Next-generation sequencing (NGS) technologies enable new insights into the diversity of virus populations within their hosts. Diversity estimation is currently restricted to single-nucleotide variants or to local fragments of no more than a few hundred nucleotides defined by the length of sequence reads. To study complex heterogeneous virus populations comprehensively, novel methods are required that allow for complete reconstruction of the individual viral haplotypes. Here, we show that assembly of whole viral genomes of similar to 8600 nucleotides length is feasible from mixtures of heterogeneous HIV-1 strains derived from defined combinations of cloned virus strains and from clinical samples of an HIV-1 superinfected individual. Haplotype reconstruction was achieved using optimized experimental protocols and computational methods for amplification, sequencing and assembly. We comparatively assessed the performance of the three NGS platforms 454 Life Sciences/Roche, Illumina and Pacific Bio-sciences for this task. Our results prove and delineate the feasibility of NGS-based full-length viral haplotype reconstruction and provide new tools for studying evolution and pathogenesis of viruses.
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机译:下一代测序(NGS)技术使人们能够洞悉其宿主内病毒种群的多样性。目前,多样性估计仅限于单核苷酸变体或不超过由序列读取长度定义的几百个核苷酸的局部片段。为了全面研究复杂的异种病毒种群,需要新颖的方法以允许完整重建单个病毒单倍型。在这里,我们表明,从源自克隆病毒株定义组合的异源HIV-1株混合物和来自HIV-1超级感染个体的临床样品的混合物中,类似于8600个核苷酸长度的整个病毒基因组的组装是可行的。使用优化的实验方案和用于扩增,测序和组装的计算方法,实现了单倍型重建。我们比较评估了这三个NGS平台454 Life Sciences / Roche,Illumina和Pacific Bio-sciences的性能。我们的结果证明并描绘了基于NGS的全长病毒单倍型重建的可行性,并为研究病毒的进化和发病机理提供了新的工具。
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