A group II intron has invaded the genus Azotobacter and is inserted within the termination codon of the essential groEL gene

Categorizing 161 plant (streptophyte) mitochondrial group II introns into 29 families of related paralogues finds only limited links between intron mobility and intron-borne maturases

Group II introns are common in the two endosymbiotic organelle genomes of the plant lineage. Chloroplasts harbor 22 positionally conserved group II introns whereas their occurrence in land plant (embryophyte) mitogenomes is highly variable and specific for the seven major clades: liverworts, mosses, hornworts, lycophytes, ferns, gymnosperms and flowering plants. Each plant group features "signature selections" of ca. 20-30 paralogues from a superset of altogether 105 group II introns meantime identified in embryophyte mtDNAs, suggesting massive intron gains and losses along the backbone of plant phylogeny. We report on systematically categorizing plant mitochondrial group II introns into "families", comprising evidently related paralogues at different insertion sites, which may even be more similar than their respective orthologues in phylogenetically distant taxa. Including streptophyte (charophyte) algae extends our sampling to 161 and we sort 104 streptophyte mitochondrial group II introns into 25 core families of related paralogues evidently arising from retrotransposition events. Adding to discoveries of only recently created intron paralogues, hypermobile introns and twintrons, our survey led to further discoveries including previously overlooked "fossil" introns in spacer regions or e.g., in the rps8 pseudogene of lycophytes. Initially excluding intron-borne maturase sequences for family categorization, we added an independent analysis of maturase phylogenies and find a surprising incongruence between intron mobility and the presence of intron-borne maturases. Intriguingly, however, we find that several examples of nuclear splicing factors meantime characterized simultaneously facilitate splicing of independent paralogues now placed into the same intron families. Altogether this suggests that plant group II intron mobility, in contrast to their bacterial counterparts, is not intimately linked to intron-encoded maturases.

U5 snRNA Interactions With Exons Ensure Splicing Precision

Imperfect conservation of human pre-mRNA splice sites is necessary to produce alternative isoforms. This flexibility is combined with the precision of the message reading frame. Apart from intron-termini GU_AG and the branchpoint A, the most conserved are the exon-end guanine and +5G of the intron start. Association between these guanines cannot be explained solely by base-pairing with U1 snRNA in the early spliceosome complex. U6 succeeds U1 and pairs +5G in the pre-catalytic spliceosome, while U5 binds the exon end. Current U5 snRNA reconstructions by CryoEM cannot explain the conservation of the exon-end G. Conversely, human mutation analyses show that guanines of both exon termini can suppress splicing mutations. Our U5 hypothesis explains the mechanism of splicing precision and the role of these conserved guanines in the pre-catalytic spliceosome. We propose: (1) optimal binding register for human exons and U5-the exon junction positioned at U5Loop1 C₃₉|C₃₈; (2) common mechanism for base-pairing of human U5 snRNA with diverse exons and bacterial Ll.LtrB intron with new loci in retrotransposition-guided by base pair geometry; and (3) U5 plays a significant role in specific exon recognition in the pre-catalytic spliceosome. Statistical analyses showed increased U5 Watson-Crick pairs with the 5'exon in the absence of +5G at the intron start. In 5'exon positions -3 and -5, this effect is specific to U5 snRNA rather than U1 snRNA of the early spliceosome. Increased U5 Watson-Crick pairs with 3'exon position +1 coincide with substitutions of the conserved -3C at the intron 3'end. Based on mutation and X-ray evidence, we propose that -3C pairs with U2 G₃₁ juxtaposing the branchpoint and the 3'intron end. The intron-termini pair, formed in the pre-catalytic spliceosome to be ready for transition after branching, and the early involvement of the 3'intron end ensure that the 3'exon contacts U5 in the pre-catalytic complex. We suggest that splicing precision is safeguarded cooperatively by U5, U6, and U2 snRNAs that stabilize the pre-catalytic complex by Watson-Crick base pairing. In addition, our new U5 model explains the splicing effect of exon-start +1G mutations: U5 Watson-Crick pairs with exon +2C/+3G strongly promote exon inclusion. We discuss potential applications for snRNA therapeutics and gene repair by reverse splicing.

