High evolutionary conservation of the secondary structure and of certain nucleotide sequences of U5 RNA.

The nucleotide sequence of chicken, pheasant, duck and Tetrahymena pyriformis U5 RNAs as well as that of new mammalian variant U5 RNAs was determined and compared to that of rat and HeLa cells U5 RNAs. Primary structure conservation is about 95% between rat and human cells, 82% between mammals and birds and 57% between the Protozoan and mammals. The same model of secondary structure, a free single-stranded region flanked by two hairpins can be constructed from all RNAs and is identical to the model previously proposed for mammalian U5 RNA on an experimental basis (1). Thus, this model is confirmed and is likely to be that of an ancestor U5 RNA. The 3' region of the U5 RNA molecule constitutes domain A, and is common to U1, U2, U4 and U5 RNAs (2). The characteristic nucleotide sequences of domain A are highly conserved throughout the phylogenetic evolution of U5 RNA suggesting that they are important elements in the function of the four small RNAs. Another region of high evolutionary conservation is the top part of the 5' side hairpin whose conserved sequence is specific to U5 RNA. It might participate in the particular function of U5 RNA.     

U2 RNA shares a structural domain with U1, U4, and U5 RNAs.

We previously reported common structural features within the 3'-terminal regions of U1, U4, and U5 RNAs. To check whether these features also exist in U2 RNA, the primary and secondary structures of the 3'-terminal regions of chicken, pheasant, and rat U2 RNAs were examined. Whereas no difference was observed between pheasant and chicken, the chicken and rat sequences were only 82.5% homologous. Such divergence allowed us to propose a unique model of secondary structure based on maximum base-pairing and secondary structure conservation. The same model was obtained from the results of limited digestion of U2 RNA with various nucleases. Comparison of this structure with those of U1, U4, and U5 RNAs shows that the four RNAs share a common structure designated as domain A, and consisting of a free single-stranded region with the sequence Pu-A-(U)n-G-Pup flanked by two hairpins. The hairpin on the 3' side is very stable and has the sequence Py-N-Py-Gp in the loop. The presence of this common domain is discussed in connection with relationships among U RNAs and common protein binding sites.     

The nuclear 5S RNAs from chicken, rat and man. U5 RNAs are encoded by multiple genes

Preparations of chicken, rat and human nuclear 5S RNA contain two sets of molecules. The set with the lowest electrophoretic mobility (5Sa) contains RNAs identical or closely related to ribosomal 5S RNA from the corresponding animal species. In HeLa cells and rat brain, we only detected an RNA identical to the ribosomal 5S RNA. In hen brain and liver, we found other species differing by a limited number of substitutions. The results suggest that mutated 5S genes may be expressed differently according to the cell type. The set with the highest mobility corresponds to U5 RNA. In both rat brain and HeLa cells, U5 RNA was found to be composed of 4 and 5 different molecules respectively (U5A, U5B1-4) differing by a small number of substitutions or insertions. In hen brain, no U5B was detected but U5A' differing from U5A by the absence of the 3'-terminal adenosine. All the U5 RNAs contain the same set of modified nucleotides. They also have the same secondary structure which consists of two hairpins joined together by a 17 nucleotide long single-stranded region. The 3' half of the molecule has a compact conformation. Together, the results suggest that U5 RNAs are transcribed from a multigene family and that mutated genes may be expressed as far as secondary structure is conserved. The conformation of U5 RNA is likely to be related to its function and it is of interest to mention that several similarities of structure are found between U5 and U1A RNA.     

Structure analysis of the 5' external transcribed spacer of the precursor ribosomal RNA from Saccharomyces cerevisiae.

Full-length precursor ribosomal RNA molecules were produced in vitro using as a template, a plasmid containing the yeast 35 S pre-rRNA gene under the control of the phage T3 promoter. The higher-order structure of the 5'-external transcribed spacer (5' ETS) sequence in the 35S pre-rRNA molecule was studied using dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluenesulfonate, RNase T1 and RNase V1 as structure-sensitive probes. Modified residues were detected by primer extension. Data produced were used to evaluate several theoretical structure models predicted by minimum free-energy calculations. A model for the entire 5'ETS region is proposed that accommodates 82% of the residues experimentally shown to be in either base-paired or single-stranded structure in the correct configuration. The model contains a high degree of secondary structure with ten stable hairpins of varying lengths and stabilities. The hairpins are composed of the Watson-Crick A.T and G.C pairs plus the non-canonical G.U pairs. Based on a comparative analysis of the 5' ETS sequence from Saccharomyces cerevisiae and Schizosaccharomyces pombe, most of the base-paired regions in the proposed model appear to be phylogenetically supported. The two sites previously shown to be crosslinked to U3 snRNA as well as the previously proposed recognition site for processing and one of the early processing site (based on sequence homology to the vertebrate ETS cleavage site) are located in single-stranded regions in the model. The present folding model for the 5' ETS in the 35 S pre-rRNA molecule should be useful in the investigations of the structure, function and processing of pre-rRNA.     

