Wei-Chan Hsu scite author profile

Wei-Chan Hsu

2Publications

3Citation Statements Received

89Citation Statements Given

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111

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National Health Research Institutes

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PP4 deficiency leads to DNA replication stress that impairs immunoglobulin class switch efficiency

Chen

Hsu

et al. 2018

Cell Death Differ

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The serine/threonine phosphatase PP4 has been implicated in DNA damage repair and cell cycle regulation through its dephosphorylation of specific substrates. We previously showed that PP4 is required for mouse B cell development, germinal center (GC) formation and immunoglobulin (Ig) class switch recombination (CSR). Here, we investigate the mechanisms underlying this requirement and demonstrate that murine PP4-deficient B lymphocytes have a defect in cell proliferation. Strikingly, the DNA damage response pathway that involves ATM/p53 and is linked to cell cycle arrest and impaired cell survival is strongly induced in these mutant B cells. In response to LPS + IL-4, stimuli that trigger IgG1 production, these PP4-deficient B cells show inefficient phosphorylation of ATR, leading to reduced retention of γH2AX-NBS1 complexes at sites of DNA damage, and compromised switching to IgG1. However, beyond the cell proliferation phase, conditional deletion of PP4 under the control of AID/cre completely restores normal IgG1 production in mutant B cell cultures. In vivo, co-deletion of PP4 and p53 by AID/cre partially rescues switching to IgG1 in B cells of mice immunized with TNP-KLH. Our findings establish that PP4 is indispensable for preventing DNA replication stress that could interfere with CSR, thereby promoting antibody switching during the humoral immune response.

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PTEN acts as a metabolic checkpoint molecule in mature B cells to suppress TLR9-mediated inflammation

Tsai

Hsu

Chen

et al. 2023

Preprint

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Phosphatase and tensin homolog (PTEN) is a negative regulator for PI3K signaling essential for B cell development. To explore the physiological effects of PTEN mutation on peripheral B cells, we generated CD23/cre-PTENFlox/Flox (CD23-cKO) mice in this study to avoid the developmental arrest. The mutant mice develop systemic inflammation associated with B cell expansion in the early phase followed with a severe immune cell-infiltration in multiple vital organs. PTEN deficiency leads to an accumulation of PI(3)P, an increase of lysosomal recruitment of TLR9/p38 complex, and an aberrant activation of TLR9/IL-6 axis in B cells. Interestingly, cholesterol biosynthesis pathway is upregulated in mutant cells upon TLR9 engagement. A blockade of cholesterol biosynthesis by targeting SQLE greatly reduces the level of PI(3)P and the interaction between TLR9 and p38, which lowers the level of TLR9-induced IL-6. Thus, PTEN represents a critical metabolic checkpoint that fine-tunes lipid and cholesterol homeostasis to control TLR9-driven inflammation.

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Wei-Chan Hsu

PP4 deficiency leads to DNA replication stress that impairs immunoglobulin class switch efficiency

PTEN acts as a metabolic checkpoint molecule in mature B cells to suppress TLR9-mediated inflammation

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