Mobility of the Sinorhizobium meliloti group II intron RmInt1 occurs by reverse splicing into DNA, but requires an unknown reverse transcriptase priming mechanism

The mobile group II introns characterized to date encode ribonucleoprotein complexes that promote mobility by a major retrohoming mechanism in which the intron RNA reverse splices directly into the sense strand of a double-stranded DNA target site, while the intron-encoded reverse transcriptase/maturase cleaves the antisense strand and uses it as primer for reverse transcription of the inserted intron RNA. Here, we show that the Sinorhizobium meliloti group II intron RmInt1, which encodes a protein lacking a DNA endonuclease domain, similarly uses both the intron RNA and an intron-encoded protein with reverse transcriptase and maturase activities for mobility. However, while RmInt1 reverse splices into both single-stranded and double-stranded DNA target sites, it is unable to carry out site-specific antisense-strand cleavage due to the lack of a DNA endonuclease domain. Our results suggest that RmInt1 mobility involves reverse splicing into double-stranded or single-stranded DNA target sites, but due to the lack of DNA endonuclease function, it requires an alternate means of procuring a primer for target DNA-primed reverse transcription.

Bacteria and Archaea Group II introns: additional mobile genetic elements in the environment

Self-splicing group II introns are present in the organelles of lower eukaryotes, plants and Bacteria and have been found recently in Archaea. It is generally accepted that group II introns originated in bacteria before spreading to mitochondria and chloroplasts. These introns are thought to be related to the progenitors of spliceosomal introns. Group II introns are also mobile genetic elements. In bacteria, they appear to spread using either other mobile genetic elements or low-expression regions as target sites. Bacteria and Archaea genome sequence annotations have revealed the diversity of group II intron classes and that they are involved in vertical and horizontal inheritance.

DNA target site requirements for homing in vivo of a bacterial group II intron encoding a protein lacking the DNA endonuclease domain

Group II intron-encoded proteins (IEPs), which have maturase and reverse transcriptase activities, form a ribonucleoprotein (RNP) complex with the intron RNA. Some IEPs also have a C-terminal DNA-binding region and conserved DNA endonuclease domain involved in the recognition and cleavage of specific DNA target sites used for intron homing. RmInt1 is a mobile group II intron of Sinorhizobium meliloti, the IEP of which lacks the endonuclease domain, as do over half of their bacterial counterparts. Here, we analyzed the DNA target sequence requirements for homing in vivo of intron RmInt1 and compared these requirements to those established for the Lactococcus lactis Ll.LtrB intron, a representative of mobile subgroup IIA introns encoding proteins with functional C-terminal DNA endonuclease domains. As for Ll.LtrB, RmInt1 homing requires modifiable base-pairing interactions between the intron RNA and the DNA target, involving 13 nucleotides. However, instead of the delta-delta' interaction, typical of subgroup IIA introns, we demonstrate that RmInt1 recognizes the first nucleotide within the 3' exon of the target site by a new EBS3/IBS3 pairing predicted for subgroup IIB self-splicing introns. Unlike Ll.LtrB, there are less stringent requirements for RmInt1 recognition of distal 5' and 3' exon regions, where only single nucleotide positions are fixed constraints for intron homing. Our results predict differences in the DNA target-site requirements among group II introns, which may have mechanistic and evolutionary implications.

Diversity of group II introns in the genome of Sinorhizobium meliloti strain 1021: splicing and mobility of RmInt1

The number and diversity of known group II introns in eubacteria are continually increasing with the addition of new data from sequencing projects, but the significance of these introns in the evolution of bacterial genomes is unknown. We analyzed the main features of the group II introns present in the genome of the soil microorganism Sinorhizobium meliloti (strain 1021), the nitrogen-fixing symbiont of alfalfa, the DNA sequence of which was recently determined. Strain 1021 harbors three different classes of group II introns: RmInt1, of bacterial class D; SMb2147/SMb21167, which cluster within bacterial class C; and SMa1875, the phylogenetic class of which is uncertain. The group II introns SMb2147/SMb21167 and SMa1875 are widely distributed in S. meliloti, but are present in lower copy numbers than RmInt1. Strain 1021 harbors three copies of RmInt1, which is pSym-specific. Although RmInt1 is spliced in strain 1021, mobility assays suggested that, in contrast to other S. meliloti strains, the genetic background of strain 1021 does not support intron homing events.

Identification and characterization of bacterial class E group II introns

Group II introns are catalytic RNAs and mobile genetic elements. Phylogenetic characterization of group II intron-encoded reverse transcriptases (RTs) established seven classes: the mitochondrial class, chloroplast-like classes 1 and 2, and bacterial classes A, B, C, and D. In this study, we identified and characterized a new bacterial class of group II introns, bacterial class E, on the basis of phylogenetic analysis of the intron-encoded protein (IEP) RT and determination of a consensus intron RNA structure.

