Bo Lin scite author profile

Respiratory syncytial virus (RSV) is a ubiquitous human pathogen and the leading cause of lower respiratory tract infections in infants. Infection of cells and subsequent formation of syncytia occur through membrane fusion mediated by the RSV fusion protein (RSV-F). A novel in vitro assay of recombinant RSV-F function has been devised and used to characterize a number of escape mutants for three known inhibitors of RSV-F that have been isolated. Homology modeling of the RSV-F structure has been carried out on the basis of a chimera derived from the crystal structures of the RSV-F core and a fragment from the orthologous fusion protein from Newcastle disease virus (NDV). The structure correlates well with the appearance of RSV-F in electron micrographs, and the residues identified as contributing to specific binding sites for several monoclonal antibodies are arranged in appropriate solvent-accessible clusters. The positions of the characterized resistance mutants in the model structure identify two promising regions for the design of fusion inhibitors.

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ATR-Chk1 activation mitigates replication stress caused by mismatch repair-dependent processing of DNA damage

Gupta

Lin

Cowan

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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The mismatch repair pathway (MMR) is essential for removing DNA polymerase errors, thereby maintaining genomic stability. Loss of MMR function increases mutation frequency and is associated with tumorigenesis. However, how MMR is executed at active DNA replication forks is unclear. This has important implications for understanding how MMR repairs -methylguanine/thymidine (G/T) mismatches created upon exposure to DNA alkylating agents. If G/T lesion recognition by MMR initiates mismatch excision, the reinsertion of a mismatched thymidine during resynthesis could initiate futile repair cycles. One consequence of futile repair cycles might be a disruption of overall DNA replication in the affected cell. Herein, we show that in MMR-proficient HeLa cancer cells, treatment with a DNA alkylating agent slows S phase progression, yet cells still progress into the next cell cycle. In the first S phase following treatment, they activate ataxia telangiectasia and Rad3-related (ATR)-Checkpoint Kinase 1 (Chk1) signaling, which limits DNA damage, while inhibition of ATR kinase activity accelerates DNA damage accumulation and sensitivity to the DNA alkylating agent. We also observed that exposure of human embryonic stem cells to alkylation damage severely compromised DNA replication in a MMR-dependent manner. These cells fail to activate the ATR-Chk1 signaling axis, which may limit their ability to handle replication stress. Accordingly, they accumulate double-strand breaks and undergo immediate apoptosis. Our findings implicate the MMR-directed response to alkylation damage as a replication stress inducer, suggesting that repeated MMR processing of mismatches may occur that can disrupt S phase progression.

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Human Pluripotent Stem Cells Have a Novel Mismatch Repair-dependent Damage Response

Lin

Gupta

Heinen

2014

Journal of Biological Chemistry

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Background: Mismatch repair is involved in the cellular response to DNA-alkylating agents. Results: Alkylation damage causes mismatch repair-dependent apoptosis in human pluripotent stem cells (PSCs) in the first S phase after damage. Conclusion: Human PSCs utilize a unique MMR-dependent damage response to alkylation damage. Significance: Understanding how PSCs respond to DNA damage is crucial for their potential use in regenerative medicine.

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Bo Lin

Structural characterization of respiratory syncytial virus fusion inhibitor escape mutants: homology model of the F protein and a syncytium formation assay

ATR-Chk1 activation mitigates replication stress caused by mismatch repair-dependent processing of DNA damage

Human Pluripotent Stem Cells Have a Novel Mismatch Repair-dependent Damage Response

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