Exploring the highly reduced spliceosome of Pseudoloma neurophilia.

Spliceosomal introns evolved early in eukaryogenesis, originating from self-splicing group II introns that invaded the proto-eukaryotic genome1. Elements of these ribozymes, now called snRNAs (U1, U2, U4, U5, U6), were co-opted to excise these invasive elements. Prior to eukaryotic diversification, the spliceosome is predicted to have accumulated hundreds of proteins2. This early complexification has obscured our understanding of spliceosomal evolution. Reduced systems with few introns and tiny spliceosomes give insights into the plasticity of the splicing reaction and provide an opportunity to study the evolution of the spliceosome3,4. Microsporidia are intracellular parasites possessing extremely reduced genomes that have lost many, and in some instances all, introns5. In the purportedly intron-lacking genome of the microsporidian Pseudoloma neurophilia6, we identified two introns that are spliced at high levels. Furthermore, with only 14 predicted proteins, the P. neurophilia spliceosome could be the smallest known. Intriguingly, the few proteins retained are divergent compared to canonical orthologs. Even the central spliceosomal protein Prp8, which originated from the proteinaceous component of group II introns, is extremely divergent. This is unusual given that Prp8 is highly conserved across eukaryotes, including other microsporidia. All five P. neurophilia snRNAs are present, and all but U2 have diverged extensively, likely resulting from the loss of interacting proteins. Despite this divergence, U1 and U2 are predicted to pair with intron sequences more extensively than previously described. The P. neurophilia spliceosome is retained to splice a mere two introns and, with few proteins and reliance on RNA-RNA interactions, could function in a manner more reminiscent of presumed ancestral splicing.

Microsporidia.

In this Quick guide, Thomas Whelan and Naomi Fast introduce the microsporidia: obligate intracellular parasites with the most extremely reduced genomes known in eukaryotes.

Contrasting outcomes of genome reduction in mikrocytids and microsporidians.

BACKGROUND: Intracellular symbionts often undergo genome reduction, losing both coding and non-coding DNA in a process that ultimately produces small, gene-dense genomes with few genes. Among eukaryotes, an extreme example is found in microsporidians, which are anaerobic, obligate intracellular parasites related to fungi that have the smallest nuclear genomes known (except for the relic nucleomorphs of some secondary plastids). Mikrocytids are superficially similar to microsporidians: they are also small, reduced, obligate parasites; however, as they belong to a very different branch of the tree of eukaryotes, the rhizarians, such similarities must have evolved in parallel. Since little genomic data are available from mikrocytids, we assembled a draft genome of the type species, Mikrocytos mackini, and compared the genomic architecture and content of microsporidians and mikrocytids to identify common characteristics of reduction and possible convergent evolution. RESULTS: At the coarsest level, the genome of M. mackini does not exhibit signs of extreme genome reduction; at 49.7 Mbp with 14,372 genes, the assembly is much larger and gene-rich than those of microsporidians. However, much of the genomic sequence and most (8075) of the protein-coding genes code for transposons, and may not contribute much of functional relevance to the parasite. Indeed, the energy and carbon metabolism of M. mackini share several similarities with those of microsporidians. Overall, the predicted proteome involved in cellular functions is quite reduced and gene sequences are extremely divergent. Microsporidians and mikrocytids also share highly reduced spliceosomes that have retained a strikingly similar subset of proteins despite having reduced independently. In contrast, the spliceosomal introns in mikrocytids are very different from those of microsporidians in that they are numerous, conserved in sequence, and constrained to an exceptionally narrow size range (all 16 or 17 nucleotides long) at the shortest extreme of known intron lengths. CONCLUSIONS: Nuclear genome reduction has taken place many times and has proceeded along different routes in different lineages. Mikrocytids show a mix of similarities and differences with other extreme cases, including uncoupling the actual size of a genome with its functional reduction.

Spliceosome assembly and regulation: insights from analysis of highly reduced spliceosomes.

