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 of the 3' end of MCF 247 murine leukemia virus

We isolated DNA clones of MCF 247, a leukemogenic, recombinant type C virus obtained from the thymus of an AKR mouse. We determined the nucleotide sequence of the viral long terminal repeat (LTR) and the 3' end of env, and we compared the sequences to corresponding sequences of the genome of Akv virus, the putative ecotropic parent of MCF 247. By analogy with Moloney leukemia virus, we identified the amino terminus of Prp15E, the C-terminal proteolytic cleavage product of env and precursor to mature virion p15E. In MCF 247 the presumptive Prp15E is encoded by a 603-nucleotide open reading frame. The majority of this sequence is identical to that of Akv. However, a recombination event near the 3' end of the Prp15E-coding region introduces nonecotropic sequences into MCF 247, and these extend to the 3' end through the U3 portion of the LTR. The U3 regions of Akv and MCF 247 are about 83% homologous. The R and U5 regions of the LTR of MCF 247 and Akv are identical. Large RNase T1-resistant oligonucleotides analyzed previously in numerous ecotropic and MCF viral genomes were located within the Akv and MCF 247 DNA sequences. The resulting precise T1 oligonucleotide maps of the 3' ends of MCF viral genomes reveal that the biologically defined, leukemogenic class I MCFs isolated from thymic neoplasms of inbred mice all share the sequence pattern seen in MCF 247, a representative of this group; they possess recombinant Prp15E genes and derive U3 from their nonecotropic parents.     

The nucleotide sequence of an untranslated but conserved domain at the 3' end of the avian sarcoma virus genome.

The genomes of numerous avian retroviruses contain at their 3' termini a conserved domain denoted "c". The precise boundaries and function of "c" have been enigmas. In an effort to resolve these issues, we determined the sequence of over 900 nucleotides at the 3' end of the genome of the Schmidt-Ruppin subgroup A strain of avian sarcoma virus (ASV). We obtained the sequence from a suitable fragment of ASV DNA that had cloned into the single-stranded DNA phage M13mp2. Computer-assisted analysis of the sequence revealed the following structural features: i) the length of "c" - 473 nucleotides; ii) the 3' terminal domain of src, ending in an amber codon at the 5'boundary of "c"; iii) terminator codons that preclude continuous translation from "c"; iv) suitably located sequences that may serve as signals for the initiation of viral RNA synthesis and for the processing and/or polyadenylation of viral mRNA; v) a repeated sequence that flanks src and that could facilitate deletion of this gene; vi) repeated sequences within "c"; and vii) unexplained homologies between sequences in "c" and sequences in several other nucleic acids, including the 5' terminal domain of the ASV genome, tRNATrp and its inversion, the complement of tRNATrp and its inversion, and the 18S RNA of eukaryotic ribosomes. We conclude that "c" probably does not encode a protein, but its sequence may nevertheless serve several essential functions in viral replication.     

Primers with 5' flaps improve real-time PCR

Primers that contain portions noncomplementary to the target region are usually used to add to the PCR product a utility sequence such as a restriction site or a universal probe binding site. We have demonstrated that primers with short 5'AT-rich overhangs increase real-time PCR fluorescent signal. The improvement is particularly significant for difficult to amplify templates, such as highly variable viral sequences or bisulfite-treated DNA.     

At least 104 nucleotides are transposed from the 5' terminus of the avian sarcoma virus genome to the 5' termini of smaller viral mRNAs.

