Control of branch-site choice by a group II intron.

The branch site of group II introns is typically a bulged adenosine near the 3'-end of intron domain 6. The branch site is chosen with extraordinarily high fidelity, even when the adenosine is mutated to other bases or if the typically bulged adenosine is paired. Given these facts, it has been difficult to discern the mechanism by which the proper branch site is chosen. In order to dissect the determinants for branch-point recognition, new mutations were introduced in the vicinity of the branch site and surrounding domains. Single mutations did not alter the high fidelity for proper branch-site selection. However, several combinations of mutations moved the branch site systematically to new positions along the domain 6 stem. Analysis of those mutants, together with a new alignment of domain 5 and domain 6 sequences, reveals a set of structural determinants that appear to govern branch-site selection by group II introns.     

CRS1, a chloroplast group II intron splicing factor, promotes intron folding through specific interactions with two intron domains

Group II introns are ribozymes that catalyze a splicing reaction with the same chemical steps as spliceosome-mediated splicing. Many group II introns have lost the capacity to self-splice while acquiring compensatory interactions with host-derived protein cofactors. Degenerate group II introns are particularly abundant in the organellar genomes of plants, where their requirement for nuclear-encoded splicing factors provides a means for the integration of nuclear and organellar functions. We present a biochemical analysis of the interactions between a nuclear-encoded group II splicing factor and its chloroplast intron target. The maize (Zea mays) protein Chloroplast RNA Splicing 1 (CRS1) is required specifically for the splicing of the group II intron in the chloroplast atpF gene and belongs to a plant-specific protein family defined by a recently recognized RNA binding domain, the CRM domain. We show that CRS1's specificity for the atpF intron in vivo can be explained by CRS1's intrinsic RNA binding properties. CRS1 binds in vitro with high affinity and specificity to atpF intron RNA and does so through the recognition of elements in intron domains I and IV. These binding sites are not conserved in other group II introns, accounting for CRS1's intron specificity. In the absence of CRS1, the atpF intron has little uniform tertiary structure even at elevated [Mg2+]. CRS1 binding reorganizes the RNA, such that intron elements expected to be at the catalytic core become less accessible to solvent. We conclude that CRS1 promotes the folding of its group II intron target through tight and specific interactions with two peripheral intron segments.     

Extensive structural conservation exists among several homologs of two Euglena chloroplast group II introns

82 of the 155 chloroplast introns in Euglena gracilis have been categorized as group II introns. Because they are shorter and more divergent than group II introns from other organisms, the assignment of these Euglena introns to the group II class has been questioned. In the current study, two homologs of E. gracilispetB intron 1 and four homologs of psbC intron 2 have been isolated from related species and characterized. Based on a comparative sequence analysis of intron homologs, the intron core and four of the six helical domains present in the canonical group II intron structural model are conserved in E. gracilispetB intron 1 and psbC intron 2 and all of their homologs. Distal portions of domain I, which are involved in most of the tertiary interactions, are less well conserved than the central core. Received: 27 June 1997 / Accepted: 6 August 1997     

Mutations in the Lactococcus lactis Ll.LtrB group II intron that retain mobility in vivo

Background

Group II introns are mobile genetic elements that form conserved secondary and tertiary structures. In order to determine which of the conserved structural elements are required for mobility, a series of domain and sub-domain deletions were made in the Lactococcus lactis group II intron (Ll.LtrB) and tested for mobility in a genetic assay. Point mutations in domains V and VI were also tested.

Results

The largest deletion that could be made without severely compromising mobility was 158 nucleotides in DIVb(1–2). This mutant had a mobility frequency comparable to the wild-type Ll.LtrB intron (ΔORF construct). Hence, all subsequent mutations were done in this mutant background. Deletion of DIIb reduced mobility to approximately 18% of wild-type, while another deletion in domain II (nts 404–459) was mobile to a minor extent. Only two deletions in DI and none in DIII were tolerated. Some mobility was also observed for a DIVa deletion mutant. Of the three point mutants at position G3 in DV, only G3A retained mobility. In DVI, deletion of the branch-point nucleotide abolished mobility, but the presence of any nucleotide at the branch-point position restored mobility to some extent.

