The Rhodobacter capsulatus glnB gene is regulated by NtrC at tandem rpoN-independent promoters.

The protein encoded by glnB of Rhodobacter capsulatus is part of a nitrogen-sensing cascade which regulates the expression of nitrogen fixation genes (nif). The expression of glnB was studied by using lacZ fusions, primer extension analysis, and in vitro DNase I footprinting. Our results suggest that glnB is transcribed from two promoters, one of which requires the R. capsulatus ntrC gene but is rpoN independent. Another promoter upstream of glnB is repressed by NtrC; purified R. capsulatus NtrC binds to sites that overlap this distal promoter region.     

Identification of three genes encoding P(II)-like proteins in Gluconacetobacter diazotrophicus: studies of their role(s) in the control of nitrogen fixation

In our studies on the regulation of nitrogen metabolism in Gluconacetobacter diazotrophicus, an endophytic diazotroph of sugarcane, three glnB-like genes were identified and their role(s) in the control of nitrogen fixation was studied. Sequence analysis revealed that one P(II) protein-encoding gene, glnB, was adjacent to a glnA gene (encoding glutamine synthetase) and that two other P(II) protein-encoding genes, identified as glnK1 and glnK2, were located upstream of amtB1 and amtB2, respectively, genes which in other organisms encode ammonium (or methylammonium) transporters. Single and double mutants and a triple mutant with respect to the three P(II) protein-encoding genes were constructed, and the effects of the mutations on nitrogenase expression and activity in the presence of either ammonium starvation or ammonium sufficiency were studied. Based on the results presented here, it is suggested that none of the three P(II) homologs is required for nif gene expression, that the GlnK2 protein acts primarily as an inhibitor of nif gene expression, and that GlnB and GlnK1 control the expression of nif genes in response to ammonium availability, both directly and by relieving the inhibition by GlnK2. This model includes novel regulatory features of P(II) proteins.     

Bacteria rather than Archaea dominate microbial ammonia oxidation in an agricultural soil

Agricultural ecosystems annually receive approximately 25% of the global nitrogen input, much of which is oxidized at least once by ammonia-oxidizing prokaryotes to complete the nitrogen cycle. Recent discoveries have expanded the known ammonia-oxidizing prokaryotes from the domain Bacteria to Archaea . However, in the complex soil environment it remains unclear whether ammonia oxidation is exclusively or predominantly linked to Archaea as implied by their exceptionally high abundance. Here we show that Bacteria rather than Archaea functionally dominate ammonia oxidation in an agricultural soil, despite the fact that archaeal versus bacterial amoA genes are numerically more dominant. In soil microcosms, in which ammonia oxidation was stimulated by ammonium and inhibited by acetylene, activity change was paralleled by abundance change of bacterial but not of archaeal amoA gene copy numbers. Molecular fingerprinting of amoA genes also coupled ammonia oxidation activity with bacterial but not archaeal amoA gene patterns. DNA-stable isotope probing demonstrated CO₂ assimilation by Bacteria rather than Archaea . Our results indicate that Archaea were not important for ammonia oxidation in the agricultural soil tested.     

The Rhizobium leguminosarum glnB gene is down-regulated during symbiosis

Symbiotic nitrogen fixation involves the development, on the legume plant root, of specialised organs called nodules, within which plant photosynthates are exchanged for combined nitrogen of bacterial origin. The glnB gene encodes a signal transduction protein (P(II)) which is a component of the bacterial nitrogen regulation (Ntr) system and an essential regulator of ammonium assimilation. We demonstrate that in Rhizobium leguminosarum the glnB promoter is strongly regulated by nitrogen and NtrC, but still shows a significant level of activity in conditions of nitrogen excess. Expression of genes involved in nitrogen assimilation has been shown to be absent in nitrogen-fixing bacteroids, and, in agreement with this, we find that the glnB promoter is down-regulated during bacteroid differentiation at a time coincident with the arrest of bacterial division in the nodule. This pattern is common to other bacterial genes involved in nitrogen assimilation and it is noteworthy that the zone where the glnB promoter is active is coincident with the region in which NtrC is expressed.     