Cells producing avian sarcoma virus (ASV) contain at least three virus-specific mRNAs, two of which are encoded within the 3' half of the viral genome. Each of these viral RNAs can hybridize with single-stranded DNA(cDNA5') that is complementary to a sequence of 101 nucleotides found at the 5' terminus of the ASV genome, but not within the 3' half of the genome. We proposed previously (Weiss, Varmus and Bishop, 1977) that this nucleotide sequence may be transposed to the 5' termini of viral mRNAs during the genesis of these RNAs. We now substantiate this proposal by reporting the isolation and chemical characterization of the nucleotide sequences complementary to cDNA5' in the genome and mRNAs of the Prague B strain of ASV. We isolated the three identified classes of ASVmRNA (38, 28 and 21S) by molecular hybridization; each class of RNA contained a "capped" oligonucleotide identical to that found at the 5' terminus of the ASV genome. When hybridized with cDNA5', each class of RNA gave rise to RNAase-resistant duplex hybrids that probably encompassed the full extent of cDNA5'. The molar yields of duplex conformed approximately to the number of virus-specific RNA molecules in the initial samples; hence most if not all of the molecules of virus-specific RNA could give rise to the duplexes. The duplexes prepared from the various RNAs all contained the capped oligonucleotide found at the 5' terminus of the viral genome and had identical "fingerprints" when analyzed by two-dimensional fractionation following hydrolysis with RNAase T1. In contrast, RNA representing the 3' half of the ASV genome did not form hybrids with cDNA5'. We conclude that a sequence of more than 100 nucleotides is transposed from the 5' end of the ASV genome to the 5' termini of smaller viral RNAs during the genesis of these RNAs. Transposition of nucleotide sequences during the production of mRNA has now been described for three families of animal viruses and may be a common feature of mRNA biogenesis in eucaryotic cells. The mechanism of transposition, however, and the function of the transposed sequences are not known.     

Molecular cloning of unintegrated visna viral DNA and characterization of frequent deletions in the 3' terminus

Visna viral DNA, like other retroviral DNA, exists in two circular forms in infected cells. The larger probably contains two copies of the LTR, the smaller, one copy. Recombinant DNA techniques were used to clone unintegrated circular visna viral DNA in the lambda WES . lambda B vector. Circular visna viral DNA was digested with the restriction enzyme SstI, which yields a 9.2-kb viral DNA fragment containing 90% of the viral genome colinear with the restriction map of linear viral DNA. This fragment extends from a site about 900 bp from the left (5') end of the viral DNA molecule, through the 3' region, including U3 and R sequences at its right (3') end. The recombinant clones isolated contain visna viral DNA inserts which range in size from 3.1 kb to 9.2 kb. All the clones contain the 5' region intact, but most had sustained deletions of varying lengths in the 3' terminal region of the cloned fragment.     

Structure of viral DNA in a rat cell line transformed by the cloned EcoRI-C fragment of adenovirus 12.

A DNA segment carrying viral DNA was cloned from a rat cell line transformed by the cloned EcoRI-C fragment (0 to 16.4 map units) of human adenovirus type 12(Ad12), and the viral sequence in the clone was analysed. The cloned segment contained the region from nucleotide positions 118 to 3520 of the Ad12 genome in the middle. No unique structure was found at the viral and non-viral DNA junctions. When examined the transforming activity, the conserved viral sequence was able to transform rat 3Y1 cells efficiently. Southern blotting analysis of the viral sequence in five re-transformed cell lines showed that the viral sequence was inserted at different sites of cellular DNA. These results indicate that (I) the Ad12 DNA moiety from the enhancer-promoter region of the E1A gene to the end of the E1B gene contains enough information for efficient transformation of the rat cell, and (II) integration of the viral sequence at unique cellular sites is not prerequisite for transformation.     

The minute virus of mice capsid specifically recognizes the 3' hairpin structure of the viral replicative-form DNA: mapping of the binding site by hydroxyl radical footprinting.

The terminal hairpin structures of the DNA of minute virus of mice (MVM) are essential for viral replication. Here we show that the hairpin 3' terminus of MVM replicative-form DNA binds specifically to empty MVM capsids. Binding of the same terminal DNA sequence in its linear double-stranded (extended) conformation was not observed. After heat denaturation and quick cooling of 3'-terminal extended-form fragments, not only the virion strand but also the complementary strand was found to bind to the capsid, presumably because each strand re-formed a similar hairpin structure. No binding affinity for the capsid was found to be associated with hairpin or extended 5' termini or with any other region of the viral DNA. Hydroxyl radical footprinting analyses revealed three protected nucleotide stretches forming a binding site at the branch point of the two 3'-terminal hairpin arms looping out from the DNA stem (T structure). Single base changes within this site did not affect the binding. In band shift experiments, specific binding to the T structure was demonstrated for VPI but not for VP2.     

Nucleotide sequence at the site of junction between adenovirus type 12 DNA and repetitive hamster cell DNA in transformed cell line CLAC1.

