Expression and functional analysis of an N-truncated NifA protein of Herbaspirillum seropedicae

Rhodobacter capsulatus AnfA is essential for production of Fe-nitrogenase proteins but dispensable for cofactor biosynthesis and electron supply

The photosynthetic α‐proteobacterium Rhodobacter capsulatus reduces and thereby fixes atmospheric dinitrogen (N₂) by a molybdenum (Mo)‐nitrogenase and an iron‐only (Fe)‐nitrogenase. Differential expression of the structural genes of Mo‐nitrogenase (nifHDK) and Fe‐nitrogenase (anfHDGK) is strictly controlled and activated by NifA and AnfA, respectively. In contrast to NifA‐binding sites, AnfA‐binding sites are poorly defined. Here, we identified two highly similar AnfA‐binding sites in the R. capsulatus anfH promoter by studying the effects of promoter mutations on in vivo anfH expression and in vitro promoter binding by AnfA. Comparison of the experimentally determined R. capsulatus AnfA‐binding sites and presumed AnfA‐binding sites from other α‐proteobacteria revealed a consensus sequence of dyad symmetry, TAC–N₆–GTA, suggesting that AnfA proteins bind their target promoters as dimers. Chromosomal replacement of the anfH promoter by the nifH promoter restored anfHDGK expression and Fe‐nitrogenase activity in an R. capsulatus strain lacking AnfA suggesting that AnfA is required for AnfHDGK production, but dispensable for biosynthesis of the iron‐only cofactor and electron delivery to Fe‐nitrogenase, pathways activated by NifA. These observations strengthen our model, in which the Fe‐nitrogenase system in R. capsulatus is largely integrated into the Mo‐nitrogenase system.

Regulation of Herbaspirillum seropedicae NifA by the GlnK PII signal transduction protein is mediated by effectors binding to allosteric sites

Herbaspirillum seropedicae is a plant growth promoting bacterium that is able to fix nitrogen and to colonize the surface and internal tissues of important crops. Nitrogen fixation in H. seropedicae is regulated at the transcriptional level by the prokaryotic enhancer binding protein NifA. The activity of NifA is negatively affected by oxygen and positively stimulated by interaction with GlnK, a PII signaling protein that monitors intracellular levels of the key metabolite 2-oxoglutarate (2-OG) and functions as an indirect sensor of the intracellular nitrogen status. GlnK is also subjected to a cycle of reversible uridylylation in response to intracellular levels of glutamine. Previous studies have established the role of the N-terminal GAF domain of NifA in intramolecular repression of NifA activity and the role of GlnK in relieving this inhibition under nitrogen-limiting conditions. However, the mechanism of this control of NifA activity is not fully understood. Here, we constructed a series of GlnK variants to elucidate the role of uridylylation and effector binding during the process of NifA activation. Our data support a model whereby GlnK uridylylation is not necessary to activate NifA. On the other hand, binding of 2-OG and MgATP to GlnK are very important for NifA activation and constitute the most important signal of cellular nitrogen status to NifA.

DNA supported graphene quantum dots for Ag ion sensing

The use of graphene quantum dots can be extended for bio-sensing and metal ion detection. Synergistic combination of graphene quantum dots (GQDs) with DNA leads to high performance Ag-ion detection system. The thoroughly characterized GQDs were found to have spherical morphology, with dimensions in the range of 5-10 nm. The atomic force microscopy studies proved that the synthesized GQDs were mostly comprised of two to four graphene layers. To make the system biocompatible, GQDs/NGQDs were combined with DNA. Two properties of DNA were exploited, capacity to provide nitrogen to GQDs; and to synergistically contribute to Ag⁺ detection. In addition to Ag⁺, the strong green photoluminescence (PL) of GQDs showed significant quenching, owing to the appearance of associated Förster resonance energy transfer processes. This led to high sensing efficiencies.

