Your search keyword '"Weizhou Qian"' showing total 6 results

1. SARS-CoV-2-Encoded MiRNAs Inhibit Host Type I Interferon Pathway and Mediate Allelic Differential Expression of Susceptible Gene

Author

Youwei Zhu, Zhaoyang Zhang, Jia Song, Weizhou Qian, Xiangqian Gu, Chaoyong Yang, Nan Shen, Feng Xue, and Yuanjia Tang

Subjects

SARS-CoV-2, COVID-19, microRNA (miRNA), innate immune response, type I interferon pathway, single-nucleotide polymorphisms (SNPs), Immunologic diseases. Allergy, RC581-607

Abstract

Infection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), causing the rapid spread of coronavirus disease 2019 (COVID-19), has generated a public health crisis worldwide. The molecular mechanisms of SARS-CoV-2 infection and virus–host interactions are still unclear. In this study, we identified four unique microRNA-like small RNAs encoded by SARS-CoV-2. SCV2-miR-ORF1ab-1-3p and SCV2-miR-ORF1ab-2-5p play an important role in evasion of type I interferon response through targeting several genes in type I interferon signaling pathway. Particularly worth mentioning is that highly expressed SCV2-miR-ORF1ab-2-5p inhibits some key genes in the host innate immune response, such as IRF7, IRF9, STAT2, OAS1, and OAS2. SCV2-miR-ORF1ab-2-5p has also been found to mediate allelic differential expression of COVID-19-susceptible gene OAS1. In conclusion, these results suggest that SARS-CoV-2 uses its miRNAs to evade the type I interferon response and links the functional viral sequence to the susceptible genetic background of the host.

Published

2021

2. Digital microfluidics-based digital counting of single-cell copy number variation (dd-scCNV Seq)

Author

Xiyuan Yu, Weidong Ruan, Fanghe Lin, Weizhou Qian, Yuan Zou, Yilong Liu, Rui Su, Qi Niu, Qingyu Ruan, Wei Lin, Zhi Zhu, Huimin Zhang, and Chaoyong Yang

Subjects

Multidisciplinary

Abstract

Single-cell copy number variations (CNVs), major dynamic changes in humans, result in differential levels of gene expression and account for adaptive traits or underlying disease. Single-cell sequencing is needed to reveal these CNVs but has been hindered by single-cell whole-genome amplification (scWGA) bias, leading to inaccurate gene copy number counting. In addition, most of the current scWGA methods are labor intensive, time-consuming, and expensive with limited wide application. Here, we report a unique single-cell whole-genome library preparation approach based on d igital microfluidics for d igital counting of s ingle- c ell C opy N umber V ariation (dd-scCNV Seq). dd-scCNV Seq directly fragments the original single-cell DNA and uses these fragments as templates for amplification. These reduplicative fragments can be filtered computationally to generate the original partitioned unique identified fragments, thereby enabling digital counting of copy number variation. dd-scCNV Seq showed an increase in uniformity in the single-molecule data, leading to more accurate CNV patterns compared to other methods with low-depth sequencing. Benefiting from digital microfluidics, dd-scCNV Seq allows automated liquid handling, precise single-cell isolation, and high-efficiency and low-cost genome library preparation. dd-scCNV Seq will accelerate biological discovery by enabling accurate profiling of copy number variations at single-cell resolution.

Published

2023

3. LINEAGE: Label-free identification of endogenous informative single-cell mitochondrial RNA mutation for lineage analysis

Author

Li Lin, Yufeng Zhang, Weizhou Qian, Yao Liu, Yingkun Zhang, Fanghe Lin, Cenxi Liu, Guangxing Lu, Di Sun, Xiaoxu Guo, YanLing Song, Jia Song, Chaoyong Yang, and Jin Li

Subjects

Multidisciplinary, RNA, Mitochondrial, Sequence Analysis, RNA, Gene Expression Profiling, High-Throughput Nucleotide Sequencing, Mutation, Exome Sequencing, Animals, Cluster Analysis, Humans, RNA, Cell Lineage, Single-Cell Analysis, Algorithms

