Symbiotic properties of C4-dicarboxylic acid transport mutants of Rhizobium leguminosarum

Isolation of Rhizobium phaseoli Tn5-induced mutants with altered expression of cytochrome terminal oxidases o and aa3

Two Rhizobium phaseoli mutants affected in cytochrome expression were obtained by Tn5-mob mutagenesis of the wild-type strain (CE3). Mutant strain CFN031 expressed sevenfold less cytochrome o in culture, expressed cytochrome aa3 under microaerophilic culture conditions, in contrast to strain CE3, and was affected in its vegetative growth properties and proliferation inside plant host cells. Mutant CFN037 expressed cytochrome aa3 under microaerophilic culture conditions, while bacteroid development and nitrogen fixation occurred earlier than in strain CE3.

The occurrence of unusual laminated structures rich in β-1,4-glucans in plastids of Phaseolus vulgaris root-nodule cells infected by an ineffective C4-dicarboxylic-acid mutant of Rhizobium leguminosarum bv. phaseoli

Root nodules induced in Phaseolus vulgaris L. by the wild-type (WT) and a C4-dicarboxylic-acid mutant strain of Rhizobium leguminosarum biovar. phaseoli were compared on the basis of ultrastructure and cytochemistry of cellulose subunits. The mutant bacteroids failed to colonize infected host cells in a normal manner, and presented a premature degenerative appearance. Starch granules, rough endoplasmic reticulum and mitochondria were found to accumulate in the ineffective nodules. The most striking difference between effective and ineffective nodules was the presence of unusual spherical, laminated structures in plastids of mutant-infected host cells only. Cytochemical observations showed that these structures contain β-1,4-glucans. The presence of β-1,4-glucans within such structures may be caused by the activity of a cellulase which is produced by either the bacteroids or the host cell and is locally hydrolyzing the host cell-wall, thus releasing cellulose subunits into the cytoplasm. Another possibility is denovo synthesis of β-1,4-glucans in the host cell.

Genetic analysis and regulation of the Rhizobium meliloti genes controlling C4-dicarboxylic acid transport

The genes controlling the transport of C4-dicarboxylic acids from Rhizobium meliloti have been cloned and analysed. The nucleotide sequence of the control region of the structural dctA and the regulatory dctBD genes has been determined. Comparison with the Rhizobium leguminosarum dct genes revealed a high degree of homology. Gene fusions to the enteric lacZY reporter gene were constructed and the expression of the dctA and dctBD genes studied under various physiological conditions. In free-living cells, the regulatory dctBD genes are absolutely required for the expression of the dctA gene. In the root nodule environment, a dctA::lacZY gene fusion was found to be expressed in an R. meliloti strain mutated in both the dctB and dctD genes, but not in a strain mutated in the dctB gene alone. The presence of the conserved upstream NifA-binding sites on the dctA promoter sequence, coupled with the fact that the dctA::lacZY gene fusion is not expressed in root nodules formed by a nifA mutant strain of R. meliloti, supports the suggestion that NifA may be involved in the symbiotic expression of dctA in the absence of the regulatory dctBD genes. Under micro-aerobic conditions, however, NifA induction alone is not sufficient for expression of the dctA promoter, even though the NifA-dependent nifHDK promoter is highly expressed under these conditions.

Identification and sequence analysis of the Rhizobium meliloti dctA gene encoding the C4-dicarboxylate carrier

Transposon Tn5-induced C4-dicarboxylate transport mutants of Rhizobium meliloti 2011 which could be complemented by cosmid pRmSC121 were subdivided into two classes. Class I mutants (RMS37 and RMS938) were defective in symbiotic C4-dicarboxylate transport and in nitrogen fixation. They were mutated in the structural gene dctA, which codes for the C4-dicarboxylate carrier. Class II mutants (RMS11, RMS16, RMS17, RMS24, and RMS31) expressed reduced activity in symbiotic C4-dicarboxylate transport and in nitrogen fixation. These mutants were mutated in regulatory dct genes which do not play an essential role in the symbiotic state. Thin sections of alfalfa nodules induced by the wild type and class I and class II mutants were analyzed by light microscopy. Class mutants induced typical Fix- nodules, showing a large senescent zone, whereas nodules induced by class II mutants only differed in an enhanced content of starch granules compared with wild-type nodules. Class I mutants could be complemented by a 2.1-kilobase SalI-HindIII subfragment of cosmid pRmSC121. DNA sequencing of this fragment resulted in the identification of an open reading frame, which was designated dctA because Tn5 insertion sites of the class I mutants mapped within this coding region. The dctA gene was preceded by a nif consensus promoter and an upstream NifA-binding element. Upstream of the dctA promoter, the 5' end of the R. meliloti dctB gene could be localized. The amino acid sequence of the N-terminal part of the R. meliloti DctB protein shared 49% homology with the corresponding part of the R. leguminosarum DctB protein. The DctA protein consisted of 441 or 453 amino acids due to two possible ATG start codons, with calculated molecular masses of 46.1 and 47.6 kilodaltons, respectively. The hydrophobicity plot suggests that DctA is a membrane protein with several membrane passages. The amino acid sequences of the R. meliloti and the R. leguminosarum DctA proteins were highly conserved (82%).