Effect of point mutations on Herbaspirillum seropedicae NifA activity

NifA is the transcriptional activator of the nif genes in Proteobacteria. It is usually regulated by nitrogen and oxygen, allowing biological nitrogen fixation to occur under appropriate conditions. NifA proteins have a typical three-domain structure, including a regulatory N-terminal GAF domain, which is involved in control by fixed nitrogen and not strictly required for activity, a catalytic AAA+ central domain, which catalyzes open complex formation, and a C-terminal domain involved in DNA-binding. In Herbaspirillum seropedicae, a β-proteobacterium capable of colonizing Graminae of agricultural importance, NifA regulation by ammonium involves its N-terminal GAF domain and the signal transduction protein GlnK. When the GAF domain is removed, the protein can still activate nif genes transcription; however, ammonium regulation is lost. In this work, we generated eight constructs resulting in point mutations in H. seropedicae NifA and analyzed their effect on nifH transcription in Escherichia coli and H. seropedicae. Mutations K22V, T160E, M161V, L172R, and A215D resulted in inactive proteins. Mutations Q216I and S220I produced partially active proteins with activity control similar to wild-type NifA. However, mutation G25E, located in the GAF domain, resulted in an active protein that did not require GlnK for activity and was partially sensitive to ammonium. This suggested that G25E may affect the negative interaction between the N-terminal GAF domain and the catalytic central domain under high ammonium concentrations, thus rendering the protein constitutively active, or that G25E could lead to a conformational change comparable with that when GlnK interacts with the GAF domain.

Effect of nitric oxide on VnfA, a transcriptional activator of VFe-nitrogenase in Azotobacter vinelandii

The transcriptional activator, VnfA, is necessary for the expression of the structural genes encoding vanadium-dependent nitrogenase in Azotobacter vinelandii. We have previously reported that VnfA harbours a Fe-S cluster as a prosthetic group, presumably a 3Fe-4S type, which is vital for the transcriptionally active VnfA. A plausible effector molecule is a reactive oxygen species (ROS), which disassembles the Fe-S cluster switching the active VnfA to become fully inactive. This finding prompted us to investigate the effect of nitric oxide (NO), another physiologically important radical species on the VnfA activity. Unlike ROS, the VnfA activity was moderately inhibited and converged to 70% of the maximum by NO irrespective of its concentration. The Fe-S cluster of VnfA was found to react with NO to form a dinitrosyl-iron complex, either in the dimeric or monomeric form, dependent on the relative stoichiometry of NO to the Fe-S cluster. The VnfA species harbouring the dinitrosyl-iron complexes in each form exhibited 50% ATPase activity compared to the active VnfA. The findings of this study would open an argument about a biological effect of NO on nitrogenase in light of its transcriptional regulatory system.

Identification of a new lipase family in the Brazilian Atlantic Forest soil metagenome

Lipases are the most investigated class of enzymes in metagenomics. Phylogenetic classification of bacterial lipases comprises eight families. Here we describe the construction and screening of three metagenomic libraries from Brazilian Atlantic Forest soil and identification of a new lipase family. The metagenomic libraries, MAF1, MAF2 and MAF3, contained 34 560, 29 280 and 36 288 clones respectively. Lipase screening on triolein-rhodamine B plates resulted in one positive clone, Lip018. The DNA insert of Lip018 was fully sequenced and 20 ORFs were identified by comparison against the GenBank. Transposon mutagenesis revealed that ORF15, similar to serine peptidases, and ORF16, a hypothetical protein, were both required for lipase activity. ORF16 has a typical lipase conserved pentapeptide G-X-S-X-G and the comparison against the Pfam database showed that ORF16 belongs to family 5 of αβ-hydrolase. Phylogenetic analyses indicated that ORF16, together with other related proteins, may be a member of a new lipase family, named LipAP, activated by a putative serine protease. Partial characterization of ORF16 lipase showed that the enzyme has activity against a broad range of p-nitrophenyl esters, but only after activation by the predicted peptidase ORF15.