Premessenger RNA splicing is catalyzed by the spliceosome, a multimegadalton RNA-protein complex that assembles in a highly regulated process on each intronic substrate. Most studies of splicing and spliceosomes have been carried out in human or S. cerevisiae model systems. There exists, however, a large diversity of spliceosomes, particularly in organisms with reduced genomes, that suggests a means of analyzing the essential elements of spliceosome assembly and regulation. In this review, we characterize changes in spliceosome composition across phyla, describing those that are most frequently observed and highlighting an analysis of the reduced spliceosome of the red alga Cyanidioschyzon merolae We used homology modeling to predict what effect splicing protein loss would have on the spliceosome, based on currently available cryo-EM structures. We observe strongly correlated loss of proteins that function in the same process, for example, in interacting with the U1 snRNP (which is absent in C. merolae), regulation of Brr2, or coupling transcription and splicing. Based on our observations, we predict splicing in C. merolae to be inefficient, inaccurate, and post-transcriptional, consistent with the apparent trend toward its elimination in this lineage. This work highlights the striking flexibility of the splicing pathway and the spliceosome when viewed in the context of eukaryotic diversity.

The evolution of pre-mRNA splicing and its machinery revealed by reduced extremophilic red algae.

The Cyanidiales are a group of mostly thermophilic and acidophilic red algae that thrive near volcanic vents. Despite their phylogenetic relationship, the reduced genomes of Cyanidioschyzon merolae and Galdieria sulphuraria are strikingly different with respect to pre-mRNA splicing, a ubiquitous eukaryotic feature. Introns are rare and spliceosomal machinery is extremely reduced in C. merolae, in contrast to G. sulphuraria. Previous studies also revealed divergent spliceosomes in the mesophilic red alga Porphyridium purpureum and the red algal derived plastid of Guillardia theta (Cryptophyta), along with unusually high levels of unspliced transcripts. To further examine the evolution of splicing in red algae, we compared C. merolae and G. sulphuraria, investigating splicing levels, intron position, intron sequence features, and the composition of the spliceosome. In addition to identifying 11 additional introns in C. merolae, our transcriptomic analysis also revealed typical eukaryotic splicing in G. sulphuraria, whereas most transcripts in C. merolae remain unspliced. The distribution of intron positions within their host genes was examined to provide insight into patterns of intron loss in red algae. We observed increasing variability of 5' splice sites and branch donor regions with increasing intron richness. We also found these relationships to be connected to reductions in and losses of corresponding parts of the spliceosome. Our findings highlight patterns of intron and spliceosome evolution in related red algae under the pressures of genome reduction.

Intron splicing: U12 spliceosomal introns not so 'minor' after all.

Whereas most eukaryotic genes are interrupted by introns removed by the U2 (major) spliceosome, U12-type introns are extremely rare. New work uncovers a case of extensive U12-type intron gain, and an unexpectedly flexible and efficient U12 (minor) spliceosome.

Characterization of Pre-mRNA Splicing and Spliceosomal Machinery in Porphyridium purpureum and Evolutionary Implications for Red Algae.

Pre-mRNA splicing is a highly conserved eukaryotic process, but our understanding of it is limited by a historical focus on well-studied organisms such as humans and yeast. There is considerable diversity in mechanisms and components of pre-mRNA splicing, especially in lineages that have evolved under the pressures of genome reduction. The ancestor of red algae is thought to have undergone genome reduction prior to the lineage's radiation, resulting in overall gene and intron loss in extant groups. Previous studies on the extremophilic red alga Cyanidioschyzon merolae revealed an intron-sparse genome with a highly reduced spliceosome. To determine whether these features applied to other red algae, we investigated multiple aspects of pre-mRNA splicing in the mesophilic red alga Porphyridium purpureum. Through strand-specific RNA-Seq, we observed high levels of intron retention across a large number of its introns, and nearly half of the transcripts for these genes are not spliced at all. We also discovered a relationship between variability of 5' splice site sequences and levels of splicing. To further investigate the connections between intron retention and splicing machinery, we bioinformatically assembled the P. purpureum spliceosome, and biochemically verified the presence of snRNAs. While most other core spliceosomal components are present, our results suggest highly divergent or missing U1 snRNP proteins, despite the presence of an uncharacteristically long U1 snRNA. These unusual aspects highlight the diverse nature of pre-mRNA splicing that can be seen in lesser-studied eukaryotes, raising the importance of investigating fundamental eukaryotic processes outside of model organisms.