Bacterial Group II Intron Genomic Neighborhoods Reflect Survival Strategies: Hiding and Hijacking

Group II (gII) introns are mobile retroelements that can spread to new DNA sites through retrotransposition, which can be influenced by a variety of host factors. To determine if these host factors bear any relationship to the genomic location of gII introns, we developed a bioinformatic pipeline wherein we focused on the genomic neighborhoods of bacterial gII introns within their native contexts and sought to determine global relationships between introns and their surrounding genes. We found that, although gII introns inhabit diverse regions, these neighborhoods are often functionally enriched for genes that could promote gII intron retention or proliferation. On one hand, we observe that gII introns are frequently found hiding in mobile elements or after transcription terminators. On the other hand, gII introns are enriched in locations in which they could hijack host functions for their movement, potentially timing expression of the intron with genes that produce favorable conditions for retrotransposition. Thus, we propose that gII intron distributions have been shaped by relationships with their surrounding genomic neighbors.

The mechanism of splicing as told by group II introns: Ancestors of the spliceosome

Spliceosomal introns and self-splicing group II introns share a common mechanism of intron splicing where two sequential transesterification reactions remove intron lariats and ligate exons. The recent revolution in cryo-electron microscopy (cryo-EM) has allowed visualization of the spliceosome's ribozyme core. Comparison of these cryo-EM structures to recent group II intron crystal structures presents an opportunity to draw parallels between the RNA active site, substrate positioning, and product formation in these two model systems of intron splicing. In addition to shared RNA architectural features, structural similarity between group II intron encoded proteins (IEPs) and the integral spliceosomal protein Prp8 further support a shared catalytic core. These mechanistic and structural similarities support the long-held assertion that group II introns and the eukaryotic spliceosome have a common evolutionary origin. In this review, we discuss how recent structural insights into group II introns and the spliceosome facilitate the chemistry of splicing, highlight similarities between the two systems, and discuss their likely evolutionary connections. This article is part of a Special Issue entitled: RNA structure and splicing regulation edited by Francisco Baralle, Ravindra Singh and Stefan Stamm.

Mobile Group II Introns as Ancestral Eukaryotic Elements

The duality of group II introns, capable of carrying out both self-splicing and retromobility reactions, is hypothesized to have played a profound role in the evolution of eukaryotes. These introns likely provided the framework for the emergence of eukaryotic retroelements, spliceosomal introns and other key components of the spliceosome. Group II introns are found in all three domains of life and are therefore considered to be exceptionally successful mobile genetic elements. Initially identified in organellar genomes, group II introns are found in bacteria, chloroplasts, and mitochondria of plants and fungi, but not in nuclear genomes. Although there is no doubt that prokaryotic and organellar group II introns are evolutionary related, there are remarkable differences in survival strategies between them. Furthermore, an evolutionary relationship of group II introns to eukaryotic retroelements, including telomeres, and spliceosomes is unmistakable.

Activating the branch-forming splicing pathway by reengineering the ribozyme component of a natural group II intron

When assayed in vitro, group IIC self-splicing introns, which target bacterial Rho-independent transcription terminators, generally fail to yield branched products during splicing despite their possessing a seemingly normal branchpoint. Starting with intron O.i.I1 from Oceanobacillus iheyensis, whose crystallographically determined structure lacks branchpoint-containing domain VI, we attempted to determine what makes this intron unfit for in vitro branch formation. A major factor was found to be the length of the helix at the base of domain VI: 4 base pairs (bp) are required for efficient branching, even though a majority of group IIC introns have a 3-bp helix. Equally important for lariat formation is the removal of interactions between ribozyme domains II and VI, which are specific to the second step of splicing. Conversely, mismatching of domain VI and its proposed first-step receptor in subdomain IC1 was found to be detrimental; these data suggest that the intron-encoded protein may promote branch formation partly by modulating the equilibrium between conformations specific to the first and second steps of splicing. As a practical application, we show that by making just two changes to the O.i.I1 ribozyme, it is possible to generate sufficient amounts of lariat intron for the latter to be purified and used in kinetic assays in which folding and reaction are uncoupled.

