Sequence studies of poliovirus RNA. I. Characterization of the 5'-terminus

Origin of adenovirus DNA replication. Role of the nuclear factor I binding site in vivo

An assay is described that detects in vivo a single round of initiation and DNA synthesis directed by a linear molecule containing an exposed single copy of an adenovirus (Ad) origin of replication. This and a previously described assay, which measures multiple rounds of DNA replication, were used to identify DNA sequences within the Ad2 and Ad4 origins of replication that are important for ori function. Linear DNA molecules containing sequences from the Ad2 or Ad4 genome termini were cotransfected with homologous and heterologous helper virus, and net amounts of DNA synthesis were compared. Linear molecules containing the Ad4 inverted terminal repeats were replicated 20-fold better in the presence of the homologous helper, whereas both Ad2 and Ad4 inverted terminal repeats were utilized efficiently by Ad4. DNA sequence analysis of the Ad2 ori and the corresponding region in Ad4 indicated that, although there are only ten variant base-pairs, eight are located within the Ad2 DNA sequence recognized by the cellular protein nuclear factor I. This protein is required to achieve the maximal rate of Ad2 DNA replication in vitro, and these differences therefore identify DNA sequences that are crucial to Ad2 ori function. The Ad4 ITR does not contain a functional nuclear factor I binding site, and deletion analysis has demonstrated that this region of the Ad4 genome is not required for ori function. In contrast to Ad2, the DNA sequences required for the initiation of Ad4 DNA replication were shown to reside entirely within the terminal 18 base-pairs of the Ad4 inverted terminal repeat.

The origin of adenovirus DNA replication: minimal DNA sequence requirement in vivo

Adenovirus mini-chromosomes which contain two cloned, inverted adenovirus termini replicate in vivo when supplied with non-defective adenovirus as a helper. This system has been used to define the minimum cis acting DNA sequences required for adenovirus DNA replication in vivo. Deletions into each end of the adenovirus inverted terminal repeat (ITR) were generated with Bal31 exonuclease and the resulting molecules constructed into plasmids which contained two inverted copies of the deleted ITR separated by the bacterial neomycin phosphotransferase gene. To determine the effect of the deletion in vivo plasmids cleaved to expose the adenovirus termini were co-transfected with adenovirus type 2 DNA into tissue culture cells. The replicative ability of the molecules bearing adenovirus termini was assayed by Southern blotting of extracted DNA which had been treated with DpnI, a restriction enzyme which cleaves only methylated and therefore unreplicated, input DNA. Molecules containing the terminal 45 bp of the viral genome were fully active whereas molecules containing only 36 bp were in-active in this assay. Therefore sequences required for DNA replication are contained entirely within the terminal 45 bp of the viral genome. Thus, both the previously described highly conserved region (nucleotides 9-18) and the binding site for the cellular nuclear factor I (nucleotides 19-48) are essential for adenovirus DNA replication in vivo.

Replication of adenovirus mini-chromosomes

We have isolated adenovirus origins of DNA replication from both the right and left ends of the genome, which are functional on linear autonomously replicating mini-chromosomes. The mini-chromosomes contain two cloned inverted adenovirus termini and require non-defective adenovirus as a helper. Replicated molecules are covalently attached to protein, and DNA synthesis is initiated at the correct nucleotide even when the origins are not located at molecular ends. The activity of embedded origins leads to the generation of linear mini-chromosomes from circular or linear molecules. These observations therefore suggest that sequences within the adenovirus origin of replication position the protein priming event at the adenovirus terminus. Experiments investigating the regeneration of deleted viral inverted terminal repeat sequences show a sequence-independent requirement for inverted sequences in this process. This result strongly suggests that repair results from the formation of a panhandle structure by a displaced single strand. On the basis of these observations we propose a model for the generation of adenovirus mini-chromosomes from larger molecules.

Applications of Oligonucleotide Fingerprinting to the Identification of Viruses

This chapter focuses on applications of oligonucleotide fingerprinting to the identification of viruses. Fingerprinting is a technique by which oligonucleotides, produced by cleavage of RNA molecules with specific ribonucleases, are separated in two dimensions. It is a definitive method of identifying RNA viruses according to their genotypes. It is not subject to the problems of antigenic drift or antigenic convergence that complicate serological identification. Furthermore, it provides a semiquantitative means of following the evolution of viral genomes in nature. Because all regions of the genome are represented by the large diagnostic oligonucleotides, a survey of the total genomic changes can be monitored. Fingerprinting has two limitations as a diagnostic tool. First, although highly definitive, fingerprinting is not as rapid or inexpensive as serological techniques and cannot be as easily scaled up for routine identification of a large number of samples. Second, the evolutionary range of fingerprinting is short and relationships may not be evident for isolates of rapidly evolving viruses obtained over long intervals. However, these limitations are not large, compared to the full benefits offered to the virologist by the fingerprinting method.

