Evidence that the 5' end of rabbit globin mRNA is hybridized with its 3' end

• 1.1. A radiopolyadenylated rabbit globin mRNA was treated with different concentrations of ribonuclease V₁ from cobra venom.
• 2.2. The enzymatic digests were chromatographed on an aminophenylboronate-agarose column, which specifically captured the cap structure i.e. n⁷G(5') ppp (5') NmP.
• 3.3. When the capture fragment was chromatographed on a Sephadex G-100 column, its size was smaller than the native molecule and also bore radioactivity, i.e. a poly(A) tail.
• 4.4. These results provide evidence that the 5' end (which encompasses the cap structure) of rabbit globin mRNA is hybridized and in close proximity to its 3' end.
• 5.5. We conclude that this conformation is required for messenger translation efficiency.

     

Sequence of 3000 nucleotides at the 5' end of Japanese encephalitis virus RNA

The 5' region of the Japanese encephalitis virus (JEV) RNA was cloned and 3000 nucleotides (nt) were determined by sequencing DNA complementary to viral RNA, and genomic RNA, using oligodeoxynucleotide primers and the dideoxy chain-termination reaction. Comparison of the nt sequence and the reduced amino-acid sequence of JEV with those of other flaviviruses showed significant homologies, which allowed locations to be assigned for three structural proteins.     

Nucleotide sequence analysis and expression from recombinant vectors demonstrate that the attachment protein G of bovine respiratory syncytial virus is distinct from that of human respiratory syncytial virus

Bovine respiratory syncytial (BRS) virus causes a severe lower respiratory tract disease in calves similar to the disease in children caused by human respiratory syncytial (HRS) virus. While there is antigenic cross-reactivity among the other major viral structural proteins, the major glycoprotein, G, of BRS virus and that of HRS virus are antigenically distinct. The G glycoprotein has been implicated as the attachment protein for HRS virus. We have carried out a molecular comparison of the glycoprotein G of BRS virus with the HRS virus counterparts. cDNA clones corresponding to the BRS virus G glycoprotein mRNA were isolated and analyzed by dideoxynucleotide sequencing. The BRS virus G mRNA contained 838 nucleotides exclusive of poly(A) and had a major open reading frame coding for a polypeptide of 257 amino acid residues. The deduced amino acid sequence of the BRS virus G polypeptide showed only 29 to 30% amino acid identity with the G protein of either the subgroup A or B HRS virus. However, despite this low level of identity, there were strong similarities in the predicted hydropathy profiles of the BRS virus and HRS virus G proteins. A cDNA molecule containing the complete BRS virus G major open reading frame was inserted into the thymidine kinase gene of vaccinia virus by homologous recombination, and a recombinant virus containing the BRS virus G protein gene was isolated. This recombinant virus expressed the BRS virus G protein, as demonstrated by Western immunoblot analysis and immunofluorescence of infected cells. The BRS virus G protein expressed from the recombinant vector was transported to and expressed on the surface of infected cells. Antisera to the BRS virus G protein made by using the recombinant vector to immunize animals recognized the BRS virus attachment protein but not the HRS virus G protein and vice versa, confirming the lack of antigenic cross-reactivity between the BRS and HRS virus attachment proteins. On the basis of the data presented here, we conclude that BRS virus should be classified within the genus Pneumovirus in a group separate from HRS virus and that it is no more closely related to HRS virus subgroup A than it is to HRS virus subgroup B.     

The first two nucleotides of the respiratory syncytial virus antigenome RNA replication product can be selected independently of the promoter terminus

There is limited knowledge regarding how the RNA-dependent RNA polymerases of the nonsegmented negative-strand RNA viruses initiate genome replication. In a previous study of respiratory syncytial virus (RSV) RNA replication, we found evidence that the polymerase could select the 5'-ATP residue of the genome RNA independently of the 3' nucleotide of the template. To investigate if a similar mechanism is used during antigenome synthesis, a study of initiation from the RSV leader (Le) promoter was performed using an intracellular minigenome assay in which RNA replication was restricted to a single step, so that the products examined were derived only from input mutant templates. Templates in which Le nucleotides 1U, or 1U and 2G, were deleted directed efficient replication, and in both cases, the replication products were initiated at the wild-type position, at position -1 or -2 relative to the template, respectively. Sequence analysis of the RNA products showed that they contained ATP and CTP at the -1 and -2 positions, respectively, thus restoring the mini-antigenome RNA to wild-type sequence. These data indicate that the RSV polymerase is able to select the first two nucleotides of the antigenome and initiate at the correct position, even if the 3'-terminal two nucleotides of the template are missing. Substitution of positions +1 and +2 of the template reduced RNA replication and resulted in increased initiation at positions +3 and +5. Together these data suggest a model for how the RSV polymerase initiates antigenome synthesis.     

