Fernando M. García-Rodríguez

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 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.

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.

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.

Use of RmInt1, a group IIB intron lacking the intron-encoded protein endonuclease domain, in gene targeting.

ABSTRACT The group IIA intron Ll.LtrB from Lactococcus lactis and the group IIB intron EcI5 from Escherichia coli have intron-encoded proteins (IEP) with a DNA-binding domain (D) and an endonuclease domain (En). Both have been successfully retargeted to invade target DNAs other than their wild-type target sites. RmInt1, a subclass IIB3/D intron with an IEP lacking D and En domains, is highly active in retrohoming in its host, Sinorhizobium meliloti. We found that RmInt1 was also mobile in E. coli and that retrohoming in this heterologous host depended on temperature, being more efficient at 28°C than at 37°C. Furthermore, we programmed RmInt1 to recognize target sites other than its wild-type site. These retargeted introns efficiently and specifically retrohome into a recipient plasmid target site or a target site present as a single copy in the chromosome, generating a mutation in the targeted gene. Our results extend the range of group II introns available for gene targeting.

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

Abstract. 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 β-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.

Use of the computer-retargeted group II intron RmInt1 of Sinorhizobium meliloti for gene targeting.

Gene-targeting vectors derived from mobile group II introns capable of forming a ribonucleoprotein (RNP) complex containing excised intron lariat RNA and an intron-encoded protein (IEP) with reverse transcriptase (RT), maturase, and endonuclease (En) activities have been described. RmInt1 is an efficient mobile group II intron with an IEP lacking the En domain. We performed a comprehensive study of the rules governing RmInt1 target site recognition based on selection experiments with donor and recipient plasmid libraries, with randomization of the elements of the intron RNA involved in target recognition and the wild-type target site. The data obtained were used to develop a computer algorithm for identifying potential RmInt1 targets in any DNA sequence. Using this algorithm, we modified RmInt1 for the efficient recognition of DNA target sites at different locations in the Sinorhizobium meliloti chromosome. The retargeted RmInt1 integrated efficiently into the chromosome, regardless of the location of the target gene. Our results suggest that RmInt1 could be efficiently adapted for gene targeting.

Functionality of In vitro Reconstituted Group II Intron RmInt1-Derived Ribonucleoprotein Particles

The functional unit of mobile group II introns is a ribonucleoprotein particle (RNP) consisting of the intron-encoded protein (IEP) and the excised intron RNA. The IEP has reverse transcriptase activity but also promotes RNA splicing, and the RNA-protein complex triggers site-specific DNA insertion by reverse splicing, in a process called retrohoming. In vitro reconstituted ribonucleoprotein complexes from the Lactococcus lactis group II intron Ll.LtrB, which produce a double strand break, have recently been studied as a means of developing group II intron-based gene targeting methods for higher organisms. The Sinorhizobium meliloti group II intron RmInt1 is an efficient mobile retroelement, the dispersal of which appears to be linked to transient single-stranded DNA during replication. The RmInt1IEP lacks the endonuclease domain (En) and cannot cut the bottom strand to generate the 3′ end to initiate reverse transcription. We used an Escherichia coli expression system to produce soluble and active RmInt1 IEP and reconstituted RNPs with purified components in vitro. The RNPs generated were functional and reverse-spliced into a single-stranded DNA target. This work constitutes the starting point for the use of group II introns lacking DNA endonuclease domain-derived RNPs for highly specific gene targeting methods.

Localization of a bacterial group II intron-encoded protein in human cells

Group II introns are mobile retroelements that self-splice from precursor RNAs to form ribonucleoparticles (RNP), which can invade new specific genomic DNA sites. This specificity can be reprogrammed, for insertion into any desired DNA site, making these introns useful tools for bacterial genetic engineering. However, previous studies have suggested that these elements may function inefficiently in eukaryotes. We investigated the subcellular distribution, in cultured human cells, of the protein encoded by the group II intron RmInt1 (IEP) and several mutants. We created fusions with yellow fluorescent protein (YFP) and with a FLAG epitope. We found that the IEP was localized in the nucleus and nucleolus of the cells. Remarkably, it also accumulated at the periphery of the nuclear matrix. We were also able to identify spliced lariat intron RNA, which co-immunoprecipitated with the IEP, suggesting that functional RmInt1 RNPs can be assembled in cultured human cells.

Intron Biology, Focusing on Group II Introns, the Ancestors of Spliceosomal Introns

Self-splicing group II introns are large ribozymes and mobile retroelements initially identified in the mitochondrial and chloroplast genomes of lower eukaryotes and plants and subsequently found in bacteria and archaea. Group II introns display structural, functional and mechanistic similarities to eukaryotic pre-mRNA nuclear introns, which may have evolved from mobile group II introns. As in spliceosomal introns, the ribozyme of group II introns excises the intron as a branched, lariat structure, through two sequential transesterification reactions. The movement of group II introns is mediated by a ribonucleoprotein (RNP) complex consisting of the IEP encoded by the ORF and the spliced intron lariat RNA, which remains associated with the IEP. These RNP complexes recognize intron targets through both the IEP and the intron lariat RNA. New possibilities for the use of these introns as biotechnological tools are emerging, due to the small number and flexibility of interactions between IEPs and target sites, through the modification of the intron RNA motifs that recognize DNA target sites by base pairing.