Reduction of technetium(VII) by Desulfovibrio fructosovorans is mediated by the nickel-iron hydrogenase.

Resting cells of the sulfate-reducing bacterium Desulfovibrio fructosovorans grown in the absence of sulfate had a very high Tc(VII)-reducing activity, which led to the formation of an insoluble black precipitate. The involvement of a periplasmic hydrogenase in Tc(VII) reduction was indicated (i) by the requirement for hydrogen as an electron donor, (ii) by the tolerance of this activity to oxygen, and (iii) by the inhibition of this activity by Cu(II). Moreover, a mutant carrying a deletion in the nickel-iron hydrogenase operon showed a dramatic decrease in the rate of Tc(VII) reduction. The restoration of Tc(VII) reduction by complementation of this mutation with nickel-iron hydrogenase genes demonstrated the specific involvement of the periplasmic nickel-iron hydrogenase in the mechanism in vivo. The Tc(VII)-reducing activity was also observed with cell extracts in the presence of hydrogen. Under these conditions, Tc(VII) was reduced enzymatically to soluble Tc(V) or precipitated to an insoluble black precipitate, depending on the chemical nature of the buffer used. The purified nickel-iron hydrogenase performed Tc(VII) reduction and precipitation at high rates. These series of genetic and biochemical approaches demonstrated that the periplasmic nickel-iron hydrogenase of sulfate-reducing bacteria functions as a Tc(VII) reductase. The role of cytochrome c(3) in the mechanism is also discussed.

The NADP-reducing hydrogenase of Desulfovibrio fructosovorans: evidence for a native complex with hydrogen-dependent methyl-viologen-reducing activity.

The NADP-reducing hydrogenase of Desulfovibrio fructosovorans represents a novel class of [Fe] hydrogenases which is encoded by the well-characterized hndABCD operon containing the genes hndA, hndB, hndC, and hndD. Expression of this operon, monitored by measuring the NADP-reducing activity, was found to be maximum during the exponential phase of growth on fructose and then decreased when the concentration of the carbon and energy source became limiting. The optimum pH for the H2-driven NADP reduction was 8, and the apparent K(m) and Vmax were determined to be 0.09 mM and 13 x 10(-3) u/mg, respectively. Heterologous expression of the hnd genes in Escherichia coli was carried out to raise antisera against the different subunits of the NADP-reducing hydrogenase. The antisera were used to detect the four subunits in cell extract of D. fructosovorans after separation by SDS- and native PAGE. The four subunits of the NADP-reducing hydrogenase were demonstrated to be associated in a complex which exhibited H2-driven methyl viologen reduction. Furthermore, on native gel, a form lacking HndD, with no hydrogen-dependent methyl viologen reductase activity was also shown to be present in D. fructosovorans.

New shuttle vectors for the introduction of cloned DNA in Desulfovibrio.

The pBG1 replicon from the cryptic plasmid of Desulfovibrio desulfuricans G100A was inserted into pTZ18U derivatives to generate a new family of shuttle vectors. These plasmids are stable both in Escherichia coli and in Desulfovibrio, they present a large number of unique restriction sites, and colonies of recombinant clones can be identified by blue/white screening in E. coli. The pBMC, pBMK, and pBMS series carry the cat, npt, or strAB genes as selectable markers, respectively. The pBMC6, pBMK6, and pBMS6 plasmids can be introduced both in D. desulfuricans and in Desulfovibrio fructosovorans by electrotransformation, and the pBMC7, pBMK7, and pBMS7 plasmids contain additional mobilization functions which makes them suitable for conjugation.

Molecular study and partial characterization of iron-only hydrogenase in Desulfovibrio fructosovorans.

An iron-only hydrogenase was partially purified and characterized from Desulfovibrio fructosovorans wild-type strain. The enzyme exhibits a molecular mass of 56 kDa and is composed of two distinct subunits HydA and HydB (46 and 13 kDa, respectively). The N-terminal amino acid sequences of the two subunits of the enzyme were determined with the aim of designing degenerate oligonucleotides. Direct and inverse polymerase chain reaction techniques were used to clone the hydrogenase encoding genes. A 9-nucleotide region located 75 bp upstream from the translational start codon of the D. fructosovorans hydA gene was found to be highly conserved. The analysis of the deduced amino acid sequence of these genes showed the presence of a signal sequence located in the small subunit, exhibiting the consensus sequence which is likely to be involved in the specific export mechanism of hydrogenases. Two ferredoxin-like motives involved in the coordination of [4Fe-4S] clusters were identified in the N-terminal domain of the large subunit. The amino acid sequence of the [Fe] hydrogenase from D. fructosovorans was compared with the amino acid sequences from eight other hydrogenases (cytoplasmic and periplasmic). These enzymes share an overall 18% identity and 28% similarity. The identity reached 73% and 69% when the D. fructosovorans hydrogenase sequence was compared with the hydrogenase sequences from Desulfovibrio vulgaris Hildenborough and Desulfovibrio vulgaris oxamicus Monticello, respectively.

