Intron definition in splicing of small Drosophila introns.

Approximately half of the introns in Drosophila melanogaster are too small to function in a vertebrate and often lack the pyrimidine tract associated with vertebrate 3' splice sites. Here, we report the splicing and spliceosome assembly properties of two such introns: one with a pyrimidine-poor 3' splice site and one with a pyrimidine-rich 3' splice site. The pyrimidine-poor intron was absolutely dependent on its small size for in vivo and in vitro splicing and assembly. As such, it had properties reminiscent of those of yeast introns. The pyrimidine-rich intron had properties intermediate between those of yeasts and vertebrates. This 3' splice site directed assembly of ATP-dependent complexes when present as either an intron or exon and supported low levels of in vivo splicing of a moderate-length intron. We propose that splice sites can be recognized as pairs across either exons or introns, depending on which distance is shorter, and that a pyrimidine-rich region upstream of the 3' splice site facilitates the exon mode.     

Mutation of putative branchpoint consensus sequences in plant introns reduces splicing efficiency

Intron lariat formation between the 5' end of an intron and a branchpoint adenosine is a fundamental aspect of the first step in animal and yeast nuclear pre-mRNA splicing. Despite similarities in intron sequence requirements and the components of splicing, differences exist between the splicing of plant and vertebrate introns. The identification of AU-rich sequences as major functional elements in plant introns and the demonstration that a branchpoint consensus sequence was not required for splicing have led to the suggestion that the transition from AU-rich intron to GC-rich exon is a major potential signal by which plant pre-mRNA splice sites are recognized. The role of putative branchpoint sequences as an internal signal in plant intron recognition/definition has been re-examined. Single nucleotide mutations in putative branchpoint adenosines contained within CUNAN sequences in four different plant introns all significantly reduced splicing efficiency. These results provide the most direct evidence to date for preferred branchpoint sequences being required for the efficient splicing of at least some plant introns in addition to the important role played by AU sequences in dicot intron recognition. The observed patterns of 3' splice site selection in the introns studied are consistent with the scanning model described for animal intron 3' splice site selection. It is suggested that, despite the clear importance of AU sequences for plant intron splicing, the fundamental processes of splice site selection and splicing in plants are similar to those in animals.     

Different effects of intron nucleotide composition and secondary structure on pre-mRNA splicing in monocot and dicot plants.

We have found previously that the sequences important for recognition of pre-mRNA introns in dicot plants differ from those in the introns of vertebrates and yeast. Neither a conserved branch point nor a polypyrimidine tract, found in yeast and vertebrate introns respectively, are required. Instead, AU-rich sequences, a characteristic feature of dicot plant introns, are essential. Here we show that splicing in protoplasts of maize, a monocot, differs significantly from splicing in a dicot, Nicotiana plumbaginifolia. As in the case of dicots, a conserved branch point and a polypyrimidine tract are not required for intron processing in maize. However, unlike in dicots, AU-rich sequences are not essential, although their presence facilitates splicing if the splice site sequences are not optimal. The lack of an absolute requirement for AU-rich stretches in monocot introns in reflected in the occurrence of GC-rich introns in monocots but not in dicots. We also show that maize protoplasts are able to process a mammalian intron and short introns containing stem--loops, neither of which are spliced in N.plumbaginifolia protoplasts. The ability of maize, but not of N.plumbaginifolia to process stem--loop-containing or GC-rich introns suggests that one of the functions of AU-rich sequences during splicing of dicot plant pre-mRNAs may be to minimize secondary structure within the intron.     

A downstream splicing enhancer is essential for in vitro pre-mRNA splicing.

Splicing enhancers have previously been shown to promote processing of introns containing weak splicing signals. Here, we extend these studies by showing that also 'strong' constitutively active introns are absolutely dependent on a downstream splicing enhancer for activity in vitro. SR protein binding to exonic enhancer elements or U1 snRNP binding to a downstream 5' splice site serve redundant functions as activators of splicing. We further show that a 5' splice site is most effective as an enhancer of splicing. Thus, a 5' splice site is functional in S100 extracts, under conditions where a SR enhancer is nonfunctional. Also, splice site pairing occurs efficiently in the absence of exonic SR enhancers, emphasizing the significance of a downstream 5' splice site as the enhancer element in vertebrate splicing.     