Effect of a Sinorhizobium meliloti strain with a modified putA gene on the rhizosphere microbial community of alfalfa

The success of a rhizobial inoculant in the soil depends to a large extent on its capacity to compete against indigenous strains. M403, a Sinorhizobium meliloti strain with enhanced competitiveness for nodule occupancy, was recently constructed by introducing a plasmid containing an extra copy of a modified putA (proline dehydrogenase) gene. This strain and M401, a control strain carrying the same plasmid without the modified gene, were used as soil inoculants for alfalfa in a contained field release experiment at León, Spain. In this study, we determined the effects of these two strains on the indigenous microbial community. 16S rRNA genes were obtained from the rhizosphere of alfalfa inoculated with strain M403 or strain M401 or from noninoculated plants by amplification of DNA from soil with bacterial group-specific primers. These genes were analyzed and compared by restriction fragment length polymorphism and temperature gradient gel electrophoresis. The results allowed us to differentiate between alterations in the microbial community apparently caused by inoculation and by the rhizosphere effect and seasonal fluctuations induced by the alfalfa plants and by the environment. Only moderate inoculation-dependent effects could be detected, while the alfalfa plants appeared to have a much stronger influence on the microbial community.

Construction and environmental release of a Sinorhizobium meliloti strain genetically modified to be more competitive for alfalfa nodulation

Highly efficient nitrogen-fixing strains selected in the laboratory often fail to increase legume production in agricultural soils containing indigenous rhizobial populations because they cannot compete against these populations for nodule formation. We have previously demonstrated, with a Sinorhizobium meliloti PutA- mutant strain, that proline dehydrogenase activity is required for colonization and therefore for the nodulation efficiency and competitiveness of S. meliloti on alfalfa roots (J. I. Jiménez-Zurdo, P. van Dillewijn, M. J. Soto, M. R. de Felipe, J. Olivares, and N. Toro, Mol. Plant-Microbe Interact. 8:492-498, 1995). In this work, we investigated whether the putA gene could be used as a means of increasing the competitiveness of S. meliloti strains. We produced a construct in which a constitutive promoter was placed 190 nucleotides upstream from the start codon of the putA gene. This resulted in an increase in the basal expression of this gene, with this increase being even greater in the presence of the substrate proline. We found that the presence of multicopy plasmids containing this putA gene construct increased the competitiveness of S. meliloti in microcosm experiments in nonsterile soil planted with alfalfa plants subjected to drought stress only during the first month. We investigated whether this construct also increased the competitiveness of S. meliloti strains under agricultural conditions by using it as the inoculum in a contained field experiment at León, Spain. We found that the frequency of nodule occupancy was higher with inoculum containing the modified putA gene for samples that were analyzed after 34 days but not for samples that were analyzed later.

Ectopic transposition of a group II intron in natural bacterial populations

Self-splicing group II introns are thought to be the evolutionary progenitors of eukaryotic spliceosomal introns. The invasion of novel (ectopic) sites by group II introns is considered to be a key mechanism by which spliceosomal introns may have become widely dispersed. However, the dynamics of these events in populations are unknown. In bacteria, only two group II introns have been shown to splice and to be mobile in vivo. One of these introns, RmInt1 from Sinorhizobium meliloti, which encodes a protein with no endonuclease domain, has been shown to invade the ectopic oxi1 site independently of recombinase. In this study, we analysed ectopic transposition of the RmInt1 intron in a natural population of S. meliloti. We characterized S. meliloti isolates by polymerase chain reaction amplification of a gene, dapB, which is found only on the pRmeGR4b plasmid diagnostic of GR4-type strains. The diversity within this specific field population of bacteria was analysed by restriction fragment length polymorphism using ISRm2011-2 (homing site of RmInt1) and RmInt1 as probes. We found that ectopic transposition of RmInt1 to the oxi1 site occurred in this natural bacterial population. This ectopic transposition was also the most frequent genetic event observed. This work provides further evidence that the ectopic transposition of group II introns is an important mechanism for their spread in natural bacterial populations.

