Naegleria nucleolar introns contain two group I ribozymes with different functions in RNA splicing and processing.

We have characterized the structural organization and catalytic properties of the large nucleolar group I introns (NaSSU1) of the different Naegleria species N. jamiesoni, N. andersoni, N. italica, and N. gruberi. NaSSU1 consists of three distinct RNA domains: an open reading frame encoding a homing-type endonuclease, and a small group I ribozyme (NaGIR1) inserted into the P6 loop of a second group I ribozyme (NaGIR2). The two ribozymes have different functions in RNA splicing and processing. NaGIR1 is an unusual self-cleaving group I ribozyme responsible for intron processing at two internal sites (IPS1 and IPS2), both close to the 5' end of the open reading frame. This processing is hypothesized to lead to formation of a messenger RNA for the endonuclease. Structurally, NaGIR2 is a typical group IC1 ribozyme, catalyzing intron excision and exon ligation reactions. NaGIR2 is responsible for circularization of the excised intron, a reaction that generates full-length RNA circles of wild-type intron. Although it is only distantly related in primary sequence, NaSSU1 RNA has a predicted organization and function very similar to that of the mobile group I intron DiSSU1 of Didymium, the only other group I intron known to encode two ribozymes. We propose that these twin-ribozyme introns define a distinct category of group I introns with a conserved structural organization and function.     

Group I introns and associated homing endonuclease genes reveals a clinal structure for <Emphasis Type="Italic">Porphyra spiralis</Emphasis> var. <Emphasis Type="Italic">amplifolia</Emphasis> (Bangiales,Rhodophyta) along the Eastern coast of South America

Background  

Group I introns are found in the nuclear small subunit ribosomal RNA gene (SSU rDNA) of some species of the genus Porphyra (Bangiales, Rhodophyta). Size polymorphisms in group I introns has been interpreted as the result of the degeneration of homing endonuclease genes (HEG) inserted in peripheral loops of intron paired elements. In this study, intron size polymorphisms were characterized for different Porphyra spiralis var. amplifolia (PSA) populations on the Southern Brazilian coast, and were used to infer genetic relationships and genetic structure of these PSA populations, in addition to cox 2-3 and rbc L-S regions. Introns of different sizes were tested qualitatively for in vitro self-splicing.     

The recent transfer of a homing endonuclease gene

The myxomycete Didymium iridis (isolate Panama 2) contains a mobile group I intron named Dir.S956-1 after position 956 in the nuclear small subunit (SSU) rRNA gene. The intron is efficiently spread through homing by the intron-encoded homing endonuclease I-DirI. Homing endonuclease genes (HEGs) usually spread with their associated introns as a unit, but infrequently also spread independent of introns (or inteins). Clear examples of HEG mobility are however sparse. Here, we provide evidence for the transfer of a HEG into a group I intron named Dir.S956-2 that is inserted into the SSU rDNA of the Costa Rica 8 isolate of D.iridis. Similarities between intron sequences that flank the HEG and rDNA sequences that flank the intron (the homing endonuclease recognition sequence) suggest that the HEG invaded the intron during the recent evolution in a homing-like event. Dir.S956-2 is inserted into the same SSU site as Dir.S956-1. Remarkably, the two group I introns encode distantly related splicing ribozymes with phylogenetically related HEGs inserted on the opposite strands of different peripheral loop regions. The HEGs are both interrupted by small spliceosomal introns that must be removed during RNA maturation.     

DiGIR1 and NaGIR1: naturally occurring group I-like ribozymes with unique core organization and evolved biological role

The group I-like ribozyme GIR1 is a unique example of a naturally occurring ribozyme with an evolved biological function. GIR1 generates the 5'-end of a nucleolar encoded messenger RNA involved in intron mobility. GIR1 is found as a cis-cleaving ribozyme within two very different rDNA group I introns (twin-ribozyme introns) in distantly related organisms. The Didymium GIR1 (DiGIR1) and Naegleria GIR1 (NaGIR1) share fundamental features in structural organization and reactivity, and display significant differences when compared to the related group I splicing ribozymes. GIR1 lacks the characteristic P1 segment present in all group I splicing ribozymes, it has a novel core organization, and it catalyses two site-specific hydrolytic cleavages rather than splicing. DiGIR1 and NaGIR1 appear to have originated from eubacterial group I introns in order to fulfil a common biological challenge: the expression of a protein encoding gene in a nucleolar context.     

Characterization of the self-splicing products of two complex Naegleria LSU rDNA group I introns containing homing endonuclease genes.

