Transcriptional elongation of the rat apolipoprotein A-I gene: identification and mapping of two arrest sites and their signals

Efficient transcription through an intron requires the binding of an Sm-type U1 snRNP with intact stem loop II to the splice donor

The mechanism behind the positive action of introns upon transcription and the biological significance of this positive feedback remains unclear. Functional ablation of splice sites within an HIV-derived env cDNA significantly reduced transcription that was rescued by a U1 snRNA modified to bind to the mutated splice donor (SD). Using this model we further characterized both the U1 and pre-mRNA structural requirements for transcriptional enhancement. U1 snRNA rescued as a mature Sm-type snRNP with an intact stem loop II. Position and sequence context for U1-binding is crucial because a promoter proximal intron placed upstream of the mutated SD failed to rescue transcription. Furthermore, U1-rescue was independent of promoter and exon sequence and is partially replaced by the transcription elongation activator Tat, pointing to an intron-localized block in transcriptional elongation. Thus, transcriptional coupling of U1 snRNA binding to the SD may licence the polymerase for transcription through the intron.

Regulation of RelB expression during the initiation of dendritic cell differentiation

The transcription factor RelB is required for proper development and function of dendritic cells (DCs), and its expression is upregulated early during differentiation from a variety of progenitors. We explored this mechanism of upregulation in the KG1 cell line model of a DC progenitor and in the differentiation-resistant KG1a subline. RelB expression is relatively higher in untreated KG1a cells but is upregulated only during differentiation of KG1 by an early enhancement of transcriptional elongation, followed by an increase in transcription initiation. Restoration of protein kinase CbetaII (PKCbetaII) expression in KG1a cells allows them to differentiate into DCs. We show that PKCbetaII also downregulated constitutive expression of NF-kappaB in KG1a-transfected cells and restores the upregulation of RelB during differentiation by increased transcriptional initiation and elongation. The two mechanisms are independent and sensitive to PKC signaling levels. Conversely, RelB upregulation was inhibited in primary human monocytes where PKCbetaII expression was knocked down by small interfering RNA targeting. Altogether, the data show that RelB expression during DC differentiation is controlled by PKCbetaII-mediated regulation of transcriptional initiation and elongation.

Delay in synthesis of the 3' splice site promotes trans-splicing of the preceding 5' splice site

Premessenger RNA (pre-mRNA) splicing can occur within an individual pre-mRNA (cis-splicing) or between separate pre-mRNAs (trans-splicing). Although a number of examples of mammalian trans-splicing have been reported, the molecular mechanisms involved are poorly understood. Here, we investigate the mechanisms of Sp1 pre-mRNA trans-splicing with human cells expressing modified Sp1 transgenes. We find that the presence of a long intron or the insertion of an RNA polymerase II pause site within an intron promotes trans-splicing. We also add examples of naturally occurring trans-splicing. We propose that Sp1 trans-splicing, and other examples of mammalian trans-splicing, are a consequence of low-frequency disruption of the normal mechanisms that couple transcription and splicing.