Conclusions

The smallest intron capable of efficient retrohoming was 725 nucleotides, comprising the DIVb(1–2) and DII(ii)a,b deletions. The tertiary elements found to be nonessential for mobility were alpha, kappa and eta. In DV, only the G3A mutant was mobile. A branch-point residue is required for intron mobility.     

Variation in sequence and RNA editing within core domains of mitochondrial group II introns among plants

The 3' regions of several group II introns within the mitochondrial genes nad1 and nad7 show unexpected sequence divergence among flowering plants, and the core domains 5 and 6 are predicted to have weaker helical structure than those in self-splicing group II introns. To assess whether RNA editing improves helical stability by the conversion of A-C mispairs to A-U pairs, we sequenced RT-PCR amplification products derived from excised intron RNAs or partially spliced precursors. Only in some cases was editing observed to strengthen the predicted helices. Moreover, the editing status within nad1 intron 1 and nad7 intron 4 was seen to differ among plant species, so that homologous intron sequences shared lower similarity at the RNA level than at the DNA level. Plant-specific variation was also seen in the length of the linker joining domains 5 and 6 of nad7 intron 3; it ranged from 4 nt in wheat to 11 nt in soybean, in contrast to the 2-4 nt length typical of classical group II introns. However, this intron is excised as a lariat structure with a domain 6 branchpoint adenosine. Our observations suggest that the core structures and sequences of these plant mitochondrial introns are subject to less stringent evolutionary constraints than conventional group II introns.     

Group II introns as phylogenetic tools: structure, function, and evolutionary constraints

Group II introns comprise the majority of noncoding DNA in many plant chloroplast genomes and include the commonly sequenced regions trnK/matK, the rps16 intron, and the rpl16 intron. As demand increases for nucleotide characters at lower taxonomic levels, chloroplast introns may come to provide the bulk of plastome sequence data for assessment of evolutionary relationships in infrageneric, intergeneric, and interfamilial studies. Group II introns have many attractive properties for the molecular systematist: they are confined to organellar genomes in eukaryotes and the majority are single-copy; they share a well-defined and empirically tested secondary and tertiary structure; and many are easily amplified due to highly conserved sequence in flanking exons. However, structure-linked mutation patterns in group II intron sequences are more complex than generally supposed and have important implications for aligning nucleotides, assessing mutational biases in the data, and selecting appropriate models of character evolution for phylogenetic analysis. This paper presents a summary of group II intron function and structure, reviews the link between that structure and specific mutational constraints in group II intron sequences, and discusses strategies for accommodating the resulting complex mutational patterns in subsequent phylogenetic analyses.     

Extensive structural conservation exists among several homologs of two Euglena chloroplast group II introns

82 of the 155 chloroplast introns in Euglena gracilis have been categorized as group II introns. Because they are shorter and more divergent than group II introns from other organisms, the assignment of these Euglena introns to the group II class has been questioned. In the current study, two homologs of E. gracilispetB intron 1 and four homologs of psbC intron 2 have been isolated from related species and characterized. Based on a comparative sequence analysis of intron homologs, the intron core and four of the six helical domains present in the canonical group II intron structural model are conserved in E. gracilispetB intron 1 and psbC intron 2 and all of their homologs. Distal portions of domain I, which are involved in most of the tertiary interactions, are less well conserved than the central core.     