The role of the GAF and central domains of the transcriptional activator VnfA in Azotobacter vinelandii

VnfA is a transcriptional activator that is required for the expression of the structural genes encoding nitrogenase-2 in Azotobacter vinelandii. VnfA consists of three domains: an N-terminal regulatory domain termed GAF, including a Cys-rich motif; a central domain from the AAA+ family; and a C-terminal domain for DNA binding. Previously, we reported that transcriptionally active VnfA harboring an Fe-S cluster (presumably of the 3Fe-4S type) as a prosthetic group and the Cys-rich motif were possibly associated with coordination of the Fe-S cluster. In the present study, we have investigated the roles of the GAF and central domains in the regulatory function of VnfA using truncated variants: ΔN15(VnfA) and ΔGAF(VnfA) that lack the N-terminal 15 residues and whole GAF domain, respectively, and GAF(VnfA) consisting of only the GAF domain. ΔN15(VnfA) and ΔGAF(VnfA) lost the ability to bind the Fe-S cluster, whereas GAF(VnfA) was still able to bind to the cluster, consistent with the hypothesis that the Cys-rich motif is essential for Fe-S cluster binding. The GAF domain showed an inhibitory effect on the transcriptional activity of VnfA, which was reversed in the presence of the Fe-S cluster, and reactivated upon disassembly of the cluster. The inhibitory activity of the GAF domain acts on the NTPase activity of the central domain, whereas the binding ability of VnfA to DNA was not significantly affected, when VnfA retains its tetrameric conformation. The results imply that a major pathway, by which VnfA function is regulated, operates via the control of NTPase activity by the GAF domain.

Role of PII proteins in nitrogen fixation control of Herbaspirillum seropedicae strain SmR1

BACKGROUND

The PII protein family comprises homotrimeric proteins which act as transducers of the cellular nitrogen and carbon status in prokaryotes and plants. In Herbaspirillum seropedicae, two PII-like proteins (GlnB and GlnK), encoded by the genes glnB and glnK, were identified. The glnB gene is monocistronic and its expression is constitutive, while glnK is located in the nlmAglnKamtB operon and is expressed under nitrogen-limiting conditions.

RESULTS

In order to determine the involvement of the H. seropedicae glnB and glnK gene products in nitrogen fixation, a series of mutant strains were constructed and characterized. The glnK- mutants were deficient in nitrogen fixation and they were complemented by plasmids expressing the GlnK protein or an N-truncated form of NifA. The nitrogenase post-translational control by ammonium was studied and the results showed that the glnK mutant is partially defective in nitrogenase inactivation upon addition of ammonium while the glnB mutant has a wild-type phenotype.

CONCLUSIONS

Our results indicate that GlnK is mainly responsible for NifA activity regulation and ammonium-dependent post-translational regulation of nitrogenase in H. seropedicae.

Purification and characterisation of Azospirillum brasilense N-truncated NtrX protein

The NtrX protein has been identified as a transcriptional activator of genes involved in the metabolic control of alternative nitrogen sources, acting as a member of a two-component regulatory system. The in silico analysis of the NtrX amino acid sequence shows that this protein contains an N-terminal receiver domain, a central AAA+ superfamily domain and a C-terminal DNA binding domain. To over-express and purify this protein, the ntrX gene of Azospirillum brasilense lacking the first eight codons was cloned into the vector pET29a+. The NtrX protein was over-expressed as an S.Tag fusion protein induced by l-arabinose in the Escherichia coli strain BL21AI and purified by ion exchange and affinity chromatography. The ATPase activity of NtrX was measured by coupling the ATP conversion to ADP with NADH oxidation. The ATPase activity of NtrX was stimulated in the presence of A. brasilense sigma(54)/NtrC-dependent promoter of the glnBA gene. Phosphorylation by carbamyl-phosphate also stimulated ATPase, in a manner similar to the NtrC protein. Together our results suggest that NtrX is active in the phosphorylated form and that there may be a cross-talk between the NtrYX and NtrBC regulatory systems in A. brasilense.

