A vector for the site-directed, genomic integration of foreign DNA into soybean root-nodule bacteria

Soybean Yellow Stripe-like 7 is a symbiosome membrane peptide transporter important for nitrogen fixation

Legumes form a symbiosis with rhizobia that convert atmospheric nitrogen (N2) to ammonia and provide it to the plant in return for a carbon and nutrient supply. Nodules, developed as part of the symbiosis, harbor rhizobia that are enclosed in a plant-derived symbiosome membrane (SM) to form an organelle-like structure called the symbiosome. In mature nodules exchanges between the symbionts occur across the SM. Here we characterize Yellow Stripe-like 7 (GmYSL7), a Yellow stripe-like family member localized on the SM in soybean (Glycine max) nodules. It is expressed specifically in infected cells with expression peaking soon after nitrogenase becomes active. Unlike most YSL family members, GmYSL7 does not transport metals complexed with phytosiderophores. Rather, it transports oligopeptides of between four and 12 amino acids. Silencing GmYSL7 reduces nitrogenase activity and blocks infected cell development so that symbiosomes contain only a single bacteroid. This indicates the substrate of YSL7 is required for proper nodule development, either by promoting symbiosome development directly or by preventing inhibition of development by the plant. RNAseq of nodules where GmYSL7 was silenced suggests that the plant initiates a defense response against rhizobia with genes encoding proteins involved in amino acid export downregulated and some transcripts associated with metal homeostasis altered. These changes may result from the decrease in nitrogen fixation upon GmYSL7 silencing and suggest that the peptide(s) transported by GmYSL7 monitor the functional state of the bacteroids and regulate nodule metabolism and transport processes accordingly. Further work to identify the physiological substrate for GmYSL7 will allow clarification of this role.

Production of nitric oxide and nitrosylleghemoglobin complexes in soybean nodules in response to flooding

Nitric oxide (NO) has gained interest as a major signaling molecule during plant development and in response to environmental cues. Formation of NO during symbiotic interactions has been reported, but the role and sources of NO in nodules remain unclear. In this work, the involvement of denitrification, performed by the symbiont Bradyrhizobium japonicum, in NO formation in soybean nodules in response to flooding conditions has been investigated by inoculating plants with napA-, nirK-, or norC-deficient mutants. Levels of nitrosylleghemoglobin (LbNO) in flooded nirK and norC nodules were significantly higher than those observed in wild-type nodules. In addition, nirK and norC nodules accumulated more nitrite and NO, respectively, than wild-type nodules. By contrast, levels of LbNO, nitrite, and NO in flooded napA nodules were lower than in wild-type nodules. These results suggest that LbNO formation in soybean nodules in response to flooding conditions is caused by nitrite and NO generated from periplasmic nitrate reductase (Nap) and also containing nitrite reductase (NirK) denitrification enzymes. Flooding caused a decrease of nifH expression and nitrogenase activity in wild-type and norC nodules but not in napA or nirK nodules. Incubation of wild-type and norC nodules with a NO scavenger counteracted the effect of flooding. Under free-living conditions, beta-galactosidase activity from a nifD'-'lacZ fusion decreased in a norC mutant, which also accumulated NO in the medium. These results suggest that NO formed by Cu-containing nitrite reductase in soybean nodules in response to flooding has a negative effect on expression of nitrogenase. We propose that Lb has a major role in detoxifying NO and nitrite produced by bacteroidal denitrification in response to flooding conditions.

Feedback regulation of the Bradyrhizobium japonicum nodulation genes

Lipochitin Nod signals are produced by rhizobia and are required for the establishment of a nitrogen-fixing symbiosis with a legume host. The nodulation genes encode products required for the synthesis of this signal and are induced in response to plant-produced flavonoid compounds. The addition of chitin and lipo-chitin oligomers to Bradyrhizobium japonicum cultures resulted in a significant reduction in the expression of a nod-lacZ fusion. Intracellular expression of NodC, encoding a chitin synthase, also reduced nod gene expression. In contrast, expression of the ChiB chitinase increased nod gene expression. The chain length of the oligosaccharide was important in feedback regulation, with chitotetraose molecules the best modulators of nod gene expression. Feedback regulation is mediated by the induction of nolA by chitin, resulting in elevated levels of the repressor protein, NodD2.

Genetic engineering strategies for environmental applications

Environmental applications of genetically engineered microorganisms are currently hampered not only by legal regulations restricting their release, but also by the frequent dearth of adequate genetic tools for their construction in the laboratory. Recent approaches to strain development include the use of non-antibiotic markers as selection determinants, the use of transposon-vectors for the permanent acquisition of recombinant genes, and the utilization of expression devices based on promoters from promiscuous plasmids and biodegradative pathway genes.

Hyperreiterated DNA regions are conserved among Bradyrhizobium japonicum serocluster 123 strains

We have identified and cloned two DNA regions which are highly reiterated in Bradyrhizobium japonicum serocluster 123 strains. While one of the reiterated DNA regions, pFR2503, is closely linked to the B. japonicum common and genotype-specific nodulation genes in strain USDA 424, the other, pMAP9, is located next to a Tn5 insertion site in a host-range extension mutant of B. japonicum USDA 438. The DNA cloned in pFR2503 and pMAP9 are reiterated 18 to 21 times, respectively, in the genomes of B. japonicum serocluster 123 strains. Gene probes from the reiterated regions share sequence homology, failed to hybridize (or hybridized poorly) to genomic DNA from other B. japonicum and Bradyrhizobium spp. strains, and did not hybridize to DNA from Rhizobium meliloti, Rhizobium fredii, Rhizobium leguminosarum biovars trifolii, phaseoli, and viceae, or Agrobacterium tumefacians. The restriction fragment length polymorphism hybridization profiles obtained by using these gene probes are useful for discriminating among serologically related B. japonicum serocluster 123 strains.

