Quantifying defective and wild-type viruses from high-throughput RNA sequencing.

Bioinformatics (Oxford, England) Pub Date : 2024-11-01 DOI:10.1093/bioinformatics/btae651

Juan C Muñoz-Sánchez, María J Olmo-Uceda, José-Ángel Oteo, Santiago F Elena

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Abstract

Motivation: Defective viral genomes (DVGs) are variants of the wild-type (wt) virus that lack the ability to complete autonomously an infectious cycle. However, in the presence of their parental (helper) wt virus, DVGs can interfere with the replication, encapsidation, and spread of functional genomes, acting as a significant selective force in viral evolution. DVGs also affect the host's immune responses and are linked to chronic infections and milder symptoms. Thus, identifying and characterizing DVGs is crucial for understanding infection prognosis. Quantifying DVGs is challenging due to their inability to sustain themselves, which makes it difficult to distinguish them from the helper virus, especially using high-throughput RNA sequencing. An accurate quantification is essential for understanding their very dynamical interactions with the helper virus.

Results: We present a method to simultaneously estimate the abundances of DVGs and wt genomes within a sample by identifying genomic regions with significant deviations from the expected sequencing depth. Our approach involves reconstructing the depth profile through a linear system of equations, which provides an estimate of the number of wt and DVG genomes of each type. Until now, in silico methods have only estimated the DVG-to-wt ratio for localized genomic regions. This is the first method that simultaneously estimates the proportions of wt and DVGs genome wide from short-reads RNA sequencing.

Availability and implementation: The Matlab code and the synthetic datasets are freely available at https://github.com/jmusan/wtDVGquantific.

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从高通量 RNA 测序中量化缺陷型和野生型病毒。

动机缺陷病毒基因组（DVG）是野生型（wt）病毒的变种，缺乏自主完成感染周期的能力。然而，在亲代（辅助）wt 病毒存在的情况下，缺陷病毒基因组可以干扰功能基因组的复制、封装和传播，成为病毒进化过程中一种重要的选择性力量。DVGs 还会影响宿主的免疫反应，并与慢性感染和较轻的症状有关。因此，识别和描述 DVGs 对于了解感染预后至关重要。由于 DVGs 无法自我维持，因此很难将其与辅助病毒区分开来，特别是使用高通量 RNA 测序（RNA-seq）时，对 DVGs 进行定量具有挑战性。准确的定量对于了解它们与辅助病毒的动态相互作用至关重要：结果：我们提出了一种方法，通过识别与预期测序深度有显著偏差的基因组区域，同时估算样本中 DVGs 和 wt 基因组的丰度。我们的方法包括通过线性方程组重建深度剖面，从而估算出每种类型的 wt 基因组和 DVG 基因组的数量。到目前为止，硅学方法只能估算局部基因组区域的 DVG 与 wt 比率。这是第一种通过短线程 RNA 测序同时估算全基因组 wt 和 DVG 比例的方法：MATLAB 代码和合成数据集可在 https://github.com/jmusan/wtDVGquantific 免费获取。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bioinformatics (Oxford, England)

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