Multiple self-splicing introns in the 16S rRNA genes of giant sulfur bacteria

The gene encoding the small subunit rRNA serves as a prominent tool for the phylogenetic analysis and classification of Bacteria and Archaea owing to its high degree of conservation and its fundamental function in living organisms. Here we show that the 16S rRNA genes of not-yet-cultivated large sulfur bacteria, among them the largest known bacterium Thiomargarita namibiensis, regularly contain numerous self-splicing introns of variable length. The 16S rRNA genes can thus be enlarged to up to 3.5 kb. Remarkably, introns have never been identified in bacterial 16S rRNA genes before, although they are the most frequently sequenced genes today. This may be caused in part by a bias during the PCR amplification step that discriminates against longer homologs, as we show experimentally. Such length heterogeneity of 16S rRNA genes has so far never been considered when constructing 16S rRNA-based clone libraries, even though an elongation of rRNA genes due to intervening sequences has been reported previously. The detection of elongated 16S rRNA genes has profound implications for common methods in molecular ecology and may cause systematic biases in several techniques. In this study, catalyzed reporter deposition-fluorescence in situ hybridization on both ribosomes and rRNA precursor molecules as well as in vitro splicing experiments were performed and confirmed self-splicing of the introns. Accordingly, the introns do not inhibit the formation of functional ribosomes.

Alternative splicing by participation of the group II intron ORF in extremely halotolerant and alkaliphilic Oceanobacillus iheyensis

Group II introns inserted into genes often undergo splicing at unexpected sites, and participate in the transcription of host genes. We identified five copies of a group II intron, designated Oi.Int, in the genome of an extremely halotolerant and alkaliphilic bacillus, Oceanobacillus iheyensis. The Oi.Int4 differs from the Oi.Int3 at four bases. The ligated exons of the Oi.Int4 could not be detected by RT-PCR assays in vivo or in vitro although group II introns can generally self-splice in vitro without the involvement of an intron-encoded open reading frame (ORF). In the Oi.Int4 mutants with base substitutions within the ORF, ligated exons were detected by in vitro self-splicing. It was clear that the ligation of exons during splicing is affected by the sequence of the intron-encoded ORF since the splice sites corresponded to the joining sites of the intron. In addition, the mutant introns showed unexpected multiple products with alternative 5' splice sites. These findings imply that alternative 5' splicing which causes a functional change of ligated exons presumably has influenced past adaptations of O. iheyensis to various environmental changes.

Splicing of the Sinorhizobium meliloti RmInt1 group II intron provides evidence of retroelement behavior

Group II introns act as both large catalytic RNAs and mobile retroelements. They are found in organelle and bacterial genomes and are spliced via a lariat intermediate, in a mechanism similar to that of spliceosomal introns. However, their distribution and insertion patterns, particularly for bacterial group II introns, suggest that they function and behave more like retroelements than organelle introns. RmInt1 is an efficient mobile intron found within the ISRm2011-2 insertion sequence in the symbiotic bacterium Sinorhizobium meliloti. This group II intron is excised, in vivo and in vitro, as intron lariats. However, the complete splicing reaction in vivo remains to be elucidated. A lacZ reporter gene system, northern blotting and real-time reverse transcription were carried out to investigate RmInt1 splicing activity. Splicing efficiency of 0.07 ± 0.02% was recorded. These findings suggest that bacterial group II introns function more like retroelements than spliceosomal introns. Their location is consistent with a role for these introns in preventing the spread of other potentially harmful mobile elements in bacteria.

The tertiary structure of group II introns: implications for biological function and evolution

Group II introns are some of the largest ribozymes in nature, and they are a major source of information about RNA assembly and tertiary structural organization. These introns are of biological significance because they are self-splicing mobile elements that have migrated into diverse genomes and played a major role in the genomic organization and metabolism of most life forms. The tertiary structure of group II introns has been the subject of many phylogenetic, genetic, biochemical and biophysical investigations, all of which are consistent with the recent crystal structure of an intact group IIC intron from the alkaliphilic eubacterium Oceanobacillus iheyensis. The crystal structure reveals that catalytic intron domain V is enfolded within the other intronic domains through an elaborate network of diverse tertiary interactions. Within the folded core, DV adopts an activated conformation that readily binds catalytic metal ions and positions them in a manner appropriate for reaction with nucleic acid targets. The tertiary structure of the group II intron reveals new information on motifs for RNA architectural organization, mechanisms of group II intron catalysis, and the evolutionary relationships among RNA processing systems. Guided by the structure and the wealth of previous genetic and biochemical work, it is now possible to deduce the probable location of DVI and the site of additional domains that contribute to the function of the highly derived group IIB and IIA introns.

