Oligonucleotide mapping of non-radioactive virus and messenger RNAs

The genetic diversity and epizootiology of infectious hematopoietic necrosis virus

Infectious hematopoietic necrosis virus (IHNV) is a rhabdovirus which causes a serious disease in salmonid fish. The T1 ribonuclease fingerprinting method was used to compare the RNA genomes of 26 isolates of IHNV recovered from sockeye salmon (Oncorhynchus nerka), chinook salmon (O. tshawytscha), and steelhead trout (O. mykiss) throughout the enzootic portion of western North America. Most of the isolates analyzed in this study were from a single year (1987) to limit time of isolation as a source of genetic variation. In addition, isolates from different years collected at three sites were analyzed to investigate genetic drift or evolution of IHNV within specific locations. All of the isolates examined by T1 fingerprint analysis contained less than a 50% variation in spot location and were represented by a single fingerprint group. The observed variation was estimated to correspond to less than 5% variation in the nucleic acid sequence. However, sufficient variation was detected to separate the isolates into four subgroups which appeared to correlate to different geographic regions. Host species appeared not to be a significant source of variation. The evolutionary and epizootiologic significance of these findings and their relationship to other evidence of genetic variation in IHNV isolates are discussed.

Genetic drift of equine 2 influenza A virus (H3N8), 1963-1988: analysis by oligonucleotide mapping

Comparative analysis by RNA oligonucleotide fingerprints of total genomic RNA as well as the individual RNA segments of equine 2 influenza A virus strains from 1963, 1968, 1979, 1984, 1987 and 1988 revealed genetic diversity. Strains from the epizootic outbreak during 1978-1979 showed minor differences among their genomes. The Swedish isolates from 1979 up to 1988 showed increasing genomic heterogeneity indicating genetic drift.

Analysis of some swine influenza H1N1 viruses by oligonucleotide fingerprinting

The genome of the swine influenza H1N1 virus Sweden/83 was compared to other H1N1 viruses by oligonucleotide fingerprinting. This analysis revealed that Sweden/83 is identical to the Danish strain Sjaelland/82 and is thus to be placed in the group of "US viruses". On the other hand, the Danish strain Als/82 was found to be different, i.e., related to the Belgium/79 strain which is a representative of the "European viruses". The results of the present genomic analysis confirm the previous findings of relationships between the above strains.

Correlation between plaque size and genetic variation of type 3 poliovirus from a vaccinate

Vaccine strain derivatives could be serially isolated from the feces of a healthy infant for about 30 days after the second administration of a trivalent poliovirus vaccine. These were all identified as poliovirus type 3, and no other types were detected. The titer in feces increased gradually until day 19, when it reached a maximum, after which it decreased. The plaque size altered roughly in parallel with the changes in the titer. On day 11 it began to increase, becoming the highest abruptly on day 15, and then fell again. Oligonucleotide mapping analysis of RNAs of isolated viruses showed that the samples from days 1 and 11 exhibited the same patterns as those shown by the vaccine strain RNA. However, on day 15 many of the preexisting spots had decreased, and new ones appeared. On day 27, the pattern was again similar to that of the original virus, rather than that of the day-15 virus. A nonmetric distance scaling and cluster analysis suggested that all the strains were derived from the same origin and that the polioviruses on days 1, 11, 21, and 27 had closer relationships, but the poliovirus on day 15 was different.

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.

Location and primary structure of a major antigenic site for poliovirus neutralization

We have determined a major antigenic site for virus neutralization on the capsid protein VP1 of poliovirus type 3. Antigenic mutant viruses selected for resistance to individual monoclonal antibodies had point mutations concentrated in a region 277-294 bases downstream from the start of the region of viral RNA coding for VP1. These findings provide the basis for an improved understanding of the molecular basis of virus neutralization.

Molecular biology of rotaviruses. IV. Molecular cloning of the bovine rotavirus genome

A new cloning strategy has been developed for cloning the genomes of double-stranded RNA viruses by using bovine rotavirus as a test system. The major modification adopted was the use of denatured polyadenylated double-stranded RNA as the template for reverse transcriptase. This allowed the two complementary strands of cDNA to be synthesized in a single reaction and removed the need for S1 nuclease digestion to remove the 5' hairpin structure normally generated in cDNA synthesis.

