Arsenite and monomethylarsonous acid generate oxidative stress response in human bladder cell culture.

Arsenicals have commonly been seen to induce reactive oxygen species (ROS) which can lead to DNA damage and oxidative stress. At low levels, arsenicals still induce the formation of ROS, leading to DNA damage and protein alterations. UROtsa cells, an immortalized human urothelial cell line, were used to study the effects of arsenicals on the human bladder, a site of arsenical bioconcentration and carcinogenesis. Biotransformation of As(III) by UROtsa cells has been shown to produce methylated species, namely monomethylarsonous acid [MMA(III)], which has been shown to be 20 times more cytotoxic. Confocal fluorescence images of UROtsa cells treated with arsenicals and the ROS sensing probe, DCFDA, showed an increase of intracellular ROS within five min after 1 microM and 10 microM As(III) treatments. In contrast, 50 and 500 nM MMA(III) required pretreatment for 30 min before inducing ROS. The increase in ROS was ameliorated by preincubation with either SOD or catalase. An interesting aspect of these ROS detection studies is the noticeable difference between concentrations of As(III) and MMA(III) used, further supporting the increased cytotoxicity of MMA(III), as well as the increased amount of time required for MMA(III) to cause oxidative stress. These arsenical-induced ROS produced oxidative DNA damage as evidenced by an increase in 8-hydroxyl-2'-deoxyguanosine (8-oxo-dG) with either 50 nM or 5 microM MMA(III) exposure. These findings provide support that MMA(III) cause a genotoxic response upon generation of ROS. Both As(III) and MMA(III) were also able to induce Hsp70 and MT protein levels above control, showing that the cells recognize the ROS and respond. As(III) rapidly induces the formation of ROS, possibly through it oxidation to As(V) and further metabolism to MMA(III)/(V). These studies provide evidence for a different mechanism of MMA(III) toxicity, one that MMA(III) first interacts with cellular components before an ROS response is generated, taking longer to produce the effect, but with more substantial harm to the cell.

Bait region involvement in the dimer-dimer interface of human alpha 2-macroglobulin and in mediating gross conformational change. Evidence from cysteine variants that form interdimer disulfides.

We have characterized four human alpha 2-macroglobulin (alpha 2M) bait region variants (G679C, M690C, V700C, and T705C) to test the hypothesis that the bait regions are involved in the interface between noncovalently associated dimers. All four variants folded correctly as judged by many normal properties. However, the presence of a cysteine resulted in disulfide formation between otherwise noncovalently associated dimers in all four variants. The extent of disulfide cross-linking varied with the location of the cysteine and gave a mixture of species that probably contained two, one, or zero interdimer disulfides in the tetramer. This was reflected in heterogeneity of conformational change upon thiol ester cleavage by methylamine, with the presence of crosslinks correlating with blockage of conformational change. The stoichiometry of trypsin inhibition was less in all cases than for wild-type alpha 2M. The M690C variant also showed evidence of some species with an intramolecular disulfide between bait regions of monomers within the same dimer. Taken together, the results are consistent with a location of the four bait regions in contact with, or in very close proximity to, one another. This suggests that they form all or part of the "cavity body" seen in the low resolution x-ray structure of transformed alpha 2M.

Comparison of Limulus alpha-macroglobulin with human alpha2-macroglobulin: thiol ester characterization, subunit organization, and conformational change.

The properties of the thiol ester-containing alpha-macroglobulin (alphaM) from the horseshoe crab (Limulus polyphemus) have been compared with those of the human analogue (alpha2M). Thiol ester accessibility was more restricted in Limulus alphaM than in human alpha2M. Fluorescent probes attached to the thiol ester cysteine indicated very similar local environments in the cleaved state of the two alphaMs. The separation between the two thiol ester cysteines in the cleaved state, determined by fluorescence resonance energy transfer, was also very similar for the two alphaMs. Differences were found in the oligomerization state and conformational changes of the two proteins. Whereas human alpha2M appears to be exclusively a dimer of dimers, Limulus alphaM can exist in both tetrameric and dimeric forms, although with marked preference for the dimer. Conformational change within a dimeric trapping unit, monitored by 6-(p-toluidino)-2-napthalene-sulfonic acid fluorescence change, showed that each monomer of the Limulus alphaM dimer appears to change conformation independently, whereas human alpha2M requires both thiol esters within a functional unit to be cleaved before the conformational change occurs. Taken together, these findings indicate that, whereas individual thiol esters in both types of alphaM are similar in properties, differences in subunit-subunit interaction result both in differences in state of oligomerization and in cooperativity of conformational change, which may reflect a fundamentally different organization of the subunits within a dimer in the two alphaMs.