DNA sequence analysis of bacterial toxic heavy metal resistances

Bacterial plasmids have genes that confer highly specific resistances to As, Bi, Cd, Cu, Cr, Hg, Pb, Te, Zn, and other toxic heavy metals. For each toxic cation or anion, generally a different resistance system exists, and these systems may be “linked” together on multiple resistance plasmids. For Cd²⁺, AsO₂ ^?, AsO₄ ^3?, Hg²⁺, and organomercurials, DNA sequence analysis has supplemented direct physiological and biochemical experiments to produce sophisticated understanding. ThecadA ATPase ofS.aureus plasmids is a 727 amino acid membrane ATPase that pumps Cd²⁺ from the cells as rapidly as it is accumulated. This polypeptide is related by sequence to other cation translocating ATPases, including the membrane K⁺ ATPases ofEscherichia coli andStreptococcus faecalis, the H⁺ ATPases of yeast andNeurospora, the Na⁺/K⁺ ATPases of vertebrate animals, and the Ca²⁺ ATPases of rabbit muscle. The conserved residues include the aspartyl residue that is phosphorylated, the lysine involved in ATP binding, and the proline within a membrane translocating region. The arsenate and arsenite translocating ATPase consists of 3 polypeptides (from DNA sequence analysis), including a recognizable ATP binding protein (arsA), an integral membrane protein (arsB gene), and a substrate specificity subunit (arsC gene). Inorganic mercury and organomercurial degradation is carried out by a series of about 6 polypeptides, including 2 soluble intracellular enzymes (organomercurial lyase and mercuric reductase). The latter is related by sequence and function to glutathione reductase and lipoamide dehydrogenase of prokaryotes and eukaryotes. These enzymes are dimeric, FAD-containing, NAD(P)H-dependent oxidoreductases. Other recognizable polypeptides in themer system include a DNA-binding regulatory protein from themerR gene and a Hg²⁺ transport system consisting of a periplasmic Hg²⁺-binding protein (merP gene) and a membrane protein (merT gene) in gram negative systems.