Faithful in vitro transcription by fission yeast RNA polymerase III reveals unique alpha-amanitin sensitivity

Transcription with fission yeast (Schizosaccharomyces pombe) RNA polymerase III (pol III) was studied in two different in vitro systems. Reactions performed with isolated nuclei gave rise to 5S and pre-tRNA molecules. Because the alpha-amanitin sensitivity of that reaction clearly differed from what has been observed with pol III enzymes of other eukaryotes, a cell-free S. pombe transcription extract was developed and analyzed with the homologous 7S L RNA (srp RNA; signal recognition particle RNA) gene. Synthesis of 7S L RNA was found to be sensitive to high concentrations of alpha-amanitin, with 50% reduction seen at 400 microg/ml of the toxin. However, even with very high alpha-amanitin concentrations, exceeding 1 mg/ml, no full inhibition of the S. pombe pol III enzyme could be obtained. Together, these results demonstrate that in contrast to the yeast Saccharomyces cerevisiae, pol III from S. pombe is sensitive to high concentrations of alpha-amanitin, yet with a clearly different dose response than that observed with the corresponding RNA polymerase of higher eukaryotes. Furthermore, while the S. pombe 7S L RNA gene was efficiently transcribed in HeLa cell extracts, the human 7S L RNA gene was not actively transcribed in the S. pombe system. This finding of divergent promoter structures of both genes was verified by the analysis of 5' deletion mutants of the S. pombe 7S L RNA gene.

Unconventional rules of small nuclear RNA transcription and cap modification in trypanosomatids

This review focuses on the spliced leader (SL) RNA and uridylic acid-rich small nuclear RNAs (U-snRNAs) involved in pre-mRNA processing in trypanosomatid protozoa, with particular emphasis on the mechanism of transcription and cap formation. The SL RNA plays a central role in mRNA biogenesis by providing the unique cap 4 structure to the 5' end of all mRNAs by trans-splicing. The trimethylguanosine capped U-snRNAs, on the other hand, represent an unusual example among eukaryotic snRNAs in that they are transcribed by RNA polymerase III. This implies the existence of a distinctive mechanism for capping enzyme selection by the transcriptional machinery. Furthermore, the transcription units of U-snRNA genes offer yet another example of the variety of choices that have been established during eukaryotic evolution, namely that an upstream tRNA gene or tRNA-like gene provides extragenic promoter elements for a downstream small RNA gene.

Novel TRF1/BRF target genes revealed by genome-wide analysis of Drosophila Pol III transcription

Metazoans have evolved multiple paralogues of the TATA binding protein (TBP), adding another tunable level of gene control at core promoters. While TBP-related factor 1 (TRF1) shares extensive homology with TBP and can direct both Pol II and Pol III transcription in vitro, TRF1 target sites in vivo have remained elusive. Here, we report the genome-wide identification of TRF1-binding sites using high-resolution genome tiling microarrays. We found 354 TRF1-binding sites genome-wide with approximately 78% of these sites displaying colocalization with BRF. Strikingly, the majority of TRF1 target genes are Pol III-dependent small noncoding RNAs such as tRNAs and small nonmessenger RNAs. We provide direct evidence that the TRF1/BRF complex is functionally required for the activity of two novel TRF1 targets (7SL RNA and small nucleolar RNAs). Our studies suggest that unlike most other eukaryotic organisms that rely on TBP for Pol III transcription, in Drosophila and possibly other insects the alternative TRF1/BRF complex appears responsible for the initiation of all known classes of Pol III transcription.

Human La is found at RNA polymerase III-transcribed genes in vivo

The human La autoantigen can bind to nascent RNA transcripts and has also been postulated to act as an RNA polymerase III (pol III) transcription initiation and termination factor. Here, we show by chromatin immunoprecipitation (ChIP) that La is associated with pol III-transcribed genes in vivo. In contrast, the Ro autoantigen, which can also bind pol III transcripts, is not found at these genes. The putative pol III transcription factors NF1 and TFIIA are also not detected at class III genes. Binding of La remains when transcription is repressed at mitosis and does not correlate with the presence of polymerase at the gene. However, gene occupancy depends on the phosphorylation status of La, with the less prevalent, unphosphorylated form being found selectively on pol III templates.

Nucleotide excision repair and photolyase preferentially repair the nontranscribed strand of RNA polymerase III-transcribed genes in Saccharomyces cerevisiae

A high-resolution primer extension technique was used to study the relationships between repair, transcription, and mutagenesis in RNA polymerase III transcribed genes in Saccharomyces cerevisiae. The in vivo repair of UV-induced DNA damage by nucleotide excision repair (NER) and by photoreactivation is shown to be preferential for the nontranscribed strand (NTS) of the SNR6 gene. This is in contrast to RNA polymerase II genes in which the NER is preferential for the transcribed strand (TS). The repair-strand bias observed in SNR6 was abolished by inactivation of transcription in a snr6Delta2 mutant, showing a contribution of RNA polymerase III transcription in this phenomenon. The same strand bias for NER (slow in TS, fast in NTS) was discovered in the SUP4 gene, but only outside of the intragenic promoter element (box A). Unexpectedly, the repair in the transcribed box A was similar on both strands. The strand specificity as well as the repair heterogeneity determined in the transcribed strand of the SUP4 gene, correlate well with the previously reported site- and strand-specific mutagenesis in this gene. These findings present a novel view regarding the relationships between DNA repair, mutagenesis, and transcription.