Nucleotide sequence determination and secondary structure of Xenopus U3 snRNA

Using a combination of RNA sequencing and construction of cDNA clones followed by DNA sequencing, we have determined the primary nucleotide sequence of U3 snRNA in Xenopus laevis and Xenopus borealis. This molecule has a length of 219 nucleotides. Alignment of the Xenopus sequences with U3 snRNA sequences from other organisms reveals three evolutionarily conserved blocks. We have probed the secondary structure of U3 snRNA in intact Xenopus laevis nuclei using single-strand specific chemical reagents; primer extension was used to map the positions of chemical modification. The three blocks of conserved sequences fall within single-stranded regions, and are therefore accessible for interaction with other molecules. Models of U3 snRNA function are discussed in light of these data.     

A pre-export U1 snRNP in Xenopus laevis oocyte nuclei.

We demonstrate that precursors of U1 snRNA are associated with nuclear proteins prior to export to the cytoplasm. The approximately 15S complexes containing pre-U1 RNA, which we call pre-export U1 snRNPs, were identified in extracts of Xenopus laevis oocyte nuclei that were synthesizing U1 RNAs from injected U1 genes. The U1 snRNP-specific A protein was associated with nuclear pre-U1 RNA since both this protein and the RNA were co-precipitated by antibodies directed against either the m7G-cap of the precursor RNA or the U1-A protein. The interaction of the U1-A protein with pre-U1 RNA required sequences in the loop II region although this region of U1 RNA was not necessary for the association of U1 A protein with mature U1 snRNPs. The U1 A protein helps protect pre-U1 RNA against degradation in the nucleus.     

Analysis of a gene cluster coding for the Xenopus laevis U7 snRNA.

A cluster of Xenopus laevis U7 snRNA genes has been isolated and sequenced. The gene structure is more compact than, but otherwise comparable to, the major U snRNA genes since the distal sequence element (DSE) is located only 4 nt upstream of the PSE. The corresponding RNA is present in the oocyte and accumulates early in oogenesis.     

Molecular analysis of dicot and monocot small nuclear RNA populations.

Oligonucleotides directed against conserved small nuclear RNA (snRNA) sequences have been used to identify the individual U1, U2, U4, U5, and U6 snRNAs in dicot and monocot nuclei. The plant snRNA populations are significantly more heterogeneous than the mammalian or Saccharomyces cerevisiae snRNA populations. U6 snRNA exists as a single species of similar size in monocot and dicot nuclei. The abundance and molecular weights of the U1, U2, U4, and U5 snRNAs expressed in monocot and dicot nuclei are significantly different. Whereas most dicot nuclei contain one or two predominant forms of U2 snRNA and a small number of U4 snRNAs, monocot nuclei contain multiple forms of U2 snRNA ranging from 208 to 260 nucleotides and multiple forms of U4 snRNA from 159 to 176 nucleotides. Multiple forms of U1 and U5 snRNA exist in both plant groups. All prominent size variants of U1, U2, U4, and U5 snRNA identified in monocot nuclei can be immunoprecipitated with anti-trimethylguanosine antibody. We conclude that the sizes and number of snRNA molecules involved in intron excision differ considerably in dicot and monocot nuclei. In wheat nuclei, we have identified an additional U1-like RNA that is differentially expressed during development.     

The genes coding for 4 snRNAs of Drosophila melanogaster: localization and determination of gene numbers.

Four small nuclear RNAs (snRNAs) have been isolated from Drosophila melanogaster flies. They have been characterized by base analysis, fingerprinting, and injection into Axolotl oocytes. The size of the molecules and the modified base composition suggest that the following correlations can be made: snRNA1 approximately U2-snRNA; snRNA2 approximately U3-snRNA; snRNA3 approximately U4-snRNA; snRNA4 approximately U6-snRNA. The snRNAs injected into Axolotl oocytes move into the nuclei, where they are protected from degradation. The genes coding for these snRNAs have been localized by "in situ" hybridization of 125-I-snRNAs to salivary gland chromosomes. Most of the snRNAs hybridize to different regions of the genome: snRNA1 to the cytological regions 39B and 40AB; snRNA2 to 22A, 82E, and 95C; snRNA3 to 14B, 23D, 34A, 35EF, 39B, and 63A; snRNA4 to 96A. The estimated gene numbers (Southern-blot analysis) are: snRNA1:3; snRNA2:7; snRNA3:7; snRNA4:1-3. The gene numbers correspond to the number of sites labeled on the polytene salivary gland chromosomes.     

Molecular comparison of monocot and dicot U1 and U2 snRNAs

To elucidate differences between the pre-mRNA splicing components in monocots and dicots, we have cloned and characterized several U1 and U2 snRNA sequence variants expressed in wheat seedling nuclei. Primer extension sequencing on wheat and pea snRNA populations has demonstrated that two 5'-terminal nucleotides found in most other U1 snRNAs are missing/modified in many plant U1 snRNAs. Comparison of the wheat U1 and U2 snRNA variants with their counterparts expressed in pea nuclei has defined regions of structural divergence between monocot and dicot U1 and U2 snRNAs. The U1 and U2 snRNA sequences involved in RNA:RNA interaction with pre-mRNAs are absolutely conserved. Significant differences occur between wheat and pea U1 snRNAs in stem I and II structures implicated in the binding of U1-specific proteins suggesting that the monocot and dicot U1-specific snRNP proteins differ in their binding specificities. Stem III structures, which are required in mammalian systems for splicing complex formation but not for U1-specific protein binding, differ more extensively than stems I, II, or IV. In U2 snRNAs, the sequence differences between these two species are primarily localized in stem III and in stem IV which has been implicated in snRNP protein binding. These differences suggest that monocot and dicot U1 and U2 snRNPs represent distinct entities that may have monocot- and dicot-specific snRNP protein variants associated with each snRNA.