Structural and functional evolution of group II intron ribozymes: insights from unusual elements carrying a 3' extension

Group II introns are large RNA elements that interrupt genes. They are self-splicing ribozymes that catalyze their own excision and mobile retroelements that can invade new genomic DNA sites. While group II introns typically consist of six structural domains, a number of elements containing an unusual 3' extension of 53-56 nucleotides have recently been identified. Bioinformatic and functional analyses of these introns have revealed that they belong to two evolutionary subgroups and that the 3' extension has a differential effect on the splicing reactions for introns of the two subgroups, a functional difference that may be related to structural differences between the introns. In addition, there is phylogenetic evidence that some introns are mobile with their extension. The unusual introns have provided dramatic examples of the structural and functional evolution of group II ribozymes that have been able to accommodate an extra segment into their compact structure while maintaining functionality.

Structural features in the C-terminal region of the Sinorhizobium meliloti RmInt1 group II intron-encoded protein contribute to its maturase and intron DNA-insertion function

Group II introns are both catalytic RNAs and mobile retroelements that move through a process catalyzed by a RNP complex consisting of an intron-encoded protein and the spliced intron lariat RNA. Group II intron-encoded proteins are multifunctional and contain an N-terminal reverse transcriptase domain, followed by a putative RNA-binding domain (domain X) associated with RNA splicing or maturase activity and a C-terminal DNA binding/DNA endonuclease region. The intron-encoded protein encoded by the mobile group II intron RmInt1, which lacks the DNA binding/DNA endonuclease region, has only a short C-terminal extension (C-tail) after a typical domain X, apparently unrelated to the C-terminal regions of other group II intron-encoded proteins. Multiple sequence alignments identified features of the C-terminal portion of the RmInt1 intron-encoded protein that are conserved throughout evolution in the bacterial ORF class D, suggesting a group-specific functionally important protein region. The functional importance of these features was demonstrated by analyses of deletions and mutations affecting conserved amino acid residues. We found that the C-tail of the RmInt1 intron-encoded protein contributes to the maturase function of this reverse transcriptase protein. Furthermore, within the C-terminal region, we identified, in a predicted alpha-helical region and downstream, conserved residues that are specifically required for the insertion of the intron into DNA targets in the orientation that would make it possible to use the nascent leading strand as a primer. These findings suggest that these group II intron intron-encoded proteins may have adapted to function in mobility by different mechanisms to make use of either leading or lagging-oriented targets in the absence of an endonuclease domain.

Group II introns in eubacteria and archaea: ORF-less introns and new varieties

Group II introns are a major class of ribozymes found in bacteria, mitochondria, and plastids. Many introns contain reverse transcriptase open reading frames (ORFs) that confer mobility to the introns and allow them to persist as selfish DNAs. Here, we report an updated compilation of group II introns in Eubacteria and Archaea comprising 234 introns. One new phylogenetic class is identified, as well as several specialized lineages. In addition, we undertake a detailed search for ORF-less group II introns in bacterial genomes in order to find undiscovered introns that either entirely lack an ORF or encode a novel ORF. Unlike organellar group II introns, we find only a handful of ORF-less introns in bacteria, suggesting that if a substantial number exist, they must be divergent from known introns. Together, these results highlight the retroelement character of bacterial group II introns, and suggest that their long-term survival is dependent upon retromobility.

Ribozymes, riboswitches and beyond: regulation of gene expression without proteins

Although various functions of RNA are carried out in conjunction with proteins, some catalytic RNAs, or ribozymes, which contribute to a range of cellular processes, require little or no assistance from proteins. Furthermore, the discovery of metabolite-sensing riboswitches and other types of RNA sensors has revealed RNA-based mechanisms that cells use to regulate gene expression in response to internal and external changes. Structural studies have shown how these RNAs can carry out a range of functions. In addition, the contribution of ribozymes and riboswitches to gene expression is being revealed as far more widespread than was previously appreciated. These findings have implications for understanding how cellular functions might have evolved from RNA-based origins.

