Direct analysis of the mini-exon donor RNA of Trypanosoma brucei: detection of a novel cap structure also present in messenger RNA.

The mini-exon, a short segment found at the 5' end of trypanosome mRNAs, is contributed by a small RNA, the mini-exon donor (medRNA). In vivo 32P-labeled medRNA, a set of smaller RNAs related to it, and mRNA, were purified from Trypanosoma brucei by hybrid selection and gel electrophoresis. Using RNA fingerprinting and sequencing techniques, mini-exon oligonucleotides were identified and characterized. We detected a novel 5' terminal capped oligonucleotide present in both medRNA and mRNA. This structure contained m7G and at least four modified nucleotides, not identified previously. If the T. brucei mini-exon has exactly four transcribed nucleotides upstream from its originally designated 5' end, it would begin with the sequence: m7GpppA*A*C*U*AA*CG (asterisks denote modification) and medRNA would be 140 nucleotides long, excluding the m7G residue. The mini-exon contains, and retains during its transfer to mRNA, a novel 5' terminal structure whose presence could confer unique functional attributes.     

Controlled turnover and 3'' trimming of the trans splicing precursor of Trypanosoma brucei.

The maturation of mRNAs in Trypanosoma brucei involves a novel step, in which a short capped sequence is spliced in trans onto the 5' end of nascent mRNAs from a 140-nucleotide precursor. This precursor is called the mini-exon-derived RNA or medRNA. We have used drugs and ultraviolet irradiation as inhibitors to probe the synthesis and processing of medRNA in vivo. Inhibition of RNA synthesis by chloroquine shows that the half-life of medRNA is about 4 minutes. Despite this high turnover, only limited accumulation of medRNA could be achieved following a block in the synthesis of high molecular weight splice acceptor substrates by UV irradiation. This implies that there is a constraint on the steady-state levels of medRNA and that excess medRNA is degraded in the cell. A 3' shortened version of medRNA accumulates upon a block in normal medRNA processing by UV irradiation or upon treatment of the cells with actinomycin D or novobiocin but was shown not to participate in trans splicing, making it a likely candidate for an in vivo degradation intermediate.     

The cap of both miniexon-derived RNA and mRNA of trypanosomes is 7-methylguanosine.

Most, if not all, trypanosome mRNAs have the same 35-base sequence at their 5' terminus which is derived from a short RNA (medRNA) probably by the process of trans-splicing. It is of interest, evolutionarily and mechanistically, to determine the chemical structure of the 5' terminus of the precursor (medRNA) and product (mRNA). We demonstrate here that the cap structure of both is most probably 7-methylguanosine in a 5',5' triphosphate linkage, consistent with a precursor/product relationship.     

Physical identification of branched intron side-products of splicing in Trypanosoma brucei.

Every mRNA in trypanosomes consists of two exons, a common 5' capped mini-exon or spliced leader and a coding-exon. All evidence suggests that the exons are joined by trans-splicing of two individual precursor RNAs, the mini-exon donor RNA or spliced leader precursor RNA (medRNA) and the pre-mRNA. We studied intermediates of the splicing reaction using denaturing two-dimensional PAGE and structurally identified a group of small (approximately 180-300 nt) non-polyadenylated, Y-shaped branched RNAs. The branched Y-shaped RNAs contain the 105 nt medRNA derived intron, joined in a 2'-5' phosphodiester bond to small heterogeneously sized RNAs. These non-polyadenylated branched Y-shaped RNA molecules are analogous to the lariat shaped introns of higher eukaryotes and presumably represent the released intron-like by-products of a trans-splicing reaction which joins the mini-exon and the major coding-exon.     

