Only two of the four sites of interaction with nuclear factors within the Xenopus U2 gene promoter are necessary for efficient transcription

Functional analysis of cis-acting DNA elements required for expression of the SL RNA gene in the parasitic protozoan Leishmania amazonensis

DNA sequences, that control expression of the spliced leader (SL) RNA gene in the parasitic protozoan Leishmania amazonensis, were mapped by block substitution mutagenesis. In the absence of a functional in vitro system for transcription, no promoter elements have yet been identified in this organism. We therefore developed an alternative in vivo approach, in which the SL RNA gene was tagged and then subjected to a series of linker scanning mutations. Each tagged and mutated SL RNA construct was introduced into parasite cells via the pX transfection vector, and was examined for expression of the tagged SL RNA followed by characterization of its transcriptional start site. The replacement of a critical DNA element was expected to prevent expression of the tagged SL RNA. We found that the putative SL RNA promoter is complex and includes two elements: one is located upstream to the coding region, between positions -30 to -70; and the other is located between -10 to +10, and includes transcribed sequences. In addition to the functional relationship between the SL RNA and vertebrate U snRNAs, we found structural similarities in their regulatory elements, which may possibly indicate a common evolutionary ancestry for these molecules.

The proximal promoter and the start site cooperate to specify correct U1 snRNA transcription initiation by RNA polymerase II

In this work, we attempted to gain insight into the detailed mechanism allowing correct transcription initiation of U1 snRNA genes by RNA polymerase II. Abolition of the CA motif residing at -1/+1 in the Xenopus U1 gene leads to a loss of the ability of the promoter to direct accurate initiation. A discrete site is selected only if a purine preceded by a pyrimidine is positioned at 58/57 bp downstream of the center of the PSE. The PSE alone is unable to designate a discrete initiation site. Rather, it serves to set the location of an initiation window without discriminating suitable from unsuitable initiation sites. The latter role is devoted to a PyPu sequence positioned at -1/+1. Therefore, it is the concomitant action of the PSE and an essential PyPu positioned at the proper distance from this promoter that specifies correct U1 snRNA transcription initiation by RNA polymerase II.

Octamer and SPH motifs in the U1 enhancer cooperate to activate U1 RNA gene expression

The transcriptional enhancer of a chicken U1 small nuclear RNA gene has been shown to extend over approximately 50 base pairs of DNA sequence located 180 to 230 base pairs upstream of the U1 transcription initiation site. It is composed of multiple functional motifs, including a GC box, an octamer motif, and a novel SPH motif. The contributions of these three distinct sequence motifs to enhancer function were studied with an oocyte expression assay. Under noncompetitive conditions in oocytes, the SPH motif is capable of stimulating U1 RNA transcription in the absence of the other functional motifs, whereas the octamer motif by itself lacks this ability. However, to form a transcription complex that is stable to challenge by a second competing small nuclear RNA transcription unit, both the octamer and SPH motifs are required. The GC box, although required for full enhancer activity, is not essential for stable complex formation in oocytes. Site-directed mutagenesis was used to study the DNA sequence requirements of the SPH motif. Functional activity of the SPH motif is spread throughout a 24-base-pair region 3' of the octamer but is particularly dependent upon sequences near an SphI restriction site located at the center of the SPH motif. Using embryonic chicken tissue as a source material, we identified and partially purified a factor, termed SBF, that binds sequence specifically to the SPH motif of the U1 enhancer. The ability of this factor to recognize and bind to mutant enhancer DNA fragments in vitro correlates with the functional activity of the corresponding enhancer sequences in vivo.

Octamer and SPH motifs in the U1 enhancer cooperate to activate U1 RNA gene expression

The transcriptional enhancer of a chicken U1 small nuclear RNA gene has been shown to extend over approximately 50 base pairs of DNA sequence located 180 to 230 base pairs upstream of the U1 transcription initiation site. It is composed of multiple functional motifs, including a GC box, an octamer motif, and a novel SPH motif. The contributions of these three distinct sequence motifs to enhancer function were studied with an oocyte expression assay. Under noncompetitive conditions in oocytes, the SPH motif is capable of stimulating U1 RNA transcription in the absence of the other functional motifs, whereas the octamer motif by itself lacks this ability. However, to form a transcription complex that is stable to challenge by a second competing small nuclear RNA transcription unit, both the octamer and SPH motifs are required. The GC box, although required for full enhancer activity, is not essential for stable complex formation in oocytes. Site-directed mutagenesis was used to study the DNA sequence requirements of the SPH motif. Functional activity of the SPH motif is spread throughout a 24-base-pair region 3' of the octamer but is particularly dependent upon sequences near an SphI restriction site located at the center of the SPH motif. Using embryonic chicken tissue as a source material, we identified and partially purified a factor, termed SBF, that binds sequence specifically to the SPH motif of the U1 enhancer. The ability of this factor to recognize and bind to mutant enhancer DNA fragments in vitro correlates with the functional activity of the corresponding enhancer sequences in vivo.