The hamster cell line CLAC1 originated from a tumor induced by injecting human adenovirus type 12 (Ad12) into newborn hamsters. Each cell contained about 12 copies of viral DNA colinearly integrated at two or three different sites. We have cloned and sequenced a DNA fragment comprising the site of junction between the left terminus of Ad12 DNA and cellular DNA. The first 174 nucleotides of Ad12 DNA were deleted at the site of junction. Within 40 nucleotides, there were one tri-, two tetra-, one penta-, and one heptanucleotide which were identical in the 174 deleted viral nucleotides and the cellular sequence replacing them. In addition, there were patch-type homologies ranging from octa- to decanucleotides between viral and cellular sequences. There is no evidence for a model assuming adenovirus DNA to integrate at identical cellular sites. The cellular DNA sequence corresponding to the junction fragment was cloned also from BHK21 (B3) hamster cells and sequenced. Up to the site of linkage with viral DNA, this middle repetitive cellular DNA sequence was almost identical with the equivalent sequence from CLAC1 hamster cells. Taken together with the results of previously published analyses (11, 12), the data suggest a model of viral (foreign) DNA integration by multiple short sequence homologies. Multiple sets of short patch homologies might be recognized as patterns in independent integration events. The model also accounts for the loss of terminal viral DNA sequences.     

Herpes simplex virus amplicon: cleavage of concatemeric DNA is linked to packaging and involves amplification of the terminally reiterated a sequence.

Herpes simplex virus-infected cells contain large concatemeric DNA molecules arising from replication of the viral genome. The large concatemers are cleaved to generate unit-length molecules terminating at both ends with the a sequence. We have used constructed defective virus vectors (amplicons) derived from herpes simplex virus to study the mechanism of cleavage of viral DNA concatemers and the packaging of viral DNA into nucleocapsids. These studies revealed that (i) a 248-base-pair a sequence contained the signal(s) required for cleavage-packaging, (ii) the cleavage of viral DNA concatemers was coupled to packaging, (iii) the a sequence contained the information required for its own amplification, and (iv) cleavage-packaging occurred by a novel process involving the amplification of the a sequence.     

Confirmation of the helical structure of the 5'/3' termini of the essential DNA packaging pRNA of phage phi 29.

Bacteriophage phi 29 is typical of double-stranded DNA viruses in that its genome is packaged into a preformed procapsid during viral assembly. An intriguing feature of phi 29 is the presence of a 120-base virus-encoded RNA (pRNA) that is indispensable for DNA packaging. Phylogenetic comparison of similar RNAs in numerous phages has revealed that the secondary structure of the pRNA is well conserved. Computer analysis predicts the presence of an extensive segment of helix with three single-base bulges generated by the pairing of the 5' and 3' ends. The desire to understand the role played by the pRNA in DNA packaging has led to a mutational analysis of the 5'-/3'-terminal region, which is believed to be important in DNA translocation. Deletion of 3 bases from the 3' end of the RNA, shortening the pRNA from 120 to 117 bases, was tolerated without loss of activity, but additional deletion of the base 117 resulted in 100-fold less activity, and a 115-base pRNA was virtually nonfunctional. Additionally, the three unpaired one-base bulges within the helical stretches of the paired proximate ends were nonessential for pRNA activity, as demonstrated by deletion of the bulge individually. An extensive series of helix disruptions by single- and multiple-base substitution almost invariably led to the loss of DNA packaging activity. Additional mutations that restored predicted base pairings rescued pRNA activity. This second site suppression confirmed that the 5'- and 3'-end region was paired and was indeed a helical stretch. The secondary structure was of greater importance than the primary sequence, with the exception of the requirement of an adenine at either the third or fourth position. The specific requirement of an adenine in phi 29 pRNA at this position, as well as conservation of this position in other phage pRNAs, implicates that this base may play a special role in either the DNA-packaging reaction or the maintenance of the pRNA tertiary structure.     

Replication of the cauliflower mosaic virus: role and stability of the cloned delta 3 discontinuity sequence

A fragment of cauliflower mosaic virus (CaMV) DNA, containing delta 3, one of the three discontinuity sequences, was cloned in various ways into CaMV DNA deleted for the delta 3 sequence. The series of constructions was monitored for the appearance of the typical single-strand (ss) discontinuity after hybrid CaMV replication in plants. The delta 3 discontinuity was observed only if the orientation of inserted DNA sequence was the same as in the wild-type virus. Long polylinker sequences used for insertion of the fragment into cloned viral DNA, affected the stability of the insert in progeny viral DNA in plants by acting as recombination targets.     