稳定的RNA发夹结构及其生物学功能

以UNCG、GNRA、CUUG(N=A、U、C或G,R=G或A)为端环能够形成稳定的、保守的发夹结构。高分辨率的溶液结构、晶体结构和计算机模拟等方法从原子水平上解析了这些发夹特殊的结构特征。在体内,它们发挥着重要的生物学功能:在折叠过程中作为折叠的起始位置帮助组织RNA分子正确折叠;与核酸受体结合参与三级相互作用;与蛋白质发生相互作用;阻止逆转录酶的延伸等等。另外,由于C(UUCG)G发夹极其稳定的特征,在体外RNA分子的实验测定中它还是稳定核酸结构的理想工具。这些稳定的发夹广泛分布于体内rRNA、催化RNA和非编码mRNA中。但在对人类编码区mRNA结构特征的研究当中,却未发现C(UUCG)G发夹。     

Plant small nuclear RNAs. V. U4 RNA is present in broad bean plants in the form of sequence variants and is base-paired with U6 RNA.

U4 RNA, which is known to play an indispensable role in pre-mRNA splicing, is present in plant nuclei, has a canonical m3 2,2,7 G cap at its 5' end and is associated with U6 RNA in snRNP particles. It occurs in broad bean in the form of a number of sequence variants. Two of these were sequenced: U4A RNA is 154 and U4B RNA is 152 nucleotides long. Sequence similarity of broad bean U4B RNA is 94 per cent to broad bean U4A RNA, 65 per cent to rat U4A RNA, 61 per cent to Drosophila U4A RNA and 50 per cent to snR14, the U4 RNA equivalent of the yeast Saccharomyces cerevisiae. Sequence conservation is much more pronounced in the 5' half of the molecule than in its 3' half. The secondary structure of both variants of broad bean U4 RNA perfectly fits with that of all other U4 RNAs sequenced so far. Nucleotide changes between broad bean U4A and U4B RNAs are restricted to molecular regions that affect the thermodynamic stability of these molecules. A model is proposed for the base pairing interaction of broad bean U4 RNA with broad bean U6 RNA. This is the first report on the structure of a plant U4 RNA.     

Use of electrophoretic mobility to determine the secondary structure of a small antisense RNA.

Natural antisense RNAs have stem-loop (hairpin) secondary structures that are important for their function. The sar antisense RNA of phage P22 is unusual: the 3' half of the molecule forms an extensive stem-loop, but potential structures for the 5' half are not predicted to be thermodynamically stable. We devised a novel method to determine the secondary structure of sar RNA by examining the electrophoretic mobility on non-denaturing gels of numerous sar mutants. The results show that the wild-type RNA forms a 5' stem-loop that enhances electrophoretic mobility. All mutations that disrupt the stem of this hairpin decrease mobility of the RNA. In contrast, mutations that change the sequence of the stem without disrupting it (e.g. change G.U to A.U) do not affect mobility. Nearly all mutations in single-stranded regions of the structure also have no effect on mobility. Confirmation of the proposed 5' stem-loop was obtained by constructing and analyzing compensatory double mutants. Combinations of mutations that restore a base-pair of the stem also restore mobility. The genetic phenotypes of sar mutants confirm that the proposed secondary structure is correct and is essential for optimal activity of the antisense RNA in vivo.     

The U2 RNA analogue of Trypanosoma brucei gambiense: implications for a splicing mechanism in trypanosomes.

We have isolated the gene coding for the U2 analogue in trypanosomes. The 148 nucleotide long U2 RNA is capped and transcribed from a single copy gene. The 5' half of the molecule is highly homologous to mammalian U2 RNA, while the 3' half does not show any significant sequence homology with the mammalian counterpart. Nevertheless, the trypanosome U2 RNA can be folded into a secondary structure resembling the one proposed for U2 RNA. The presence of a U2 analogue and most likely other U RNAs in trypanosomes suggests that splicing is involved at some point in the maturation of mRNA. Possible interactions of the U2 RNA with the spliced leader RNA are considered.     

Characterization of the highly divergent U2 RNA homolog in the microsporidian Vairimorpha necatrix.

An RNA homologous to U2 RNA and a single copy gene encoding the RNA homolog have been characterized in the microsporidian, Vairimorpha necatrix. The RNA which is 165 nucleotides in length possesses significant similarity to U2 RNA, particularly in the 5' half of the molecule. The U2 homolog contains the highly conserved GUAGUA branch point binding sequence seen in all U2 RNAs except those of the trypanosomes. A U2 RNA sequence element implicated in a U2:U6 RNA intermolecular pairing is also present in the U2 homolog. The V. necatrix U2 RNA homolog differs at positions previously found to be invariant in U2 RNAs and appears to lack an Sm binding site sequence. The RNA can be folded into a secondary structure possessing three of the four principal stem-loops proposed for the consensus U2 RNA structure. A cis-diol containing cap structure is present at the 5' end of the U2 homolog. Unlike the cap structures seen in U-snRNAs and mRNAs it is neither 2,2,7-trimethylguanosine, gamma-monomethyl phosphate, nor 7-methylguanosine.