Polymorphism of Metallothionein 2A Modifies Lead Body Burden in Workers Chronically Exposed to the Metal.

Lead (Pb) is a metal that accumulates in the human body, inducing several adverse health effects. One of the proteins responsible for the distribution of metal in the body is metallothionein (MT), which is expressed by different genes, and it is supposed that genetic variation in the genes that encode MTs may affect the Pb body burden. The present study aimed to evaluate the genetic effects of the polymorphism of MT2A (single nucleotide polymorphism rs10636; Cx2192;G) on blood Pb levels (BLL) of workers from car battery factories who are chronically exposed to the metal. In total, 221 men participated in the study; genomic DNA from whole blood was extracted, and genotyping of MT2A was performed by TaqMan assays; BLL were quantified by inductively coupled plasma mass spectrometry (ICP-MS). BLL were 25 ± 14 µg/dl (range 1.9-68); BLL were positively correlated with duration of work and smoking status. Individuals who carried at least one C allele had higher BLL than those with the GG genotype (ß = -0.45; p = 0.025, multivariable linear regression analyses). Taken together, our data support the hypothesis that polymorphisms in genes related to the transport of Pb, such as MTs, may modulate the concentrations of the metal in the body and, consequently, adverse health effects induced by Pb exposure.

Effects of genetic polymorphisms on antioxidant status and concentrations of the metals in the blood of riverside Amazonian communities co-exposed to Hg and Pb.

There have been reports of genetic effects affecting the metabolism of Hg and Pb individually, and thus modulating their toxicities. However, there is still a knowledge gap with respect to how genetics may influence the toxicities of these toxic metals during a co-exposure scenario. This present study is therefore aimed at investigating the effects of polymorphisms in genes (GSTM1, GSTT1, GSTP1, GCLM, GCLC, GPx1, ALAD, VDR and MDR1) that have been implicated in Hg and Pb metabolisms affects the kinetics of these metals, as well as various blood antioxidant status parameters: MDA and GSH, and the activities of CAT, GPx and ALAD among populations that have been co-exposed to both Hg and Pb. Study subjects (207 men; 188 women) were from an Amazonian population in Brazil, exposed to Hg and Pb from diet. The blood levels of Hg and Pb were determined by ICP-MS while genotyping were performed by PCR assays. The median values of Hg and Pb in blood were 39.8µg/L and 11.0µg/dL, respectively. GSTM1, ALAD and VDR polymorphisms influenced Hg in blood (ß=0.17; 0.37 and 0.17; respectively, p<0.050) while variations on GCLM, GSTT1 and MDR1 (TT) modulated the concentrations of Pb among the subjects (ß=-0.14; 0.13 and -0.22; re-spectively, p<0.050). GSTT1 and GCLM polymorphisms also are associated to changes of MDA concentrations. Persons with null GSTM1 genotype had higher activity of the antioxidant enzyme CAT than carries of the allele. Individuals with deletion of both GSTM1 and GSTT1 had a decreased expression of GPx compared to those that expressed at least, one of the enzymes. ALAD 1/2 subjects had lower ALAD activity than individuals with the non-variant genotype. Our findings give further support that polymorphisms related to Hg and Pb metabolism may modulate Hg and Pb body burden and, consequently metals-induced toxicity.