The two group I introns Nae.L1926 and Nmo.L2563, found at two different sites in nuclear LSU rRNA genes of Naegleria amoebo-flagellates, have been characterized in vitro. Their structural organization is related to that of the mobile Physarum intron Ppo.L1925 (PpLSU3) with ORFs extending the L1-loop of a typical group IC1 ribozyme. Nae.L1926, Nmo.L2563 and Ppo.L1925 RNAs all self-splice in vitro, generating ligated exons and full-length intron circles as well as internal processed excised intron RNAs. Formation of full-length intron circles is found to be a general feature in RNA processing of ORF-containing nuclear group I introns. Both Naegleria LSU rDNA introns contain a conserved polyadenylation signal at exactly the same position in the 3' end of the ORFs close to the internal processing sites, indicating an RNA polymerase II-like expression pathway of intron proteins in vivo. The intron proteins I-NaeI and I-NmoI encoded by Nae.L1926 and Nmo.L2563, respectively, correspond to His-Cys homing endonucleases of 148 and 175 amino acids. I-NaeI contains an additional sequence motif homologous to the unusual DNA binding motif of three antiparallel beta sheets found in the I-PpoI endonuclease, the product of the Ppo.L1925 intron ORF.     

Flanking sequences with an essential role in hydrolysis of a self-cleaving group I-like ribozyme

DiGIR1 is a group I-like ribozyme derived from the mobile twin ribozyme group I intron DiSSU1 in the nuclear ribosomal DNA of the myxomycete Didymium iridis. This ribozyme is responsible for intron RNA processing in vitro and in vivo at two internal sites close to the 5′-end of the intron endonuclease open reading frame and is a unique example of a group I ribozyme with an evolved biological function. DiGIR1 is the smallest functional group I ribozyme known from nature and has an unusual core organization including the 6 bp P15 pseudoknot. Here we report results of functional and structural analyses that identify RNA elements critical for hydrolysis outside the DiGIR1 ribozyme core moiety. Results from deletion analysis, disruption/compensation mutagenesis and RNA structure probing analysis all support the existence of two new segments, named P2 and P2.1, involved in the hydrolysis of DiGIR1. Significant decreases in the hydrolysis rate, k_obs, were observed in disruption mutants involving both segments. These effects were restored by compensatory base pairing mutants. The possible role of P2 is to tether the ribozyme core, whereas P2.1 appears to be more directly involved in catalysis.     

A conformational switch in the DiGIR1 ribozyme involved in release and folding of the downstream I-DirI mRNA

DiGIR1 is a group I-like cleavage ribozyme found as a structural domain within a nuclear twin-ribozyme group I intron. DiGIR1 catalyzes cleavage by branching at an Internal Processing Site (IPS) leading to formation of a lariat cap at the 5′-end of the 3′-cleavage product. The 3′-cleavage product is subsequently processed into an mRNA encoding a homing endonuclease. By analysis of combinations of 5′- and 3′-deletions, we identify a hairpin in the 5′-UTR of the mRNA (HEG P1) that is formed by conformational switching following cleavage. The formation of HEG P1 inhibits the reversal of the branching reaction, thus giving it directionality. Furthermore, the release of the mRNA is a consequence of branching rather than hydrolytic cleavage. A model is put forward that explains the release of the I-DirI mRNA with a lariat cap and a structured 5′-UTR as a direct consequence of the DiGIR1 branching reaction. The role of HEG P1 in GIR1 branching is reminiscent of that of hairpin P-1 in splicing of the Tetrahymena rRNA group I intron and illustrates a general principle in RNA-directed RNA processing.     

Invasion of protein coding genes by green algal ribosomal group I introns

The spread of group I introns depends on their association with intron-encoded homing endonucleases. Introns that encode functional homing endonuclease genes (HEGs) are highly invasive, whereas introns that only encode the group I ribozyme responsible for self-splicing are generally stably inherited (i.e., vertical inheritance). A number of recent case studies have provided new knowledge on the evolution of group I introns, however, there are still large gaps in understanding of their distribution on the tree of life, and how they have spread into new hosts and genic sites. During a larger phylogenetic survey of chlorophyceaen green algae, we found that 23 isolates contain at least one group I intron in the rbcL chloroplast gene. Structural analyses show that the introns belong to one of two intron lineages, group IA2 intron-HEG (GIY-YIG family) elements inserted after position 462 in the rbcL gene, and group IA1 introns inserted after position 699. The latter intron type sometimes encodes HNH homing endonucleases. The distribution of introns was analyzed on an exon phylogeny and patterns were recovered that are consistent with vertical inheritance and possible horizontal transfer. The rbcL 462 introns are thus far reported only within the Volvocales, Hydrodictyaceae and Bracteacoccus, and closely related isolates of algae differ in the presence of rbcL introns. Phylogenetic analysis of the intron conserved regions indicates that the rbcL699 and rbcL462 introns have distinct evolutionary origins. The rbcL699 introns were likely derived from ribosomal RNA L2449 introns, whereas the rbcL462 introns form a close relationship with psbA introns.     