Three highly homologous membrane-bound lipoproteins participate in oligopeptide transport by the Ami system of the gram-positive Streptococcus pneumoniae.

Oligopeptides are an important source of nutrients, but can serve also as signals for intercellular communication. Oligopeptide-binding proteins seem likely to play a role both in oligopeptide transport and in communication processes. One such protein, AmiA, has been identified in Streptococcus pneumoniae. amiA is the first gene of an operon, ami, which encodes a multicomponent oligopeptide transporter belonging to the family of ABC transporters (or traffic ATPases). This transporter was the first system of this type described in Gram-positive bacteria. To investigate the role and the subcellular location of the putative oligopeptide-binding protein in a bacterium devoid of periplasm, AmiA null mutants were first constructed. None was affected for oligopeptide uptake by the Ami system. Since this apparent dispensability of AmiA could result from a functional redundancy, we looked for chromosomal genes encoding homologues of AmiA. Two homologous genes were identified by DNA-DNA hybridization at low stringency with an amiA probe. Both genes (aliA and aliB) were cloned and shown to encode putative lipoproteins highly homologous to AmiA (close to 60% amino acid identity). Examination of all combinations of amiA, aliA and aliB mutations indicated that these proteins have overlapping specificities toward oligopeptides. The triple mutant is as deficient for oligopeptide transport as mutants in the amiCDE or F genes, which demonstrates that an oligopeptide-binding component is absolutely required for transport by the Ami system. Metabolic labelling with [3H]palmitic acid and cell fractionation were used to demonstrate that the three proteins are indeed membrane-bound lipoproteins in S. pneumoniae. This supports our previous hypothesis that substrate-binding lipoproteins are functionally equivalent to the periplasmic substrate-binding component of ABC transporters of Gram-negative bacteria. Finally, the observation that competence for genetic transformation was drastically reduced in a particular AliB mutant suggests that oligopeptide sensing is important for triggering competence.

Modular structure of the FixL protein of Rhizobium meliloti.

FixL protein of Rhizobium meliloti is a haemo-protein kinase which activates the transcription of nifA and fixK genes via the transcriptional activator protein FixJ under microaerobic conditions. FixL and FixJ proteins belong to the family of two-component regulatory systems for which primary sequence data predicts a modular structure. We showed, using Escherichia coli as heterologous host, that FixL indeed has a modular structure. The amino-terminal hydrophobic domain is dispensable for the oxygen-regulated activity of FixL in vivo. The central cytoplasmic non-conserved domain is necessary for the oxygen-sensing function of FixL whereas it is not necessary for the activation of FixJ by FixL. We propose that, under aerobic conditions, the central domain represses the activating function associated with the carboxy-terminal conserved domain.

Rhizobium meliloti Fix L is an oxygen sensor and regulates R. meliloti nifA and fixK genes differently in Escherichia coli.

In Rhizobium meliloti, nif and fix genes, involved in nitrogen fixation during symbiosis with alfalfa, are under the control of two transcriptional regulators encoded by nifA and fixK. Expression of nifA and fixK is under the control of FixL/J, a two-component regulatory system. We showed, using Escherichia coli as a heterologous host, that FixL/J controls nifA and fixK expression in response to microaerobiosis. Furthermore, expression of the sensor gene fixL and of the activator gene fixJ under the control of two different promoters allowed us to show that FixL mediates microaerobic induction of nifA when the level of FixJ is low and aerobic repression of nifA when the level of FixJ is high. Similarly, activation of fixK occurred in microaerobiosis when the FixJ level was low in the presence of FixL. In contrast to nifA, fixK expression was not affected by FixL in aerated cultures when the level of FixJ was high. We conclude that R. meliloti FixL senses oxygen in the heterologous host E. coli consistent with the microaerobic induction of nifA and fixK in R. meliloti and that nifA and fixK promoters are differentially activated by FixJ in response to the oxygen signal.