History on the biological nitrogen fixation research in graminaceous plants: special emphasis on the Brazilian experience

This review covers the history on Biological Nitrogen Fixation (BNF) in Graminaceous plants grown in Brazil, and describes research progress made over the last 40 years, most of whichwas coordinated by Johanna Döbereiner. One notable accomplishment during this period was the discovery of several nitrogen-fixing bacteria such as the rhizospheric (Beijerinckia fluminensis and Azotobacter paspali), associative (Azospirillum lipoferum, A. brasilense, A. amazonense) and the endophytic (Herbaspirillum seropedicae, H. rubrisubalbicans, Gluconacetobacter diazotrophicus, Burkholderia brasilensis and B. tropica). The role of these diazotrophs in association with grasses, mainly with cereal plants, has been studied and a lot of progress has been achieved in the ecological, physiological, biochemical, and genetic aspects. The mechanisms of colonization and infection of the plant tissues are better understood, and the BNF contribution to the soil/plant system has been determined. Inoculation studies with diazotrophs showed that endophytic bacteria have a much higher BNF contribution potential than associative diazotrophs. In addition, it was found that the plant genotype influences the plant/bacteria association. Recent data suggest that more studies should be conducted on the endophytic association to strengthen the BNF potential. The ongoing genome sequencing programs: RIOGENE (Gluconacetobacter diazotrophicus) and GENOPAR (Herbaspirillum seropedicae) reflect the commitment to the BNF study in Brazil and should allow the country to continue in the forefront of research related to the BNF process in Graminaceous plants.

Effect of T- and C-loop mutations on the Herbaspirillum seropedicae GlnB protein in nitrogen signalling

Proteins of the PII family are found in species of all kingdoms. Although these proteins usually share high identity, their functions are specific to the different organisms. Comparison of structural data from Escherichia coli GlnB and GlnK and Herbaspirillum seropedicae GlnB showed that the T-loop and C-terminus were variable regions. To evaluate the role of these regions in signal transduction by the H. seropedicae GlnB protein, four mutants were constructed: Y51F, G108A/P109a, G108W and Q3R/T5A. The activities of the native and mutated proteins were assayed in an E. coli background constitutively expressing the Klebsiella pneumoniae nifLA operon. The results suggested that the T-loop and C-terminus regions of H. seropedicae GlnB are involved in nitrogen signal transduction.

GlnB is specifically required for Azospirillum brasilense NifA activity in Escherichia coli

The Azospirillum brasilense transcription regulator NifA and the nitrogen-status signaling proteins GlnB, GlnZ and GlnK were expressed in Escherichia coli and analyzed for their ability to activate nif gene expression. When expressed separately, none of the proteins were able to activate nifH promoter expression in any tested conditions; in contrast, nifH expression was observed in cells grown in the absence of ammonium and oxygen and when expressing simultaneously NifA and GlnB proteins, but not when expressing NifA and GlnZ or GlnK. Our results show that the GlnB protein is required for transcription activation by Azospirillum brasilense NifA and it cannot be replaced by GlnZ or GlnK.

Fnr is involved in oxygen control of Herbaspirillum seropedicae N-truncated NifA protein activity in Escherichia coli

Herbaspirillum seropedicae is an endophytic diazotroph belonging to the beta-subclass of the class Proteobacteria, which colonizes many members of the Gramineae. The activity of the NifA protein, a transcriptional activator of nif genes in H. seropedicae, is controlled by ammonium ions through its N-terminal domain and by oxygen through mechanisms that are not well understood. Here we report that the NifA protein of H. seropedicae is inactive and more susceptible to degradation in an fnr Escherichia coli background. Both effects correlate with oxygen exposure and iron deprivation. Our results suggest that the oxygen sensitivity and iron requirement for H. seropedicae NifA activity involve the Fnr protein.

Expression, purification, and functional analysis of the C-terminal domain of Herbaspirillum seropedicae NifA protein

The Herbaspirillum seropedicae NifA protein is responsible for nif gene expression. The C-terminal domain of the H. seropedicae NifA protein, fused to a His-Tag sequence (His-Tag-C-terminal), was over-expressed and purified by metal-affinity chromatography to yield a highly purified and active protein. Band-shift assays showed that the NifA His-Tag-C-terminal bound specifically to the H. seropedicae nifB promoter region in vitro. In vivo analysis showed that this protein inhibited the Central + C-terminal domains of NifA protein from activating the nifH promoter of K. pneumoniae in Escherichia coli, indicating that the protein must be bound to the NifA-binding site (UAS site) at the nifH promoter region to activate transcription.

