Exon sequence requirements for excision in vivo of the bacterial group II intron RmInt1

<p>Abstract</p> <p>Background</p> <p>Group II intron splicing proceeds through two sequential transesterification reactions in which the 5' and 3'-exons are joined together and the lariat intron is released. The intron-encoded protein (IEP) assists the splicing of the intron <it>in vivo </it>and remains bound to the excised intron lariat RNA in a ribonucleoprotein particle (RNP) that promotes intron mobility. Exon recognition occurs through base-pairing interactions between two guide sequences on the ribozyme domain dI known as EBS1 and EBS2 and two stretches of sequence known as IBS1 and IBS2 on the 5' exon, whereas the 3' exon is recognized through interaction with the sequence immediately upstream from EBS1 [(δ-δ' interaction (subgroup IIA)] or with a nucleotide [(EBS3-IBS3 interaction (subgroup IIB and IIC))] located in the coordination-loop of dI. The δ nucleotide is involved in base pairing with another intron residue (δ') in subgroup IIB introns and this interaction facilitates base pairing between the 5' exon and the intron.</p> <p>Results</p> <p>In this study, we investigated nucleotide requirements in the distal 5'- and 3' exon regions, EBS-IBS interactions and δ-δ' pairing for excision of the group IIB intron RmInt1 <it>in vivo</it>. We found that the EBS1-IBS1 interaction was required and sufficient for RmInt1 excision. In addition, we provide evidence for the occurrence of canonical δ-δ' pairing and its importance for the intron excision <it>in vivo.</it></p> <p>Conclusions</p> <p>The excision <it>in vivo </it>of the RmInt1 intron is a favored process, with very few constraints for sequence recognition in both the 5' and 3'-exons. Our results contribute to understand how group II introns spread in nature, and might facilitate the use of RmInt1 in gene targeting.</p

Role of Rhizobium endoglucanase CelC2 in cellulose biosynthesis and biofilm formation on plant roots and abiotic surfaces

Background: The synthesis of cellulose is among the most important but poorly understood biochemical processes, especially in bacteria, due to its complexity and high degree of regulation. In this study, we analyzed both the production of cellulose by all known members of the Rhizobiaceae and the diversity of Rhizobium celABC operon predicted to be involved in cellulose biosynthesis. We also investigated the involvement in cellulose production and biofilm formation of celC gene encoding an endoglucanase (CelC2) that is required for canonical symbiotic root hair infection by Rhizobium leguminosarum bv. trifolii.Results: ANU843 celC mutants lacking (ANU843ΔC2) or overproducing cellulase (ANU843C2+) produced greatly increased or reduced amounts of external cellulose micro fibrils, respectively. Calcofluor-stained cellulose micro fibrils were considerably longer when formed by ANU843ΔC2 bacteria rather than by the wild-type strain, in correlation with a significant increase in their flocculation in batch culture. In contrast, neither calcofluor-stained extracellular micro fibrils nor flocculation was detectable in ANU843C2+cells. To clarify the role of cellulose synthesis in Rhizobium cell aggregation and attachment, we analyzed the ability of these mutants to produce biofilms on different surfaces. Alteration of wild-type CelC2 levels resulted in a reduced ability of bacteria to form biofilms both in abiotic surfaces and in planta.Conclusions: Our results support a key role of the CelC2 cellulase in cellulose biosynthesis by modulating the length of the cellulose fibrils that mediate firm adhesion among Rhizobium bacteria leading to biofilm formation. Rhizobium cellulose is an essential component of the biofilm polysaccharidic matrix architecture and either an excess or a defect of this " building material" seem to collapse the biofilm structure. These results position cellulose hydrolytic enzymes as excellent anti-biofilm candidates. © 2012 Robledo et al.; licensee BioMed Central Ltd

Wide-range transcriptional modulating effect of ntrR under microaerobiosis in Sinorhizobium meliloti

Puskas LG, Nagy ZB, Kelemen JZ, et al. Wide-range transcriptional modulating effect of ntrR under microaerobiosis in Sinorhizobium meliloti. MOLECULAR GENETICS AND GENOMICS. 2004;272(3):275-289.A mutation in the second gene in the ntrPR operon results in increased expression of nodulation (nod) and nitrogen fixation (nif) genes in Sinorhizobium meliloti. Since this pleiotropic effect is particularly pronounced in the presence of external combined nitrogen, a nitrogen regulatory function has been suggested for NtrR. To identify the complete set of protein-coding genes influenced by loss of ntrR function, microarray hybridizations were carried out to compare transcript levels in the wild type and mutant strains grown under aerobic and microaerobic conditions. Of the 6207 genes examined, representing the entire genome of S. meliloti, 7% exhibited altered expression: 4.5% of the genes are affected under oxic, 2.5% under microoxic conditions. 0.4% of all the genes are affected under both oxygen concentrations. A microoxic environment is required for the induction of genes related to symbiotic functions but results in the down-regulation of other (e.g. metabolic) functions. When the alterations in transcription levels at low oxygen concentration in the mutant strain were compared to those of the wild type, a modulating effect of the ntrR mutation was observed. For example, symbiotic nif/fix genes were induced in both strains, but the level of induction was higher in the ntrR mutant. In contrast, genes related to transcription/translation functions were down-regulated in both strains, and the effect was greater in the wild-type strain than in the ntrR mutant. A relatively wide range of functions was affected by this modulating influence, suggesting that ntrR is not a nitrogen regulatory gene. Since genes encoding various unrelated functions were affected, we propose that NtrR may either interfere with general regulatory mechanisms, such as phosphorylation/dephosphorylation, or may influence RNA stability