Aberrant DNA damage response and DNA repair pathway in high glucose conditions.

Journal of cancer research updates Pub Date : 2018-06-25 DOI:10.6000/1929-2279.2018.07.03.1

Amy Zhong, Melissa H Y Chang, T-H Yu, Raymond Gau, D. Riley, Yumay Chen, Phang-lang Chen

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引用次数: 21

Abstract

Background Higher cancer rates and more aggressive behavior of certain cancers have been reported in populations with diabetes mellitus. This association has been attributed in part to the excessive reactive oxygen species generated in diabetic conditions and to the resulting oxidative DNA damage. It is not known, however, whether oxidative stress is the only contributing factor to genomic instability in patients with diabetes or whether high glucose directly also affects DNA damage and repair pathways. Results Normal renal epithelial cells and renal cell carcinoma cells are more chemo- and radiation resistant when cultured in high concentrations of glucose. In high glucose conditions, the CHK1-mediated DNA damage response is not activated properly. Cells in high glucose also have slower DNA repair rates and accumulate more mutations than cells grown in normal glucose concentrations. Ultimately, these cells develop a transforming phenotype. Conclusions In high glucose conditions, defective DNA damage responses most likely contribute to the higher mutation rate in renal epithelial cells, in addition to oxidative DNA damage. The DNA damage and repair are normal enzyme dependent mechanisms requiring euglycemic environments. Aberrant DNA damage response and repair in cells grown in high glucose conditions underscore the importance of maintaining good glycemic control in patients with diabetes mellitus and cancer.

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高糖条件下异常的DNA损伤反应和DNA修复途径。

背景在糖尿病人群中，癌症发病率较高，某些癌症的侵袭性更强。这种关联部分归因于糖尿病条件下产生的过量活性氧以及由此产生的DNA氧化损伤。然而，目前尚不清楚氧化应激是否是糖尿病患者基因组不稳定的唯一因素，或者高糖是否也直接影响DNA损伤和修复途径。结果正常肾上皮细胞和肾细胞癌细胞在高浓度葡萄糖环境中培养，具有较强的化疗和放疗耐受性。在高糖条件下，CHK1介导的DNA损伤反应没有被正确激活。与在正常葡萄糖浓度下生长的细胞相比，在高糖下的细胞也具有较慢的DNA修复率，并积累更多的突变。最终，这些细胞形成转化表型。结论在高糖条件下，除了氧化性DNA损伤外，缺陷性DNA损伤反应最有可能导致肾上皮细胞突变率升高。DNA损伤和修复是正常的酶依赖机制，需要良好的血糖环境。在高血糖条件下生长的细胞中异常的DNA损伤反应和修复强调了糖尿病和癌症患者保持良好血糖控制的重要性。

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来源期刊

Journal of cancer research updates

CiteScore

0.20

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0.00%

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