Abstract

Single-cell RNA-sequencing (scRNA-seq) has become a powerful tool for biomedical research by providing a variety of valuable information with the advancement of computational tools. Lineage analysis based on scRNA-seq provides key insights into the fate of individual cells in various systems. However, such analysis is limited by several technical challenges. On top of the considerable computational expertise and resources, these analyses also require specific types of matching data such as exogenous barcode information or bulk assay for transposase-accessible chromatin with high throughput sequencing (ATAC-seq) data. To overcome these technical challenges, we developed a user-friendly computational algorithm called "LINEAGE" (label-free identification of endogenous informative single-cell mitochondrial RNA mutation for lineage analysis). Aiming to screen out endogenous markers of lineage located on mitochondrial reads from label-free scRNA-seq data to conduct lineage inference, LINEAGE integrates a marker selection strategy by feature subspace separation and de novo "low cross-entropy subspaces" identification. In this process, the mutation type and subspace-subspace "cross-entropy" of features were both taken into consideration. LINEAGE outperformed three other methods, which were designed for similar tasks as testified with two standard datasets in terms of biological accuracy and computational efficiency. Applied on a label-free scRNA-seq dataset of BRAF-mutated cancer cells, LINEAGE also revealed genes that contribute to BRAF inhibitor resistance. LINEAGE removes most of the technical hurdles of lineage analysis, which will remarkably accelerate the discovery of the important genes or cell-lineage clusters from scRNA-seq data.

Published

2022

4. Simultaneous Single-Cell Genome and Transcriptome Sequencing in Nanoliter Droplet with Digital Microfluidics Identifying Essential Driving Genes

Author

Xing Xu, Li Lin, Jian Yang, Weizhou Qian, Rui Su, Xiaoxu Guo, Linfeng Cai, Zirun Zhao, Jia Song, and Chaoyong Yang

Subjects

Biomedical Engineering, Pharmaceutical Science, General Materials Science, Bioengineering, Biotechnology

Published

2022

5. Single-cell transcriptome lineage tracing of human pancreatic development identifies distinct developmental trajectories of alpha and beta cells

Author

Yufeng Zhang, Chaoyong Yang, Fanghe Lin, Guangxing Lu, Yingkun Zhang, Weizhou Qian, Yao Liu, Jia Song, Jin Li, Li Lin, Cenxi Liu, and Yanling Song

Subjects

Mitochondrial DNA, geography, Lineage (genetic), geography.geographical_feature_category, Cell, Alpha (ethology), Biology, Islet, Cell biology, medicine.anatomical_structure, medicine, Progenitor cell, Beta (finance), Reprogramming

Abstract

In comparison to mouse, the developmental process of human islets has not been properly elucidated. The advancement of single cell RNA-seq technology enables us to study the properties of alpha and beta cells at single cell resolution. By using mitochondrial genome variants as endogenous lineage-tracing markers, we found that human alpha and beta cells have different lineage features. This finding suggests specific endocrine progenitors for alpha and beta cells, which is different from mouse islet cells. This strategy was also applied to a study of chemically-induced islet cell reprogramming and was used to help identify artemether-induced alpha-to-beta trans-differentiation in human islets. The computational results of this study will inspire future studies to establish, maintain, and expand beta cell-specific progenitors in vitro and in vivo.

Published

2021

6. Mapping Gene Expression in the Spatial Dimension

Author

Yingwen Chen, Li Lin, Shaowei Jiang, Chaoyong Yang, Linfeng Cai, Jia Song, Weizhou Qian, Kun Yin, and Ray P. S. Han

Subjects

Combinatorics, Spatial Analysis, Dimension (vector space), Sequence Analysis, RNA, Gene Expression Profiling, Gene expression, Computational Biology, Humans, General Materials Science, General Chemistry, Single-Cell Analysis, Mathematics

Abstract

The main function and biological processes of tissues are determined by the combination of gene expression and spatial organization of their cells. RNA sequencing technologies have primarily interrogated gene expression without preserving the native spatial context of cells. However, the emergence of various spatially-resolved transcriptome analysis methods now makes it possible to map the gene expression to specific coordinates within tissues, enabling transcriptional heterogeneity between different regions, and for the localization of specific transcripts and novel spatial markers to be revealed. Hence, spatially-resolved transcriptome analysis technologies have broad utility in research into human disease and developmental biology. Here, recent advances in spatially-resolved transcriptome analysis methods are summarized, including experimental technologies and computational methods. Strengths, challenges, and potential applications of those methods are highlighted, and perspectives in this field are provided.

Published

2021