Alteration in oligonucleotide fingerprint patterns of the viral genome in poliovirus type 2 isolated from paralytic patients

A close relationship was demonstrated by oligonucleotide fingerprinting between genomes of the poliovirus type 2 Sabin vaccine strain and recent isolates from paralytic cases associated with vaccination in Japan. The oligonucleotide maps of isolates from an agammaglobulinemic patient, who continued to excrete poliovirus type 2 for 3.5 years after the administration of oral vaccine, showed that the genomic alteration proceeded gradually, retaining the majority of the oligonucleotides characteristic of the vaccine strain for a long period, indicating vaccine origin for the isolates. The final isolate at month 41, however, lost the majority of these oligonucleotides. The heterologous antigenic relationship between the final isolate and the previous isolates was also observed. The serial alteration in electrophoretic mobility of the major structural proteins (VP1, VP2, and VP3) was observed throughout the excreting period. These results indicate that the population of the virus in this individual changed markedly during the last short period (about 3 months), in which the treatment with secretory immunoglobulin A was carried out. Genome comparisons in oligonucleotide maps show that some oligonucleotides in the genome of the vaccine strain are highly mutable after passage in humans.

Oligonucleotide mapping: evaluation of its sensitivity by computer-simulation

A frequently used method of comparing large RNA molecules employs the two-dimensional display of oligonucleotides generated through the action of specific RNases (oligonucleotide mapping, fingerprinting). Using computer simulations and simple analytic expressions the number of large RNase T1-resistant oligonucleotides obtained from random RNA sequences can be estimated. The computer simulations also permit estimation of the number of large oligonucleotides which remain unchanged as random variations are introduced into a random RNA sequence. In addition, computer analysis also provides a means of estimating statistical confidence limits to be used in a quantitative comparison of fingerprints of different RNA molecules. The model shows that two RNA sequences which differ overall by 1%, 5% or 10% share, on average, only 85%, 50% or 25%, respectively, of their large oligonucleotides. Thus, the use of fingerprint analysis is recommended only when closely related RNAs or regions of RNAs are compared (sequence homology greater than 90%).

A comparative analysis of measles virus RNA by oligonucleotide fingerprinting

Isolates from two cases of acute measles, one case of acute measles encephalitis and three patients with subacute sclerosing panencephalitis were compared. This comparison was based upon the electrophoretic analysis of T1 oligonucleotides from single-stranded, full-length RNA isolated from cytoplasmic nucleocapsids. Although all viruses have oligonucleotides in common, each isolate generated a unique pattern of oligonucleotides. However, no group of oligonucleotides was observed which would allow a differentiation between viruses isolated from acute infections and those isolated from CNS diseases; indicating that probably all measles viruses differ in their nucleotide sequence, regardless of origin.

A sensitive method for the production of diagnostic fingerprints of the genome segments of field isolates of rotavirus

The 3'-terminal labelling procedure for analyzing the genome segment profile of field isolates of rotavirus (Clarke and McCrae, 1981, J. Virol. Methods 2, 203) has been further developed to produce a rapid and sensitive method for generating diagnostic fingerprints from individual species of double-stranded RNA. The fingerprints were obtained by a one-dimensional resolution of overlapping terminally labelled oligonucleotides produced by partial nuclease digestion with a base-specific nuclease. This fingerprinting method should be of great value in characterizing the molecular details of genome segment variation and will facilitate detailed molecular epidemiological studies of this important virus group.

Methylated regions of hamster mitochondrial ribosomal RNA: structural and functional correlates

The positions of post-transcriptionally methylated residues within hamster mitochondrial ribosomal RNA have been established. Comparisons with other mitochondrial rRNA, and with bacterial, eucaryotic and chloroplast rRNA show that the methylated regions i) are comprised of conserved primary sequences and/or secondary structures and ii) are situated at the subunit interface of the ribosome. The comparative analyses also reveal that the ribose-methylated sequence UmGmU of hamster mitochondrial large ribosomal subunit (LSU1) RNA lies in a universally conserved hairpin loop which contains a putative puromycin-reactive nucleotide. The "UmGmU hairpin" is within 100 nucleotides of two chloramphenicol-resistance residues of LSU RNA. We present a secondary structure for this region which is conserved in LSU RNAs. This structure allows physical juxtaposition of the three antibiotic-interacting loci and thus defines RNA components of the ribosomal-binding site for the 3'-terminus of aminoacyl-tRNA.

Nucleotide sequences associated with differences in electrophoretic mobility of envelope glycoprotein gp70 and with GIX antigen phenotype of certain murine leukemia viruses