Mesorhizobium chacoense sp. nov., a novel species that nodulates Prosopis alba in the Chaco Arido region (Argentina)

Low-molecular-weight RNA analysis was performed for the identification and classification of 20 Argentinian strains isolated from the root nodules of Prosopis alba. SDS-PAGE of total cellular proteins, determination of the DNA base composition, DNA-DNA reassociation experiments and physiological and biochemical tests were also carried out for these strains and the whole 16S rRNA gene was sequenced from one of the strains, strain LMG 19008T. Results of the genotypic and phenotypic characterization showed that the strains isolated in this study belong to a group that clustered in the genus Mesorhizobium. The results of DNA-DNA hybridizations showed that this group is a novel species of this genus. The name Mesorhizobium chacoense sp. nov. is proposed for this species. The type strain is LMG 19008T (= CECT 5336T).

Group II introns in the bacterial world

Group II introns are large catalytic RNA molecules that act as mobile genetic elements. They were initially identified in the organelle genomes of lower eukaryotes and plants, and it has been suggested that they are the progenitors of nuclear spliceosomal introns. Group II self-splicing introns were shown to be present in bacteria in 1993, since when the various bacterial genome sequencing projects have led to a significant increase in the number of group II intron sequences present in databases. However, few of these introns have been characterized, and most were identified on the basis of their intron-encoded protein (IEP), with little data available concerning their ribozyme/RNA structure. Their frequency in prokaryotes is also unknown. We attempt here to provide a first comprehensive review of bacterial group II introns based on recent genome sequencing data and mechanistic studies.

RecA-independent ectopic transposition in vivo of a bacterial group II intron

RmInt1 is a group II intron of Sinorhizobium meliloti which was initially found within the insertion sequence ISRm2011-2. Although the RmInt1 intron-encoded protein lacks a recognizable endonuclease domain, it is able to mediate insertion of RmInt1 at an intron-specific location in intronless ISRm2011-2 recipient DNA, a phenomenon termed homing. Here we have characterized three additional insertion sites of RmInt1 in the genome of S.meliloti. Two of these sites are within IS elements closely related to ISRm2011-2, which appear to form a characteristic group within the IS630-Tc1 family. The third site is in the oxi1 gene, which encodes a putative oxide reductase. The newly identified integration sites contain conserved intron-binding site (IBS1 and IBS2) and delta' sequences (14 bp). The RNA of the intron-containing oxi1 gene is able to splice and the oxi1 site is a DNA target for RmInt1 transposition in vivo. Ectopic transposition of RmInt1 into the oxi1 gene occurs at 20-fold lower efficiency than into the homing site (ISRm2011-2) and is independent of the major RecA recombination pathway. The possibility that transposition of RmInt1 to the oxi1 site occurs by reverse splicing into DNA is discussed.

Sinorhizobium meliloti nfe (nodulation formation efficiency) genes exhibit temporal and spatial expression patterns similar to those of genes involved in symbiotic nitrogen fixation

The nfe genes (nfeA, nfeB, and nfeD) are involved in the nodulation efficiency and competitiveness of the Sinorhizobium meliloti strain GR4 on alfalfa roots. The nfeA and nfeB genes are preceded by functional nif consensus sequences and NifA binding motifs. Here, we determined the temporal and spatial expression patterns of the nfe genes in symbiosis with alfalfa. Translational fusions of the nfe promoters with the gusA gene and reverse transcription-polymerase chain reaction analyses indicate that they are expressed and translated within mature nitrogen-fixing nodules and not during early steps of nodule development. Within the nodules the three nfe genes exhibit a spatial expression pattern similar to that of genes involved in symbiotic nitrogen fixation. We show that nfeB and nfeD genes are expressed not only from their own promoters but also from the upstream nfe promoter sequences. Furthermore, with the use of specific antibodies the NfeB and NfeD proteins were detected within the root nodule bacteroid fraction. Finally, NfeB was inmunolocalized in the bacteroid cell membrane whereas NfeD was detected in the bacteroid cytoplasm.

Characterization of the Sinorhizobium meliloti genes encoding a functional dihydrodipicolinate synthase (dapA) and dihydrodipicolinate reductase (dapB)

In bacteria, the known pathways for diaminopimelate (DAP) and lysine biosynthesis share two key enzymes, dihydrodipicolinate synthase and dihydrodipicolinate reductase, encoded by the dapA and dapB genes, respectively. In rhizobia, these genes have not yet been genetically characterized. In this work, by sequence analysis, we identified two divergent open reading frames on the 140-MDa plasmid pRmeGR4b of Sinorhizobium meliloti strain GR4. Termed dapA and dapB, these encode products which show significant sequence similarities to DapA and DapB proteins, respectively. Escherichia coli DAP auxotrophs (dapA and dapB mutants) could be complemented with the pRmeGR4b dapA and dapB genes, indicating that these genes code for functional dihydrodipicolinate synthase and dihydrodipicolinate reductase, respectively. Reverse-transcriptase PCR analyses and beta-galactosidase assays using transcriptional dapA-lacZ and dapB-lacZ fusions suggest that these genes are constitutively expressed in S. meliloti. The dapA and dapB genes are not widely distributed in S. meliloti and appear to be specific for strains carrying pRmeGR4b-type plasmids.

