An important clue to the mechanism for O(2) tolerance of certain [NiFe]-hydrogenases is the conserved presence of a modified environment around the iron-sulfur cluster that is proximal to the active site. The O(2)-tolerant enzymes contain two cysteines, located at opposite ends of this cluster, which are glycines in their O(2)-sensitive counterparts. The strong correlation highlights special importance for electron-transfer activity in the protection mechanism used to combat O(2). Site-directed mutagenesis has been carried out on Escherichia coli hydrogenase-1 to substitute these cysteines (C19 and C120) individually and collectively for glycines, and the effects of each replacement have been determined using protein film electrochemistry and electron paramagnetic resonance (EPR) spectroscopy. The "split" iron-sulfur cluster EPR signal thus far observed when oxygen-tolerant [NiFe]-hydrogenases are subjected to oxidizing potentials is found not to provide any simple, reliable correlation with oxygen tolerance. Oxygen tolerance is largely conferred by a single cysteine (C19), replacement of which by glycine removes the ability to function even in 1% O(2).
Nature provides key components for generating fuels from renewable resources in the form of enzymatic nanomachines which catalyze crucial steps in biological energy conversion, for example, the photosynthetic apparatus, which transforms solar power into chemical energy, and hydrogenases, capable of generating molecular hydrogen. As sunlight is usually used to synthesize carbohydrates, direct generation of hydrogen from light represents an exception in nature. On the molecular level, the crucial step for conversion of solar energy into H(2) lies in the efficient electronic coupling of photosystem I and hydrogenase. Here we show the stepwise assembly of a hybrid complex consisting of photosystem I and hydrogenase on a solid gold surface. This device gave rise to light-induced H(2) evolution. Hydrogen production is possible at far higher potential and thus lower energy compared to those of previously described (bio)nanoelectronic devices that did not employ the photosynthesis apparatus. The successful demonstration of efficient solar-to-hydrogen conversion may serve as a blueprint for the establishment of this system in a living organism with the paramount advantage of self-replication.
Two genes, norB and norZ, encoding two independent nitric oxide reductases have been identified in Alcaligenes eutrophus H16. norB and norZ predict polypeptides of 84.5 kDa with amino acid sequence identity of 90%. While norB resides on the megaplasmid pHG1, the norZ gene is located on a chromosomal DNA fragment. Amino acid sequence analysis suggests that norB and norZ encode integral membrane proteins composed of 14 membrane-spanning helices. The region encompassing helices 3 to 14 shows similarity to the NorB subunit of common bacterial nitric oxide reductases, including the positions of six strictly conserved histidine residues. Unlike the Nor enzymes characterized so far from denitrifying bacteria, NorB and NorZ of A. eutrophus contain an amino-terminal extension which may form two additional helices connected by a hydrophilic loop of 203 amino acids. The presence of a NorB/NorZ-like protein was predicted from the genome sequence of the cyanobacterium Synechocystis sp. strain PCC6803. While the common NorB of denitrifying bacteria is associated with a second cytochrome c subunit, encoded by the neighboring gene norC, the nor loci of A. eutrophus and Synechocystis lack adjacent norC homologs. The physiological roles of norB and norZ in A. eutrophus were investigated with mutants disrupted in the two genes. Mutants bearing single-site deletions in norB or norZ were affected neither in aerobic nor in anaerobic growth with nitrate or nitrite as the terminal electron acceptor. Inactivation of both norB and norZ was lethal to the cells under anaerobic growth conditions. Anaerobic growth was restored in the double mutant by introducing either norB or norZ on a broad-host-range plasmid. These results show that the norB and norZ gene products are isofunctional and instrumental in denitrification.
The hypX gene of the facultative lithoautotrophic bacterium Ralstonia eutropha is part of a cassette of accessory genes (the hyp cluster) required for the proper assembly of the active site of the [NiFe]-hydrogenases in the bacterium. A deletion of the hypX gene led to a severe growth retardation under lithoautotrophic conditions with 5 or 15% oxygen, when the growth was dependent on the activity of the soluble NAD ؉ -reducing hydrogenase. The enzymatic and infrared spectral properties of the soluble hydrogenase purified from a HypXnegative strain were compared with those from an enzyme purified from a HypX-positive strain. In activity assays under anaerobic conditions both enzyme preparations behaved the same. Under aerobic conditions, however, the mutant enzyme became irreversibly inactivated during H 2 oxidation with NAD ؉ or benzyl viologen as the electron acceptor. Infrared spectra and chemical determination of cyanide showed that one of the four cyanide groups in the wild-type enzyme was missing in the mutant enzyme. The data are consistent with the proposal that the HypX protein is specifically involved in the biosynthetic pathway that delivers the nickel-bound cyanide. The data support the proposal that this cyanide is crucial for the enzyme to function under aerobic conditions. 2 from the -proteobacterium Ralstonia eutropha H16. This is a heterotetrameric enzyme with subunits HoxF (67 kDa), HoxH (55 kDa), HoxU (26 kDa), and HoxY (23 kDa) (9, 10). The enzyme comprises two functionally different heterodimeric complexes, which have been separated and characterized (9, 11). The HoxFU dimer constitutes an enzyme module, termed NADH dehydrogenase or diaphorase, involved in the reduction of NAD Fig. 1A. The bridging oxygen ligand is removed upon reduction, whereby these enzymes become activated (17,24).The SH of R. eutropha belongs to a subclass of [NiFe]-hydrogenases where the polypeptide of the small hydrogenase subunit (HoxY) ends shortly after the position of the fourth Cys residue coordinating the proximal cluster. The large hydrogenase subunit (HoxH) of the SH contains the four Cys residues, conserved in all [NiFe]-hydrogenases, for the binding of the
The role of phagocytes and the complement system as potential host defense mechanisms against bacterial infection were studied in mice with two isogenic strains of Yersinia enterocolitica serotype 08 differing in pathogenicity because of differences in plasmid content. Complement depletion in mice by intraperitoneal injection of cobra venom factor did not affect the course of colonization of the intestinal tissue by each strain, indicating that in mice complement is not essential for the elimination of these bacteria. This conclusion is supported by the fact that fresh murine serum had no bactericidal effect in vitro either on the pathogenic or on the nonpathogenic strain. However, in the intestinal tissue as well as in the peritoneal cavity, only the pathogenic, plasmid-bearing Y. enterocolitica strain survived, while the nonpathogenic, plasmidless strain was rapidly eliminated. Since elimination from the peritoneal cavity is due to phagocytosis by polymorphonuclear leukocytes and macrophages, resistance to phagocytosis in vivo seems to be the decisive factor determining the virulence of pathogenic Y. enterocolitica strains.
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