Previous genetic and biochemical studies led to the identification of two large RNase T1-resistant oligonucleotides, designated the G(IX) (+) and G(IX) (-) oligonucleotides, whose presence in the genomes of closely related murine leukemia viruses is mutually exclusive and predictive of two properties of the viral envelope glycoprotein gp70. Viruses harboring the G(IX) (+) oligonucleotide induce expression of the gp70-associated antigen G(IX) and possess gp70s with more rapid electrophoretic mobility on sodium dodecyl sulfate/polyacrylamide gels than viruses that possess the G(IX) (-) oligonucleotide. The latter viruses fail to induce G(IX) on infected fibroblasts. The G(IX) (+) and G(IX) (-) oligonucleotides lie in corresponding positions in the 3' third of the oligonucleotide maps of their respective viruses. We have determined the nucleotide sequences of the G(IX) (+) and G(IX) (-) oligonucleotides. The sequence of the G(IX) (-) oligonucleotide is U-A-U-C-U-C-A-A-C-C-A-C-C-A-U-A-C-U-U-A-A-C-C-U-C-A-C-C-A-C-[unk]-G, and the sequence of the G(IX) (+) oligonucleotide is U-A-U-C-U-C-A-A-C-C-A-C-C-A-U-A-C-U-U-G. Thus, a single base change could result in the interconversion of the two oligonucleotides. Consideration of the amino acids specified by the two oligonucleotides suggests that this single base difference may result in the presence of an additional oligosaccharide chain in the gp70s of the G(IX) (-) viruses. Evidence supporting this prediction has been obtained by M. R. Rosner, J.-S. Tung, E. Fleissner, and P. W. Robbins (personal communication). It is entirely possible that the single nucleotide change that apparently results in a different electrophoretic mobility of the gp70s of the G(IX) (+) and G(IX) (-) viruses is also responsible for the presence or absence of the G(IX) antigenic determinant; however, the validity of this possibility awaits further investigation.

Analysis of the genome of an endogenous, ecotropic retrovirus of the AKR strain of mice: micromethod for detailed characterization of high-molecular-weight RNA

A detailed characterization of the genome of an endogenous, ecotropic type C virus, the Akv virus, is presented. Approximately 100 RNase T1-resistant oligonucleotides characteristic of the Akv genome were identified by two-dimensional gel electrophoresis, and the complete nucleotide sequence is presented for 75 of these oligonucleotides. A correspondence between the sequence of some of these oligonucleotides and the amino acid sequence of some virus-coded gag gene proteins is reported. For this study we developed methods suitable for the analysis of high-molecular-weight RNA species in nanogram quantities. The in vitro labeling procedures used here led to uniform labeling of the unique oligonucleotides.

Isolation of influenza C virus recombinants

Recombinants between two different influenza C viruses were isolated. In MDCK (canine kidney) cells, one strain, C/JJ/50, caused lytic plaques, whereas C/JHG/66 virus did not produce clear plaques. From a mixed infection of MDCK cells with C/JHG/66 virus and UV-inactivated C/JJ/50 virus, clones were isolated which possessed the clear-plaque phenotype. Fingerprint analyses indicated that the RNAs of parent viruses had different oligonucleotide patterns and that one of the clones derived from the mixed infection was formed by reassortment of parental genes. This recombinant clone most likely inherited RNAs 1, 2, 3, 6, and 7 from C/JGH/66 virus and RNAs 4 and 5 from C/JJ/50 virus.

Evolution of human influenza A viruses in nature: sequential mutations in the genomes of new H1N1

The genetic variation of the new pandemic H1N1 influenza A viruses isolated in 1977 was analyzed by two-dimensional oligonucleotide fingerprinting and RNA sequencing. Differences were observed in the fingerprints of the RNAs of these viruses, and analysis of the changes suggested that sequential mutations occurred in their genomes. Based on these data, a scheme is presented which proposes divergent evolution of strains from a common ancestry. Furthermore, it was found that mutations were not restricted to the genes coding for the hemagglutinin and the neuraminidase, but were scattered throughout the genome, suggesting that selective antibody pressure is not solely responsible for the emergence of genetic variants. Our data also strengthen the hypothesis that the new H1N1 influenza virus strains are derived from strains circulating in 1950.

Restriction endonuclease cleavage of linear and closed circular murine leukemia viral DNAs: discovery of a smaller circular form

Both linear (form III) and closed circular (form I) viral DNAs obtained from mouse cells infected with Moloney murine leukemia virus were cleaved by Sal I, Sma I, Bam HI and Pst I restriction endonucleases. DNA fragments generated by these cleavages were ordered with respect to the 5' and 3' ends of the RNA genome by several techniques, including comparisons of the DNA fragments from cleavages of the linear and closed circular forms, double digestions using different combinations of enzymes and the use of an RNA probe specific for the 3' end. DNA from Hirt extractions of infected cells yielded a discrete species of linear viral DNA whose size was determined by agarose gel electrophoresis to be 5.7 x 10(6) daltons. In the course of characterizing the closed circular DNA, we observed two form I DNA molecules. The larger molecule was the same size as the linear DNA. The second molecule migrated faster on agarose gels and was the predominant species of the two closed circular DNAs. Using the restriction endonuclease maps which we derived, we demonstrate that this novel form I DNA is a smaller homogeneous species of viral DNA, missing about 600 nucleotides found in the linear and larger closed circular DNA molecules. We have localized the site of this missing DNA piece to be at either one or both ends of the linear viral DNA.