Cryptic splice sites and split genes

We describe a new program called cryptic splice finder (CSF) that can reliably identify cryptic splice sites (css), so providing a useful tool to help investigate splicing mutations in genetic disease. We report that many css are not entirely dormant and are often already active at low levels in normal genes prior to their enhancement in genetic disease. We also report a fascinating correlation between the positions of css and introns, whereby css within the exons of one species frequently match the exact position of introns in equivalent genes from another species. These results strongly indicate that many introns were inserted into css during evolution and they also imply that the splicing information that lies outside some introns can be independently recognized by the splicing machinery and was in place prior to intron insertion. This indicates that non-intronic splicing information had a key role in shaping the split structure of eukaryote genes.     

Identification and experimental validation of splicing regulatory elements in Drosophila melanogaster reveals functionally conserved splicing enhancers in metazoans

RNA sequence elements involved in the regulation of pre-mRNA splicing have previously been identified in vertebrate genomes by computational methods. Here, we apply such approaches to predict splicing regulatory elements in Drosophila melanogaster and compare them with elements previously found in the human, mouse, and pufferfish genomes. We identified 99 putative exonic splicing enhancers (ESEs) and 231 putative intronic splicing enhancers (ISEs) enriched near weak 5' and 3' splice sites of constitutively spliced introns, distinguishing between those found near short and long introns. We found that a significant proportion (58%) of fly enhancer sequences were previously reported in at least one of the vertebrates. Furthermore, 20% of putative fly ESEs were previously identified as ESEs in human, mouse, and pufferfish; while only two fly ISEs, CTCTCT and TTATAA, were identified as ISEs in all three vertebrate species. Several putative enhancer sequences are similar to characterized binding-site motifs for Drosophila and mammalian splicing regulators. To provide additional evidence for the function of putative ISEs, we separately identified 298 intronic hexamers significantly enriched within sequences phylogenetically conserved among 15 insect species. We found that 73 putative ISEs were among those enriched in conserved regions of the D. melanogaster genome. The functions of nine enhancer sequences were verified in a heterologous splicing reporter, demonstrating that these sequences are sufficient to enhance splicing in vivo. Taken together, these data identify a set of predicted positive-acting splicing regulatory motifs in the Drosophila genome and reveal regulatory sequences that are present in distant metazoan genomes.     

Bacteriophage introns: parasites within parasites?

Several bacteriophage introns carry the information necessary to perform a complex series of RNA as well as DNA rearrangements. The RNA splicing reactions allow expression of the intron-containing genes, whereas recombination at the DNA level results in the mobility and invasive potential of the introns. The RNA and DNA transactions are temporally regulated to permit timely splicing early in infection, and expression of intron-encoded DNA endonucleases involved in mobility at late times. This is achieved through efficient use of the viral regulatory machinery, ensuring the perpetuation of the 'parasitic' introns.     

Fine structure of ribosomal RNA. IV. Extraordinary evolutionary conservation in sequences that flank introns in rDNA.

By hybridization and DNA sequencing, we have defined a specific region in Xenopus rDNA that is extremely conserved between Tetrahymena, a protozoan, and Xenopus, a vertebrate. This highly conserved region is found at the site where an intron has been shown to interrupt Tetrahymena rDNA [1,2], although we have not detected introns in genomic or cloned Xenopus rDNA. We have noted that the sequences corresponding to nuclear rDNA interon-flanking regions show an intriguing complementarity to tRNAiMet. This suggests possible models for tRNA-rRNA interactions in protein synthesis and/or rRNA splicing.     

The Peculiarities of Large Intron Splicing in Animals

In mammals a considerable 92% of genes contain introns, with hundreds and hundreds of these introns reaching the incredible size of over 50,000 nucleotides. These “large introns” must be spliced out of the pre-mRNA in a timely fashion, which involves bringing together distant 5′ and 3′ acceptor and donor splice sites. In invertebrates, especially Drosophila, it has been shown that larger introns can be spliced efficiently through a process known as recursive splicing—a consecutive splicing from the 5′-end at a series of combined donor-acceptor splice sites called RP-sites. Using a computational analysis of the genomic sequences, we show that vertebrates lack the proper enrichment of RP-sites in their large introns, and, therefore, require some other method to aid splicing. We analyzed over 15,000 non-redundant, large introns from six mammals, 1,600 from chicken and zebrafish, and 560 non-redundant large introns from five invertebrates. Our bioinformatic investigation demonstrates that, unlike the studied invertebrates, the studied vertebrate genomes contain consistently abundant amounts of direct and complementary strand interspersed repetitive elements (mainly SINEs and LINEs) that may form stems with each other in large introns. This examination showed that predicted stems are indeed abundant and stable in the large introns of mammals. We hypothesize that such stems with long loops within large introns allow intron splice sites to find each other more quickly by folding the intronic RNA upon itself at smaller intervals and, thus, reducing the distance between donor and acceptor sites.     