Microsporidian Introns Retained against a Background of Genome Reduction: Characterization of an Unusual Set of Introns.

Spliceosomal introns are ubiquitous features of eukaryotic genomes, but the mechanisms responsible for their loss and gain are difficult to identify. Microsporidia are obligate intracellular parasites that have significantly reduced genomes and, as a result, have lost many if not all of their introns. In the microsporidian Encephalitozoon cuniculi, a relatively long intron was identified and was spliced at higher levels than the remaining introns. This long intron is part of a set of unique introns in two unrelated genes that show high levels of sequence conservation across diverse microsporidia. The introns possess a unique internal conserved region, which overlaps with a shared, predicted stem-loop structure. The unusual similarity and retention of these long introns in reduced microsporidian genomes could indicate that these introns function similarly, are homologous, or both. Regardless, the significant genome reduction in microsporidia provides a rare opportunity to understand intron evolution.

Evolution and Diversity of Pre-mRNA Splicing in Highly Reduced Nucleomorph Genomes.

Eukaryotic genes are interrupted by introns that are removed in a conserved process known as pre-mRNA splicing. Though well-studied in select model organisms, we are only beginning to understand the variation and diversity of this process across the tree of eukaryotes. We explored pre-mRNA splicing and other features of transcription in nucleomorphs, the highly reduced remnant nuclei of secondary endosymbionts. Strand-specific transcriptomes were sequenced from the cryptophyte Guillardia theta and the chlorarachniophyte Bigelowiella natans, whose plastids are derived from red and green algae, respectively. Both organisms exhibited elevated nucleomorph antisense transcription and gene expression relative to their respective nuclei, suggesting unique properties of gene regulation and transcriptional control in nucleomorphs. Marked differences in splicing were observed between the two nucleomorphs: the few introns of the G. theta nucleomorph were largely retained in mature transcripts, whereas the many short introns of the B. natans nucleomorph are spliced at typical eukaryotic levels (>90%). These differences in splicing levels could be reflecting the ancestries of the respective plastids, the different intron densities due to independent genome reduction events, or a combination of both. In addition to extending our understanding of the diversity of pre-mRNA splicing across eukaryotes, our study also indicates potential links between splicing, antisense transcription, and gene regulation in reduced genomes.

Splicing diversity revealed by reduced spliceosomes in C. merolae and other organisms.

Pre-mRNA splicing has been considered one of the hallmarks of eukaryotes, yet its diversity is astonishing: the number of substrate introns for splicing ranges from hundreds of thousands in humans to a mere handful in certain parasites. The catalytic machinery that carries out splicing, the spliceosome, is similarly diverse, with over 300 associated proteins in humans to a few tens in other organisms. In this Point of View, we discuss recent work characterizing the reduced spliceosome of the acidophilic red alga Cyanidioschyzon merolae, which further highlights the diversity of splicing in that it does not possess the U1 snRNP that is characteristically responsible for 5' splice site recognition. Comparisons to other organisms with reduced spliceosomes, such as microsporidia, trypanosomes, and Giardia, help to identify the most highly conserved splicing factors, pointing to the essential core of this complex machine. These observations argue for increased exploration of important biochemical processes through study of a wider ranger of organisms.

Dramatically reduced spliceosome in Cyanidioschyzon merolae.