RNA sequencing provides evidence for allelism of determinants of the N-, B- or NB-tropism of murine leukemia viruses

Previous genetic and biochemical studies identified three large RNAase T1-resistant oligonucleotides, each associated with either the N-, B- or NB-tropism of murine C-type viruses of BALB/c origin. These oligonucleotides were shown to lie in the 5' third of the oligonucleotide maps of their respective viruses. We sequenced the three oligonucleotides and found that they share a 10 base sequence. Together these observations provide good evidence that the determinants of N-, B- or NB-tropism monitored by the three oligonucleotides are allelic. The oligonucleotides associated with N- and B-tropism differ in sequence at four of sixteen nucleotides, while the B- and NB-tropism-associated oligonucleotides differ in sequence by only one base out of sixteen. These results are consistent with the possibilities that B-tropic viruses may arise from N-tropic viruses by recombination, while NB-tropic viruses may arise from B-tropic virus by mutation. An unexplained finding was that a 10 base sequence present in the oligonucleotide associated with N-tropism is also found in the 3' third of the genomes of the N-, B- and NB-tropic viruses studied.

Recent human influenza A (H1N1) viruses are closely related genetically to strains isolated in 1950

Comparison of the oligonucleotide maps of the RNAs of current human influenza (H1N1) virus isolates shows these strains to be much more closely related to viruses isolated in 1950 than to strains which circulated before or after that period.

Sequence of 129 nucleotides at the 3'-terminus of encephalomyocarditis virus RNA

The sequence of 129 nucleotides next to the poly(A) tail of encephalomyocarditis virus RNA has been determined by rapid gel sequencing of cDNA synthesized with DNA polymerase I or reverse transcriptase and a phasing primer, [5'-32P]p(dT)8dC. The sequence is in accord with (a) the pyrimidine tracts which were mapped in blocks along the cDNA, (B) the sequences of seven characteristic T1 RNase oligonucleotides in the RNA transcribed from the cDNA with RNA polymerase, and (c) a limited amount of sequence deduced by partial spleen phosphodiesterase digestion and depurination of endonuclease IV oligonucleotides. The 3' end shows little secondary structure on its own. Ten nonsense codons block all three reading frames such that at least 26 nucleotides do not code for protein. The possible function of a homology A-A-U-A-A-A with other polyadenylated RNAs is discussed.

Biochemical evidence that "new" influenza virus strains in nature may arise by recombination (reassortment)

Oligonucleotide analysis of two avian influenza A viruses (Hav6N2 and Hav6Nav4) isolated in nature showed identical or almost identical patterns for the corresponding M and HA genes; 24 of 25 and 13 of 13 large oligonucleotides were indistinguishable by two-dimensional gel analysis. On the other hand, remarkable differences in the oligonucleotide patterns of the remaining genes were observed. Only 2 of 11 oligonucleotide spots of the NS gene, 10 of 27 spots of the NA/NP genes, and 22 of 49 spots of the P genes were indistinguishable between the two strains. On the basis of this observation that at least two genes of these viruses are virtually identical whereas others show easily detectable differences, we conclude that the two avian strains are related to each other by a recombinational event. In addition, it was found that animals in nature can be doubly infected with influenza viruses. Both lines of evidence strongly suggest that recombination is at least one mechanism by which "new" influenza virus strains emerge in nature.

Studies on the primary and secondary structure of potato spindle tuber viroid: products of digestion with ribonuclease A and ribonuclease T1, and modification with bisulfite

Potato spindle tuber viroid (PSTV), a small infectios RNA, has been completely digested with RNase T1 and RNase A, and the resulting oligonucleotides have been sequenced using 5'-terminal 32p-labelling with gamma-32p ATP and T4 polynucleotide kinase, fingerprinting and controlled nuclease P1 digestion. Modified nucleotides have not been detected in 5'-positions of these oligonucleotides. PSTV consists of about 359 nucleotides and contains a remarkable stretch of 18 purines, mainly adenosines; there is no AUG initiation triplet present. The established oligonucleotide sequences preclude a perfect intramolecular base complementarity within the covalently closed viroid circle. Therefore, the rigid, rod-like native secondary structure of PSTV, as seen in the electron microscope, must be based on a defective rather than on a homogeneous RNA helix. The detailed analysis of the bisulfite-catalized modification of cytidine to uridine in PSTV revealed a higher reactivity for the majority of the cytidines than would be expected for a perfect helix. Since only cytidines in single-stranded regions are knonw to be fully reactive, this finding provides additional evidence for defects in the helical secondary structure of PSTV.