A nitrogen-fixation gene (nifC) in Clostridium pasteurianum with sequence similarity to chlJ of Escherichia coli

The molybdenum-containing nitrogenase contains an iron-molybdenum cofactor, whose synthesis involves at least six nif genes. Genes corresponding to nifE, N, B, and V occur in proximity in Clostridium pasteurianum, with nifN-B occurring as one gene and with nifV omega and nifV alpha in place of nifV. Between nifN-B and nifV omega V alpha, we found a gene whose sequence is similar to chlJ of Escherichia coli. chlJ is part of the chlD locus, which is involved in Mo transport. C. pasteurianum actively accumulates Mo in a process coregulated with nitrogen fixation. We propose that nifC is involved in Mo transport. The expression of nifC may be coregulated with nitrogen fixation because of the presence of nif-distinctive promoter and upstream sequences preceding nifC-nifV omega-nifV alpha. NifC contains a region typical of integral membrane proteins. Our findings suggest the involvement of a membrane-located nif gene product in Mo transport in C. pasteurianum.     

nifV is contiguous to nifHDK in Frankia strain FaC1

The organization of genes with the capacity to code for four proteins involved in nitrogen fixation in Frankia strain FaC1 was determined by restriction fragment mapping and nucleotide sequence analysis. Analysis of the 44-kb genomic cosmid clone pFAH 1. isolated from a cosmid library made from Frankia strain FaCl, resulted in the identification of a 7.2-kb Pst I fragment to which Klebsiella nif H, nif D and nif K probes hybridized. This nif -hybridizing fragment was subcloned and analyzed by restriction fragment mapping. Further subcloning of the 7.2-kb fragment and subsequent sequence analysis of approximately 6.8 kb revealed the presence of six open reading frames (ORFs). Four of these ORFs have the potential to code for nif V-, nif H-, nif D- and nif K-like gene products and the two others are unidentified ORFs. The organization of the structural genes for nitrogenase is the same in this Frankia strain as it is in most other nitrogen-fixing prokaryotes, but the positioning of the nif V-like gene relative to the nif HDK cluster differs, A consensus nif -promoter-like sequence, found 5'to nif H. was not detected upstream of the nif V-like gene. Nine copies of a 7-bp direct repeat were found 5'to ORFA.     

Reiteration of genes involved in symbiotic nitrogen fixation by fast-growing Rhizobium japonicum.

By using cloned Rhizobium meliloti nodulation (nod) genes and nitrogen fixation (nif) genes, we found that the genes for both nodulation and nitrogen fixation were on a plasmid present in fast-growing Rhizobium japonicum strains. Two EcoRI restriction fragments from a plasmid of fast-growing R. japonicum hybridized with nif structural genes of R. meliloti, and three EcoRI restriction fragments hybridized with the nod clone of R. meliloti. Cross-hybridization between the hybridizing fragments revealed a reiteration of nod and nif DNA sequences in fast-growing R. japonicum. Both nif structural genes D and H were present on 4.2- and 4.9-kilobase EcoRI fragments, whereas nifK was present only on the 4.2-kilobase EcoR2 fragment. These results suggest that the nif gene organizations in fast-growing and in slow-growing R. japonicum strains are different.     

Modulation of NifA activity by PII in Azospirillum brasilense: evidence for a regulatory role of the NifA N-terminal domain.

Azospirillum brasilense NifA, which is synthesized under all physiological conditions, exists in an active or inactive from depending on the availability of ammonia. The activity also depends on the presence of PII, as NifA is inactive in a glnB mutant. To investigate further the mechanism that regulates NifA activity, several deletions of the nifA coding sequence covering the amino-terminal domain of NifA were constructed. The ability of these truncated NifA proteins to activate the nifH promoter in the absence or presence of ammonia was assayed in A. brasilense wild-type and mutant strains. Our results suggest that the N-terminal domain is not essential for NifA activity. This domain plays an inhibitory role which prevents NifA activity in the presence of ammonia. The truncated proteins were also able to restore nif gene expression to a glnB mutant, suggesting that PII is required to activate NifA by preventing the inhibitory effect of its N-terminal domain under conditions of nitrogen fixation. Low levels of nitrogenase activity in the presence of ammonia were also observed when the truncated gene was introduced into a strain devoid of the ADP-ribosylation control of nitrogenase. We propose a model for the regulation of NifA activity in A. brasilense.     

Characterization of nifB, nifS, and nifU genes in the cyanobacterium Anabaena variabilis: NifB is required for the vanadium-dependent nitrogenase.

Anabaena variabilis ATCC 29413 is a heterotrophic, nitrogen-fixing cyanobacterium containing both a Mo-dependent nitrogenase encoded by the nif genes and V-dependent nitrogenase encoded by the vnf genes. The nifB, nifS, and nifU genes of A. variabilis were cloned, mapped, and partially sequenced. The fdxN gene was between nifB and nifS. Growth and acetylene reduction assays using wild-type and mutant strains indicated that the nifB product (NifB) was required for nitrogen fixation not only by the enzyme encoded by the nif genes but also by the enzyme encoded by the vnf genes. Neither NifS nor NifU was essential for nitrogen fixation in A. variabilis.