Non-contiguous segments of the polyoma genome required in cis for DNA replication

The boundaries of the origin of polyoma DNA replication have been analyzed using a set of deletion mutants. The majority of these had small deletions, 5 to 30 basepairs in size, which together removed most of the non-translated sequences of the genome. The phenotype of the mutants was characterized by analysis of infectivity, transforming ability and DNA synthesis. All mutants with reduced or abolished infectivity had corresponding defects of viral DNA synthesis. The effect of the deletion was cis-acting, since the replication of the mutants was not stimulated by the presence of wild-type DNA. Deletions causing a reduction of DNA synthesis were found at two sites. The first at the 32 base-pair inverted repeat sequence and the neighbouring A . T tract previously implicated in the initiation of DNA synthesis, and the second close to the late genes. The two sites were separated by at least 60 base-pairs of non-essential DNA. Only one mutant with a deletion at the second site was unable to express early gene functions. The mutants were constructed by linearization, shortening and recircularization of polyoma DNA inserted into the plasmid pBR322. The mutagenesis was directed at restriction endonuclease BglI or PvuII cleavage sites. The BglI-directed mutagenesis was focussed to polyoma DNA by using as a vector a derivative of pBR322 resistant to cleavage by BglI.

Picornaviral structure and assembly

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The location of the polio genome protein in viral RNAs and its implication for RNA synthesis

Evidence is presented that a small protein (VPg) is covalently attached to the 5'-terminal oligonucleotide VPg-pU-U-A-A-A-A-C-A-Gp of the polio genome, to nascent strands of the polio replicative intermediate and to poly(U) of minus strands. A model of polio RNA replication is proposed implicating VPg in initiation of RNA symthesis, possibly as primer.

On the nature of 5' termini in nuclear pre-mRNA of Ehrlich carcinoma cells

5' terminal nucleosides of nuclear pre-mRNA of Ehrlich ascites carcinoma cells were analyzed by a combination of different chromatographic methods and phosphatase treatment. The heavy nuclear pre-mRNA contains mainly unblocked triphosphorylated nucleosides at the 5' end, although some capped 5' ends could also be found. In this respect, it differs from cytoplasmic poly(A)+ mRNA which contains blocked 5' termini and no triphosphorylated ends. The 5' terminal nucleotides in pre-mRNA are pppGp and pppAp (in a ratio of 3:2). The determination of pppNp content in poly (A)+, poly(U)+, and poly (A)-(U)- fragments of RNA has been used as an approach to establish the topography of pre-mRNA. We also established that the technique for isolation of triphosphorylated 5' terminal fragments of RNA based on hydroxyapatite chromatography (Bajszár, Samarina, and Georgiev, 1974) is still valid in the presence of blocked oligonucleotides. The latter do not interfere with fragments containing free triphosphate groups. Using this technique, we showed that a small but significant portion of triphosphorylated 5' end fragments of 100 nucleotides in length contain oligo(U) sequences reacting with poly(A)-Sepharose.

Poliovirus-induced infectious double-stranded RNA: Effect of RNA-degrading enzymes

The infectivity of replicative form RNA (RF-RNA) isolated from poliovirus-infected HeLa cells is completely resistant to the action of T-1 RNase but decreases after exposure to RNase A in the presence of 0.3 M NaCl. Under these conditions neither enzyme produces single-stranded nicks in RF-RNA. Three endonuclease-free exonuleases (RNase II, polynucleotide phosphorylase and spleen phosphodiesterase) rapidly destroy the infectivity of single-stranded RNA, but do not alter the infectivity of RF-RNA. It is concluded that RF-RNA does not contain single-stranded ends essential for infectivity. Indirect evidence suggests that all or most of the poly A region at the 3' end of the plus strand of infectious RF-RNA is base-paired to a poly U region at the 5 end of the minus strand.

Nucleotide sequence analysis of RNA synthesized from rabbit globin complementary DNA

Rabbit globin complementary DNA made with RNA-dependent DNA polymerase (reverse transcriptase) was used as template for in vitro synthesis of (32)P-labeled RNA. The sequences of the nucleotides in most of the fragments resulting from combined ribonuclease T(1) and alkaline phosphatase digestion have been determined. Several fragments were long enough to fit uniquely with the alpha or beta globin amino-acid sequences. These data demonstrate that the cDNA was copied from globin mRNA and contained no detectable contaminants.

Occurrence of uridylate-rich oligonucleotide regions in heterogeneous nuclear RNA of HeLa cells

Heterogeneous nuclear RNA molecules from HeLa cells contain a specific segment of about 30 nucleotides length that is largely (about 80%) uridylic acid. This oligo(U) segment is located predominantly in the larger (70S-90S) heterogeneous nuclear RNA molecules, and is essentially absent in messenger RNA and 45S ribosomal precursor RNA molecules. The oligo(U) hybridizes rapidly to cellular DNA, suggesting that it is transcribed from the repeated regions of the DNA.