Sinorhizobium meliloti putA gene regulation: a new model within the family Rhizobiaceae

Proline dehydrogenase (PutA) is a bifunctional enzyme that catalyzes the oxidation of proline to glutamate. In Sinorhizobium meliloti, as in other microorganisms, the putA gene is transcriptionally activated in response to proline. In Rhodobacter capsulatus, Agrobacterium, and most probably in Bradyrhizobium, this activation is dependent on an Lrp-like protein encoded by the putR gene, located immediately upstream of putA. Interestingly, sequence and genetic analysis of the region upstream of the S. meliloti putA gene did not reveal such a putR locus or any other encoded transcriptional activator of putA. Furthermore, results obtained with an S. meliloti putA null mutation indicate the absence of any proline-responsive transcriptional activator and that PutA serves as an autogenous repressor. Therefore, the model of S. meliloti putA regulation completely diverges from that of its Rhizobiaceae relatives and resembles more that of enteric bacteria. However, some differences have been found with the latter model: (i) S. meliloti putA gene is not catabolite repressed, and (ii) the gene encoding for the major proline permease (putP) does not form part of an operon with the putA gene.

Homing of a bacterial group II intron with an intron-encoded protein lacking a recognizable endonuclease domain

RmInt1 is a functional group II intron found in Sinorhizobium meliloti where it interrupts a group of IS elements of the IS630-Tc1 family. In contrast to many other group II introns, the intron-encoded protein (IEP) of RmInt1 lacks the characteristic conserved part of the Zn domain associated with the IEP endonuclease activity. Nevertheless, in this study, we show that RmInt1 is capable of inserting into a vector containing the DNA spanning the RmInt1 target site from the genome of S. meliloti. Efficient homing was also observed in the absence of homologous recombination (RecA- strains). In addition, it is shown that RmInt1 is able to move to its target in a heterologous host (S. medicae). Homing of RmInt1 occurs very efficiently upon DNA target uptake (conjugation/electroporation) by the host cell resulting in a proportion of invaded target of 11-30%. Afterwards, the remaining intronless target DNA is protected from intron invasion.

The Sinorhizobium meliloti insertion sequence (IS) elements ISRm102F34-1/ISRm7 and ISRm220-13-5 belong to a new family of insertion sequence elements

The Sinorhizobium meliloti insertion sequence (IS) elements ISRm102F34-1 and ISRm220-13-5 are 1481 and 1550 base pairs (bp) in size, respectively. ISRm102F34-1 is bordered by 15 bp imperfect terminal inverted repeat sequences (two mismatches), whereas the terminal inverted repeat of ISRm220-13-5 has a length of 16 bp (two mismatches). Both insertion sequence elements generate a 6-bp target duplication upon transposition. The putative transposase enzymes of ISRm102F34-1 and ISRm220-13-5 consist of 449 or 448 amino acid residues with predicted molecular weights of 50.7 or 51.3 kDa and theoretical isoelectric points of 10.8 or 11.1, respectively. ISRm102F34-1 is identical in 98.9% of its nucleotide sequence to an apparently inactive copy of an insertion sequence element, designated ISRm7, which flanks the left-end of the nodule formation efficiency (nfe) region of plasmid pRmeGR4b of S. meliloti strain GR4. ISRm102F34-1 and ISRm220-13-5 are closely related since they show an overall identity of 57.0% at the nucleotide sequence level and of 47.3% at the deduced amino acid level of their putative transposases. Both insertion sequence elements displayed significant similarity to the Xanthomonas campestris ISXc6 and its homolog IS1478a. Since none of these insertion sequence elements could be allocated to existing families of insertion sequence elements, a new family is proposed. Analysis of the distribution of ISRm102F34-1/ISRm7 in various local S. meliloti populations sampled from Medicago sativa, Medicago sphaerocarpa and Melilotus alba host plants at different locations in Spain revealed its presence in 35% of the isolates with a copy number ranging from 1 to 5. Furthermore, ISRm102F34-1/ISRm7 homologs were identified in other rhizobial species.