Domains 2 and 3 interact to form critical elements of the group II intron active site

Group II introns are self-splicing RNA molecules that also behave as mobile genetic elements. The secondary structure of group II intron RNAs is typically described as a series of six domains that project from a central wheel. Most structural and mechanistic analyses of the intron have focused on domains 1 and 5, which contain the residues essential for catalysis, and on domain 6, which contains the branch-point adenosine. Domains 2 and 3 (D2, D3) have been shown to make important contributions to intronic activity; however, information about their function is quite limited. To elucidate the role of D2 and D3 in group II ribozyme catalysis, we built a series of multi-piece ribozyme constructs based on the ai5gamma group II intron. These constructs are designed to shed light on the roles of D2 and D3 in some of the major reactions catalyzed by the intron: 5'-exon cleavage, branching, and substrate hydrolysis. Reactions with these constructs demonstrate that D3 stimulates the chemical rate constant of group II intron reactions, and that it behaves as a form of catalytic effector. However, D3 is unable to associate independently with the ribozyme core. Docking of D3 is mediated by a short duplex that is found at the base of D2. In addition to recruiting D3 into the core, the D2 stem directs the folding of the adjacent j(2/3) linker, which is among the most conserved elements in the group II intron active site. In turn, the D2 stem contributes to 5'-splice site docking and ribozyme conformational change. Nucleotide analog interference mapping suggests an interaction between the D2 stem and D3 that builds on the known theta-theta' interaction and extends it into D3. These results establish that D3 and the base of D2 are key elements of the group II intron core and they suggest a hierarchy for active-site assembly.     

A ribonuclease III domain protein functions in group II intron splicing in maize chloroplasts

Chloroplast genomes in land plants harbor approximately 20 group II introns. Genetic approaches have identified proteins involved in the splicing of many of these introns, but the proteins identified to date cannot account for the large size of intron ribonucleoprotein complexes and are not sufficient to reconstitute splicing in vitro. Here, we describe an additional protein that promotes chloroplast group II intron splicing in vivo. This protein, RNC1, was identified by mass spectrometry analysis of maize (Zea mays) proteins that coimmunoprecipitate with two previously identified chloroplast splicing factors, CAF1 and CAF2. RNC1 is a plant-specific protein that contains two ribonuclease III (RNase III) domains, the domain that harbors the active site of RNase III and Dicer enzymes. However, several amino acids that are essential for catalysis by RNase III and Dicer are missing from the RNase III domains in RNC1. RNC1 is found in complexes with a subset of chloroplast group II introns that includes but is not limited to CAF1- and CAF2-dependent introns. The splicing of many of the introns with which it associates is disrupted in maize rnc1 insertion mutants, indicating that RNC1 facilitates splicing in vivo. Recombinant RNC1 binds both single-stranded and double-stranded RNA with no discernible sequence specificity and lacks endonuclease activity. These results suggest that RNC1 is recruited to specific introns via protein-protein interactions and that its role in splicing involves RNA binding but not RNA cleavage activity.     

Constraints on the evolution of plastid introns: the group II intron in the gene encoding tRNA-Val(UAC).

The evolution of the group II intron in the plastid gene encoding tRNA(Val)UAC (trnV) from seven plant taxa was studied by aligning secondary and other structural features. Levels of evolutionary divergence between six angiosperms and a liverwort, Marchantia polymorpha, were compared for the six domains commonly demonstrated for group II introns and were shown to be statistically heterogeneous. Evolutionary rates varied substantially among various domains and other features. Domain II showed the highest evolutionary rate, approaching the synonymous substitution rate reported for cpDNA-encoded genes, while domain VI and the helix and loop region bearing EBS1 evolved at rates similar to those for nonsynonymous substitutions of a number of cpDNA-encoded genes. The minimum free-energy structure of domain I varied among the seven taxa, suggesting that possible protein-RNA or tertiary interactions are important for intron processing.     

Updated Progress on Group II Intron Splicing Factors in Plant Chloroplasts

Group II introns are large catalytic RNAs (ribozymes) in the bacteria and organelle genomes of several lower eukaryotes. Many critical photosynthesis-related genes in the plant chloroplast genome also contain group II introns, and their splicing is critical for chloroplast biogenesis and photosynthesis processes. The structure of chloroplast group II introns was altered during evolution, resulting in the loss of intron self-splicing. Therefore, the assistance of protein factors was required for their splicing processes. As an increasing number of studies focus on the mechanism of chloroplast intron splicing; many new nuclear-encoded splicing factors that are involved in the chloroplast intron splicing process have been reported. This report reviewed the research progress of the updated splicing factors found to be involved in the splicing of chloroplast group II introns. We discuss the main problems that remain in this research field and suggest future research directions.     