Identification of the essential histidine residue for high-affinity binding of AlbA protein to albicidin antibiotics

The albA gene from Klebsiella oxytoca encodes a protein that binds albicidin phytotoxins and antibiotics with high affinity. Previously, it has been shown that shifting pH from 6 to 4 reduces binding activity of AlbA by about 30%, indicating that histidine residues might be involved in substrate binding. In this study, molecular analysis of the albA coding region revealed sequence discrepancies with the albA sequence reported previously, which were probably due to sequencing errors. The albA gene was subsequently cloned from K. oxytoca ATCC 13182(T) to establish the revised sequence. Biochemical and molecular approaches were used to determine the functional role of four histidine residues (His(78), His(125), His(141) and His(189)) in the corrected sequence for AlbA. Treatment of AlbA with diethyl pyrocarbonate (DEPC), a histidine-specific alkylating reagent, reduced binding activity by about 95 %. DEPC treatment increased absorbance at 240-244 nm by an amount indicating conversion to N-carbethoxyhistidine of a single histidine residue per AlbA molecule. Pretreatment with albicidin protected AlbA against modification by DEPC, with a 1 : 1 molar ratio of albicidin to the protected histidine residues. Based on protein secondary structure and amino acid surface probability indices, it is predicted that His(125) might be the residue required for albicidin binding. Mutation of His(125) to either alanine or leucine resulted in about 32 % loss of binding activity, and deletion of His(125) totally abolished binding activity. Mutation of His(125) to arginine and tyrosine had no effect. These results indicate that His(125) plays a key role either in an electrostatic interaction between AlbA and albicidin or in the conformational dynamics of the albicidin-binding site.

Inter-domain cross-talk controls the NifA protein activity of Herbaspirillum seropedicae

Herbaspirillum seropedicae is an endophytic diazotroph, which colonizes sugar cane, wheat, rice and maize. The activity of NifA, a transcriptional activator of nif genes in H. seropedicae, is controlled by ammonium ions through a mechanism involving its N-terminal domain. Here we show that this domain interacts specifically in vitro with the N-truncated NifA protein, as revealed by protection against proteolysis, and this interaction caused an inhibitory effect on both the ATPase and DNA-binding activities of the N-truncated NifA protein. We suggest that the N-terminal domain inhibits NifA-dependent transcriptional activation by an inter-domain cross-talk between the catalytic domain of the NifA protein and its regulatory N-terminal domain in response to fixed nitrogen.

Rhodobacter capsulatus nifA mutants mediating nif gene expression in the presence of ammonium

Expression of nitrogen fixation genes in Rhodobacter capsulatus is repressed by ammonium at different regulatory levels including an NtrC-independent mechanism controlling NifA activity. In contrast to R. capsulatus NifA, heterologous NifA proteins of Klebsiella pneumoniae and Rhizobium meliloti, respectively, were not subjected to this posttranslational ammonium control in R. capsulatus. The characterization of ammonium-tolerant R. capsulatus NifA1 mutants indicated that the N-terminal domain of NifA was involved in posttranslational regulation. Analysis of a double mutant carrying amino acid substitutions in both the N-terminal domain and the C-terminal DNA-binding domain gave rise to the hypothesis that an interaction between these two domains might be involved in ammonium regulation of NifA activity. Western analysis demonstrated that both constitutively expressed wild-type and ammonium-tolerant NifA1 proteins exhibited high stability and accumulated to comparable levels in cells grown in the presence of ammonium excluding the possibility that proteolytic degradation was responsible for ammonium-dependent inactivation of NifA.

