Department of Occupation Health and Toxicology, School of Public Health, Fudan University, Shanghai 200032, China.
Department of Occupational Disease, Shanghai Pulmonary Hospital/Shanghai Hospital for Occupational Disease Prevention and Treatment, Shanghai 200082, China.
Sci Total Environ. 2021 Apr 15;765:142740. doi: 10.1016/j.scitotenv.2020.142740. Epub 2020 Oct 3.
Mechanisms for hematotoxicity and health effects from exposure to low doses of benzene (BZ) remain to be identified. To address the information gap, our investigation was focused onto using appropriate populations and cell cultures to investigate novel BZ-induced effects such as disruption of DNA repair capacity (DRC). From our study, abnormal miRNAs were identified and validated using lymphocytes from 56 BZ-poisoned workers and 53 controls. In addition, 173 current BZ-exposed workers and 58 controls were investigated for key miRNA expression using RT-PCR and for cellular DRC using a challenge assay. Subsequently, the observed activities in lymphocytes were verified using human HL-60 (p53 null) and TK6 (p53 wild-type) cells via 1,4-benzoquinone (1,4-BQ) treatment and miR-222 interferences. The targeting of MDM2 by miR-222 was validated using a luciferase reporter. Our results indicate induction of genotoxicity in lymphocytes from workers with low exposure doses to BZ. In addition, miR-222 expression was up-regulated among both BZ-poisoned and BZ-exposed workers together with inverse association with DRC. Our in vitro validation studies using both cell lines indicate that 1,4-BQ exposure increased expression of miR-222 and Comet tail length but decreased DRC. Loss of miR-222 reduced DNA damage, but induced S-phase arrest and apoptosis. However, silencing of MDM2 failed to activate p53 in TK6 cells. In conclusion, our in vivo observations were confirmed by in vitro studies showing that BZ/1,4-BQ exposures caused genotoxicity and high expression of miR-222 which obstructed expression of the MDM2-p53 axis that led to failed activation of p53, abnormal DRC and serious biological consequences.
苯(BZ)低剂量暴露引起血液毒性和健康影响的机制仍有待确定。为了解决信息空白,我们的研究集中在使用合适的人群和细胞培养物来研究新的 BZ 诱导效应,如 DNA 修复能力(DRC)的破坏。在我们的研究中,使用来自 56 名 BZ 中毒工人和 53 名对照者的淋巴细胞鉴定和验证了异常的 miRNA。此外,使用 RT-PCR 对 173 名当前 BZ 暴露工人和 58 名对照者进行了关键 miRNA 表达调查,并使用挑战测定法进行了细胞 DRC 调查。随后,通过 1,4-苯醌(1,4-BQ)处理和 miR-222 干扰,使用人 HL-60(p53 缺失)和 TK6(p53 野生型)细胞验证了在淋巴细胞中观察到的活性。通过荧光素酶报告验证了 miR-222 对 MDM2 的靶向作用。我们的结果表明,BZ 低暴露剂量的工人淋巴细胞中存在遗传毒性诱导。此外,miR-222 的表达在 BZ 中毒和 BZ 暴露工人中均上调,与 DRC 呈反比。我们使用两种细胞系进行的体外验证研究表明,1,4-BQ 暴露增加了 miR-222 的表达和彗星尾长度,但降低了 DRC。miR-222 的缺失减少了 DNA 损伤,但诱导了 S 期停滞和细胞凋亡。然而,在 TK6 细胞中沉默 MDM2 未能激活 p53。总之,我们的体内观察结果通过体外研究得到了证实,表明 BZ/1,4-BQ 暴露导致了遗传毒性和 miR-222 的高表达,从而阻碍了 MDM2-p53 轴的表达,导致 p53 激活失败、DRC 异常和严重的生物学后果。