A long-range interaction in Qbeta RNA that bridges the thousand nucleotides between the M-site and the 3' end is required for replication.

The genome of the positive strand RNA bacteriophage Qbeta folds into a number of structural domains, defined by long-distance interactions. The RNA within each domain is ordered in arrays of three- and four-way junctions that confer rigidity to the chain. One such domain, RD2, is about 1,000-nt long and covers most of the replicase gene. Its downstream border is the 3' untranslated region, whereas upstream the major binding site for Qbeta replicase, the M-site, is located. Replication of Qbeta RNA has always been puzzling because the binding site for the enzyme lies some 1,500-nt away from the 3' terminus. We present evidence that the long-range interaction defining RD2 exists and positions the 3' terminus in the vicinity of the replicase binding site. The model is based on several observations. First, mutations destabilizing the long-range interaction are virtually lethal to the phage, whereas base pair substitutions have little effect. Secondly, in vitro analysis shows that destabilizing the long-range pairing abolishes replication of the plus strand. Thirdly, passaging of nearly inactive mutant phages results in the selection of second-site suppressor mutations that restore both long-range base pairing and replication. The data are interpreted to mean that the 3D organization of this part of Qbeta RNA is essential to its replication. We propose that, when replicase is bound to the internal recognition site, the 3' terminus of the template is juxtaposed to the enzyme's active site.     

The organisation and interviral homologies of genes at the 3' end of tobacco rattle virus RNA1

The RNA1 of tobacco rattle virus (TRV) has been cloned as cDNA and the nucleotide sequence determined of 2 kb from the 3'-terminal region. The sequence contains three long open reading frames. One of these starts 5' of the cDNA and probably corresponds to the carboxy-terminal sequence of a 170-K protein encoded on RNA1. The deduced protein sequence from this reading frame shows homology with the putative replicases of tobacco mosaic virus (TMV) and tricornaviruses. The location of the second open reading frame, which encodes a 29-K polypeptide, was shown by Northern blot analysis to coincide with a 1.6-kb subgenomic RNA. The validity of this reading frame was confirmed by showing that the cDNA extending over this region could be transcribed and translated in vitro to produce a polypeptide of the predicted size which co-migrates in electrophoresis with a translation product of authentic viral RNA. The sequence of this 29-K polypeptide showed homology with two regions in the 30-K protein of TMV. This homology includes positions in the TMV 30-K protein where mutations have been identified which affect the transport of virus between cells. The third open reading frame encodes a potential 16-K protein and was shown by Northern blot hybridisation to be contained within the region of a 0.7-kb subgenomic RNA which is found in cellular RNA of infected cells but not virus particles. The many similarities between TRV and TMV in viral morphology, gene organisation and sequence suggest that these two viral groups may share a common viral ancestor.     

The genome of respiratory syncytial virus is a negative-stranded RNA that codes for at least seven mRNA species.

The RNA from purified respiratory syncytial (RS) virions and the RNAs from RS virus-infected cells were isolated and characterized. The RNA from RS virions was found to be a unique species of single-stranded RNA of approximately 5 x 10(6) daltons. Specific annealing experiments demonstrated that at least 93% of the virion RNA was of negative (nonmessage) polarity. Eight major and three minor species of virus-specific RNA were detected in the cytoplasm of RS virus-infected HEp-2 cells. The largest intracellular RNA species comigrated with RNA from purified virions, was not polyadenylated, and was synthesized only in the presence of concomitant protein synthesis. The seven major smaller species of RNA were synthesized in the presence of an inhibitor of protein synthesis. These RNAs were all polyadenylated and were shown to be RS virus specific by their ability to anneal specifically to purified virion RNA. The sum of the sizes of the major RS virus-specific polyadenylated RNAs was sufficient to account for the coding capacity of the RS virus genome (within the limits of reliability of the methods we have used to determine size).     

Sequence of 1000 nucleotides at the 3'' end of tobacco mosaic virus RNA.

