The U1 snRNA gene repeat from the sea urchin (Strongylocentrotus purpuratus): the 70 kilobase tandem repeat ends directly 3'' to a U1 gene.

Lambda phage clones containing multiple copies of the 1.1 kb tandemly repeated unit of the sea urchin (S. purpuratus) U1 RNA genes were isolated from a gene library. The 1.1 kb repeat unit encodes a single copy of the predominant U1 RNA expressed in oocytes and embryos prior to the blastula stage. The tandem repeat unit is about 80 kb in size and is probably present one time per haploid genome as judged by pulsed-field electrophoresis of sperm DNA digested with restriction enzymes which do not cut in the repeat unit. Two of the phage contained DNA flanking the repeat unit as well as several repeat units. The tandem repeat unit ends just 3' to the U1 coding region. There is only limited homology in the 5' flanking region with U1 snRNA genes from the sea urchin L. variegatus.     

Domains of human U4atac snRNA required for U12-dependent splicing in vivo

U4atac snRNA forms a base-paired complex with U6atac snRNA. Both snRNAs are required for the splicing of the minor U12-dependent class of eukaryotic nuclear introns. We have developed a new genetic suppression assay to investigate the in vivo roles of several regions of U4atac snRNA in U12-dependent splicing. We show that both the stem I and stem II regions, which have been proposed to pair with U6atac snRNA, are required for in vivo splicing. Splicing activity also requires U4atac sequences in the 5' stem-loop element that bind a 15.5 kDa protein that also binds to a similar region of U4 snRNA. In contrast, mutations in the region immediately following the stem I interaction region, as well as a deletion of the distal portion of the 3' stem-loop element, were active for splicing. Complete deletion of the 3' stem-loop element abolished in vivo splicing function as did a mutation of the Sm protein binding site. These results show that the in vivo sequence requirements of U4atac snRNA are similar to those described previously for U4 snRNA using in vitro assays and provide experimental support for models of the U4atac/U6atac snRNA interaction.     

Functional analysis of the sea urchin U7 small nuclear RNA.

U7 small nuclear RNA (snRNA) is an essential component of the RNA-processing machinery which generates the 3' end of mature histone mRNA in the sea urchin. The U7 small nuclear ribonucleoprotein particle (snRNP) is classified as a member of the Sm-type U snRNP family by virtue of its recognition by both anti-trimethylguanosine and anti-Sm antibodies. We analyzed the function-structure relationship of the U7 snRNP by mutagenesis experiments. These suggested that the U7 snRNP of the sea urchin is composed of three important domains. The first domain encompasses the 5'-terminal sequences, up to about nucleotides 7, which are accessible to micrococcal nuclease, while the remainder of the RNA is highly protected and hence presumably bound by proteins. This region contains the sequence complementarities between the U7 snRNA and the histone pre-mRNA which have previously been shown to be required for 3' processing (F. Schaufele, G. M. Gilmartin, W. Bannwarth, and M. L. Birnstiel, Nature [London] 323:777-781, 1986). Nucleotides 9 to 20 constitute a second domain which includes sequences for Sm protein binding. The complementarities between the U7 snRNA sequences in this region and the terminal palindrome of the histone mRNA appear to be fortuitous and play only a secondary, if any, role in 3' processing. The third domain is composed of the terminal palindrome of U7 snRNA, the secondary structure of which must be maintained for the U7 snRNP to function, but its sequence can be drastically altered without any observable effect on snRNP assembly or 3' processing.     

The inability of the Psammechinus miliaris H3 RNA to be processed in the Xenopus oocyte is associated with sequences distinct from those highly conserved amongst sea urchin histone RNAs.

3' processing of precursors of the H3 RNA of the sea urchin Psammechinus miliaris in Xenopus oocytes is dependent upon sea urchin U7 snRNA. Sequences necessary for this interaction are highly conserved in all sea urchin histone precursor RNAs (including the Psammechinus H3) which, in contrast, are efficiently processed in the Xenopus oocyte without the addition of the homologous U7 snRNA. We resolve this seeming paradox by demonstrating here that the inability of the sea urchin Psammechinus miliaris H3 histone RNA to be processed in the Xenopus oocyte is associated with nucleotides immediately 3' to the conserved downstream sea urchin histone sequence element. Thus, a sequence-specific element (or lack of it) is responsible for the poor recognition of the Psammechinus H3 precursor RNA by the Xenopus processing machinery.     

Specific contacts between mammalian U7 snRNA and histone precursor RNA are indispensable for the in vitro 3'' RNA processing reaction.