Characterization of a fixLJ-regulated Bradyrhizobium japonicum gene sharing similarity with the Escherichia coli fnr and Rhizobium meliloti fixK genes

We describe the cloning, sequencing, regulation, and mutational analysis of a Bradyrhizobium japonicum fixK-like gene whose product belongs to the family of Fnr-Crp-related regulatory proteins. The predicted 237-amino-acid FixK protein was found to share between 28 and 38% sequence identity with the Escherichia coli Fnr protein, other bacterial Fnr-like proteins (FnrN, Anr, and HlyX), and two rhizobial FixK proteins. The B. japonicum fixK-like gene, when expressed from a lac promoter, could functionally complement an fnr mutant strain of E. coli and activate transcription from an fnr-dependent promoter in the E. coli background; this activation was sixfold higher in anaerobic cultures than in aerobically grown cells, a finding that suggested oxygen sensitivity of the FixK protein and was consistent with the presence of a cysteine-rich, putatively oxygen-responsive domain at its N-terminal end. Similar to the situation in Rhizobium meliloti, expression of the fixK gene in B. japonicum was shown to be induced at low O2 tension and this induction was dependent on the two-component regulatory system FixLJ. Despite this dependency, however, a B. japonicum fixK mutant did not have the phenotypic characteristics of B. japonicum fixL and fixJ mutants: the fixK mutant was neither Fix- in symbiosis with soybean plants nor defective in anaerobic respiration with nitrate as the terminal electron acceptor. Also, the fixK mutant was unaffected in the expression of one of the two B. japonicum sigma 54 genes, rpoN1, which was previously shown to be controlled by the fixLJ genes. When fixK was introduced into the B. japonicum fixJ mutant and expressed therein from a constitutive promoter (i.e., uncoupling it from regulation by FixJ), the FixK protein thus synthesized fully restored anaerobic nitrate respiration in that strain. We interpret this to mean that the B. japonicum wild type has two homologs of fixLJ-regulated fixK genes which can functionally substitute for each other.

Dual control of the Bradyrhizobium japonicum symbiotic nitrogen fixation regulatory operon fixR nifA: analysis of cis- and trans-acting elements

Aerobic expression of the fixR nifA operon in Bradyrhizobium japonicum was shown to depend on a cis-acting, promoter-upstream DNA sequence located between the -24/-12 promoter and position -86 relative to the transcription start site. An adenine at position -66 was essential for maximal expression. A chromosomal deletion of the upstream activator sequence (UAS) led to a symbiotically defective phenotype which was typical of nifA mutants. B. japonicum crude extracts contained a protein that bound to the UAS. By using chromosomally integrated fixR-lacZ fusions, the level of expression of the fixR nifA operon was found to be fivefold higher under reduced oxygen tension than under aerobiosis. This increase was due to autoactivation by the NifA protein and was partly independent of the UAS. Based on these data, we propose a model for the regulation of nitrogen fixation genes in B. japonicum that involves dual positive control of the fixR nifA operon. At high oxygen concentrations, the operon is expressed at a moderate level, subject to activation by the binding of a trans-acting factor to the UAS. Under such conditions, the nifA gene product is known to be inactive. At very low oxygen concentrations--a condition favorable to NifA activity--the NifA protein is the trans-acting factor which (i) enhances the level of fixR nifA expression (and hence its own synthesis) and (ii) activates other nif and fix genes.

A broad-host-range shuttle system for gene insertion into the chromosomes of gram-negative bacteria

A deletion derivative of transposon Tn7 containing the Escherichia coli lacZY genes as a selectable marker for insertion of foreign DNA into the chromosomes of soil bacteria was improved to facilitate the cloning of additional genes and their insertion by this element. This report describes a series of plasmid vectors that enable this cloning to be carried out in small, high-copy, narrow host-range plasmids. The final Tn element can then be easily moved (by transposition) without further use of restriction enzymes, to plasmids suitable for delivering it to the bacterial chromosome. The very high specificity for insertion of Tn7 into single locations in bacterial chromosomes has been exploited in the construction of a shuttle system for delivering these Tn7 elements.

Direct response of Bradyrhizobium japonicum nifA-mediated nif gene regulation to cellular oxygen status

The nifA genes of Klebsiella pneumoniae and Bradyrhizobium japonicum were constitutively expressed from the pBR329-derived chloramphenicol resistance promoter. The inserts of these nifA plasmid constructs were devoid of any other intact flanking genes. The nifA genes thus expressed led to a marked activation of a B. japonicum nifD-lacZ fusion under microaerobic conditions. Under aerobic growth conditions, however, activation was mediated only by the K. pneumoniae nifA gene but not by the B. japonicum nifA gene. This selective effect was observed in both the Escherichia coli as well as the B. japonicum backgrounds. Several lines of evidence suggest that in these experiments oxygen adversely affects B. japonicum nifA-dependent nif gene regulation at the post-transcriptional level, probably even at the post-translational level, and that this effect does not require a nifL-like gene. Models are proposed in which oxygen inhibits the B. japonicum NifA protein either directly or indirectly via other cellular components involved in general protein oxidation pathways.