Multicopy vectors carrying the Klebsiella pneumoniae nifA gene do not enhance the nodulation competitiveness of Sinorhizobium meliloti on alfalfa

It has been reported that Sinorhizobium meliloti strains harboring IncQ and IncP multicopy vectors containing constitutively expressed Klebsiella pneumoniae nifA exhibit an increase in nodulation competitiveness on alfalfa (J. Sanjuan and J. Olivares, Mol. Plant-Microbe Interact. 4:365-369, 1991). In our efforts to understand the mechanisms involved, in this work, we have found that the observed enhancement on nodulation competitiveness by IncQ derivatives carrying K. pneumoniae nifA was not dependent on the plasmid-borne nifA activity but on the sensitivity of nonresistant strains to the streptomycin carried over from growth cultures. Furthermore, it was also determined that the nifA of K. pneumoniae on an IncP vector does not have an effect on competitiveness.

Characterization and splicing in vivo of a Sinorhizobium meliloti group II intron associated with particular insertion sequences of the IS630-Tc1/IS3 retroposon superfamily

By sequence analysis of Sinorhizobium meliloti strain GR4 plasmid pRmeGR4b, we have identified a group II intron named RmInt1 inserted within the insertion sequence ISRm2011-2 of the IS630-Tc1/IS3 retroposon superfamily. Like some other group II introns, RmInt1 possesses, in addition to the structurally conserved ribozyme core, an open reading frame (ORF) with homology to reverse transcriptases. Using a T7 expression system in Escherichia coli, we show that the intron is active in splicing in vivo and that splicing efficiency requires the intron-encoded ORF, which suggests that the putative intron encoded protein has a maturase function. DNA hybridization studies indicate that intron RmInt1 is widespread within S. meliloti native populations and appears to be mostly located within this IS element. Nevertheless, some S. meliloti strains harbour one copy of RmInt1 at a different location. DNA sequence analysis of the 5' exon of one of these heterologous intron insertion sites revealed the presence of a putative IS element closely related to insertion sequence ISRm2011-2. The intron-binding sites (IBS1 and IBS2 motifs) are conserved, although a transition of a G-->A in the IBS1 has occurred. Our results demonstrate an association of intron RmInt1 with particular insertion sequences of the IS630-Tc1/IS3 retroposon superfamily that may have ensured the spread and maintenance of this group II intron in S. meliloti.

ISRm4-1 and ISRm9, two novel insertion sequences from Sinorhizobium meliloti

Two novel insertion sequences, ISRm4-1 and ISRm9 have been identified in Sinorhizobium meliloti. ISRm4-1 is 936-bp in length, flanked by 17-bp putative terminal inverted repeats and a putative target duplication of 3-bp. ISRm4-1 is a member of the IS5 family of insertion sequences, closely related to ISRm4. ISRm9 is 2797-bp in length and carries 25-bp inverted repeats with target duplication of 7-bp: ISRm9 belongs to the IS21 family of insertion elements. On the non-pSym plasmid pRmeGR4b from S. meliloti strain GR4, a copy of ISRm4-1 is interrupted at nucleotide 150 from its 5'-end by a copy of ISRm9. Whereas ISRm4-like elements are widespread in S. meliloti, the distribution of ISRm9 appears to be correlated to that of pRmeGR4b-type plasmids.

A new insertion sequence from Sinorhizobium meliloti with homology to IS1357 from Methylobacterium sp. and IS1452 from Acetobacter pasteurianus

The insertion sequence ISRm8 was identified by sequence analysis of the cryptic plasmid pRmeGR4b of Sinorhizobium meliloti GR4. ISRm8 is 1451 bp in length and carries 22/24-bp terminal imperfect inverted repeats with seven mismatches and a direct target site duplication of 3 bp. ISRm8 carries a unique open reading frame whose putative protein showed significant similarity to the insertion sequences IS1357 and IS1452, isolated from Methylobacterium sp. and Acetobacter pasteurianus, respectively. Two copies of this IS element were found in strain GR4; one of them is linked to plasmid pRmeGR4b, whereas the other is localized out of the non-pSym plasmids. In S. meliloti field populations ISRm8 shows a limited distribution (50% of the strains tested carry the IS element), with a copy number ranging from 1 to 6.

The Rhizobium meliloti putA gene: its role in the establishment of the symbiotic interaction with alfalfa

Little is known about the energy sources used by rhizobia during colonization, invasion and root nodule formation on leguminous plants. We have recently reported that an impaired proline metabolism in rhizobium meliloti leads to a reduced nodulation efficiency and competitiveness on alfalfa roots. In the present study we have characterized the R. meliloti proline dehydrogenase gene (putA) and addressed the question of its role in symbiosis. This rhizobial gene encodes a 1224-amino-acid-long polypeptide which is homologous to enteric bacteria, Rhodobacter capsulatus and Bradyrhizobium japonicum PutA proteins. Like the situation in these bacteria, sequence analysis identified the proline dehydrogenase (PDH) and pyrroline-5-carboxylate dehydrogenase (P5CDH) domains in the R. meliloti putA-encoded protein. Beta-galactosidase assays performed with free-living cells carrying a putA-lacZ transcriptional fusion revealed that R. meliloti putA gene expression is induced by proline, autoregulated by its encoded product, and independent of the general nitrogen regulatory system (Ntr). In addition, analysis of putA expression during the different steps of the symbiotic interaction with alfalfa showed that expression of this gene is turned on by the root exudates (RE), during root invasion and nodule formation, but not in differentiated nitrogen-fixing bacteroids. Furthermore, we show that the PutA- phenotype leads to a significant reduction of alfalfa root colonization by R. meliloti.

