Department of Biosciences, Institute of Health and Society, Federal University of São Paulo, Rua XV de Novembro 195, CEP 11.060-001, Santos, Brazil.
Center of Natural and Human Sciences, Federal University of ABC, Avenida Dos Estados, 5001, CEP 09210-580, Santo André, Brazil.
Chemosphere. 2023 Sep;334:138897. doi: 10.1016/j.chemosphere.2023.138897. Epub 2023 May 12.
Although the mechanisms of Pb-induced genotoxicity are well established, a wide individual's variation response is seen in biomarkers related to Pb toxicity, despite similar levels of metal exposure. This may be related to intrinsic variations, such as genetic polymorphisms; moreover, very little is known about the impact of genetic variations related to DNA repair system on DNA instability induced by Pb. In this context, the present study aimed to assess the impact of SNPs in enzymes related to DNA repair system on biomarkers related to acute toxicity and DNA damage induced by Pb exposure, in individuals occupationally exposed to the metal. A cross-sectional study was run with 154 adults (males, >18 years) from an automotive batteries' factory, in Brazil. Blood lead levels (BLL) were determined by ICP-MS; biomarkers related to acute toxicity and DNA instability were monitored by the buccal micronucleus cytome (BMNCyt) assay and genotyping of polymorphisms of MLH1 (rs1799977), OGG1 (rs1052133), PARP1 (rs1136410), XPA (rs1800975), XPC (rs2228000) and XRCC1 (rs25487) were performed by TaqMan assays. BLL ranged from 2.0 to 51 μg dL (mean 20 ± 12 μg dL) and significant associations between BLL and BMNCyt biomarkers related to cellular proliferation and cytokinetic, cell death and DNA damage were observed. Furthermore, SNPs from the OGG1,XPA and XPC genes were able to modulate interactions in nuclear bud formation (NBUDs) and micronucleus (MNi) events. Taken together, our data provide further evidence that polymorphisms related to DNA repair pathways may modulate Pb-induced DNA damage; studies that investigate the association between injuries to genetic material and susceptibilities in the workplace can provide additional information on the etiology of diseases and the determination of environmentally responsive genes.
虽然铅诱导遗传毒性的机制已经得到很好的证实,但在与铅毒性相关的生物标志物中,尽管金属暴露水平相似,但仍存在广泛的个体反应差异。这可能与内在变异有关,如基因多态性;此外,关于与 DNA 修复系统相关的遗传变异对铅诱导的 DNA 不稳定性的影响,人们知之甚少。在这种情况下,本研究旨在评估 DNA 修复系统相关酶的 SNP 对职业接触金属的个体中铅暴露引起的急性毒性和 DNA 损伤相关生物标志物的影响。巴西一家汽车电池厂进行了一项横断面研究,共纳入 154 名成年人(男性,>18 岁)。采用电感耦合等离子体质谱法(ICP-MS)测定血铅水平(BLL);通过口腔微核细胞(BMNCyt)试验监测与急性毒性和 DNA 不稳定性相关的生物标志物,并采用 TaqMan 法对 MLH1(rs1799977)、OGG1(rs1052133)、PARP1(rs1136410)、XPA(rs1800975)、XPC(rs2228000)和 XRCC1(rs25487)多态性进行基因分型。BLL 范围为 2.0 至 51μg/dL(平均 20±12μg/dL),BLL 与细胞增殖和细胞动力学、细胞死亡和 DNA 损伤相关的 BMNCyt 生物标志物之间存在显著相关性。此外,OGG1、XPA 和 XPC 基因的 SNP 能够调节核芽形成(NBUDs)和微核(MNi)事件的相互作用。总之,我们的数据进一步表明,与 DNA 修复途径相关的多态性可能调节铅诱导的 DNA 损伤;研究遗传物质损伤与工作场所易感性之间的关系,可以提供更多关于疾病病因学和环境反应基因确定的信息。
