RNA polymerases IV and V influence the 3' boundaries of Polymerase II transcription units in Arabidopsis.

Nuclear multisubunit RNA polymerases IV and V (Pol IV and Pol V) evolved in plants as specialized forms of Pol II. Their functions are best understood in the context of RNA-directed DNA methylation (RdDM), a process in which Pol IV-dependent 24 nt siRNAs direct the de novo cytosine methylation of regions transcribed by Pol V. Pol V has additional functions, independent of Pol IV and 24 nt siRNA biogenesis, in maintaining the repression of transposons and genomic repeats whose silencing depends on maintenance cytosine methylation. Here we report that Pol IV and Pol V play unexpected roles in defining the 3' boundaries of Pol II transcription units. Nuclear run-on assays reveal that in the absence of Pol IV or Pol V, Pol II occupancy downstream of poly A sites increases for approximately 12% of protein-coding genes. This effect is most pronounced for convergently transcribed gene pairs. Although Pols IV and V are detected near transcript ends of the affected Pol II - transcribed genes, their role in limiting Pol II read-through is independent of siRNA biogenesis or cytosine methylation for the majority of these genes. Interestingly, we observed that splicing was less efficient in pol IV or pol V mutant plants, compared to wild-type plants, suggesting that Pol IV or Pol V might affect pre-mRNA processing. We speculate that Pols IV and V (and/or their associated factors) play roles in Pol II transcription termination and pre-mRNA splicing by influencing polymerase elongation rates and/or release at collision sites for convergent genes.

Analysis of Viral Promoter Usage in EBV-Infected Cell Lines: A Comparison of qPCR Following Conventional RNA Isolation and Nuclear Run-On Assay.

To interpret the results of an epigenetic analysis in gene expression studies, it is essential to characterize the activity of the relevant promoters. According to the literature, real-time PCR assay is the most widely used method for the determination of latent EBV promoter usage. Here we describe two alternative approaches to measure the activity of viral promoters in cell lines carrying latent EBV episomes. The widespread typical approach relies on total cellular RNA isolation, whereas the nuclear run-on assay described here is based on the initial isolation of nuclei, followed by in vitro transcription in the presence of biotinylated-UTP, and purification of RNA transcripts using avidin-coated magnetic beads. Finally, both methods apply reverse transcription-based real-time PCR (i.e., quantitative polymerase chain reaction, qPCR) to quantitatively measure the amount of specific transcripts. We shall describe these methods step by step and demonstrate their use for the determination of EBER1 promoter activity in EBV-positive cell lines.

Genome-Wide Analysis of Nascent Transcription in Saccharomyces cerevisiae.

The assessment of transcriptional regulation requires a genome-wide survey of active RNA polymerases. Thus, we combined the nuclear run-on assay, which labels and captures nascent transcripts, with high-throughput DNA sequencing to examine transcriptional activity in exponentially growing Saccharomyces cerevisiae. Sequence read data from these nuclear run-on libraries revealed that transcriptional regulation in yeast occurs not only at the level of RNA polymerase recruitment to promoters but also at postrecruitment steps. Nascent synthesis signals are strongly enriched at TSS throughout the yeast genome, particularly at histone loci. Nascent transcripts reveal antisense transcription for more than 300 genes, with the read data providing support for the activity of distinct promoters driving transcription in opposite directions rather than bidirectional transcription from single promoters. By monitoring total RNA in parallel, we found that transcriptional activity accounts for 80% of the variance in transcript abundance. We computed RNA stabilities from nascent and steady-state transcripts for each gene and found that the most stable and unstable transcripts encode proteins whose functional roles are consistent with these stabilities. We also surveyed transcriptional activity after heat shock and found that most, but not all, heat shock-inducible genes increase their abundance by increasing their RNA synthesis. In summary, this study provides a genome-wide view of RNA polymerase activity in yeast, identifies regulatory steps in the synthesis of transcripts, and analyzes transcript stabilities.