The sequence of 1000 nucleotides at the 3' end of tobacco mosaic virus RNA has been determined. The sequence contains the entire coat protein cistron as well as regions to its left and right. Sequence characterization was by conventional methods for use with uniformly 32P labeled RNA complemented by newer methods for in vitro 5' and 3' 32P end-labeling of RNA and its subsequent rapid analysis. The noncoding region separating the coat protein cistron from the 3' terminus is 204 residues long and may be folded into a clover-leaf-type secondary structure. The distribution of termination codons to the left of the coat protein cistron suggests that the end of the adjacent cistron is separated from the beginning of the coat protein cistron by only two nucleotides. The subgenomic viral coat protein mRNA was isolated from infected tissue and shown to be capped. The nontranslated sequence separating the cap from the AUG initiation codon is 9 residues long and thus overlaps a portion of the adjacent cistron on the genome RNA.     

Recombinant Sendai virus induces T cell immunity against respiratory syncytial virus that is protective in the absence of antibodies

Respiratory syncytial virus (RSV) causes severe respiratory disease in infants and a vaccine is highly desirable. The fusion (F) protein of RSV is an important vaccine target, but the contribution of F-specific T cells to successful vaccination remains unclear. We studied the immune response to vaccination of mice with a recombinant Sendai virus expressing RSV F (rSeV F). rSeV F induced protective neutralizing antibody and RSV F-specific CTL responses. T cell immunity was stronger than that induced by recombinant vaccinia virus (rVV F), a well characterized reference vector. Vaccination of antibody-deficient mice showed that vaccine-induced RSV F-specific T cells were sufficient for protective immunity. rSeV F induced T cell immunity in the presence of neutralizing antibodies, which did not impair the vaccine response. Although the F protein only contains a subdominant CTL epitope, vaccination with rSeV F is sufficient to induce protective T cell immunity against RSV in mice.     

Requirements for polyadenylation at the 3' end of LINE-1 elements

LINE-1 (L1) is the only active, autonomous, non-LTR, human retroelement. There are about 5 × 10⁵ L1 copies in the human genome, the majority of which are truncated at their 5′ ends. Both truncated and full-length L1 insertions contain a polyadenylation (polyA) signal at their 3′ ends. A typical polyA site consists of the three main cis-acting elements: a conserved hexamer, cleavage site, and a GU-rich downstream region. A newly inserted L1 copy contains the conserved AATAAA hexamer at the end of its sequence. However, the GU-rich downstream region has to be provided by the neighboring genomic sequences and therefore it would vary for every L1 copy. Using northern blot analysis of transiently transfected L1 expression vectors we demonstrate that L1 element contain sequence that allow efficient polyadenylation at the L1 3′ end upon retrotransposition into a new genomic location independent of the base composition downstream of the insertion site. The strategy of polyadenylation at the 3′ end of L1 parallels the approach the element employs at its 5′UTR by having an unusual internal polymerase II promoter, making new insertions less dependent on the properties of the flanking sequences at the new locus.     

Evidence that the nuclease activities associated with the herpes simplex type 1 DNA polymerase are due to the 3'-5' exonuclease.

We investigated nuclease activities associated with the catalytic subunit of herpes simplex virus type 1 DNA polymerase. We confirm that a 3'-5' exonuclease copurifies with this enzyme. Previous reports suggested that a 5' DNase was intrinsic to the polymerase. Our preparation lacks such activity.     

Charge scan reveals an extended region at the intracellular end of the GABA receptor pore that can influence ion selectivity

Selective permeability is a fundamental property of ion channels. The Cys-loop receptor superfamily is composed of both excitatory (ACh, 5-HT) and inhibitory (GABA, glycine) neurotransmitter-operated ion channels. In the GABA receptor, it has been previously shown that the charge selectivity of the integral pore can be altered by a single mutation near the intracellular end of the second transmembrane-spanning domain (TM2). We have extended these findings and now show that charge selectivity of the anionic rho1 GABA receptor can be influenced by the introduction of glutamates, one at a time, over an 8-amino acid stretch (-2' to 5') in the proposed intracellular end of TM2 and the TM1-TM2 intracellular linker. Depending on the position, glutamate substitutions in this region produced sodium to chloride permeability ratios (P(Na)+(/Cl)-) varying from 0.64 to 3.4 (wild type P(Na)+(/Cl)- = 0). In addition to providing insight into the mechanism of ion selectivity, this functional evidence supports a model proposed for the homologous nicotinic acetylcholine receptor in which regions of the protein, in addition to TM2, form the ion pathway.