Identification and distribution of plasmid-type A replicator region in rhizobia

Sinorhizobium meliloti strain GR4 harbors two cryptic plasmids, named pRmeGR4a and pRmeGR4b in addition to the symbiotic megaplasmids. The replicator region of plasmid pRmeGR4a has been recently cloned and sequenced. By DNA hybridization, homology to former replicator region was found on plasmid pRmeGR4b as well as on other plasmids harbored by S. meliloti and S. fredii strains. In these former bacteria, a PCR product of 362 bp was generated using pRmeGR4a-repC derived primers (C1 and C2). DNA sequence analysis showed that the amplified repC fragments were closely related being classified into two subgroups designated A(I) and A(II). Similarly, a PCR product of 482 bp was obtained when primers (C3 and C5) derived from pRmeGR4a repC-upstream non-coding DNA region (IR) were used. DNA sequence analysis of the corresponding amplified products showed that, as occurs, with repC the IRs were also conserved. In addition, we designed a set of primers (P2/P4), derived from the S. meliloti and S. fredii consensus sequence encompassing the IRs and repC loci, that are able to recognize homologous plasmid-type A replicator regions in Rhizobium. By using these primers, we determined that the former replicator region is widespread in S. meliloti indigenous populations and that its frequency within the infective isolates depends on the host plant. Furthermore, it is shown that the replicator region type A is linked to cryptic plasmids in S. meliloti and S. fredii, whereas it is located in the pSym of R. tropici strains.

Identification and nucleotide sequence of Rhizobium meliloti insertion sequence ISRm6, a small transposable element that belongs to the IS3 family

The insertion sequence ISRm6 is a small transposable element identified in Rhizobium meliloti strain GR4 by sequence analysis. Two copies of this IS element were found in strain GR4, one of them is linked to the nfe genes located on plasmid pRmeGR4b. ISRm6 seems to be widespread in R. meliloti. Data suggest that ISRm6 is active in transposition at an estimated frequency of 2 x 10(-5) per generation per cell in strain GR4. This 1269-bp element carries 27/26-bp terminal imperfect inverted repeats with six mismatches and a direct target site duplication of 4 bp. The IR terminate with the dinucleotide 5'-TG as all the members of the IS3 family. In addition, as other IS belonging to the IS3 family, ISRm6 carries two open reading frames (ORFA and ORFB) with a characteristic translational frame-shifting window in the overlapping region. Furthermore, ISRm6 putative transposase contains the triad of amino acids called DDE motif. Comparison of the ISRm6 DNA sequence and the putative proteins encoded with sequences derived from the EMBL, GenBank, PIR and Swissprot databases showed significant similarity to IS that belongs to the IS3 family with a highest homology to a subclass containing IS476 from Xanthomonas campestris, IS407 from Burkholderia cepacia, and ISR1 from Rhizobium lupini.

The insertion sequence element ISRm2011-2 belongs to the IS630-Tc1 family of transposable elements and is abundant in Rhizobium meliloti

The insertion sequence (IS) element ISRm2011-2 of Rhizobium meliloti (Rm) is characterized by 19-bp imperfect terminal inverted repeats (three mismatches) and a size of 1053 bp. Upon transposition, ISRm2011-2 generates a putative target duplication of 2 bp. ISRm2011-2 carries two major overlapping open reading frames (ORFA and B) with a coding capacity of 135 and 201 amino acids (aa), respectively. A potential translational frameshifting window (5'-AAAAAAAG) is located in the overlapping region of both ORFs. The putative fusion product of both proteins, which probably represents the mature transposase, has a predicted molecular mass of 35.8 kDa and a pI of 10.5. Comparison of the deduced aa sequence of ORFA with database entries revealed homology to putative transposases of some IS elements of the IS3 family, as well as to eukaryotic transcription factors. The protein encoded by ORFB shows homology to transposases (Tps) of the recently proposed IS630-Tc1 family which includes Tps of both prokaryotic and eukaryotic transposable elements. Analyses of the distribution of ISRm2011-2 in natural Rm populations showed that this IS element is abundant in Rm strains.

