- Volume 72, Issue 6, 1991

The 72K immediate early (IE) 1 protein of human cytomegalovirus and the 68K protein, also encoded by the IE1 gene, were detected by immunoelectron microscopy using monoclonal antibodies specific for the 68K or 72K proteins. Early after infection, both proteins were localized to the nucleus, but with different localization patterns. Late after infection, both of the proteins decreased markedly in the nucleus, in which nucleocapsids appeared. Simultaneously, the 68K protein became diffusely distributed in the cytoplasm and the plasma membrane, whereas the 72K protein was distributed in the nuclear envelope and the plasma membrane. Both proteins were also observed in the coating membrane of the extracellular dense bodies.

We have developed a hybridoma, designated 25G11, which produced a monoclonal antibody (MAb) reactive with a 52K protein of murine cytomegalovirus (MCMV). This MAb, 25G11, was reactive with a protein band of 52K in MCMV-infected cell lysates and with a protein of 49K in human CMV (HCMV)-infected cell lysates as detected by immunoblot analysis. With purified MCMV virions, 25G11 gave a faintly immunoreactive band of 52K. However, no immunoreactive protein band was detected with purified HCMV virions, nor with purified HCMV or MCMV envelope preparations. By immunocytochemistry, 25G11 detected viral antigen primarily in the nucleus of HCMV- or MCMV-infected cells. The antibody 25G11 was used to screen a λgt11 library of HCMV DNA fragments. One of the isolated clones (λ32323B) was employed for gene mapping on the HCMV genome, which suggested that the immunoreactive HCMV protein was the DNA-binding protein (ICP36). Analysis of the recombinant fusion protein with antibody 25G11 and with an MAb (CH16) specific for an HCMV DNA-binding protein confirmed the identity of the cross-reacting protein as ICP36. Furthermore, we found that whereas the epitope recognized by 25G11 was conserved between HCMV and MCMV proteins, the epitope recognized by CH16 was unique to HCMV and thus represents a variable region in the protein.

The glycoprotein gp6/gp10/gp17, gp11/VP24 and gp8 are major bovine herpesvirus type 4 antigens. The temporal expression of these glycoproteins was studied and it was shown that gp6/gp10/gp17 appeared as early as 6 h post-inoculation (p.i.), and gp11/VP24 and gp8 were detected 8 h p.i. Moreover, a precursor of two components of gp6/gp10/gp17 glycoprotein [p(gp10/gp17)] was a beta-gamma protein, whereas the gp11/VP24 and gp8 glycoproteins were gamma proteins.

The nucleotide sequences of the coding region of the thymidine kinase (TK) gene of pseudorabies virus strain NIA3 and a TK− mutant (ATK5) were determined. The coding region of the TK gene consists of 320 codons capable of producing a polypeptide with an M r of 34979. The mutant expressed an inactive TK polypeptide when translated in vitro; a unique base substitution was detected in the mutant TK modifying amino acid position 13, at which aspartic acid replaces glycine. This modification affects the nucleotide-binding site, thus explaining the expression of an inactive TK polypeptide.

Infection of Vero cells with herpes simplex virus (HSV) causes a marked increase in the dTTP pool size of infected cells. In this study we examined the relative importance of the HSV-encoded ribonucleotide reductase (RR) and thymidine kinase (TK) in the increase of dTTP. In cells infected with an RR deletion mutant of HSV-1 strain KOS, there was no significant increase in the size of the dTTP pool, whereas the dTTP pool in HSV-1(TK−)-infected cells was increased in size to almost the same extent as that in HSV-1(TK+)-infected cells. Moreover, it was found that the increase in dTTP pool size was strongly inhibited by the addition of hydroxyurea, a specific inhibitor of RR, and 5-fluoro-2′-deoxyuridine, a specific inhibitor of thymidylate synthetase. These results suggest that the induction of viral RR is of primary importance in the increase of dTTP pool size in HSV-1-infected Vero cells.

Several vaccinia virus (VV)-varicella-zoster virus (VZV) recombinants expressing glycoprotein I (gpI) of VZV were isolated from the Prague strain of VV. One of these, v46, was inoculated intraperitoneally into mice. Groups of mice were bled 4 and 8 weeks later and their sera were examined for anti-VZV and anti-VV antibodies by ELISA. At 4 weeks, all mice inoculated with the three largest virus doses (107, 106 and 105 p.f.u.), and at 8 weeks all mice inoculated with the four highest virus doses (107, 106, 105 and 104 p.f.u.), had developed both anti-VV and anti-VZV antibodies. Antibodies were also detected in a high proportion of mice infected with lower doses of virus and in some instances VZV antibodies were present in the absence of VV antibodies. None of the animals inoculated in parallel with either a thymidine kinase-negative mutant of the original VV or diluent alone developed antibody reactive with VZV. The specificity of the reaction was assessed further by Western blotting using anti-gpI monoclonal antibodies as a positive control. Sera from animals immunized with v46 possessed antibody capable of neutralizing extracellular VZV in the presence of complement.

We have constructed a recombinant baculovirus containing cloned DNA encoding the membrane and envelope (E) proteins of 17D yellow fever vaccine virus. Spodoptera frugiperda cells infected with this recombinant baculovirus produced a 66K protein which corresponded to the estimated size of the protein encoded by the cloned inserted DNA, and a 54K protein with the same molecular size as that of the authentic 17D yellow fever virus E protein. This recombinant 54K protein was labile, producing E protein-specific breakdown products (45K to 36K). Indirect immunofluorescence, using a panel of E protein-specific monoclonal antibodies, showed that the recombinant protein was presented both inside as well as on the surface of cells and was antigenically indistinguishable from the E protein of 17D yellow fever vaccine virus.