Conservation between coding and regulatory elements of Rhizobium meliloti and Rhizobium leguminosarum dct genes

Complementation of Rhizobium leguminosarum dct mutants with a cosmid bank yielded Rhizobium meliloti homologs of the dctA, dctB, and dctD genes. The genes dctB and dctD are thought to form a two-component system which responds to the presence of C4-dicarboxylates to regulate expression of a transport protein encoded by dctA. DNA sequence analysis showed that dct coding and intergenic regions, including putative binding sites for the dctD protein and sigma 54-RNA polymerase, were highly conserved between these two Rhizobium species. Mutation of R. meliloti dctD showed that it was not essential for symbiotic nitrogen fixation but was needed for growth on succinate and the expression of a dctA-lacZ fusion gene in free-living cells. Hybridization of R. meliloti genomic DNA with probes representing the central portion of dctD potentially identified more than 20 similar regulatory genes, all of which are likely to depend upon the alternative sigma factor encoded by rpoN and stimulate transcription in a manner very similar to ntrC activation of glnA in enteric bacteria.

Analysis of C4-dicarboxylate transport genes in Rhizobium meliloti

A 5.1 kbp DNA fragment was isolated which complemented C4-dicarboxylate transport mutants (dct) of Rhizobium meliloti. Characterization of this fragment by subcloning, transposon mutagenesis, and complementation analysis revealed three loci, designated dctA, dctB, and dctD. TnphoA-generated alkaline phosphatase fusions to dctA suggested that this gene encodes the structural transport protein and allowed the determination of its direction of transcription. Analysis of the fusions in various mutant backgrounds demonstrated that dctB, dctD, and ntrA products are required for dctA expression. The dctA fusion was constitutively expressed in a dctA mutant background, but was not expressed in dctA dctB or dctA dctD double mutants. This suggests that the constitutive expression in a dctA mutant background is mediated through dctB and dctD. Three independent second-site Dct+ revertant mutations in ntrA mutant strains mapped to the dct locus. Succinate transport in these revertant strains was constitutive, whereas in the wild type, succinate transport was inducible. These results are consistent with the direct requirement of the ntrA gene product for dctA expression. Alfalfa plants inoculated with the dctB and dctD mutants showed reduced nitrogen-fixing activity. Nodules induced by dctA mutants failed to fix nitrogen. These symbiotic phenotypes are consistent with previous suggestions that dctA expression in bacteroids can occur independently of dctB and dctD.

Symbiotic loci of Rhizobium meliloti identified by random TnphoA mutagenesis

We have developed a system for using TnphoA (TnphoA is Tn5 IS50L::phoA), which generates fusions to alkaline phosphatase (C. Manoil and J. Beckwith, Proc. Natl. Acad. Sci. USA 82:8129-8133, 1985), in Rhizobium meliloti. Active fusions expressing alkaline phosphatase can arise only when this transposon inserts in genes encoding secreted or membrane-spanning proteins. By confining our screening to 1,250 TnphoA-generated mutants of R. meliloti that expressed alkaline phosphatase, we efficiently identified 25 symbiotically defective mutants, all of which formed ineffective (Fix-) nodules on alfalfa. Thirteen of the mutants were unable to synthesize an acidic exopolysaccharide (exo::TnphoA) that is required for nodule invasion. Twelve of the mutations created blocked at later stages of nodule development (fix::TnphoA) and were assigned to nine symbiotic loci. One of these appeared to be a previously undescribed locus located on the pRmeSU47a megaplasmid and to encode a membrane protein. Two others were located on the pRmeSU47b megaplasmid: one was a new locus which was induced by luteolin and encoded a membrane protein, and the other was dctA, the structural gene for dicarboxylic acid transport. The remaining six loci were located on the R. meliloti chromosome. One of these was inducible by luteolin and encoded a membrane protein which determined lipopolysaccharide structure. Three additional chromosomal loci also appeared to encode membrane proteins necessary for symbiosis. The remaining two chromosomal loci encoded periplasmic proteins required for symbiosis.

