A second soluble Hox-type NiFe enzyme completes the hydrogenase set in Thiocapsa roseopersicina BBS.

Three functional NiFe hydrogenases were previously characterized in Thiocapsa roseopersicina BBS: two of them are attached to the periplasmic membrane (HynSL and HupSL), and one is localized in the cytoplasm (HoxEFUYH). The ongoing genome sequencing project revealed the presence of genes coding for another soluble Hox-type hydrogenase enzyme (hox2FUYH). Hox2 is a heterotetrameric enzyme; no indication for an additional subunit was found. Detailed comparative in vivo and in vitro activity and expression analyses of HoxEFUYH (Hox1) and the newly discovered Hox2 enzyme were performed. Functional differences between the two soluble NiFe hydrogenases were disclosed. Hox1 seems to be connected to both sulfur metabolism and dark/photofermentative processes. The bidirectional Hox2 hydrogenase was shown to be metabolically active under specific conditions: it can evolve hydrogen in the presence of glucose at low sodium thiosulfate concentration. However, under nitrogen-fixing conditions, it can oxidize H(2) but less than the other hydrogenases in the cell.

Electron-transfer subunits of the NiFe hydrogenases in Thiocapsa roseopersicina BBS.

Thiocapsa roseopersicina BBS contains at least three different active NiFe hydrogenases: two membrane-bound enzymes and one apparently localized in the cytoplasm. In addition to the small and large structural subunits, additional proteins are usually associated with the NiFe hydrogenases, connecting their activity to other redox processes in the cells. The operon of the membrane-associated hydrogenase, HynSL, has an unusual gene arrangement: between the genes coding for the large and small subunits, there are two open reading frames, namely isp1 and isp2. Isp1 is a b-type haem-containing transmembrane protein, whereas Isp2 displays marked sequence similarity to the heterodisulfide reductases. The other membrane-bound (Hup) NiFe hydrogenase contains the hupC gene, which codes for a cytochrome b-type protein that probably plays a role in electron transport. The operon of the NAD(+)-reducing Hox hydrogenase contains a hoxE gene. In addition to the hydrogenase and diaphorase parts of the complex, the fifth HoxE subunit may serve as a third redox gate of this enzyme. The physiological functions of these putative electron-mediating subunits were studied by disruption of their genes. The deletion of some accessory proteins dramatically reduced the in vivo activities of the hydrogenases, although they were fully active in vitro. The absence of HupC resulted in a decrease in HupSL activity in the membrane, but removal of the Isp1 and Isp2 proteins did not have any significant effect on the location of HynSL activity. Through the use of a tagged HoxE protein, the whole Hox hydrogenase pentamer could be purified as an intact complex.