P(II) signal transduction proteins, pivotal players in microbial nitrogen control

The P(II) family of signal transduction proteins are among the most widely distributed signal proteins in the bacterial world. First identified in 1969 as a component of the glutamine synthetase regulatory apparatus, P(II) proteins have since been recognized as playing a pivotal role in control of prokaryotic nitrogen metabolism. More recently, members of the family have been found in higher plants, where they also potentially play a role in nitrogen control. The P(II) proteins can function in the regulation of both gene transcription, by modulating the activity of regulatory proteins, and the catalytic activity of enzymes involved in nitrogen metabolism. There is also emerging evidence that they may regulate the activity of proteins required for transport of nitrogen compounds into the cell. In this review we discuss the history of the P(II) proteins, their structures and biochemistry, and their distribution and functions in prokaryotes. We survey data emerging from bacterial genome sequences and consider other likely or potential targets for control by P(II) proteins.

Concerted inhibition of the transcriptional activation functions of the enhancer-binding protein NIFA by the anti-activator NIFL

The Azotobacter vinelandii NIFL regulatory flavoprotein responds to the redox, energy and nitrogen status of the cell to inhibit transcriptional activation by the sigmaN-dependent enhancer binding protein, NIFA, via the formation of a NIFL-NIFA protein complex. The NIFA protein contains three domains: an N-terminal domain of unknown function; a central catalytic domain required to couple nucleotide hydrolysis to activation of the sigmaN-RNA polymerase holoenzyme; and a C-terminal DNA-binding domain. We report that truncated NIFA proteins that either lack the amino-terminal domain or contain only the isolated central domain remain responsive to inhibition by NIFL but, in contrast to native NIFA, continue to hydrolyse nucleotides when NIFL is present. We also report that NIFL is competent to inhibit the DNA-binding function of NIFA. Taken together, these results suggest that NIFL inhibits NIFA via a concerted mechanism in which DNA binding, catalytic activity and, potentially, interaction with the polymerase are controlled by NIFL in order to prevent transcriptional activation under detrimental environmental conditions.

Use of lactose to induce expression of soluble NifA protein domains of Herbaspirillum seropedicae in Escherichia coli

Overexpression and purification are procedures used to allow functional and structural characterization of proteins. Many overexpressed proteins are partially or completely insoluble, and can not be easily purified. The NifA protein is an enhancer-binding protein involved in activating the expression of nif and some fix genes. The NifA protein from many organisms is usually insoluble when over-expressed, and therefore difficult to work with in vitro. In this work we have overexpressed the central + C-terminal and the central domains of the Herbaspirrilum seropedicae NifA protein in an Escherichia coli background. Expression was induced with either IPTG or lactose. The data showed that induction with lactose promoted a significantly higher percentage of these proteins in the soluble fraction than with IPTG. This probably reflects a slower kinetics of induction by lactose.

Azospirillum, a free-living nitrogen-fixing bacterium closely associated with grasses: genetic, biochemical and ecological aspects