Specialized lineages of bacterial group II introns

The Avi.groEL intron of Azotobacter vinelandii, which interrupts the termination codon of the groEL gene, is shown to belong to a monophyletic subset of bacterial group II introns that share a large insertion at their 5' extremity and a peculiar genetic localization. Some of these introns are inserted within, right next to, or very close to, a stop codon while others are located immediately 3' of, or close to, an initiation codon. After subgroup IIC introns, which target rho-independent transcription terminators, this is the second instance of a genetically specialized lineage of bacterial group II introns. Both the members of subgroup IIC and the relatives of Avi.groEL stand in contrast against the rest of group II retrotransposons in that features other than sequence must be used in target recognition. Among other specialized characters that could unite the two subgroups are: (i) the presence, next to the 5' splice site, of conserved RNA structures incompatible with the active fold of the group II ribozyme; and (ii) the likely involvement of the ribosome in the facilitation of the splicing process.

Bacterial group II introns: not just splicing

Group II introns are both catalytic RNAs (ribozymes) and mobile retroelements that were discovered almost 14 years ago. It has been suggested that eukaryotic mRNA introns might have originated from the group II introns present in the alphaproteobacterial progenitor of the mitochondria. Bacterial group II introns are of considerable interest not only because of their evolutionary significance, but also because they could potentially be used as tools for genetic manipulation in biotechnology and for gene therapy. This review summarizes what is known about the splicing mechanisms and mobility of bacterial group II introns, and describes the recent development of group II intron-based gene-targetting methods. Bacterial group II intron diversity, evolutionary relationships, and behaviour in bacteria are also discussed.

Dispersion of the RmInt1 group II intron in the Sinorhizobium meliloti genome upon acquisition by conjugative transfer

RmInt1 is a self-splicing and mobile group II intron initially identified in the bacterium Sinorhizobium meliloti, which encodes a reverse transcriptase–maturase (Intron Encoded Protein, IEP) lacking the C-terminal DNA binding (D) and DNA endonuclease domains (En). RmInt1 invades cognate intronless homing sites (ISRm2011-2) by a mechanism known as retrohoming. This work describes how the RmInt1 intron spreads in the S.meliloti genome upon acquisition by conjugation. This process was revealed by using the wild-type intron RmInt1 and engineered intron-donor constructs based on ribozyme coding sequence (ΔORF)-derivatives with higher homing efficiency than the wild-type intron. The data demonstrate that RmInt1 propagates into the S.meliloti genome primarily by retrohoming with a strand bias related to replication of the chromosome and symbiotic megaplasmids. Moreover, we show that when expressed in trans from a separate plasmid, the IEP is able to mobilize genomic ΔORF ribozymes that afterward displayed wild-type levels of retrohoming. Our results contribute to get further understanding of how group II introns spread into bacterial genomes in nature.

Self-splicing of a group IIC intron: 5' exon recognition and alternative 5' splicing events implicate the stem-loop motif of a transcriptional terminator

Bacterial IIC introns are a newly recognized subclass of group II introns whose ribozyme properties have not been characterized in detail. IIC introns are typically located downstream of transcriptional terminator motifs (inverted repeat followed by T's) or other inverted repeats in bacterial genomes. Here we have characterized the self-splicing activity of a IIC intron, B.h.I1, from Bacillus halodurans. B.h.I1 self-splices in vitro through hydrolysis to produce linear intron, but interestingly, additional unexpected products were formed that were highly dependent on ionic conditions. These products were determined to represent alternative splicing events at the 5' junction and cleavages throughout the RNA transcript. The alternative splicing and cleavage events occurred at cryptic splice sites containing stem-loop and IBS1 motifs, suggesting that the 5' exon is recognized by both elements. These results provide the first example of a group II intron that uses 5' splice sites nonadjacent to the ribozyme structure. Furthermore, the data suggest that IIC introns differ from IIA and IIB introns with respect to 5' exon definition, and that the terminator stem-loop substitutes in part for the missing IBS2-EBS2 (intron and exon binding sites 2) interaction.

