利用虚拟微阵列从RNA-seq数据分析前列腺肿瘤中RNA剪接的全基因组谱。

Subhashini Srinivasan, Arun H Patil, Mohit Verma, Jonathan L Bingham, Raghunathan Srivatsan
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引用次数: 2

摘要

背景:第二代RNA测序技术(RNA-seq)提供了研究癌症中全基因组差异RNA剪接的潜力。然而,由于跨越剪接的短RNA读取不能连续地映射到染色体上,因此需要从RNA-seq数据中分析剪接的方法。在RNA-seq技术发明之前,含有代表已知基因外显子-外显子连接的探针序列的微阵列已被用于杂交细胞rna以测量上下文特异性差异剪接。在这里,我们将这种方法扩展到从RNA-seq数据集检测前列腺癌中肿瘤特异性剪接。方法:建立一个数据库SPEventH,它代表了人类少于100万个非冗余剪接事件的探针序列,并使用优化长度的外显子-外显子连接作为虚拟微阵列。SPEventH被用于绘制来自10名前列腺癌患者的匹配肿瘤正常样本的数千万个读数。从肿瘤和匹配正常中映射到每个事件的reads的差异计数用于确定前列腺中具有统计学意义的肿瘤特异性剪接事件。结果:我们发现61(61)个剪接事件在前列腺肿瘤中差异表达,p值小于0.0001,与相应的匹配正常样本相比,其倍数变化大于1.5。有趣的是,在公共数据库中,唯一的证据EST (BF372485)也来自前列腺肿瘤组织,该证据表明KLK3基因中的一个内含子与KLK2中的一个内含子连接的肿瘤特异性剪接事件之一。此外,p值小于0.001的765个事件以特定于上下文的方式对所有20个样本进行了聚类,很少有因样本覆盖率低而产生的例外。结论:我们证明,使用人类剪接事件非冗余数据库的虚拟微阵列实验是一种高效而敏感的方法,可以分析生物样本中的全基因组剪接,并在RNA-seq技术的数据集中检测肿瘤特异性剪接特征。大量剪接事件的特征可以将肿瘤和匹配的正常样本聚集成两个紧密分离的簇,这表明差异剪接是另一种RNA表型,与基因表达和snp一起,可以用于肿瘤分层。
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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Genome-wide Profiling of RNA splicing in prostate tumor from RNA-seq data using virtual microarrays.

Unlabelled:

Background: Second generation RNA sequencing technology (RNA-seq) offers the potential to interrogate genome-wide differential RNA splicing in cancer. However, since short RNA reads spanning spliced junctions cannot be mapped contiguously onto to the chromosomes, there is a need for methods to profile splicing from RNA-seq data. Before the invent of RNA-seq technologies, microarrays containing probe sequences representing exon-exon junctions of known genes have been used to hybridize cellular RNAs for measuring context-specific differential splicing. Here, we extend this approach to detect tumor-specific splicing in prostate cancer from a RNA-seq dataset.

Method: A database, SPEventH, representing probe sequences of under a million non-redundant splice events in human is created with exon-exon junctions of optimized length for use as virtual microarray. SPEventH is used to map tens of millions of reads from matched tumor-normal samples from ten individuals with prostate cancer. Differential counts of reads mapped to each event from tumor and matched normal is used to identify statistically significant tumor-specific splice events in prostate.

Results: We find sixty-one (61) splice events that are differentially expressed with a p-value of less than 0.0001 and a fold change of greater than 1.5 in prostate tumor compared to the respective matched normal samples. Interestingly, the only evidence, EST (BF372485), in the public database for one of the tumor-specific splice event joining one of the intron in KLK3 gene to an intron in KLK2, is also derived from prostate tumor-tissue. Also, the 765 events with a p-value of less than 0.001 is shown to cluster all twenty samples in a context-specific fashion with few exceptions stemming from low coverage of samples.

Conclusions: We demonstrate that virtual microarray experiments using a non-redundant database of splice events in human is both efficient and sensitive way to profile genome-wide splicing in biological samples and to detect tumor-specific splicing signatures in datasets from RNA-seq technologies. The signature from the large number of splice events that could cluster tumor and matched-normal samples into two tight separate clusters, suggests that differential splicing is yet another RNA phenotype, alongside gene expression and SNPs, that can be exploited for tumor stratification.

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