Azospirillum represents the best characterized genus of plant growth-promoting rhizobacteria. Other free-living diazotrophs repeatedly detected in association with plant roots, include Acetobacter diazotrophicus, Herbaspirillum seropedicae, Azoarcus spp. and Azotobacter. Four aspects of the Azospirillum-plant root interaction are highlighted: natural habitat, plant root interaction, nitrogen fixation and biosynthesis of plant growth hormones. Each of these aspects is dealt with in a comparative way. Azospirilla are predominantly surface-colonizing bacteria, whereas A. diazotrophicus, H. seropedicae and Azoarcus sp. are endophytic diazotrophs. The attachment of Azospirillum cells to plant roots occurs in two steps. The polar flagellum, of which the flagellin was shown to be a glycoprotein, mediates the adsorption step. An as yet unidentified surface polysaccharide is believed to be essential in the subsequent anchoring phase. In Azoarcus sp. the attachment process is mediated by type IV pili. Nitrogen fixation structural genes (nif) are highly conserved among all nitrogen-fixing bacteria, and in all diazotrophic species of the class of proteobacteria examined, the transcriptional activator NifA is required for expression of other nif genes in response to two major environmental signals (oxygen and fixed N). However, the mechanisms involved in this control can vary in different organisms. In Azospirillum brasilense and H. seropedicae (alpha- and beta-subgroup, respectively), NifA is inactive in conditions of excess nitrogen. Activation of NifA upon removal of fixed N seems to involve, either directly or indirectly, the signal transduction protein P(II). The presence of four conserved cysteine residues in the NifA protein might be an indication that NifA is directly sensitive to oxygen. In Azotobacter vinelandii (gamma-subgroup) nifA is cotranscribed with a second gene nifL. The nifL gene product inactivates NifA in response to high oxygen tension and cellular nitrogen-status. NifL was found to be a redox-sensitive flavoprotein. The relief of NifL inhibition on NifA activity, in response to N-limitation, is suggested to involve a P(II)-like protein. Moreover, nitrogenase activity is regulated according to the intracellular nitrogen and O(2) level. In A. brasilense and Azospirillum lipoferum posttranslational control of nitrogenase, in response to ammonium and anaerobiosis, involves ADP-ribosylation of the nitrogenase iron protein, mediated by the enzymes DraT and DraG. At least three pathways for indole-3-acetic acid (IAA) biosynthesis in A. brasilense exist: two Trp-dependent (the indole-3-pyruvic acid and presumably the indole-3-acetamide pathway) and one Trp-independent pathway. The occurrence of an IAA biosynthetic pathway not using Trp (tryptophan) as precursor is highly unusual in bacteria. Nevertheless, the indole-3-pyruvate decarboxylase encoding ipdC gene is crucial in the overall IAA biosynthesis in Azospirillum. A number of genes essential for Trp production have been isolated in A. brasilense, including trpE(G) which codes for anthranilate synthase, the key enzyme in Trp biosynthesis. The relevance of each of these four aspects for plant growth promotion by Azospirillum is discussed.

In-trans regulation of the N-truncated-NIFA protein of Herbaspirillum seropedicae by the N-terminal domain

The NifA protein is responsible for transcription activation of nif genes in the endophytic diazotroph Herbaspirillum seropedicae. When expressed in Escherichia coli this NifA protein is unable to activate the transcription of a Klebsiella pneumoniae nifH::lacZ fusion. However, a form of NifA lacking the N-terminal domain did activate transcription and its activity was not inhibited by ammonium. In this work we show that when expressed separately, the N-terminal domain of H. seropedicae NifA protein can restore ammonium control of the N-truncated NifA activity in E. coli. This effect is dependent on the relative concentrations of the N-terminal domain and the N-truncated protein and suggests that the N-terminal domain behaves in this respect in a manner similar to that of NifL of the gamma proteobacteria.

Mechanisms for redox control of gene expression

This review discusses various mechanisms that regulatory proteins use to control gene expression in response to alterations in redox. The transcription factor SoxR contains stable [2Fe-2S] centers that promote transcription activation when oxidized. FNR contains [4Fe-4S] centers that disassemble under oxidizing conditions, which affects DNA-binding activity. FixL is a histidine sensor kinase that utilizes heme as a cofactor to bind oxygen, which affects its autophosphorylation activity. NifL is a flavoprotein that contains FAD as a redox responsive cofactor. Under oxidizing conditions, NifL binds and inactivates NifA, the transcriptional activator of the nitrogen fixation genes. OxyR is a transcription factor that responds to redox by breaking or forming disulfide bonds that affect its DNA-binding activity. The ability of the histidine sensor kinase ArcB to promote phosphorylation of the response regulator ArcA is affected by multiple factors such as anaerobic metabolites and the redox state of the membrane. The global regulator of anaerobic gene expression in alpha-purple proteobacteria, RegB, appears to directly monitor respiratory activity of cytochrome oxidase. The aerobic repressor of photopigment synthesis, CrtJ, seems to contain a redox responsive cysteine. Finally, oxygen-sensitive rhizobial NifA proteins presumably bind a metal cofactor that senses redox. The functional variability of these regulatory proteins demonstrates that prokaryotes apply many different mechanisms to sense and respond to alterations in redox.