric artefacts.ConclusionsUsing our optimised RT-PCR conditions, in combination with our modified PCR amplification procedure, we have developed a reliable technique for accurate determination of RNA species using NGS technology.

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“…However, and although this is still uncertain, drug-resistant HIV-1 minority variants (i.e., those present in as low as 1% of the viral population) have been suggested to be clinically relevant, as they have a high chance of selection under antiretroviral drug pressure conditions (49)(50)(51)(52)(53)(54)(55)(56)(57). For that reason, a series of ultrasensitive assays have been developed to detect drug-resistant HIV-1 minority variants, e.g., allele-specific PCR (49,58), oligonucleotide ligation assays (33,59), and deep (next-generation) sequencing (60)(61)(62). On the other hand, as described above, the adoption of genotypic HIV-1 tropism assays in the clinical setting has been hampered by the limited sensitivities of the population-based sequencing assays to detect minor non-R5 variants.…”

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confidence: 99%