Mutants of Rhizobium meliloti defective in succinate metabolism

We characterized mutants of Rhizobium meliloti SU47 that were unable to grow on succinate as the carbon source. The mutants fell into five groups based on complementation of the succinate mutations by individual recombinant plasmids isolated from a R. meliloti clone bank. Enzyme analysis showed that mutants in the following groups lacked the indicated common enzyme activities: group II, enolase (Eno); group III, phosphoenolpyruvate carboxykinase (Pck); group IV, glyceraldehyde-3-phosphate dehydrogenase (Gap), and 3-phosphoglycerate kinase (Pgk). Mutants in groups I and V lacked C4-dicarboxylate transport (Dct-) activity. Wild-type cells grown on succinate as the carbon source had high Pck activity, whereas no Pck activity was detected in cells that were grown on glucose as the carbon source. It was found that in free-living cells, Pck is required for the synthesis of phosphoenolpyruvate during gluconeogenesis. In addition, the enzymes of the lower half of the Embden-Meyerhoff-Parnas pathway were absolutely required for gluconeogenesis. Eno, Gap, Pck, and one of the Dct loci (ntrA) mapped to different regions of the chromosome; the other Dct locus was tightly linked to a previously mapped thi locus, which was located on the megaplasmid pRmeSU47b.

Rhizobium meliloti genes required for C4-dicarboxylate transport and symbiotic nitrogen fixation are located on a megaplasmid

A mutant of Rhizobium meliloti unable to transport C4 dicarboxylates (dct) was isolated after Tn5 mutagenesis. The mutant, 4F6, could not grow on aspartate or the tricarboxylic acid cycle intermediates succinate, fumarate, or malate. It produced symbiotically ineffective nodules on Medicago sativa in which bacteroids appeared normal, but the symbiotic zone was reduced and the plant cells contained numerous starch granules at their peripheries. Cosmids containing the dct region were obtained by selecting those which restored the ability of 4F6 to grow on succinate. The Tn5 insertion in 4F6 was found to be within a 5.9-kilobase (kb) EcoRI fragment common to the complementing cosmids. Site-specific Tn5-mutagenesis revealed dct genes in a segment of DNA about 4 kb in size extending from within the 5.9-kb EcoRI fragment into an adjacent 2.9-kb EcoRI fragment. The 4F6 mutation was found to be in a complementation group in which mutations yielded a Fix- phenotype, whereas other dct mutations in the region resulted in mutants which produced effective nodules in most, although not all, plant tests (partially Fix-). The dct region was found to be located on a megaplasmid known to carry genes required for exopolysaccharide production.

Identification of cytoplasmic nodule-associated forms of malate dehydrogenase involved in the symbiosis between Rhizobium leguminosarum and Pisum sativum

The malate dehydrogenase activity (EC 1.1.1.37), present in the cytoplasm of Pisum sativum root nodules, can be separated by ion-exchange chromatography into four different fractions. Malate dehydrogenase activity present in the cytoplasm of roots elutes mainly as a single peak. During nodule development an increase in malate dehydrogenase activity per gram of material was observed. This increase occurred concomitantly with the increase in nitrogenase activity. The kinetic properties of the separated malate dehydrogenases of root nodule cytoplasm and root cytoplasm were studied. The Km values for malate (2.6 mM), NAD+ (27 microM), oxaloacetate (18 microM) and NADH (13 microM) of the dominant form of the root nodule cytoplasm are much lower than those of the dominant malate dehydrogenase root form (64 mM, 4.4 mM, 89 microM and 70 microM respectively). Binding of malate by the enzyme-NADH complex from root nodules results in an abortive complex, thereby blocking the further reduction of oxaloacetate by NADH. The dominant root malate dehydrogenase does not form the abortive complex. From the kinetic data it is concluded, first, that the root nodule forms of the enzyme are capable of catalysing at a high rate the reduction of oxaloacetate, to meet the demands for malate governed by the bacteroid and the infected plant cell. The second conclusion, drawn from the kinetic data, is that under physiological conditions the conversion of oxaloacetate can be controlled just by the malate concentration. Consequently the major root nodule forms of malate dehydrogenase are able to allow a high flux of malate production from oxaloacetate but also to establish a sufficient oxaloacetate concentration necessary for the assimilation and transport of fixed nitrogen.

