Insect small nuclear RNA gene promoters evolve rapidly yet retain conserved features involved in determining promoter activity and RNA polymerase specificity

In animals, most small nuclear RNAs (snRNAs) are synthesized by RNA polymerase II (Pol II), but U6 snRNA is synthesized by RNA polymerase III (Pol III). In Drosophila melanogaster, the promoters for the Pol II-transcribed snRNA genes consist of approximately 21 bp PSEA and approximately 8 bp PSEB. U6 genes utilize a PSEA but have a TATA box instead of the PSEB. The PSEAs of the two classes of genes bind the same protein complex, DmSNAPc. However, the PSEAs that recruit Pol II and Pol III differ in sequence at a few nucleotide positions that play an important role in determining RNA polymerase specificity. We have now performed a bioinformatic analysis to examine the conservation and divergence of the snRNA gene promoter elements in other species of insects. The 5' half of the PSEA is well-conserved, but the 3' half is divergent. Moreover, within each species positions exist where the PSEAs of the Pol III-transcribed genes differ from those of the Pol II-transcribed genes. Interestingly, the specific positions vary among species. Nevertheless, we speculate that these nucleotide differences within the 3' half of the PSEA act similarly to induce conformational alterations in DNA-bound SNAPc that result in RNA polymerase specificity.     

Characterisation of sequences required for RNA initiation from the PGK promoter of Saccharomyces cerevisiae.

In the phosphoglycerate kinase (PGK) gene of yeast, as in other highly expressed yeast genes, the sequences surrounding the site of RNA initiation have a loosely conserved structure of a CT rich stretch followed by the tetranucleotide CAAG. Using internal deletions and insertions we have identified the elements in the PGK promoter which are required for correct RNA initiation at the CAAG sequence at -39. The results indicate that two different components of the PGK promoter contribute to correct RNA initiation, the TATA homologies, located at -152 and -113, and the sequences at the site of initiation. Both TATA elements can function in RNA initiation. Deletion of the upstream TATA element, TATAI, results in slightly heterogeneous RNA initiation, but the majority of the RNA initiates correctly. Deletion of both the PGK TATA elements results in the majority of the RNA initiating at sites downstream from the wild-type I site, within the structural gene between +40 to +80. The CT rich box is not essential for correct mRNA initiation as shown by deletion analysis. The site of RNA initiation in the PGK promoter appears to be determined by sequences located immediately 5' of the CAAG sequence motif. This short sequence, ACAGATC, when located the correct distance from the TATA elements may be sufficient to determine a discrete initiation site.