We have made a detailed molecular analysis of the reactions leading to the formation of mature 3' ends in mammalian histone mRNAs. Using two analytical protocols we have identified an essential sequence motif in the downstream spacer which is consistently present, albeit in diffuse form, mammalian histone genes. Tampering with this sequence element completely abolishes 3' processing. However, 3' cleavage in vitro, although at a very much reduced rate, can be detected when the conserved hairpin is deleted from histone precursor mRNAs. U7 snRNA, previously shown to be essential for the maturation of sea urchin histone messages, was isolated from murine cells and the sequence was determined. The approximately 63-nucleotide, trimethyl-G-capped, murine U7 snRNA possesses a sequence shown in the sea urchin U7 to be required for Sm-precipitability, and like the sea urchin U7, the 3' end of murine U7 is encased in a hairpin structure. The 5' sequence of murine U7 exhibits extensive sequence complementarity to the conserved downstream motif of the histone precursor. As expected, oligo-nucleotide-directed RNase H cleavage of this portion of murine U7 inhibits the in vitro processing reaction. These experiments identify a set of specific contacts between mammalian U7 and histone precursor RNA which is indispensable for the maturation reaction.     

Structural and functional characterization of mouse U7 small nuclear RNA active in 3'' processing of histone pre-mRNA.

Oligonucleotides derived from the spacer element of the histone RNA 3' processing signal were used to characterize mouse U7 small nuclear RNA (snRNA), i.e., the snRNA component active in 3' processing of histone pre-mRNA. Under RNase H conditions, such oligonucleotides inhibited the processing reaction, indicating the formation of a DNA-RNA hybrid with a functional ribonucleoprotein component. Moreover, these oligonucleotides hybridized to a single nuclear RNA species of approximately 65 nucleotides. The sequence of this RNA was determined by primer extension experiments and was found to bear several structural similarities with sea urchin U7 snRNA. The comparison of mouse and sea urchin U7 snRNA structures yields some further insight into the mechanism of histone RNA 3' processing.     

Sox regulates transcription of the sea urchin arylsulfatase gene

A 50 bp region from -194 bp to -144 bp of the arylsulfatase gene (HpArs) of the sea urchin, Hemicentrotus pulcherrimus, is related to the temporally regulated expression of this gene. This region contains a Sox (Sry-related HMG box)-binding site, and the introduction of sequence mutations to this site significantly reduced the activity of the HpArs promoter, even in the presence of the C15 enhancer, which consists of HpOtx and CAAT motifs. A protein that binds to the Sox-binding site in the 50 bp region of the HpArs gene was detected in nuclear extracts of mesenchyme blastulae and a protein synthesized in vitro using SoxB1 cDNA of another sea urchin, Strongylocentrotus purpuratus, also bound to this Sox site. These results suggest that HpSox, which is maternally expressed and remains abundant by the pluteus stage, is clearly implicated in regulation of the HpArs gene. The presence of a negatively acting cis element in this 50 bp region has also been detected.     

Conserved sequences in the U2 snRNA-encoding genes of Kinetoplastida do not include the putative branchpoint recognition region

The U2 small nuclear RNA (snRNA) of Trypanosoma brucei gambiense, a flagellated protozoon of the order Kinetoplastida, is 148 nucleotides (nt) long, and thus the smallest U2 snRNA identified so far. To examine the evolutionary conservation of this RNA among Kinetoplastida, we have cloned and sequenced the U2 genes from Trypanosoma congolense and Leishmania mexicana amazonensis, which are 145 and 141 nt in length, respectively. The sequences of the Kinetoplastida U2 snRNAs are essentially identical in the 5' half of the molecule. Surprisingly, the putative branch site recognition sequence of L. m. amazonensis U2 snRNA shows two nt changes when compared with the other two U2 snRNAs. The sequence of the 3' half of the Kinetoplastida U2 snRNAs is less conserved with T. congolense and L. m. amazonensis RNAs showing 23 and 35 nt sequence variations, respectively, when compared with the corresponding sequence of the T. b. gambiense U2 snRNA. Alignment of the flanking regions of the U2 genes revealed several elements which are conserved both in sequence and in position relative to the U2 coding region and which may function in the biosynthesis of U2 snRNAs. One upstream element specifically binds protein factor(s) present in T. brucei nuclear extracts.     

Splicing factor slt11p and its involvement in formation of U2/U6 helix II in activation of the yeast spliceosome

Slt11p is a new splicing factor identified on the basis of synthetic lethality with a mutation in the 5' end of U2 snRNA, a region that is involved in intermolecular U2/U6 helix II interaction. Slt11p is required for spliceosome assembly. Our genetic results suggest that Slt11p is involved in the base-pairing interaction of U2/U6 helix II in vivo. We showed that the recombinant protein binds to RNAs with some degree of structural specificity. Slt11p also anneals RNA and binds to the resulting duplexes, which contain two separated helical regions. These RNA structures are reminiscent of U2/U6 helix II, which is formed concomitantly with U4/U6 stem II, and suggest that Slt11p facilitates the cooperative formation of helix II in association with stem II in the spliceosome. We show that Slt11p and Slu7p, a second-step factor, interact with each other both in vivo and in vitro and that the binding of Slu7p to Slt11p impairs the RNA-binding activity of the latter. These results suggest that the function of Slt11p is regulated by Slu7p in the spliceosome.