The phosphoprotein (P protein) from human respiratory syncytial virus Long strain, labelled in vivo with [32P]orthophosphate, was purified from virions or virus-infected human epithelial (Hep-2) cells. The main phosphorylated amino acid found was serine. The determination of the N-terminal sequence of unphosphorylated and phosphorylated fragments of P protein obtained after chemical or enzymic treatments suggested that some or all of the six serines present at positions 116, 117, 119, 143, 156 and 161 are the major phosphorylated residues, although a modification in serine residues at positions 86, 94 and 99 can not be ruled out.

The M2 protein of influenza A virus, a 97 amino acid integral membrane protein expressed on the surface of infected cells, is covalently modified with long chain fatty acids. The fatty acid bond is sensitive to treatment with neutral hydroxylamine and mercaptoethanol, which indicates a labile thioester type linkage. Thinlayer chromatographic fatty acid analysis of [3H]myristic and [3H]palmitic acid-labelled M2 protein shows that palmitic acid is the predominant fatty acid linked to this polypeptide. Palmitoylation of M2 occurs post-translationally and causes an upward shift in the SDS-PAGE mobility of the protein.

The specific contributions of human adenovirus type 5 early region 1B (E1B) proteins were examined using mutants which synthesize these products individually. In cooperation with E1A, transformation of primary baby rat kidney cells was achieved with either the 176R protein or 496R protein alone, albeit at an efficiency considerably less than that observed when both were present. These results indicate that transformation mediated by either E1B product can proceed independently, but that the processes involved are additive.

Small insertions were made independently at each of four unique restriction sites on African cassava mosaic virus (ACMV) DNA A to disrupt the three overlapping complementary-sense open reading frames (ORFs) herein designated AC1, AC2 and AC3. The DNA A mutants were assayed for their infectivity by agroinoculation of monomeric constructs to Nicotiana benthamiana plants containing chromosomal insertions of ACMV DNA B. Disruption of the AC3 ORF alone resulted in a delay and amelioration of disease symptoms which correlated with reduced replication of DNA B. Normal replication of DNA A still carrying the AC3 ORF mutation was found in extracts from these plants. No ACMV DNA or symptoms were observed in corresponding inoculations with either the simultaneous disruption of the overlapping AC2 and AC3 ORFs or disruption of the AC1 ORF. Complementation by the inoculation of different mutant pairs produced a delay in disease symptoms followed by repair of mutated sites. A DNA A construct with the virus-sense AV1 (coat protein) ORF deleted was infectious producing typical ACMV disease symptoms. A similar construct with a larger deletion encompassing the complementary-sense AC3 ORF produced symptomless infections. The DNA recovered from plants revealed DNA A of normal size where the position of the deleted ORF was replaced with cloning vector DNA. Significantly reduced DNA B replication was observed for the AC3 deletion construct.

In nature, rice tungro disease is caused by an RNA and a DNA virus complex, but we have obtained an independently infectious clone of rice tungro bacilliform virus (RTBV) DNA. Infectivity could be demonstrated only when a more than unit-length copy was cloned in the Agrobacterium binary vector Bin19 and agroinoculated into rice plants. Rice plants thus agroinfected with cloned RTBV DNA showed typical symptoms of tungro disease, presence of viral DNA and bacilliform particles, and could be used as a source of virus to infect healthy plants by the green leafhopper (Nephotettix virescens). The importance of this infectious clone in understanding the molecular biology of RTBV and the rice tungro disease is discussed.

The purpose of this work has been to investigate in vivo transcription and translation products from an open reading frame (ORF) located downstream of the coat protein (CP) cistron on RNA-2 of pea early browning virus (PEBV). This work was initiated as a step towards elucidation of the significance of this putative gene. Sequence data on RNA-2 suggest that a 29600 M r (29.6K) protein is translated from the ORF in question. Hybridization with ORF-specific probes on Northern blots with RNA from infected plants showed that PEBV synthesizes a subgenomic RNA encoding CP (RNA-2a) with a size of 3000 nucleotides (nt) and that a putative subgenomic RNA (RNA-2b) encoding the 29.6K protein appears to have a size of 1600 nt. This is 300 nt less than the size predicted from the sequencing data. For antibody production, a cDNA fragment harbouring 85% of the 29.6K ORF was cloned into the pUEX3 expression vector. The resulting plasmid expresses the 29.6K protein as a fusion protein with β-galactosidase and this protein was used for raising antiserum containing specific anti-29.6K protein antibodies. By using these antibodies on immunoblots it was demonstrated that the 29.6K protein is expressed in infected plants.

A general diagnostic assay for a number of distinct luteoviruses was developed using the polymerase chain reaction (PCR) and restriction enzyme analysis. Two minimally degenerate, group-specific primers were derived from previously published RNA sequences of three luteoviruses. This primer pair generated specific PCR fragments of about 530 bp from extracts of plants infected with potato leafroll virus, beet western yellows virus, or New York barley yellow dwarf virus (BYDV) serotypes MAV, PAV, RMV, RPV and SGV, which span much of the respective viral coat protein gene. Each virus was easily distinguished from the others by restriction enzyme analysis of the amplified DNA products. Samples from BYDV-infected oat and wheat collected in Nebraska were identified as containing PAV-like serotypes; micro-heterogeneity was detected in several samples. This method provides a rapid, sensitive and relatively inexpensive means of luteovirus detection and identification. It is the first test capable of simultaneously detecting all five BYDV serotypes.

Circular dichroism (CD) measurements on the coat protein of narcissus mosaic virus particles show that the dominant secondary structure is the α-helix, with a 45 (±2)% content. The β-sheet content is much lower at 5 (±3)%. Both values are essentially the same as those found in potato virus X coat protein. The CD results are used to assess the results of secondary structure prediction methods.