- Volume 81, Issue 3, 2000

The effects of interferon (IFN)-α, IFN-β and IFN-γ on human papillomavirus (HPV) oncogene expression were studied in various cervical carcinoma cell lines containing integrated copies of either HPV type 16 or HPV type 18. The levels of E6 and E7 transcripts were examined 6 h and 30 h after treatment with IFN. In HeLa cells, all three classes of IFNs effected a decrease in the level of HPV-18 E6 and E7 transcripts. On the other hand, none of the IFNs altered the level of these transcripts in C-4II cells. Only IFN-γ decreased the level of HPV-16 E6 and E7 transcripts in CaSki and HPK1A cells, while IFN-γ actually increased the level of these transcripts in SiHa cells. This differential IFN regulation of HPV expression in various cervical cancer cell lines may account for the contradictory clinical results observed after treatment of cervical cancer with IFN.

To evaluate the humoral immune response to human papillomavirus (HPV) in women infected with human immunodeficiency virus (HIV), serum samples of 83 HIV-positive individuals were analysed by ELISA for specific antibodies of the isotypes IgG, IgA and IgM recognizing HPV-6, -11, -16, -18 and -31 L1 virus-like particles (VLPs). Papillomavirus-related lesions were present in 30 of 83 HIV-positive women. Twenty-one women (25%) presented with high-/intermediate-grade anogenital squamous intraepithelial lesions. PCR analysis and sequencing for HPV typing was done from biopsy specimens of 18 women; PCR-positive results were obtained in 90% of cases. In addition, HPV DNA hybrid capture assays were performed from cervical swabs of 58 HIV-positive women, 53% of whom had a positive result for high-risk HPV. Overall, positive IgG reactivity to HPV-6/-11 and HPV-16/-18/-31 was seen in 19%/31% and 49%/30%/24% of HIV-positive women, respectively. HPV-seropositivity was even higher than in 48 HIV-negative cervical intraepithelial neoplasia/cancer patients with percentages as follows: 8%/2% and 31%/15%/15%. This difference was significant for HPV-16 (P=0·046). IgA responses were comparable to IgG. IgM responses were low. The extraordinarily high rate of antibodies to the capsid protein L1 of high-risk HPVs (HPV-16, -18 and/or -31) in 58% of HIV-positive women compared to 19% (P=0·00001) of 102 healthy HIV-negative control women suggests a high lifetime cumulative exposure to HPV and increased expression of capsid proteins due to cellular immunodeficiency in HIV-infected women.

Two different motifs in the coat protein (CP) of Plum pox virus (PPV) (R3015Q3016, D3059) were mutated by replacing the respective amino acids with others possessing different chemical properties. The mutated CP genes were introduced into an infectious full-length clone of PPV (p35PPV-NAT) to investigate their influence on systemic infection of transgenic wild-type PPV CP-expressing and non-transgenic plants of Nicotiana benthamiana. All mutants failed to establish systemic infections in non-transgenic N. benthamiana plants, but were complemented by intact CP in transgenic plants. Moreover, the CP-RQ-D mutant (carrying mutations in both the RQ and D motifs) was introduced into p35PPV-NAT engineered to express β-glucuronidase (GUS) for direct observation of systemic movement and particle assembly in N. benthamiana leaves. GUS-staining revealed that the CP mutant (RQ-D) was restricted to initially infected cells without forming virions. Systemic movement and particle assembly were restored in CP-transgenic N. benthamiana plants. Finally, transgenic N. benthamiana plants were generated that expressed each of the three mutated CP genes. Homozygous T2 lines were selected and tested for resistance to PPV. Immunogold labelling and electron microscopy revealed that heterologous encapsidation with challenging Chilli veinal mottle virus and Potato virus Y was suppressed in these lines. In addition, assembly mutants did not complement CP-defective p35PPV-NAT. The possible use of modified viral CP genes for the production of virus-resistant transgenic plants, thereby reducing the putative risks of heterologous encapsidation and complementation, is discussed.