Use of targetrons to disrupt essential and nonessential genes in Staphylococcus aureus reveals temperature sensitivity of Ll.LtrB group II intron splicing

We show that a targetron based on the Lactococcus lactis Ll.LtrB group II intron can be used for efficient chromosomal gene disruption in the human pathogen Staphylococcus aureus. Targetrons expressed from derivatives of vector pCN37, which uses a cadmium-inducible promoter, or pCN39, a derivative of pCN37 with a temperature-sensitive replicon, gave site-specific disruptants of the hsa and seb genes in 37%-100% of plated colonies without selection. To disrupt hsa, an essential gene, we used a group II intron that integrates in the sense orientation relative to target gene transcription and thus could be removed by RNA splicing, enabling the production of functional HSa protein. We show that because splicing of the Ll.LtrB intron by the intron-encoded protein is temperature-sensitive, this method yields a conditional hsa disruptant that grows at 32 degrees C but not 43 degrees C. The temperature sensitivity of the splicing reaction suggests a general means of obtaining one-step conditional disruptions in any organism. In nature, temperature sensitivity of group II intron splicing could limit the temperature range of an organism containing a group II intron inserted in an essential gene.

Potential for alternative intron-exon pairings in group II intron RmInt1 from Sinorhizobium meliloti and its relatives

Ribozyme constructs derived from group II intron RmInt1 of Sinorhizobium meliloti self-splice in vitro when incubated under permissive conditions, but exon ligation is unusually inefficient when the 5' exon is truncated close to the IBS2 intron-binding site. One plausible explanation for this observation is the presence of an alternative intron-exon pairing between an intron segment that overlaps with the EBS2 exon-binding site and a 5' exon site located just distal of IBS2 relative to the splice junction. Strikingly, the existence of this pairing is supported by comparative sequence analysis of introns related to RmInt1.

An alternative intron-exon pairing scheme implied by unexpected in vitro activities of group II intron RmInt1 from Sinorhizobium meliloti

RmInt1 is a mobile group II intron which interrupts ISRm2011-2, another mobile element from the bacterium Sinorhizobium meliloti. Ribozyme constructs derived from intron RmInt1 self-splice in vitro when incubated under permissive conditions, but the excised intron and ligated exons are largely replaced by unconventional products. These include a slightly shorter, 5'-end truncated 3' exon, truncated variants of the linear and lariat forms of the intron-3' exon reaction intermediate, as well as presumably circular molecules derived from the latter. Two factors explain the abundance of these products: (i) nucleotides 5-11 of the 3' exon (IBS1*) provide a better match to the EBS1 5'-exon-binding site than the authentic IBS1 sequence in the 5' exon; (ii) exon ligation is unusually inefficient, and especially so when the 5' exon is truncated close to the second (IBS2) intron-binding site. We propose that reactions at the IBS1* site play a part in the regulation of the intron ISRm2011-2 host in vivo.

Group II intron retroelements: function and diversity

Group II introns are a class of retroelements capable of carrying out both self-splicing and retromobility reactions. In recent years, the number of known group II introns has increased dramatically, particularly in bacteria, and the new information is altering our understanding of these intriguing elements. Here we review the basic properties of group II introns, and summarize the differences between the organellar and bacterial introns with regard to structures, insertion patterns and inferred behaviors. We also discuss the evolution of group II introns, as they are the putative ancestors of spliceosomal introns and possibly non-LTR retroelements, and may have played an important role in the development of eukaryote genomes.

Housekeeping recA gene interrupted by group II intron in the thermophilic Geobacillus kaustophilus

Most of group II introns are found in intergenes and CDSs with unknown functions, but not in housekeeping genes. In particular, no group II intron within the housekeeping recA gene has been reported either in eukaryotic genomes or in prokaryotic genomes. In this study, we found that the recA gene of the thermophilic Geobacillus kaustophilus genome is interrupted by a group II intron (Gk. Int1), and that Gk.Int1 can splice in temperatures above 70 degrees C in vivo. Here, we report the first prokaryotic group II intron to be found in a housekeeping gene, the characteristics of its self-splicing in vivo and in vitro, and our conclusion that the recA gene functions through the self-splicing of Gk.Int1. It is suggested that the amelioration of Gk.Int1 intron has occurred recently, and that it is still in the process of evolution to the recipient genome.

