Chelsea M. Burgwin scite author profile

RAD51 is a key protein of homologous recombination that plays a critical role in the repair of DNA double-strand breaks (DSB) and interstrand cross links (ICL). To better understand the cellular function(s) of human RAD51, we propose to develop specific RAD51 inhibitors. RAD51 inhibitors may also help to increase the potency of anticancer drugs that act by inducing DSBs or ICLs, e.g., cisplatin or ionizing radiation. In vitro, RAD51 promotes DNA strand exchange between homologous ss- and dsDNA. Here, we developed a DNA strand exchange assay based on fluorescence resonance energy transfer and used this assay to identify RAD51 inhibitors by high throughput screening of the NIH Small Molecule Repository (>200,000 compounds). Seventeen RAD51 inhibitors were identified and analyzed for selectivity using additional non-fluorescent DNA-based assays. As a result, we identified a compound (B02) that specifically inhibited human RAD51 (IC50 = 27.4 μM), but not its E. coli homologue RecA (IC50 > 250 μM). Two other compounds (A03 and A10) were identified that inhibited both RAD51 and RecA, but not the structurally unrelated RAD54 protein. The structure-activity relationship (SAR) analysis allowed us to identify the structural components of B02 that are critical for RAD51 inhibition. The described approach can be used for identification of specific inhibitors of other human proteins that play an important role in DNA repair, e.g., RAD54 or Bloom’s syndrome helicase.

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Identification of Optimal Mouse Models of Systemic Sclerosis by Interspecies Comparative Genomics

Sargent

Aliprantis

et al. 2016

Arthritis & Rheumatology

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Objective Understanding the pathogenesis of systemic sclerosis (SSc) is confounded by considerable disease heterogeneity. Animal models of SSc that recapitulate distinct subsets of disease at the molecular level have not been delineated. We applied interspecies comparative analysis of genomic data from multiple mouse models of SSc and patients with SSc to determine which animal models best reflect the SSc intrinsic molecular subsets. Methods Gene expression measured in skin from mice with sclerodermatous graft-versus-host disease (sclGVHD), bleomycin-induced fibrosis, Tsk1/+ or Tsk2/+ mice was mapped to human orthologs and compared to SSc skin biopsy-derived gene expression. TGFβ activation was assessed using a responsive signature in mouse and Tnfrsf12a expression measured in SSc and mouse skin. Results Gene expression in skin from mice with sclGVHD and bleomycin-induced fibrosis corresponded to that in SSc patients in the inflammatory molecular subset. In contrast, Tsk2/+ mice showed gene expression corresponding to the fibroproliferative SSc subset. Bleomycin and Tsk2/+ mice showed enrichment of a TGFβ-responsive signature. Expression of Tnfrsf12a (the Tweak-Receptor / Fn14) is elevated in skin from fibroproliferative SSc patients and skin of Tsk2/+ mice. Conclusion This study reveals similarities in cutaneous gene expression between distinct mouse models of SSc and specific molecular subsets of the disease. Different pathways underlie the intrinsic subsets including TGF-β, IL13 and IL4. We identify a novel target, Tnfrsf12a that is elevated in skin from fibroproliferative patients and Tsk2/+ mice. The information will serve to inform mechanistic and translational pre-clinical studies in SSc.

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The Tsk2/+ Mouse Fibrotic Phenotype Is Due to a Gain-of-Function Mutation in the PIIINP Segment of the Col3a1 Gene

Long

Burgwin

et al. 2015

Journal of Investigative Dermatology

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Systemic sclerosis (SSc) is a polygenic, autoimmune disorder of unknown etiology, characterized by the excessive accumulation of extracellular matrix (ECM) proteins, vascular alterations, and autoantibodies. The tight skin (Tsk)2/+ mouse model of SSc demonstrates signs similar to SSc including tight skin and excessive deposition of dermal ECM proteins. By linkage analysis, we mapped the Tsk2 gene mutation to less than 3 megabases on chromosome 1. We performed both RNA sequencing of skin transcripts and genome capture DNA sequencing of the region spanning this interval in Tsk2/+ and wild-type littermates. A missense point mutation in the procollagen III amino terminal propeptide segment (PIIINP) of Col3a1 was found to be the best candidate for Tsk2, so both in vivo and in vitro genetic complementation tests were used to prove that this Col3a1 mutation is the Tsk2 gene. All previously documented mutations in the human Col3a1 gene are associated with Ehlers-Danlos syndrome, a connective tissue disorder that leads to a defect in type III collagen synthesis. To our knowledge, the Tsk2 point mutation is the first documented gain-of-function mutation associated with Col3a1, which leads instead to fibrosis. This discovery provides insight into the mechanism of skin fibrosis manifested by Tsk2/+ mice.

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Cysteine-rich domain of type III collagen N-propeptide inhibits fibroblast activation by attenuating TGFβ signaling

et al. 2022

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Tight Skin 2 Mice Exhibit Delayed Wound Healing Caused by Increased Elastic Fibers in Fibrotic Skin

Long

Burgwin

Huneke

et al. 2014

Advances in Wound Care

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Characterization of the Cell-Autonomous Traits of Tsk2/+ Mice, a Model of Systemic Sclerosis

Burgwin¹

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