Selective protection of 5' ... GGCC ... 3' and 5' ... GCNGC ... 3' sequences by the hypermodified oxopyrimidine in Bacillus subtilis bacteriophage SP10 DNA.

The DNA of Bacillus subtilis bacteriophage SP10 is partially resistant to cleavage and methylation in vitro by restriction enzyme R . BsuRI and its cognate methylase even though greater than 20 copies of the target sequence, 5' ... GGCC ... 3', are present on the phage genome. YThy, a hypermodified oxopyrimidine that replaces a fraction of the thymine residues in SP10 DNA, was responsible for this protection, since YThy-free DNA was no longer resistant. Sites that were normally resistant could nevertheless be cleaved or methylated in vitro if the salt concentration was reduced or dimethyl sulfoxide was added to the reaction buffer. Analysis of the termini produced by cleavage suggested that resistant sites occurred in the sequence 5' ... GGCC-YThy ... 3', whereas sensitive sites, of which there were only two per genome, occurred in the sequence 5' ... GGCCG ... 3'. These in vitro results provide an explanation for the in vivo resistance of SP10 to restriction-modification by B. subtilis R. They also suggest ways in which the presence of the atypical base YThy in regions that flank the target might upset critical DNA-enzyme interactions necessary to locate and recognize the specific site of cleavage or methylation. YThy also strongly protected 5' ... GCNGC ... 3' (R . Fnu4HI) sequences on SP10 DNA, but the biological relevance of this protection is unclear.     

Interference between M13 and oriM13 plasmids is mediated by a replication enhancer sequence near the viral strand origin

The origin of replication for the viral strand of bacteriophage M13 DNA is contained within a 507 base-pair intergenic region of the phage chromosome. The viral strand origin is defined as the specific site at which the M13 gene II protein nicks the duplex replicative form of M13 DNA to initiate rolling-circle synthesis of progeny viral DNA. Using in vitro techniques we have constructed deletion mutations in M13 DNA at the unique AvaI site which is located 45 nucleotides away on the 3' side of the gene II protein nicking site. This deletion analysis has identified a sequence near the viral strand origin that is required for efficient replication of the M13 genome. We refer to this part of the intergenic region as a "replication enhancer" sequence. We have also studied the function of this sequence in chimeric pBR322-M13 plasmids and found that plasmids carrying both the viral strand origin and the replication enhancer sequence interfere with M13 phage replication. Based upon these findings we propose a model for the mechanism of action of the replication enhancer sequence involving binding of the M13 gene II protein.     

Inhibition of HIV-1 integrase by modified oligonucleotides derived from U5' LTR.

Retroviral integrase catalyzes integration of double-stranded viral DNA into the host chromosome by a process that has become an attractive target for drug design. In the 3' processing reaction, two nucleotides are specifically cleaved from both 3' ends of viral DNA yielding a 5' phosphorylated dimer (pGT). The resulting recessed 3' hydroxy groups of adenosine provide the attachment sites to the host DNA in the strand transfer reaction. Here, we studied the effect of modified double-stranded oligonucleotides mimicking both the unprocessed (21-mer oligonucleotides) and 3' processed (19-mer oligonucleotides) U5 termini of proviral DNA on activities of HIV-1 integrase in vitro. The inhibitions of 3' processing and strand transfer reactions were studied using 21-mer oligonucleotides containing isopolar, nonisosteric, both conformationally flexible and restricted phosphonate internucleotide linkages between the conservative AG of the sequence CAGT, and using a 21-mer oligonucleotide containing 2'-fluoroarabinofuranosyladenine. All modified 21-mer oligonucleotides competitively inhibited both reactions mediated by HIV-1 integrase with nanomolar IC50 values. Our studies with 19-mer oligonucleotides showed that modifications of the 3' hydroxyl significantly reduced the strand transfer reaction. The inhibition of integrase with 19-mer oligonucleotides terminated by (S)-9-(3-hydroxy-2-phosphonomethoxypropyl)adenine, 9-(2-phosphonomethoxyethyl)adenine, and adenosine showed that proper orientation of the 3' OH group and the presence of the furanose ring of adenosine significantly influence the strand transfer reaction.