[
Methods Cell Biol,
2011]
In Caenorhabditis elegans, newly transcribed RNA is processed in several novel ways. Although introns are removed by a canonical spliceosome, they have evolved several specialized features that reflect the differences in the way they are recognized and the way they are spliced. C. elegans introns are unusually short, in part because they have no specific branch-point sequences and contain minimal polypryimidine tracts. Instead, their 3' splice site is characterized by a highly conserved consensus sequence, which alone may be sufficient to position all spliceosomal elements at the 3' end of the intron. Many RNA molecules are also trans-spliced: a capped 22nt RNA leader is donated by one of a family of specialized snRNPs and spliced to an unpaired 3' splice site, usually just upstream of the start codon. The RNA upstream of this splice site, the outron, is removed during trans-splicing and presumably degraded, making the identification of the transcriptional start site problematic. Transcripts from approximately 70% of all genes are trans-spliced. Trans-splicing has enabled the evolution of operons - multigene clusters in which a single upstream promoter drives the transcription of a polycistronic pre-mRNA. The C. elegans genome contains more than 1000 such operons. The polycistronic pre-mRNA is processed into individual gene-encoding mRNAs by coordinated upstream 3' end formation and downstream trans-splicing. An intercistronic RNA sequence, the Ur element, plays a key role in specifying downstream trans-splicing.
[
WormBook,
2012]
About 70% of C. elegans mRNAs are trans-spliced to one of two 22 nucleotide spliced leaders. SL1 is used to trim off the 5' ends of pre-mRNAs and replace them with the SL1 sequence. This processing event is very closely related to cis-splicing, or intron removal. The SL1 sequence is donated by a 100 nt small nuclear ribonucleoprotein particle (snRNP), the SL1 snRNP. This snRNP is structurally and functionally similar to the U snRNAs (U1, U2, U4, U5 and U6) that play key roles in intron removal and trans-splicing, except that the SL1 snRNP is consumed in the process. More than half of C. elegans pre-mRNAs are subject to SL1 trans-splicing, whereas ~30% are not trans-spliced. The remaining genes are trans-spliced by SL2, which is donated by a similar snRNP, the SL2 snRNP. SL2 recipients are all downstream genes in closely spaced gene clusters similar to bacterial operons. They are transcribed from a promoter at the 5' end of the cluster of between 2 and 8 genes. This transcription makes a polycistronic pre-mRNA that is co-transcriptionally processed by cleavage and polyadenylation at the 3' end of each gene, and this event is closely coupled to the SL2 trans-splicing event that occurs only ~100 nt further downstream. SL2 trans-splicing requires a sequence between the genes, the Ur element, that likely base pairs with the 5' splice site on the SL2 snRNP, in a manner analogous to the interaction between the 5' splice site in cis-splicing with the U1 snRNP. The key difference is that in trans-splicing, the snRNP contains the 5' splice site, whereas in cis-splicing the pre-mRNA does. Some operons, termed "hybrid operons", contain an additional promoter between two genes that can express the downstream gene or genes with a developmental profile that is different from that of the entire operon. The operons contain primarily genes required for rapid growth, including genes whose products are needed for mitochondrial function and the basic machinery of gene expression. Recent evidence suggests that RNA polymerase is poised at the promoters of growth genes, and operons allow more efficient recovery from growth-arrested states, resulting in reduction in the need for this cache of inactive RNA polymerase.