Dicarboxylic acid transport in Bradyrhizobium japonicum: use of Rhizobium meliloti dct gene(s) to enhance nitrogen fixation

A recombinant plasmid encoding Rhizobium meliloti sequences involved in dicarboxylic acid transport (plasmid pRK290:4:46) (E. Bolton, B. Higgisson, A. Harrington, and F. O'Gara, Arch. Microbiol. 144:142-146, 1986) was used to study the relationship between dicarboxylic acid transport and nitrogen fixation in Bradyrhizobium japonicum. The expression of the dct sequences on plasmid pRK290:4:46 in B. japonicum CJ1 resulted in increased growth rates in media containing dicarboxylic acids as the sole source of carbon. In addition, strain CJ1(pRK290:4:46) exhibited enhanced succinate uptake activity when grown on dicarboxylic acids under aerobic conditions. Under free-living nitrogen-fixing conditions, strain CJ1(pRK290:4:46) exhibited higher nitrogenase (acetylene reduction) activity compared with that of the wild-type strain. This increase in nitrogenase activity also correlated with an enhanced dicarboxylic acid uptake rate under these microaerobic conditions. The regulation of dicarboxylic acid transport by factors such as metabolic inhibitors and the presence of additional carbon sources was similar in both the wild-type and the engineered strains. The implications of increasing nitrogenase activity through alterations in the dicarboxylic acid transport system are discussed.

Deduced products of C4-dicarboxylate transport regulatory genes of Rhizobium leguminosarum are homologous to nitrogen regulatory gene products

We have sequenced two genes dctB and dctD required for the activation of the C4-dicarboxylate transport structural gene dctA in free-living Rhizobium leguminosarum. The hydropathic profile of the dctB gene product (DctB) suggested that its N-terminal region may be located in the periplasm and its C-terminal region in the cytoplasm. The C-terminal region of DctB was strongly conserved with similar regions of the products of several regulatory genes that may act as environmental sensors, including ntrB, envZ, virA, phoR, cpxA, and phoM. The N-terminal domains of the products of several regulatory genes thought to be transcriptional activators, including ntrC, ompR, virG, phoB and sfrA. In addition, the central and C-terminal regions of DctD were strongly conserved with the products of ntrC and nifA, transcriptional activators that require the alternate sigma factor rpoN (ntrA) as co-activator. The central region of DctD also contained a potential ATP-binding domain. These results are consistent with recent results that show that rpoN product is required for dctA activation, and suggest that DctB plus DctD-mediated transcriptional activation of dctA may be mechanistically similar to NtrB plus NtrC-mediated activation of glnA in E. coli.

Requirement of succinate dehydrogenase activity for symbiotic bacteroid differentiation of Rhizobium meliloti in alfalfa nodules

Transmission electron microscopy was used to study the cellular morphologies of a wild-type Rhizobium meliloti strain (L5-30), a nitrogen fixation-ineffective (Fix-) succinate dehydrogenase mutant (Sdh-) strain, and a Fix+ Sdh+ revertant strain within alfalfa nodules and after free-living growth in a minimal medium containing 27 mM mannitol plus 20 mM succinate. The results showed a requirement of succinate dehydrogenase activity for symbiotic differentiation and maintenance of R. meliloti bacteroids within alfalfa nodules and for succinate-induced cellular pleomorphism in free-living cultures. Also, the Sdh- strain had a 3.5-fold lower rate of oxygen consumption in the defined medium than did the wild type.

A new symbiotic cluster on the pSym megaplasmid of Rhizobium meliloti 2011 carries a functional fix gene repeat and a nod locus

A 290-kilobase (kb) region of the Rhizobium meliloti 2011 pSym megaplasmid, which contains nodulation genes (nod) as well as genes involved in nitrogen fixation (nif and fix), was shown to carry at least six sequences repeated elsewhere in the genome. One of these reiterated sequences, about 5 kb in size, had previously been identified as part of a cluster of fix genes located 220 kb downstream of the nifHDK promoter. Deletion of the reiterated part of this fix cluster does not alter the symbiotic phenotype. Deletion of the second copy of this reiterated sequence, which maps on pSym 40 kb upstream of the nifHDK promoter, also has no effect. Deletion of both of these copies however leads to a Fix- phenotype, indicating that both sequences carry functionally reiterated fix gene(s). The fix copy 40 kb upstream of nifHDK is part of a symbiotic cluster which also carries a nod locus, the deletion of which produces a marked delay in nodulation.