The human spliceosome is a large ribonucleoprotein complex that catalyzes pre-mRNA splicing. It consists of five snRNAs and more than 200 proteins. Because of this complexity, much work has focused on the Saccharomyces cerevisiae spliceosome, viewed as a highly simplified system with fewer than half as many splicing factors as humans. Nevertheless, it has been difficult to ascribe a mechanistic function to individual splicing factors or even to discern which are critical for catalyzing the splicing reaction. We have identified and characterized the splicing machinery from the red alga Cyanidioschyzon merolae, which has been reported to harbor only 26 intron-containing genes. The U2, U4, U5, and U6 snRNAs contain expected conserved sequences and have the ability to adopt secondary structures and form intermolecular base-pairing interactions, as in other organisms. C. merolae has a highly reduced set of 43 identifiable core splicing proteins, compared with ∼90 in budding yeast and ∼140 in humans. Strikingly, we have been unable to find a U1 snRNA candidate or any predicted U1-associated proteins, suggesting that splicing in C. merolae may occur without the U1 small nuclear ribonucleoprotein particle. In addition, based on mapping the identified proteins onto the known splicing cycle, we propose that there is far less compositional variability during splicing in C. merolae than in other organisms. The observed reduction in splicing factors is consistent with the elimination of spliceosomal components that play a peripheral or modulatory role in splicing, presumably retaining those with a more central role in organization and catalysis.

Ancient and novel small RNA pathways compensate for the loss of piRNAs in multiple independent nematode lineages.

Small RNA pathways act at the front line of defence against transposable elements across the Eukaryota. In animals, Piwi interacting small RNAs (piRNAs) are a crucial arm of this defence. However, the evolutionary relationships among piRNAs and other small RNA pathways targeting transposable elements are poorly resolved. To address this question we sequenced small RNAs from multiple, diverse nematode species, producing the first phylum-wide analysis of how small RNA pathways evolve. Surprisingly, despite their prominence in Caenorhabditis elegans and closely related nematodes, piRNAs are absent in all other nematode lineages. We found that there are at least two evolutionarily distinct mechanisms that compensate for the absence of piRNAs, both involving RNA-dependent RNA polymerases (RdRPs). Whilst one pathway is unique to nematodes, the second involves Dicer-dependent RNA-directed DNA methylation, hitherto unknown in animals, and bears striking similarity to transposon-control mechanisms in fungi and plants. Our results highlight the rapid, context-dependent evolution of small RNA pathways and suggest piRNAs in animals may have replaced an ancient eukaryotic RNA-dependent RNA polymerase pathway to control transposable elements.

Microsporidian diversity in soil, sand, and compost of the Pacific Northwest.

Microsporidia are intracellular parasites considered to be ubiquitous in the environment. Yet the true extent of their diversity in soils, sand, and compost remains unclear. We examined microsporidian diversity found in the common urban environments of soil, sand, and compost. We retrieved 22 novel microsporidian sequences and only four from described species. Their distribution was generally restricted to a single site and sample type. Surprisingly, one novel microsporidian showed a wide distribution, and high prevalence, as it was detected in five different compost samples and in soil samples collected over 200 km apart. These results suggest that the majority of Microsporidia appear to have a narrow distribution. Our phylogenetic analysis indicated that the Microsporidia detected in this study include representatives from four of the five major microsporidian groups. Furthermore, the addition of our new sequences calls into question the cohesiveness of microsporidian clade II. These results highlight the importance of increasing our knowledge of microsporidian diversity to better understand the phylogenetic relationships and evolutionary history of this important group of emerging parasites.

Gene invasion in distant eukaryotic lineages: discovery of mutually exclusive genetic elements reveals marine biodiversity.

Inteins are rare, translated genetic parasites mainly found in bacteria and archaea, while spliceosomal introns are distinctly eukaryotic features abundant in most nuclear genomes. Using targeted metagenomics, we discovered an intein in an Atlantic population of the photosynthetic eukaryote, Bathycoccus, harbored by the essential spliceosomal protein PRP8 (processing factor 8 protein). Although previously thought exclusive to fungi, we also identified PRP8 inteins in parasitic (Capsaspora) and predatory (Salpingoeca) protists. Most new PRP8 inteins were at novel insertion sites that, surprisingly, were not in the most conserved regions of the gene. Evolutionarily, Dikarya fungal inteins at PRP8 insertion site a appeared more related to the Bathycoccus intein at a unique insertion site, than to other fungal and opisthokont inteins. Strikingly, independent analyses of Pacific and Atlantic samples revealed an intron at the same codon as the Bathycoccus PRP8 intein. The two elements are mutually exclusive and neither was found in cultured Bathycoccus or other picoprasinophyte genomes. Thus, wild Bathycoccus contain one of few non-fungal eukaryotic inteins known and a rare polymorphic intron. Our data indicate at least two Bathycoccus ecotypes exist, associated respectively with oceanic or mesotrophic environments. We hypothesize that intein propagation is facilitated by marine viruses; and, while intron gain is still poorly understood, presence of a spliceosomal intron where a locus lacks an intein raises the possibility of new, intein-primed mechanisms for intron gain. The discovery of nucleus-encoded inteins and associated sequence polymorphisms in uncultivated marine eukaryotes highlights their diversity and reveals potential sexual boundaries between populations indistinguishable by common marker genes.