Splicing signals and factors in plant intron removal

Constitutive splicing of the potato invertase mini-exon 2 (9 nt long) requires a branchpoint sequence positioned around 50 nt upstream of the 5' splice site of the adjacent intron and a U(11) element found just downstream of the branchpoint in the upstream intron [Simpson, Hedley, Watters, Clark, McQuade, Machray and Brown (2000) RNA 6, 422-433]. The sensitivity of this in vivo plant splicing system has been used to demonstrate exon scanning in plants, and to characterize plant intronic elements, such as branchpoint and poly-pyrimidine tract sequences. Plant introns differ from their vertebrate and yeast counterparts in being UA- or U-rich (up to 85% UA). One of the key differences in splicing between plants and other eukaryotes lies in early intron recognition, which is thought to be mediated by UA-binding proteins. We are adopting three approaches to studying the RNA-protein interactions in plant splicing. First, overexpression of plant splicing factors and, in particular, UA-binding proteins, in conjunction with a range of mini-exon mutants. Secondly, the sequences of around 65% of vertebrate and yeast splicing factors have high-quality matches to Arabidopsis proteins, opening the door to identification and analysis of gene knockouts. Finally, to discover plant-specific proteins involved in splicing and in, for example, rRNA or small nuclear RNA processing, green fluorescent protein-cDNA fusion libraries in viral vectors are being screened.     

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.     

Branchpoint selection in the splicing of U12-dependent introns in vitro

In metazoans, splicing of introns from pre-mRNAs can occur by two pathways: the major U2-dependent or the minor U12-dependent pathways. Whereas the U2-dependent pathway has been well characterized, much about the U12-dependent pathway remains to be discovered. Most of the information regarding U12-type introns has come from in vitro studies of a very few known introns of this class. To expand our understanding of U12-type splicing, especially to test the hypothesis that the simple base-pairing mechanism between the intron and U12 snRNA defines the branchpoint of U12-dependent introns, additional in vitro splicing substrates were created from three putative U12-type introns: the third intron of the Xenopus RPL1 a gene (XRP), the sixth intron of the Xenopus TFIIS.oA gene (XTF), and the first intron of the human Sm E gene (SME). In vitro splicing in HeLa nuclear extract confirmed U12-dependent splicing of each of these introns. Surprisingly, branchpoint mapping of the XRP splicing intermediate shows use of the upstream rather than the downstream of two consecutive adenosines within the branchpoint sequence (BPS), contrary to the prediction based on alignment with the sixth intron of human P120, a U12-dependent intron whose branch site was previously determined. Also, in the SME intron, the position of the branchpoint A residue within the region base paired with U12 differs from that in P120 and XTF. Analysis of these three additional introns therefore rules out simple models for branchpoint selection by the U12-type spliceosome.     

Analysis of the role of Caenorhabditis elegans GC-AG introns in regulated splicing

GC-AG introns represent 0.7% of total human pre-mRNA introns. To study the function of GC-AG introns in splicing regulation, 196 cDNA-confirmed GC-AG introns were identified in Caenorhabditis elegans. These represent 0.6% of the cDNA- confirmed intron data set for this organism. Eleven of these GC-AG introns are involved in alternative splicing. In a comparison of the genomic sequences of homologous genes between C.elegans and Caenorhabditis briggsae for 26 GC-AG introns, the C at the +2 position is conserved in only five of these introns. A system to experimentally test the function of GC-AG introns in alternative splicing was developed. Results from these experiments indicate that the conserved C at the +2 position of the tenth intron of the let-2 gene is essential for developmentally regulated alternative splicing. This C allows the splice donor to function as a very weak splice site that works in balance with an alternative GT splice donor. A weak GT splice donor can functionally replace the GC splice donor and allow for splicing regulation. These results indicate that while the majority of GC-AG introns appear to be constitutively spliced and have no evolutionary constraints to prevent them from being GT-AG introns, a subset of GC-AG introns is involved in alternative splicing and the C at the +2 position of these introns can have an important role in splicing regulation.