Sequencing of laminin B chain cDNAs reveals C-terminal regions of coiled-coil alpha-helix.

cDNAs for laminin B chains have been isolated from a parietal endoderm cDNA library in pUC8 and pUC9. Identification is based on: ability to direct the synthesis in Escherichia coli of polypeptides carrying laminin antigen determinants, in vitro translation of hybrid selected mRNA, and hybridization to high mol. wt. RNA differentially expressed in cells synthesizing large amounts of laminin. The plasmid pPE9 hybrid selects mRNA for the B2 (mol. wt. 185 000) chain and provides 217 residues of C-terminal amino acid sequence. The plasmids pPE386 and 49 both hybrid select mRNAs for the B1a (mol. wt. 205 000) and B1b (mol. wt. 200 000) chains. These two cDNAs are identical over much of their sequence, but pPE386 includes 133 nucleotides of 3' non-coding sequence and a poly(A) tail. Together they provide 495 residues of C-terminal amino acid sequence. Analysis of the predicted sequences reveals a striking heptad repeat, with a high probability that residues a and d are hydrophobic. Such a repeat is typical of the coiled-coil alpha-helices found in proteins such as myosin, tropomyosin and desmin (2-stranded) and fibrinogen (3-stranded).     

The nucleotide sequence of cowpea mosaic virus B RNA

The complete sequence of the bottom component RNA (B RNA) of cowpea mosaic virus (CPMV) has been determined. Restriction enzyme fragments of double-stranded cDNA were cloned in M13 and the sequence of the inserts was determined by a combination of enzymatic and chemical sequencing techniques. Additional sequence information was obtained by primed synthesis on first strand cDNA. The complete sequence deduced is 5889 nucleotides long excluding the 3' poly(A), and contains an open reading frame sufficient to code for a polypeptide of mol. wt. 207 760. The coding region is flanked by a 5' leader sequence of 206 nucleotides and a 3' non-coding region of 82 residues which does not contain a polyadenylation signal.     

Binding of ribosomes to the 5' leader sequence (N = 258) of RNA 3 from alfalfa mosaic virus.

RNA 3 of alfalfa mosaic virus (AlMV) contains information for two genes: near the 5' end an active gene coding for a 35 Kd protein and, near the 3' end, a silent gene coding for viral coat protein. We have determined a sequence of 318 nucleotides which contains the potential initiation codon for the 35 Kd protein at 258 nucleotides from the 5' end. This long leader sequence can form initiation complexes containing three 80 S ribosomes. A shorter species of RNA, corresponding to a molecule of RNA 3 lacking the cap and the first 154 nucleotides (RNA 3') has been isolated. The remaining leader sequence of 104 nucleotides in RNA 3' forms a single 80 S initiation complex with wheat germ ribosomes. The location of the regions of the leader sequence of RNA 3 involved in initiation complex formation with 80 S ribosomes is reported.     

Bunyamwera bunyavirus RNA synthesis requires cooperation of 3'- and 5'-terminal sequences

Bunyamwera virus (BUNV) is the prototype of both the Orthobunyavirus genus and the Bunyaviridae family of segmented negative-sense RNA viruses. The tripartite BUNV genome consists of small (S), medium (M), and large (L) segments that are each transcribed to yield a single mRNA and are replicated to generate an antigenome that acts as a template for synthesis of further genomic strands. As for all negative-sense RNA viruses, the 3'- and 5'-terminal nontranslated regions (NTRs) of the BUNV S, M, and L segments exhibit nucleotide complementarity and, except for one conserved U-G pairing, this complementarity extends for 15, 18, and 19 nucleotides, respectively. We investigated whether the complementarity of 3' and 5' NTRs reflected a functional requirement for terminal cooperation to promote BUNV RNA synthesis or, alternatively, was a consequence of genomic and antigenomic NTRs having similar functions requiring sequence conservation. We show that cooperation between 3'- and 5'-NTR sequences is required for BUNV RNA synthesis, and our results suggest that this cooperation is due to nucleotide complementarity allowing 3' and 5' NTRs to associate through base-pairing interactions. To examine the importance of complementarity in promoting BUNV RNA synthesis, we utilized a competitive replication assay able to examine the replication ability of all possible combinations of interacting nucleotides within a defined region of BUNV 3' and 5' NTRs. We show here that maximal RNA replication was signaled when sequences exhibiting perfect complementarity within 3' and 5' NTRs were selected.