Characterization of a Rhizobium meliloti proline dehydrogenase mutant altered in nodulation efficiency and competitiveness on alfalfa roots

Rhizobium meliloti strain GRM8 is able to transform ornithine into proline by means of an ornithine cyclodeaminase and, therefore, has the ability to use either of these amino acids as its sole carbon and nitrogen source. By Tn5 insertion mutagenesis we obtained a GRM8 mutant derivative strain (LM1) unable to catabolize either ornithine or proline. DNA hybridization studies showed that the LM1 mutant carries a single Tn5 insertion within a chromosomally located gene that, as deduced from a partial nucleotide sequence, encodes a proline dehydrogenase (ProDH). Enzymatic assays confirmed the lack of ProDH activity in cell extracts of strain LM1 and revealed that production of this enzyme is inducible in the parental strain by proline and ornithine. Ultrastructural nodule microscopy analysis, acetylene reduction assays, and dry-weight determinations of nodulated alfalfa plants showed no obvious defect in the nitrogen fixation process of the ProDH- mutant LM1. However, nodulation tests and competition assays demonstrated that in R. meliloti ProDH is required for nodulation efficiency and competitiveness on alfalfa roots.

Surface polysaccharide mutants of Rhizobium sp. (Acacia) strain GRH2: major requirement of lipopolysaccharide for successful invasion of Acacia nodules and host range determination

Two transposon Tn5-induced mutants of wild-type broad-host-range Rhizobium sp. GRH2 were isolated and found to harbour different alterations in surface polysaccharides. These mutants, designated GRH2-14 and GRH2-50, induced a few, empty nodules on Acacia and lost the ability to nodulate most host herbaceous legumes. Whereas mutant GRH2-14 produces an acidic exopolysaccharide (EPS) similar to the wild-type, the acidic EPS of mutant GRH2-50 lacks galactose and the pyruvyl and 3-hydroxybutyryl substituents attached to this sugar moiety. In addition, both mutants GRH2-50 and GRH2-14 were altered in smooth lipopolysaccharides (LPS). DNA sequence analyses of the corresponding Tn5 insertions revealed that strain GRH2-50 was mutated in a DNA locus homologous to galE, and in vitro enzyme assays indicated that the UDPglucose 4-epimerase (GalE) activity was missing in this mutant strain. DNA hybridization studies showed that the GRH2-50 mutant DNA has homologous sequences within the different biovars of Rhizobium leguminosarum. However, no DNA homology to GRH2-14 altered DNA was found in those rhizobial strains, indicating that it represents a new chromosomal lps locus in Rhizobium sp. (Acacia) involved in symbiotic development.

Identification of a novel Rhizobium meliloti nodulation efficiency nfe gene homolog of Agrobacterium ornithine cyclodeaminase

The nfe genes located on the large plasmid pRmeGR4b are involved in the nodulation efficiency and competitiveness of Rhizobium meliloti GR4 on alfalfa roots. One hundred twenty-eight base-pairs downstream of nfe2 gene we found an open reading frame designated ORFC, 970 bp long and potentially coding for a 320 amino acid long protein. The amino acid sequence of the putatively encoded ORFC product shows similarity with ornithine cyclodeaminase (OCD) of Agrobacterium tumefaciens an unusual enzyme that converts ornithine into proline. The gene product of ORFC was identified as a 37-kDa protein by in vitro-coupled transcription-translation and in vivo by the T7 RNA polymerase/promoter system. DNA hybridization studies showed that strain GR4 carries a single copy of the ocd-like gene. No homologous sequences to GR4 ORFC DNA were found in other R. meliloti strains or Rhizobium spp. assayed. Furthermore, a GR4 derivative mutant obtained by plasmid disruption of ORFC showed an impaired nodulation efficiency as compared to that of the wild-type strain GR4. Thus, the former locus should be considered a novel nfe gene. We propose to rename the nfe genes, nfe1, 2 and ORFC as nfeA, B, and D, respectively.

Characterization and symbiotic importance of acidic extracellular polysaccharides of Rhizobium sp. strain GRH2 isolated from acacia nodules

Rhizobium sp. wild-type strain GRH2 was originally isolated from root nodules of the leguminous tree Acacia cyanophylla and has a broad host range which includes herbaceous legumes, e.g., Trifolium spp. We examined the extracellular exopolysaccharides (EPSs) produced by strain GRH2 and found three independent glycosidic structures: a high-molecular-weight acidic heteropolysaccharide which is very similar to the acidic EPS produced by Rhizobium leguminosarum biovar trifolii ANU843, a low-molecular-weight native heterooligosaccharide resembling a dimer of the repeat unit of the high-molecular-weight EPS, and low-molecular-weight neutral beta (1,2)-glucans. A Tn5 insertion mutant derivative of GRH2 (exo-57) that fails to form acidic heteropolysaccharides was obtained. This Exo- mutant formed nitrogen-fixing nodules on Acacia plants but infected a smaller proportion of cells in the central zone of the nodules than did wild-type GRH2. In addition, the exo-57 mutant failed to nodulate several herbaceous legume hosts that are nodulated by wild-type strain GRH2.