The Mitochondrial LSU rRNA Group II Intron of Ustilago maydis Encodes an Active Homing Endonuclease Likely Involved in Intron Mobility

Background

The a2 mating type locus gene lga2 is critical for uniparental mitochondrial DNA inheritance during sexual development of Ustilago maydis. Specifically, the absence of lga2 results in biparental inheritance, along with efficient transfer of intronic regions in the large subunit rRNA gene between parental molecules. However, the underlying role of the predicted LAGLIDADG homing endonuclease gene I-UmaI located within the group II intron LRII1 has remained unresolved.

Methodology/Principal Findings

We have investigated the enzymatic activity of I-UmaI in vitro based on expression of a tagged full-length and a naturally occurring mutant derivative, which harbors only the N-terminal LAGLIDADG domain. This confirmed Mg²⁺-dependent endonuclease activity and cleavage at the LRII1 insertion site to generate four base pair extensions with 3′ overhangs. Specifically, I-UmaI recognizes an asymmetric DNA sequence with a minimum length of 14 base pairs (5′-GACGGGAAGACCCT-3′) and tolerates subtle base pair substitutions within the homing site. Enzymatic analysis of the mutant variant indicated a correlation between the activity in vitro and intron homing. Bioinformatic analyses revealed that putatively functional or former functional I-UmaI homologs are confined to a few members within the Ustilaginales and Agaricales, including the phylogenetically distant species Lentinula edodes, and are linked to group II introns inserted into homologous positions in the LSU rDNA.

Conclusions/Significance

The present data provide strong evidence that intron homing efficiently operates under conditions of biparental inheritance in U. maydis. Conversely, uniparental inheritance may be critical to restrict the transmission of mobile introns. Bioinformatic analyses suggest that I-UmaI-associated introns have been acquired independently in distant taxa and are more widespread than anticipated from available genomic data.     

I-OmiI and I-OmiII: Two intron-encoded homing endonucleases within the Ophiostoma minus rns gene

The mitochondrial small subunit ribosomal RNA (rns) gene of the ascomycetous fungus Ophiostoma minus [strain WIN(M)371] was found to contain a group IC2 and a group IIB1 intron at positions mS569 and mS952 respectively. Both introns have open reading frames (ORFs) embedded that encode double motif LAGLIDADG homing endonucleases (I-OmiI and I-OmiII respectively). Codon-optimized versions of I-OmiI and I-OmiII were synthesized for overexpression in Escherichia coli. The in vitro characterization of I-OmiII showed that it is a functional homing endonuclease that cleaves the rns target site two nucleotides upstream (sense strand) of the intron insertion site generating 4 nucleotide 3′ overhangs. The endonuclease activity of I-OmiII was tested using linear and circular substrates and cleavage activity was evaluated at various temperatures. The I-OmiI protein was expressed in E. coli, but purification was difficult, thus the endonuclease activity of this protein was tested via in vivo assays. Overall this study showed that there are many native forms of functional homing endonucleases yet to be discovered among fungal mtDNA genomes.     

Better late than early: delayed translation of intron‐encoded endonuclease I‐TevI is required for efficient splicing of its host group I intron

The td group I intron interrupting the thymidylate synthase (TS) gene of phage T4 is a mobile intron that encodes the homing endonuclease I‐TevI. Efficient RNA splicing of the intron is required to restore function of the TS gene, while expression of I‐TevI from within the intron is required to initiate intron mobility. Three distinct layers of regulation temporally limit I‐TevI expression to late in the T4 infective cycle, yet the biological rationale for stringent regulation has not been tested. Here, we deleted key control elements to deregulate I‐TevI expression at early and middle times post T4 infection. Strikingly, we found that deregulation of I‐TevI, or of a catalytically inactive variant, generated a thymidine‐dependent phenotype that is caused by a reduction in td intron splicing. Prematurely terminating I‐TevI translation restores td splicing, full‐length TS synthesis, and rescues the thymidine‐dependent phenotype. We suggest that stringent translational control of I‐TevI evolved to prevent the ribosome from disrupting key structural elements of the td intron that are required for splicing and TS function at early and middle times post T4 infection. Analogous translational regulatory mechanisms in unrelated intron‐open reading frame arrangements may also function to limit deleterious consequences on splicing and host gene function.     

The group I intron of apocytochrome b gene from Chlamydomonas smithii encodes a site-specific endonuclease

The mitochondrial DNA molecules of two interfertile algal species, Chlamydomonas smithii and C. reinhardtii, are co-linear except for a 1075 bp intron (the -insert) that is present in the cob gene of C. smithii. The -insert, a group I intron (Cs cob·1) containing an open reading frame (ORF) which encodes a basic, hydrophilic protein of 237 amino acids, is unidirectionally transmitted to all diploid progeny during interspecific crosses. In this report, we show that the Cs cob·1-encoded protein is a site-specific endonuclease (I-Csm I) which could mediate the intron transfer via the gene conversion mechanism. The Cs cob·1 ORF was cloned into the vector pMALcr1 and over-expressed as a hybrid protein fused to maltose-binding protein (MBP). This fusion protein exhibited an in vivo endonuclease activity which specifically cleaved the intron homing site within the intronless cob gene.