Waitang Tsui scite author profile

Waitang Tsui

3Publications

36Citation Statements Received

293Citation Statements Given

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Fudan University

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A Small Subset of Cytosolic dsRNAs Must Be Edited by ADAR1 to Evade MDA5-Mediated Autoimmunity

Sun

Geisinger

et al. 2022

Preprint

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The innate immune system detects viral infection via pattern recognition receptors and induces defense reactions such as production of type I interferon1. One such receptor, MDA5, is activated upon the recognition of double-stranded RNAs (dsRNAs) that are often produced during viral replication2. Endogenous dsRNAs evade MDA5 activation through RNA editing by ADAR1, thus preventing autoimmunity3-5. Among the large number of endogenous dsRNAs, the key substrates whose editing is critical to evade MDA5 activation (termed as immunogenic dsRNAs) remain elusive. Here we reveal the identity of human immunogenic dsRNAs, a surprisingly small fraction of all cellular dsRNAs, to fill the gap in the ADAR1-dsRNA-MDA5 axis. We found that, in contrast to previous findings6,7, the immunogenic dsRNAs were highly enriched in mRNAs and depleted of introns, an expected indication of bona fide substrates of cytosolic MDA5. The immunogenic dsRNAs, in contrast to non-immunogenic dsRNAs, tended to have shorter loop between the stems, which may facilitate dsRNA formation. They also tended to be enriched at the GWAS signals of common inflammatory diseases, implying that they are truly immunogenic. We validated the MDA5-dependent immunogenicity of the dsRNAs, which was dampened following ADAR1-mediated RNA editing. We anticipate that a focused analysis of immunogenic dsRNAs will greatly facilitate the understanding and treatment of cancer and inflammatory diseases in which the important roles of dsRNA editing and sensing continue to be revealed8-13.

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Identification and Comparative Genomic Analysis of Type VI Secretion Systems and Effectors in Klebsiella pneumoniae

Liu

Tsui

et al. 2022

Front. Microbiol.

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Klebsiella pneumoniae is a nosocomial opportunistic pathogen that can cause pneumonia, liver abscesses, and infections of the bloodstream. The resistance and pathogenicity of K. pneumoniae pose major challenges to clinical practice. However, the ecology and pathogenic mechanisms of K. pneumoniae have not been fully elucidated. Among these mechanisms, the secretion systems encoded by strains of the bacteria confer adaptive advantages depending on the niche occupied. The type VI secretion system (T6SS) is a multi-protein complex that delivers effector proteins to the extracellular environment or directly to eukaryotic or prokaryotic cells. T6SSs are widely distributed in Gram-negative bacteria and play an important role in bacterial virulence and the interactions between bacteria and other microorganisms or the environment. This study aimed to enhance the understanding of the characteristics of T6SSs in K. pneumoniae through an in-depth comparative genomic analysis of the T6SS in 241 sequenced strains of K. pneumoniae. We identified the T6SS loci, the synteny of the loci in different species, as well as the effectors and core T6SS-related genes in K. pneumoniae. The presence of a T6SS was a common occurrence in K. pneumoniae, and two T6SS clusters are the most prevalent. The variable region downstream of the gene vgrG usually encodes effector proteins. Conserved domain analysis indicated that the identified putative effectors in K. pneumoniae had the functions of lipase, ribonuclease, deoxyribonuclease, and polysaccharide hydrolase. However, some effectors did not contain predicted functional domains, and their specific functions have yet to be elucidated. This in silico study represents a detailed analysis of T6SS-associated genes in K. pneumoniae and provides a foundation for future studies on the mechanism(s) of T6SSs, especially effectors, which may generate new insights into pathogenicity and lead to the identification of proteins with novel antimicrobial properties.

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DHX9 resolves G-quadruplex condensation to prevent DNA double-strand breaks

Xue¹,

Chen

Ling

et al. 2022

Preprint

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DNA G-quadruplexes (G4s) structures are abundantly present in mammalian genomes and correlated with genome instability. However, the mechanism by which G4s are timely resolved remains unknown. Here, we report that DHX9 functions as a resolvase to unwind G4s globally in activated B cells. DHX9-deficient B cells show gross DNA double-strand breaks at the accumulated G4 sites, which are clustered together and form liquid condensates. We demonstrate that DHX9 also undergoes phase separation and fuses with G4 condensates for the productive unwinding of G4s in an ATP-dependent manner. Physiologically, G4-accumulation-induced DNA breaks can promote immunoglobulin class-switch recombination for producing high-affinity antibodies. Surprisingly, the DHX9Y1189C mutant identified in Hashimoto’s thyroiditis patients shows compromised phase separation and G4 unwinding abilities, causing elevated DNA damage and abnormal antibody production. Our findings suggest a DHX9-dependent G4 condensation-resolving mechanism to prevent DNA damage in mammalian cells. Disrupting this homeostasis may induce autoimmune disorders and lymphoid malignancies.

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Waitang Tsui

A Small Subset of Cytosolic dsRNAs Must Be Edited by ADAR1 to Evade MDA5-Mediated Autoimmunity

Identification and Comparative Genomic Analysis of Type VI Secretion Systems and Effectors in Klebsiella pneumoniae

DHX9 resolves G-quadruplex condensation to prevent DNA double-strand breaks

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