117 research outputs found
XRCC1 Deficiency Sensitizes Human Lung Epithelial Cells to Genotoxicity by Crocidolite Asbestos and Libby Amphibole
Background: Asbestos induces DNA and chromosomal damage, but the DNA repair pathways protecting human cells against its genotoxicity are largely unknown. Polymorphisms in XRCC1 have been associated with altered susceptibility to asbestos-related diseases. However, it is unclear whether oxidative DNA damage repaired by XRCC1 contributes to asbestos-induced chromosomal damage
Telomeric protein TRF2 protects Holliday junctions with telomeric arms from displacement by the Werner syndrome helicase
WRN protein loss causes Werner syndrome (WS), which is characterized by premature aging as well as genomic and telomeric instability. WRN prevents telomere loss, but the telomeric protein complex must regulate WRN activities to prevent aberrant telomere processing. Telomere-binding TRF2 protein inhibits telomere t-loop deletion by blocking Holliday junction (HJ) resolvase cleavage activity, but whether TRF2 also modulates HJ displacement at t-loops is unknown. In this study, we used multiplex fluorophore imaging to track the fate of individual strands of HJ substrates. We report the novel finding that TRF2 inhibits WRN helicase strand displacement of HJs with telomeric repeats in duplex arms, but unwinding of HJs with a telomeric center or lacking telomeric sequence is unaffected. These data, together with results using TRF2 fragments and TRF2 HJ binding assays, indicate that both the TRF2 B- and Myb domains are required to inhibit WRN HJ activity. We propose a novel model whereby simultaneous binding of the TRF2 B-domain to the HJ core and the Myb domain to telomeric arms promote and stabilize HJs in a stacked arm conformation that is unfavorable for unwinding. Our biochemical study provides a mechanistic basis for the cellular findings that TRF2 regulates WRN activity at telomeres
Comparison of Gene Expression Profiles in Chromate Transformed BEAS-2B Cells
Hexavalent chromium [Cr(VI)] is a potent human carcinogen.
Occupational exposure has been associated with increased risk of respiratory
cancer. Multiple mechanisms have been shown to contribute to Cr(VI) induced
carcinogenesis, including DNA damage, genomic instability, and epigenetic
modulation, however, the molecular mechanism and downstream genes mediating
chromium's carcinogenicity remain to be elucidated.We established chromate transformed cell lines by chronic exposure of normal
human bronchial epithelial BEAS-2B cells to low doses of Cr(VI) followed by
anchorage-independent growth. These transformed cell lines not only
exhibited consistent morphological changes but also acquired altered and
distinct gene expression patterns compared with normal BEAS-2B cells and
control cell lines (untreated) that arose spontaneously in soft agar.
Interestingly, the gene expression profiles of six Cr(VI) transformed cell
lines were remarkably similar to each other yet differed significantly from
that of either control cell lines or normal BEAS-2B cells. A total of 409
differentially expressed genes were identified in Cr(VI) transformed cells
compared to control cells. Genes related to cell-to-cell junction were
upregulated in all Cr(VI) transformed cells, while genes associated with the
interaction between cells and their extracellular matrices were
down-regulated. Additionally, expression of genes involved in cell
proliferation and apoptosis were also changed.This study is the first to report gene expression profiling of Cr(VI)
transformed cells. The gene expression changes across individual chromate
exposed clones were remarkably similar to each other but differed
significantly from the gene expression found in anchorage-independent clones
that arose spontaneously. Our analysis identified many novel gene expression
changes that may contribute to chromate induced cell transformation, and
collectively this type of information will provide a better understanding of
the mechanism underlying chromate carcinogenicity
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