Nucleotide sequence and characterization of Rhizobium meliloti nodulation competitiveness genes nfe

Rhizobium meliloti large plasmid pRmeGR4b carries the nodulation competitiveness locus nfe responsible for the nodulation efficiency and competitive ability of strain GR4 on alfalfa roots. We report here the nucleotide sequence and characterization of a 3345 base-pair DNA section of the nfe region. Sequence analysis revealed four open reading frames (ORFs), two of them with rightward polarity, termed nfe1 and nfe2, are preceded by functional nif consensus sequences and NifA-binding motifs. An additional, NifA-independent, transcriptional start site for nfe1 was also found. Two other ORFs with leftward polarity, designated ORFA and ORFB, were identified upstream from nfe1 and nfe2 but no nif consensus sequences were found. However, expression of ORFA might be indirectly coupled to the NifA-NtrA regulatory network. The gene products of nfe1 and nfe2 were identified using in vitro transcription/translation and bacteriophage T7 RNA polymerase/promoter system, respectively. A high degree of homology between the amino terminal domain of Nfe1 and the nifH gene product was found. In addition, nfe1 shows homology with the upstream non-coding DNA region of the fixABCX operon. Furthermore, the putative ORFB encoded protein contains a helix-turn-helix motif that resembles the DNA-binding consensus sequence proposed for many prokaryotic regulatory proteins.

Sequence of ISRm4 from Rhizobium meliloti strain GR4

ISRm4, an IS-like sequence structurally similar to Pseudomonas cepacia insertion element IS402, was identified by sequence analysis. This 933-bp element carries 17-bp putative terminal inverted repeats with five mismatches and a putative direct target duplication of 3 bp.

The Agrobacterium tumefaciens virC1 gene product binds to overdrive, a T-DNA transfer enhancer

In Agrobacterium tumefaciens, a cis-active 24-base-pair sequence adjacent to the right border of the T-DNA, called overdrive, stimulates tumor formation by increasing the level of T-DNA processing. Recent results from our laboratory have suggested that the virC operon which enhances T-DNA processing probably does so because the VirC1 protein interacts with overdrive (N. Toro, A. Datta, M. Yanofsky, and E. W. Nester, Proc. Natl. Acad. Sci. USA 85:8558-8562, 1988). We report here the purification of the VirC1 protein from cells of Escherichia coli harboring a plasmid containing the coding sequences of the virC locus of the octopine Ti plasmid. By gel mobility shift and DNase I footprinting assays, we showed that this purified virC1 gene product binds to overdrive but not to the right border of T-DNA.

Role of the overdrive sequence in T-DNA border cleavage in Agrobacterium

The T-DNA of the Ti plasmid of Agrobacterium is flanked by 25-base-pair imperfect direct repeats that are required in cis for transfer to the genome of the plant host. Another sequence, designated overdrive, is located adjacent to the right-border repeats and functions in cis to enhance tumor formation. We have examined the effect of the overdrive sequence on the early steps in T-DNA processing. We report here that overdrive greatly enhances cleavage by the site-specific endonuclease in Agrobacterium, perhaps by directing the endonuclease to the adjacent border sequences. We also show by a gel mobility-shift assay that overdrive affinity-purified proteins from acetosyringone-induced Agrobacterium cells interact with T-DNA border and overdrive sequences. Further, we show that in vivo the virC operon enhances cleavage at the T-DNA borders, most likely by interaction between the VirC1 protein and the overdrive sequence.

A Rhizobium meliloti mutant that forms ineffective pseudonodules in alfalfa produces exopolysaccharide but fails to form beta-(1----2) glucan

A mutant of Rhizobium meliloti that elicited the formation of inactive nodules in alfalfa was found not to form beta-(1----2) glucan in vivo or in vitro. It was nonmotile because it lacks flagella. The 235-kilodalton protein which acts as an intermediate in beta-(1----2) glucan synthesis was undetectable in the mutant. These properties of the mutant are common to those of chvB mutants of Agrobacterium tumefaciens. Exopolysaccharide formation by the R. meliloti mutant was about double that by the wild type.