Unusual group II introns in bacteria of the Bacillus cereus group

A combination of sequence and structure analysis and reverse transcriptase PCR experiments was used to characterize the group II introns in the complete genomes of two strains of the pathogen Bacillus cereus. While B. cereus ATCC 14579 harbors a single intron element in the chromosome, B. cereus ATCC 10987 contains three introns in the chromosome and four in its 208-kb pBc10987 plasmid. The most striking finding is the presence in B. cereus ATCC 10987 of an intron [B.c.I2(a)] located on the reverse strand of a gene encoding a putative cell surface protein which appears to be correlated to strains of clinical origin. Because of the opposite orientation of B.c.I2(a), the gene is disrupted. Even more striking is that B.c.I2(a) splices out of an RNA transcript corresponding to the opposite DNA strand. All other intragenic introns studied here are inserted in the same orientation as their host genes and splice out of the mRNA in vivo, setting the flanking exons in frame. Noticeably, B.c.I3 in B. cereus ATCC 10987 represents the first example of a group II intron entirely included within a conserved replication gene, namely, the alpha subunit of DNA polymerase III. Another striking finding is that the observed 3' splice site of B.c.I4 occurs 56 bp after the predicted end of the intron. This apparently unusual splicing mechanism may be related to structural irregularities in the 3' terminus. Finally, we also show that the intergenic introns of B. cereus ATCC 10987 are transcribed with their upstream genes and do splice in vivo.

Analysis of the genome of Azotobacter vinelandii revealed the presence of two genetically distinct group II introns on the chromosome

Azotobacter vinelandii belongs to the y subdivision of eubacteria and has one of the highest respiratory rates. It is considered to be among the probable progenitors of mitochondria. Group II introns were originally identified on organelle genomes. Analysis of the A. vinelandii genome for the presence of group II introns using a deduced group II intron consensus sequence identified two putative introns. The first intron (AVI) which was found to be inserted in the groEL, an essential gene, was already characterized. Our study identified another group II intron (AV2) in A. vinelandii genome. This intron is inserted in a mobile genetic element, similar to most of the group II introns in bacteria, which in this case is a transposase like gene, tnpAl. This putative TnpAl protein is 52% identical to TnpA, the transposase of bacteriophage Lambda, and 85% identical to TnpAl of Pseudomonas stutzeri. Sequence analysis showed that this intron encodes a reverse transcriptase (RT) like motif in domain IV, similar to other group II introns. The RT of this intron open reading frame (ORF) is 53% homologous with that of AVI intron and 66% homologous with that of Pseudomonas putida (Tn5041c) intron. Secondary structure analysis showed that this intron has the typical sub-group IIB1 structure, but the EBS2-IBS2 interaction appears to be missing. Using the RNA generated by in vitro transcription of the intron sequence with its flanking exons, in vitro splicing experiments were performed. It was found that the AV2 intron is functional, despite of lacking the EBS2-IBS2 interaction that plays a role in exon recognition.

Quantitative analysis of group II intron expression and splicing in Lactococcus lactis

The group II intron Ll.ltrB is found within the ltrB relaxase gene of the conjugative element pRS01 in Lactococcus lactis. Precise splicing of the intron is essential for pRS01 transfer. The transcription regulation and in vivo splicing activity of Ll.ltrB have not been investigated thoroughly in L. lactis in the natural pRS01 context. We developed absolute quantitative real-time reverse transcription-PCR assays to quantify RNA levels of the 5' exon (ltrBE1) and the spliced relaxase (ltrB) and intron-encoded protein (ltrA) genes, as well as Ll.ltrB splicing activity under different physiological conditions. The mRNA levels for the ATP-binding protein OppD were assayed for comparison to the ltrB transcripts. The oppD mRNA ranged from 10- to 10,000-fold higher than ltrB region genes. ltrBE1 expression was growth-phase dependent. The mRNA level of ltrA was almost constant during all growth phases and in all media tested. Ll.ltrB in vivo splicing activity ranged from (6.5 +/- 2.1)% to (22.1 +/- 8.0)%. Acid challenge significantly decreased both ltrB region mRNA levels and intron splicing activity. The presence of recipient cells, different mating environments, and temperature stress had no significant effects on expression and splicing. Western blotting showed that the level of LtrB protein expressed from an intronless ltrB gene was much higher (about 20-fold) than the level of protein expressed from an intron-containing construct. Interestingly, LtrB protein showed a tendency to function in cis on its oriT target. The low level of ltrB transcript and relatively inefficient splicing of the intron may limit Ll.ltrB mobility and dissemination in nature.