Involvement of glutamate in the respiratory metabolism of Bradyrhizobium japonicum bacteroids

Bradyrhizobium japonicum bacteroids were isolated anaerobically and supplied with 14C-labeled succinate, malate, aspartate, or glutamate for periods of up to 60 min in the presence of myoglobin to control the O2 concentration. Succinate and malate were absorbed about twice as rapidly as glutamate and aspartate. Conversion of substrate to CO2 was most rapid for malate, followed by succinate, glutamate, and aspartate. When CO2 production was expressed as a proportion of total carbon taken up, malate was still the most rapidly respired substrate, with 68% of the label absorbed converted to CO2. The comparable values for succinate, glutamate, and aspartate were 37, 50, and 38%, respectively. Considering the fate of labeled substrate not respired, greater than 95% of absorbed glutamate remained as glutamate in the bacteroids. In contrast, from 39 to 66% of the absorbed succinate, malate, or aspartate was converted to glutamate. An increase in the rate of CO2 formation from labeled substrates after 20 min appeared to coincide with a maximum accumulation of label in glutamate. The results indicate the presence of a substantial glutamate pool in bacteroids and the involvement of glutamate in the respiratory metabolism of bacteroids.

Iron requirement of Rhizobium leguminosarum and secretion of anthranilic acid during growth on an iron-deficient medium

Rhizobium leguminosarum GF160 required iron for growth under aerobic conditions in a chemically defined medium. Maximal growth of bacteria previously depleted in iron was obtained with approximately 50 microM unchelated ferric iron and with glucose as the only carbon source. Growth under iron deficiency did not result in the production of detectable levels of siderophores of either the catechol or hydroxamate types. Growing cells released a Fe3+-reducing agent that was identified as anthranilic acid by paper and thin-layer chromatography, ultraviolet and nuclear magnetic resonance spectroscopy, and mass spectrometry. The amount of anthranilic acid secreted per unit of cell growth was inversely related to the iron concentration in the culture medium and reached concentrations up to 1 mM. Ferric but not ferrous ions were solubilized in the growth medium by anthranilic acid.

Molecular cloning and genetic organization of C4-dicarboxylate transport genes from Rhizobium leguminosarum

Cosmids containing C4-dicarboxylate transport (dct) genes were identified from a gene bank of Rhizobium leguminosarum DNA made in the broad-host-range vector pLAFR1 by their ability to complement R. trifolii dct mutants. The dct genes were further characterized by subcloning, restriction site mapping, and transposon Tn5 and Tn7 mutageneses. Three dct loci were identified within a 5.5-kilobase region of DNA, in the order dctA-dctB-dctC. The results suggested that dctA encoded a structural component necessary for C4-dicarboxylate transport, whereas dctB and dctC encoded positive regulatory elements, and that dctA was transcribed divergently from dctB and dctC. Expression of dctA and dctC was obtained from vector promoters in some pLAFR1- and pSUP106-based plasmids.

Evidence for a Terpene-Based Food Chain in the Gulf of Alaska

A mixture of 14 C-terpenes was prepared from conifer seedlings and introduced into fresh seawater samples taken near Seward, Alaska. Initial rates of oxidation by the indigenous bacteria were linear and faster than the rates of toluene oxidation. Turnover times were 4 to 19 days. Autoradiographic measurements with 3 H-terpenes indicated that at least 10% of the 0.6 � 10 9 to 2.7 � 10 9 bacteria per liter present could catabolize terpenes. The rate of terpene oxidation, 24 μg of terpenes per g of cells per h with 3 μg of terpenes added per liter, was a constant function of bacterial biomass. The specific affinity of the process was estimated to be between 8.1 and 81 liters/g of cells per h, indicating a high state of induction and the probable presence of terpenes. Terpene-oxidizing bacteria were grown on [ 14 C]alanine and added to fresh seawater samples. Transfer of the bacterial radioactivity into larger particles at a rate of 146 pg/liter per h from the 2.3 � 10 9 organisms added indicated that any terpenes present would participate in the food chain.