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Related Concept Videos

RNA-seq03:21

RNA-seq

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RNA sequencing, or RNA-Seq, is a high-throughput sequencing technology used to study the transcriptome of a cell. Transcriptomics helps to interpret the functional elements of a genome and identify the molecular constituents of an organism. Additionally, it also helps in understanding the development of an organism and the occurrence of diseases. 
Before the discovery of RNA-seq, microarray-based methods and Sanger sequencing were used for transcriptome analysis. However, while...
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Droplet Barcoding-Based Single Cell Transcriptomics of Adult Mammalian Tissues
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Deconvolution from bulk gene expression by leveraging sample-wise and gene-wise similarities and single-cell RNA-Seq

Chenqi Wang1, Yifan Lin1, Shuchao Li1

  • 1Department of Automation, Xiamen University, Xiamen, China.

BMC Genomics
|September 18, 2024
PubMed
Summary
This summary is machine-generated.

We developed DSSC, a new computational method to simultaneously identify cell type proportions and gene expression profiles from bulk RNA sequencing data. This approach offers a cost-effective way to study cellular heterogeneity in biological samples.

Keywords:
Cell type abundanceCell type-specific gene expression profileDeconvolutionSimilarity matrixSingle-cell RNA-seq data

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Area of Science:

  • Genomics
  • Computational Biology
  • Bioinformatics

Background:

  • Bulk RNA sequencing (RNA-seq) averages gene expression, obscuring crucial cell type heterogeneity.
  • Single-cell RNA-seq (scRNA-seq) reveals cellular heterogeneity but is resource-intensive and impractical for large-scale studies.
  • Existing computational deconvolution methods often require prior knowledge of either cell type composition or cell type-specific gene expression profiles.

Purpose of the Study:

  • To develop a novel computational deconvolution algorithm for simultaneous inference of cell type proportions and cell type-specific gene expression profiles (GEPs) from bulk RNA-seq data.
  • To provide a practical and accurate alternative to experimental methods for characterizing cellular heterogeneity.

Main Methods:

  • Developed DSSC, a deconvolution algorithm that leverages gene-gene and sample-sample similarities in bulk RNA-seq and scRNA-seq data.
  • Evaluated DSSC's performance on simulated pseudo-bulk data (intra- and inter-dataset) and experimental bulk data (mixture and real samples).

Main Results:

  • DSSC accurately infers both cell type proportions and cell type-specific GEPs simultaneously.
  • The method demonstrates robustness across various simulation types and experimental datasets.
  • DSSC exhibits efficiency in terms of cost and time compared to existing approaches.

Conclusions:

  • DSSC offers a practical and effective computational solution for dissecting cellular composition and gene expression heterogeneity in bulk samples.
  • This method advances the study of biological mechanisms by providing detailed insights into cellular heterogeneity without the need for expensive experimental techniques.