The Xenopus laevis U2 gene distal sequence element (enhancer) is composed of four subdomains that can act independently and are partly functionally redundant

The sequences involved in enhancement of transcription of the Xenopus U2 small nuclear RNA gene by the distal sequence element (DSE) of its promoter were analyzed in detail by microinjection of mutant genes into Xenopus oocytes. The DSE was shown to be roughly 60 base pairs long. Within this region, four motifs were found to contribute to DSE function: an ATGCAAAT octamer sequence, an SpI binding site, and two additional motifs which, since they are related in sequence, may bind the same transcription factor. These motifs were named D2 (for DSE; U2). Both the octamer sequence and the SpI site bound nuclear factors in vitro, but no factor binding to the D2 motifs was detected. All four elements were independently capable of enhancing transcription of the U2 gene to some extent. Furthermore, when assayed under both competitive and noncompetitive conditions, the individual units of the DSE displayed functional redundancy.

The Xenopus U2 gene PSE is a single, compact, element required for transcription initiation and 3' end formation

The proximal sequence element (PSE) of a Xenopus U2 snRNA gene has been analysed by extensive local mutagenesis. The PSE is compact, lying between -61 and -50 bp upstream of the transcription start site and is involved in signalling both transcription initiation and 3' end formation. No PSE mutants were found in which these two activities were differentially affected. Analysis of U2 gene promoters mutant in both the PSE and DSE failed to reveal any evidence for multiple signals involved in 3' end formation, leading to the conclusion that the PSE is the only promoter element required for this function. The U2 and U6 PSEs, which direct either pol II or both pol II and pol III transcription respectively, are shown to be functionally interchangeable. Apparent differences in human and Xenopus U2 gene PSE structure are discussed.

The Xenopus laevis U2 gene distal sequence element (enhancer) is composed of four subdomains that can act independently and are partly functionally redundant

The sequences involved in enhancement of transcription of the Xenopus U2 small nuclear RNA gene by the distal sequence element (DSE) of its promoter were analyzed in detail by microinjection of mutant genes into Xenopus oocytes. The DSE was shown to be roughly 60 base pairs long. Within this region, four motifs were found to contribute to DSE function: an ATGCAAAT octamer sequence, an SpI binding site, and two additional motifs which, since they are related in sequence, may bind the same transcription factor. These motifs were named D2 (for DSE; U2). Both the octamer sequence and the SpI site bound nuclear factors in vitro, but no factor binding to the D2 motifs was detected. All four elements were independently capable of enhancing transcription of the U2 gene to some extent. Furthermore, when assayed under both competitive and noncompetitive conditions, the individual units of the DSE displayed functional redundancy.

Common mechanisms of promoter recognition by RNA polymerases II and III

Recent results indicate that RNA polymerase III can use upstream promoters that are structurally and functionally very similar to those recognized by RNA polymerase II. The demonstration that RNA polymerases II and III can use the same transcription factors emphasizes the fundamental similarities between these distinct activities. It is also clear now that transcription factors can be functionally interchanged between distantly related species, indicating that the basic structures involved in promoter recognition are highly conserved throughout evolution.

Anti-OTF-1 antibodies inhibit NFIII stimulation of in vitro adenovirus DNA replication

HeLa cell OTF-1 has been purified on the basis of its DNA binding activity and used to raise a polyclonal rabbit antiserum. This antiserum is shown to recognize both native and denatured OTF-1 from both human and a similar protein from Xenopus culture cells, but to react either more weakly or not at all with the lymphoid cell-specific OTF-2. Separately, NFIII has been purified on the basis of its ability to stimulate Adenovirus DNA replication in vitro. On denaturing polyacrylamide gels OTF-1 and NFIII exhibit identical mobility. Anti-OTF-1 antiserum recognizes NFIII and neutralizes its stimulatory effect on DNA replication. Moreover, OTF-1 can functionally replace NFIII. Taken together with previously published DNA binding data, this indicates that OTF-1 and NFIII are either very closely related or identical.

Transcription analysis of a human U4C gene: involvement of transcription factors novel to snRNA gene expression

We have investigated the promoter requirements for in vivo transcription of a human U4C snRNA gene following transfection into HeLa cells. Two elements required for maximal U4C transcription were identified. The first, located upstream of -50, provides a basal level of transcription 2-3% of the full activity, and probably corresponds to the previously identified snRNA gene proximal element. The distal element, centered around -220, acts as a transcriptional enhancer and contains motifs for three previously recognized transcription factors: the octamer-binding protein, NF-A, which binds to motifs in the distal elements of other snRNA genes, and two factors not previously shown to be involved in snRNA gene transcription, cAMP response element binding protein (CREB) and AP-2. The octamer and putative AP-2 motifs are required for maximal transcription of the U4C gene. Specific binding of NF-A and CREB to the motifs in the distal element has been shown in vitro by DNase I and DMS methylation protection footprint competition analyses using HeLa nuclear extracts. The presence of a binding motif for the inducible factor CREB, together with the transcriptional requirement for the putative AP-2 motif, suggests a means by which expression of snRNA genes might be regulated.