Group II intron domain 5 facilitates a trans-splicing reaction.

A self-splicing group II intron of yeast mitochondrial DNA (aI5g) was divided within intron domain 4 to yield two RNAs that trans-spliced in vitro with associated trans-branching of excised intron fragments. Reformation of the domain 4 secondary structure was not necessary for the trans reaction, since domain 4 sequences were shown to be dispensable. Instead, the trans reaction depended on a previously unpredicted interaction between intron domain 5, the most highly conserved region of group II introns, and another region of the RNA. Domain 5 was shown to be essential for cleavage at the 5' splice site. It stimulated that cleavage when supplied as a trans-acting RNA containing only 42 nucleotides of intron sequence. The relevance of our findings to in vivo trans-splicing mechanisms is discussed.     

Two CRM protein subfamilies cooperate in the splicing of group IIB introns in chloroplasts

Chloroplast genomes in angiosperms encode approximately 20 group II introns, approximately half of which are classified as subgroup IIB. The splicing of all but one of the subgroup IIB introns requires a heterodimer containing the peptidyl-tRNA hydrolase homolog CRS2 and one of two closely related proteins, CAF1 or CAF2, that harbor a recently recognized RNA binding domain called the CRM domain. Two CRS2/CAF-dependent introns require, in addition, a CRM domain protein called CFM2 that is only distantly related to CAF1 and CAF2. Here, we show that CFM3, a close relative of CFM2, associates in vivo with those CRS2/CAF-dependent introns that are not CFM2 ligands. Mutant phenotypes in rice and Arabidopsis support a role for CFM3 in the splicing of most of the introns with which it associates. These results show that either CAF1 or CAF2 and either CFM2 or CFM3 simultaneously bind most chloroplast subgroup IIB introns in vivo, and that the CAF and CFM subunits play nonredundant roles in splicing. These results suggest that the expansion of the CRM protein family in plants resulted in two subfamilies that play different roles in group II intron splicing, with further diversification within a subfamily to accommodate multiple intron ligands.     

Arabidopsis orthologs of maize chloroplast splicing factors promote splicing of orthologous and species-specific group II introns

Chloroplast genomes in plants and green algae contain numerous group II introns, large ribozymes that splice via the same chemical steps as spliceosome-mediated splicing in the nucleus. Most chloroplast group II introns are degenerate, requiring interaction with nucleus-encoded proteins to splice in vivo. Genetic approaches in maize (Zea mays) and Chlamydomonas reinhardtii have elucidated distinct sets of proteins that assemble with chloroplast group II introns and facilitate splicing. Little information is available, however, concerning these processes in Arabidopsis (Arabidopsis thaliana). To determine whether the paucity of data concerning chloroplast splicing factors in Arabidopsis reflects a fundamental difference between protein-facilitated group II splicing in monocot and dicot plants, we examined the mutant phenotypes associated with T-DNA insertions in Arabidopsis genes encoding orthologs of the maize chloroplast splicing factors CRS1, CAF1, and CAF2 (AtCRS1, AtCAF1, and AtCAF2). We show that the splicing functions and intron specificities of these proteins are largely conserved between maize and Arabidopsis, indicating that these proteins were recruited to promote the splicing of plastid group II introns prior to the divergence of monocot and dicot plants. We show further that AtCAF1 promotes the splicing of two group II introns, rpoC1 and clpP-intron 1, that are found in Arabidopsis but not in maize; AtCAF1 is the first splicing factor described for these introns. Finally, we show that a strong AtCAF2 allele conditions an embryo-lethal phenotype, adding to the body of data suggesting that cell viability is more sensitive to the loss of plastid translation in Arabidopsis than in maize.