Dispersal and evolution of the Sinorhizobium meliloti group II RmInt1 intron in bacteria that interact with plants

Group II introns are both self-splicing RNAs and mobile retroelements found in bacterial and archaeal genomes and in organelles of eukaryotes. They are thought to be the ancestors of eukaryote spliceosomal introns and non-long terminal repeat retrotransposons. We show here that RmInt1, a bacterial group II intron first described in the nitrogen-fixing symbiont of alfalfa (Medicago sativa) Sinorhizobium meliloti, is also present in other Sinorhizobium and Rhizobium species. The intron-homing sites in these species are IS elements of the ISRm2011-2 group as in S. meliloti, but ectopic insertion is also observed. We present evidence that these related bacteria have acquired RmInt1 by vertical inheritance from a common ancestor and by independent horizontal transfer events. We also show that RmInt1 is mobile in related taxa of bacteria that interact with plants and tends to evolve toward an inactive form by fragmentation, with loss of the 3' terminus including the intron-encoded protein. Our results provide an overview of the evolution and dispersion of a bacterial group II intron.

Mobile Group II Introns

Mobile group II introns, found in bacterial and organellar genomes, are both catalytic RNAs and retrotransposable elements. They use an extraordinary mobility mechanism in which the excised intron RNA reverse splices directly into a DNA target site and is then reverse transcribed by the intron-encoded protein. After DNA insertion, the introns remove themselves by protein-assisted, autocatalytic RNA splicing, thereby minimizing host damage. Here we discuss the experimental basis for our current understanding of group II intron mobility mechanisms, beginning with genetic observations in yeast mitochondria, and culminating with a detailed understanding of molecular mechanisms shared by organellar and bacterial group II introns. We also discuss recently discovered links between group II intron mobility and DNA replication, new insights into group II intron evolution arising from bacterial genome sequencing, and the evolutionary relationship between group II introns and both eukaryotic spliceosomal introns and non-LTR-retrotransposons. Finally, we describe the development of mobile group II introns into gene-targeting vectors, "targetrons," which have programmable target specificity.

The RmInt1 group II intron has two different retrohoming pathways for mobility using predominantly the nascent lagging strand at DNA replication forks for priming

Sinorhizobium meliloti RmInt1 is an efficient mobile group II intron that uses an unknown reverse transcriptase priming mechanism as the intron ribonucleoprotein complex can reverse splice into DNA target substrates but cannot carry out site-specific second strand cleavage due to the lack of a C-terminal DNA endonuclease domain. We show here that, like other mobile group II introns, RmInt1 moves around by an efficient RNA-based retrohoming mechanism. We found evidence of two distinct RmInt1 retrohoming pathways for mobility depending on the orientation of the target site relative to the direction of DNA replication. The preferred retrohoming pathway is consistent with reverse splicing of the intron RNA into single-stranded DNA at a replication fork, using a nascent lagging DNA strand as the primer for reverse transcription. This strand bias is the opposite of that reported for mobility of the lactococcal Ll.ltrB intron in the absence of second strand cleavage. The mobility mechanism found here for RmInt1 may be used for dissemination by many bacterial group II introns encoding proteins lacking the DNA endonuclease domain.

Principles of 3' splice site selection and alternative splicing for an unusual group II intron from Bacillus anthracis

We investigated the self-splicing properties of two introns from the bacterium Bacillus anthracis. One intron (B.a.I1) splices poorly in vitro despite having typical structural motifs, while the second (B.a.I2) splices well while having apparently degenerated features. The spliced exons of B.a.I2 were sequenced, and splicing was found to occur at a 3' site shifted one nucleotide from the expected position, thus restoring missing gamma-gamma' and IBS3-EBS3 pairings, but leaving the two conserved exonic ORFs out of frame. Because of the unexpected splice site, the principles for 3' intron definition were examined, which showed that the 3' splice site is flexible but contingent on gamma-gamma' and IBS3-EBS3 pairings, and can be as far away as four nucleotides from the wild-type site. Surprisingly, alternative splicing occurs at position +4 for wild-type B.a.I2 intron, both in vitro and in vivo, and the alternative event fuses the two conserved exon ORFs, presumably leading to translation of the downstream ORF. The finding suggests that the structural irregularities of B.a.I2 may be an adaptation to facilitate gene expression in vivo.