In vitro RNA transcription by the New Jersey serotype of vesicular stomatitis virus. II. Characterization of the leader RNA.

The New Jersey serotype of vesicular stomatitis virus (VSV) was able to synthesize a small RNA (leader RNA) approximately 70 bases in length similar to the leader RNA synthesized in vitro by the genetically distinct Indiana serotype of VSV. Also, the New Jersey leader RNA contained the same 5'-terminal sequence, ppA-C-G, as the Indiana leader RNA and had a very similar base composition, with 42% AMP, 16% CMP, 18.6% GMP, and 23.4% UMP. The 3'-terminal sequence of the VSV New Jersey genome RNA was detemined and found to contain the sequence- Py-G-UOH, again the same as that of the Indiana serotype of VSV. Evidence that the New Jersey leader RNA is transcribed from the 3' end of the genome RNA was obtained from the fact that it can protect the 3'-terminal base of [3H]borohydride-labeled New Jersey genome RNA from RNase digestion. Although the New Jersey and Indiana leader RNAs were similar in many respects, they were unable to form RNase-resistant hybrids when annealed to heterologous genome RNA.     

trans splicing of polycistronic Caenorhabditis elegans pre-mRNAs: analysis of the SL2 RNA

Genes in Caenorhabditis elegans operons are transcribed as polycistronic pre-mRNAs in which downstream gene products are trans spliced to a specialized spliced leader, SL2. SL2 is donated by a 110-nucleotide RNA, SL2 RNA, present in the cell as an Sm-bound snRNP. SL2 RNA can be conceptually folded into a phylogenetically conserved three-stem-loop secondary structure. Here we report an in vivo mutational analysis of the SL2 RNA. Some sequences can be changed without consequence, while other changes result in a substantial loss of trans splicing. Interestingly, the spliced leader itself can be dramatically altered, such that the first stem-loop cannot form, with only a relatively small loss in trans-splicing efficiency. However, the primary sequence of stem II is crucial for SL2 trans splicing. Similarly, the conserved primary sequence of the third stem-loop plays a key role in trans splicing. While mutations in stem-loop III allow snRNP formation, a single nucleotide substitution in the loop prevents trans splicing. In contrast, the analogous region of SL1 RNA is not highly conserved, and its mutation does not abrogate function. Thus, stem-loop III appears to confer a specific function to SL2 RNA. Finally, an upstream sequence, previously predicted to be a proximal sequence element, is shown to be required for SL2 RNA expression.     

Terminal sequences of vesicular stomatitis virus RNA are both complementary and conserved.

The nucleotide sequences at the 5' and 3' termini of RNA isolated from the New Jersey serotype of vesicular stomatitis virus [vsV(NJ)] and two of its defective interfering (DI) particles have been determined. The sequence differs from that previously demonstrated for the RNA from the Indiana serotype of VSV at only 1 of the first 17 positions from the 3' terminus and at only 2 of the first 17 positions from the 5' terminus. The 5'-terminal sequence of VSV(NJ) RNA is the complement of the 3'-terminal sequence, and duplexes which are 20 bases long and contain the 3' and 5' termini have been isolated from this RNA. The RNAs isolated from DI particles of VSV(NJ) have the same base sequences as do the RNAs from the parental virus. These results are in sharp contrast to those obtained with the Indiana serotype of VSV and its DI particles, in which the 3'-terminal sequences differ in 3 positions within the first 17. However, with both serotypes, the 3'-terminal sequence of the DI RNA is the complement of the 5'-terminal sequence of the RNA from the infectious virus. These findings suggest that the 3' and 5' RNA termini are highly conserved in both serotypes and that the 3' terminus of DI RNA is ultimately derived by copying the 5' end of the VSV genome, as recently proposed (D. Kolakofsky, M. Leppert, and L. Kort, in B. W. J. Mahy and R. D. Barry, ed., Negative-Strand Virus and the Host Cell, 1977; M. Leppert, L. Kort, and D. Kolakofsky, Cell 12:539-552, 1977; A. S. Huang, Bacteriol. Rev. 41:811-8218 1977).