RAG-seq: A NSR Primed and Transposase Tagmentation Mediated Strand-specific Total RNA Sequencing in Single Cell.

Ping Xu, Zhiheng Yuan, Xiaohua Lu, Peng Zhou, Ding Qiu, Zhenghao Qiao, Zhongcheng Zhou, Li Guan, Yongkang Jia, Xuan He, Ling Sun, Youzhong Wan, Ming Wang, Yang Yu
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Abstract

Single-cell RNA sequencing (scRNA-seq) has transformed our understanding of cellular diversity with unprecedented resolution. However, many current methods are limited in capturing full-length transcripts and discerning strand orientation. We present RAG-seq, an innovative strand-specific total RNA sequencing technique that combines not-so-random (NSR) primers with Tn5 transposase-mediated tagmentation. RAG-seq overcomes previous limitations by delivering comprehensive transcript coverage and maintaining strand orientation, which is essential for accurate quantification of overlapping genes and detection of antisense transcripts. Through optimized reverse transcription with oligo dT primers, rRNA depletion via Depletion of Abundant Sequences by Hybridization (DASH), and linear amplification, RAG-seq enhances sensitivity and reproducibility, especially for low-input samples and single cells. Application to mouse oocytes and early embryos highlights RAG-seq's superior performance in identifying stage-specific antisense transcripts, shedding light on their regulatory roles during early development. This advancement represents a significant leap in transcriptome analysis within complex biological contexts.

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RAG-seq:NSR引物和转座酶标记介导的单细胞链特异性总RNA测序。
单细胞 RNA 测序(scRNA-seq)以前所未有的分辨率改变了我们对细胞多样性的认识。然而,目前的许多方法在捕获全长转录本和分辨链方向方面存在局限性。我们介绍的 RAG-seq 是一种创新的链特异性总 RNA 测序技术,它结合了非随机(NSR)引物和 Tn5 转座酶介导的标记。RAG-seq 克服了以往的局限性,能提供全面的转录本覆盖范围并保持链定向,这对于准确量化重叠基因和检测反义转录本至关重要。通过使用寡聚 dT 引物进行优化反转录、通过杂交去除冗余序列(DASH)去除 rRNA 以及线性扩增,RAG-seq 提高了灵敏度和可重复性,尤其适用于低输入样本和单细胞。在小鼠卵母细胞和早期胚胎中的应用凸显了 RAG-seq 在鉴定阶段特异性反义转录本方面的卓越性能,揭示了它们在早期发育过程中的调控作用。这一进步标志着复杂生物背景下转录组分析的重大飞跃。
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