Transcriptome analysis of the parasite Encephalitozoon cuniculi: an in-depth examination of pre-mRNA splicing in a reduced eukaryote.

BACKGROUND: The microsporidian Encephalitozoon cuniculi possesses one of the most reduced and compacted eukaryotic genomes. Reduction in this intracellular parasite has affected major cellular machinery, including the loss of over fifty core spliceosomal components compared to S. cerevisiae. To identify expression changes throughout the parasite's life cycle and also to assess splicing in the context of this reduced system, we examined the transcriptome of E. cuniculi using Illumina RNA-seq. RESULTS: We observed that nearly all genes are expressed at three post-infection time-points examined. A large fraction of genes are differentially expressed between the first and second (37.7%) and first and third (43.8%) time-points, while only four genes are differentially expressed between the latter two. Levels of intron splicing are very low, with 81% of junctions spliced at levels below 50%. This is dramatically lower than splicing levels found in two other fungal species examined. We also describe the first case of alternative splicing in a microsporidian, an unexpected complexity given the reduction in spliceosomal components. CONCLUSIONS: Low levels of splicing observed are likely the result of an inefficient spliceosome; however, at least in one case, splicing appears to be playing a functional role. Although several RNA decay genes are encoded in E. cuniculi, the lack of a few key players could be reducing decay levels and therefore increasing the proportion of unspliced transcripts. Significant proportions of genes are differentially expressed in the first forty-eight hours but not after, indicative of genetic changes that precede the intracellular to infective stage transition.

Algal genomes reveal evolutionary mosaicism and the fate of nucleomorphs.

Cryptophyte and chlorarachniophyte algae are transitional forms in the widespread secondary endosymbiotic acquisition of photosynthesis by engulfment of eukaryotic algae. Unlike most secondary plastid-bearing algae, miniaturized versions of the endosymbiont nuclei (nucleomorphs) persist in cryptophytes and chlorarachniophytes. To determine why, and to address other fundamental questions about eukaryote-eukaryote endosymbiosis, we sequenced the nuclear genomes of the cryptophyte Guillardia theta and the chlorarachniophyte Bigelowiella natans. Both genomes have >21,000 protein genes and are intron rich, and B. natans exhibits unprecedented alternative splicing for a single-celled organism. Phylogenomic analyses and subcellular targeting predictions reveal extensive genetic and biochemical mosaicism, with both host- and endosymbiont-derived genes servicing the mitochondrion, the host cell cytosol, the plastid and the remnant endosymbiont cytosol of both algae. Mitochondrion-to-nucleus gene transfer still occurs in both organisms but plastid-to-nucleus and nucleomorph-to-nucleus transfers do not, which explains why a small residue of essential genes remains locked in each nucleomorph.

Patterns of 5' untranslated region length distribution in Encephalitozoon cuniculi: implications for gene regulation and potential links between transcription and splicing.

