Organization and regulation of cbb CO2 assimilation genes in autotrophic bacteria

The Calvin-Benson-Bassham cycle constitutes the principal route of CO2 assimilation in aerobic chemoautotrophic and in anaerobic phototrophic purple bacteria. Most of the enzymes of the cycle are found to be encoded by cbb genes. Despite some conservation of the internal gene arrangement cbb gene clusters of the various organisms differ in size and operon organization. The cbb operons of facultative autotrophs are more strictly regulated than those of obligate autotrophs. The major control is exerted by the cbbR gene, which codes for a transcriptional activator of the LysR family. This gene is typically located immediately upstream of and in divergent orientation to the regulated cbb operon, forming a control region for both transcriptional units. Recent studies suggest that additional protein factors are involved in the regulation. Although the metabolic signal(s) received by the regulatory components of the operons is (are) still unknown, the redox state of the cell is believed to play a key role. It is proposed that the control of the cbb operon expression is integrated into a regulatory network.

Homology and distribution of CO dehydrogenase structural genes in carboxydotrophic bacteria

The 17 (S), 30 (M) and 87 kDa (L) subunits of CO dehydrogenases from the CO-oxidizing bacteria Pseudomonas carboxydoflava, Pseudomonas carboxydohydrogena and Pseudomonas carboxydovorans OM5 were isolated and purified. The N-terminal sequences of same subunits from different bacteria showed distinct homologies. Dot blot hybridization employing oligonucleotide probes derived from the sequences of the S-subunit of P. carboxydovorans OM5 and the M-subunit of P. carboxydohydrogena and DNA of the plasmid-containing CO-oxidizing bacteria Alcaligenes carboxydus, Azomonas B1, P. carboxydoflava, P. carboxydovorans OM2, OM4 and OM5 indicated that all genes encoding these subunits reside on plasmids. That in P. carboxydovorans OM5 CO dehydrogenase structural genes are located entirely on plasmid pHCG3 was evident from the absence of hybridization employing DNA from the cured mutant strain OM5-12. CO dehydrogenase structural genes could be identified on the chromosome of the plasmid-free bacteria Arthrobacter 11/x, Bacillus schlegelii, P. carboxydohydrogena and P. carboxydovorans OM3. There was no example of a plasmid-harboring carboxydotrophic bacterium that did not carry CO dehydrogenase structural genes on the plasmid. The N-terminal sequences of CO dehydrogenase structural genes were found to be conserved among carboxydotrophic bacteria of distinct taxonomic position, independent of the presence of plasmids. It is discussed whether this might be the consequence of horizontal gene transfer.

Conjugal transfer of hydrogen-oxidizing ability of Alcaligenes hydrogenophilus to Pseudomonas oxalaticus

Conjugal transfer of hydrogen-oxidizing ability (Hox) of the hydrogen bacterium Alcaligenes hydrogenophilus was examined. Intraspecific cross of plasmid pHG21-a that encodes hydrogenases that mediate hydrogen oxidation was most frequent at 25 C; the optimal temperature for growth was 30 C. The plasmid could be transferred from A. hydrogenophilus to Pseudomonas oxalaticus OX1 and OX4, and the resulting strains gained the capacity for autotrophic growth with H2 and CO2. Plasmid pHG21-a was maintained in P. oxalaticus OX1 and OX4 as stably as in A. hydrogenophilus.

Genetics of hydrogenase from aerobic lithoautotrophic bacteria

Aerobic facultatively autotrophic hydrogen bacteria are distinguished on the basis of their hydrogen-oxidizing enzyme system (Hox). The major group, represented by Paracoccus denitrificans and Pseudomonas facilis, contains a membrane-bound, electron transport-coupled protein. Species of Nocardia are characterized by the possession of a cytoplasmic NAD-dependent hydrogenase. Both enzymes are present in strains of Alcaligenes. All hydrogenases from lithoautotrophs are H2-consuming nickel-iron-sulfur proteins. Despite these common characteristics, hydrogenases differ in catalytic and molecular properties, in particular in the regulation of enzyme synthesis. Hydrogenase formation is either inducible by H2 (e.g. P. denitrificans strain F1, Alcaligenes hydrogenophilus) or subject to derepression in response to the supply of reductant, temperature, and oxygen (e.g. Alcaligenes eutrophus). The only plasmid-encoded Hox function has been conclusively identified in species of Alcaligenes. Structural and regulatory hox genes reside on megaplasmids, ranging in size between 400 and 500 kilobase pairs (kb). Most of the plasmids are self-transmissible by conjugation. Hox genes of A. eutrophus H16 have been localized by plasmid curing, genetic transfer, molecular cloning and analysis of plasmid deletions and insertions. They seem to be clustered in a DNA sequence of approximately 50 kb, representing several transcriptional units. In addition, a chromosomally encoded regulatory function is required for the expression of plasmid-linked hox genes. Plasmid pHGl of A. eutrophus H16 has been transferred to the non-lithoautotrophic soil bacterium JMP222. Both hydrogenases are expressed in the new host. The current state of hydrogenase genetics in Alcaligenes is discussed in reference to hydrogenase systems of other lithoautotrophic bacteria.

Suicide plasmid vehicles for insertion mutagenesis in Rhizobium meliloti and related bacteria

We describe the construction and use of a set of plasmid vectors of the transposons Tn1, Tn5, and Tn9 that are suicidal in Rhizobium species and therefore suitable for mutagenesis with these three transposons. The vectors are composed of the p15A replicon which functions in Escherichia coli but not in Rhizobium species and a region encoding the N type of bacterial conjugation system which is very efficient in matings between E. coli and Rhizobium species. The usefulness of the vectors has been most extensively assessed in Rhizobium meliloti. It is likely that they will be useful for mutagenesis and genome manipulation in other bacteria as well.