Encephalitozoon cuniculi, a eukaryotic intracellular parasite belonging to the group Microsporidia, has a highly reduced and compacted genome. Its mRNA transcripts have been found to differ between the two life stages, the spore and meront, of the parasite. Spore transcripts generally have more transcription start sites, longer 5' untranslated regions (UTRs), and overlap more frequently with upstream genes than those of meronts. A previous analysis of 31 meront gene transcripts showed that most have short 5'UTRs, and intron-containing genes, mostly ribosomal protein genes, exclusively have very short 5'UTRs. Here we analyzed a larger set of transcripts from meronts, and we find a pattern of 5'UTR length distribution similar to other reduced genomes. There is an abundance of very short 5'UTRs that are <20 bp in length, and very few 5'UTRs that are much longer. We also find a relationship between gene categories and 5'UTR length: intron-containing genes and ribosomal protein genes have exclusively short 5'UTRs. We suggest that the abundance of short 5'UTRs may be related to a class of highly expressed genes that benefit the parasite's growth cycle. Also, the longer 5'UTRs may be playing a role in down-regulating expression of genes that require temporal or environment-induced expression.

Constrained intron structures in a microsporidian.

The 2.9-Mbp genome of the microsporidian Encephalitozoon cuniculi is severely reduced and compacted, possessing only 16 known tiny spliceosomal introns. Based on motif and expression data, intron profiles were constructed to screen the genome. Twenty additional introns were predicted and verified, doubling the previous estimate. We further predict that accurate 3' splice site (3'SS) selection is accomplished via a scanning mechanism with specificity achieved by maintaining a constrained variable length between the branch point motif and 3'SS. Only introns in ribosomal protein genes exhibit positional bias, and we hypothesize that splicing could be regulating expression of these genes. The large set of new introns in non-ribosomal protein genes suggests that current models of intron loss are unlikely sufficient to explain the distribution of introns. Together, these results extend our understanding of the role of intron loss in genome evolution and contribute to a novel model for splice site selection.

Splicing and transcription differ between spore and intracellular life stages in the parasitic microsporidia.

Microsporidia are a diverse group of highly derived fungal relatives that are intracellular parasites of many animals. Both transcription and introns have been shown to be unusual in microsporidia: The complete genome of the human parasite Encephalitozoon cuniculi has only a few very short introns, and two distantly related microsporidian spores have been shown to harbor transcripts encoding several genes that overlap on different strands. However, microsporidia alternate between two life stages: the intracellular proliferative stage and the extracellular and largely metabolically dormant infectious spore. To date, most studies have focused on the spore. Here, we have compared transcription profiles for a number of genes from both life stages of microsporidia and found major differences in both the prevalence of overlapping transcription and splicing. Specifically, spore transcripts in E. cuniculi have longer 5' untranslated regions, overlap more frequently with upstream genes, and have a significantly higher number of transcription initiation sites compared with intracellular transcripts from the same species. In addition, we demonstrate that splicing occurs exclusively in the intracellular stage and not in spore messenger RNAs (mRNAs) in both E. cuniculi and the distantly related Antonospora locustae. These differences between the microsporidian life stages raise questions about the functional importance of transcripts in the spore. We hypothesize that at least some transcripts in spores are a product of the cell's transition into a dormant state and that these unusual mRNAs could play a structural role rather than an informational one.

Alpha- and beta-tubulin phylogenies support a close relationship between the microsporidia Brachiola algerae and Antonospora locustae.

Microsporidia are a large and diverse group of intracellular parasites related to fungi. Much of our understanding of the relationships between microsporidia comes from phylogenies based on a single gene, the small subunit (SSU) rRNA, because only this gene has been sampled from diverse microsporidia. However, SSUrRNA trees are limited in their ability to resolve basal branches and some microsporidian affiliations are inconsistent between different analyses. Protein phylogenies have provided insight into relationships within specific groups of microsporidia, but have rarely been applied to the group as a whole. We have sequenced alpha- and beta-tubulins from microsporidia from three different subgroups, including representatives from what have previously been inferred to be the basal branches, allowing the broadest sampled protein-based phylogenetic analysis to date. Although some relationships remain unresolved, many nodes uniting subgroups are strongly supported and consistent in both individual trees as well as a concatenate of both tubulins. One such relationship that was previously unclear is between Brachiola algerae and Antonospora locustae, and their close association with Encephalitozoon and Nosema. Also, an uncultivated microsporidian that infects cyclopoid copepods is shown to be related to Edhazardia aedis.