Isolates of tobacco mild green mosaic tobamovirus (TMGMV) were obtained from 58 plants of Nicotiana glauca in southern California and placed in one of two groups (Small type and Large type) based on the size of the subgenomic RNA for the coat protein (CP). The CP sequence differed by no more than one amino acid for the two types, and the Small type was identical to that published for TMGMV. Thirty-six of the isolates had a double-stranded (ds)RNA profile that matched that of type TMGMV, and the nucleotide sequence of the 3′ untranslated region (3′UTR) of six of these isolates was similar to the published sequence of TMGMV. Twenty-two isolates had a larger dsRNA for the CP subgenomic RNA. Six of these were sequenced and all had a repeat sequence of between 147 and 165 bases in the part of the 3′UTR that is involved in the formation of pseudoknots. These novel but common isolates are predicted to have six rather than three pseudoknots. Small types (three pseudoknots=type TMGMV) yielded twice as much virus after purification as Large types (six pseudoknots). The two groups of isolates could be distinguished in N. rustica (Large type, but not Small type gave a systemic infection), and N. clevelandii (Small type but not Large type induced systemic lethal necrosis). Almost all isolates of TMGMV used in this study were initially associated with satellite tobacco mosaic virus (STMV), and both types supported STMV experimentally.

Transgenic tobacco plants expressing an altered form of the 2a replicase gene from the Fny strain of Cucumber mosaic virus (CMV) exhibit suppressed virus replication and restricted virus movement when inoculated mechanically or by aphid vectors. Additional transformants have been generated which contain replicase gene constructs designed to determine the role(s) of transgene mRNA and/or protein in resistance. Resistance to systemic disease caused by CMV, as well as delayed infection, was observed in several lines of transgenic plants which were capable of expressing either full-length or truncated replicase proteins. In contrast, among plants which contained nontranslatable transgene constructs, only one of 61 lines examined exhibited delays or resistance. Once infected, plants never recovered, regardless of transgene translatability. Transgenic plants exhibiting a range of resistance levels were examined for transgene copy number, mRNA and protein levels. Although ribonuclease protection assays demonstrated that transgene mRNA levels were very low, resistant lines had consistently more steady-state transgene mRNA than susceptible lines. Furthermore, chlorotic or necrotic local lesions developed on the inoculated leaves of transgenic lines containing translatable transgenes, but not on inoculated leaves of lines containing nontranslatable transgenes. These results demonstrate that translatability of the transgene and possibly expression of the transgene protein itself facilitates replicase-mediated resistance to CMV in tobacco.

In the positive-stranded RNA genome of beet yellows closterovirus (BYV), the 5′-terminal ORF 1a encodes a 295 kDa polyprotein with the domains of papain-like cysteine proteinase, methyltransferase (MT) and helicase (HEL), whereas ORF 1b encodes an RNA-dependent RNA polymerase. Eleven and five hybridoma cell lines secreting monoclonal antibodies (MAbs) were derived from mice injected with the bacterially expressed fragments of the BYV 1a product encompassing the MT and HEL domains, respectively. On immunoblots of protein from BYV-infected Tetragonia expansa plants, four MAbs against the MT recognized a ∼63 kDa protein, and two MAbs against the HEL recognized a ∼100 kDa protein. Both the methyltransferase-like protein and the helicase-like protein were found mainly in the fractions of large organelles (P1) and membranes (P30) of the infected plants. These data clearly indicate that (i) the BYV methyltransferase-like and helicase-like proteins, like other related viral enzymes, are associated with membrane compartments in cells, and (ii) the 1a protein, apart from the cleavage by the leader papain-like proteinase that is expected to produce the 66 kDa and 229 kDa fragments, undergoes additional processing by a virus-encoded or cellular proteinase.

The genome of Grapevine leafroll-associated virus 1 (GLRaV-1) was cloned and the sequence of 12394 nts determined. It contains 10 major open reading frames (ORFs) and a 3′-non-coding region lacking a poly(A) tract. The first ORF (ORF 1a) encodes a putative RNA helicase at the C-terminal portion of an apparently larger protein. The downstream ORF, 1b, overlaps ORF 1a and lacks an initiation codon. This ORF encodes an RNA-dependent RNA polymerase of M r 59276. ORF 2 encodes a small hydrophobic protein of M r 6736, and ORF 3 encodes a homologue of the HSP70 family of heat shock proteins and has an M r of 59500. ORF 4 encodes a protein with an M r of 54648 that shows similarity to the corresponding proteins of other closteroviruses. ORF 5 encodes the viral coat protein (CP) with an M r of 35416. The identity of this ORF as the CP gene was confirmed by expression in Escherichia coli and testing with the viral antibody. ORFs 6 and 7 code for two CP-related products with M r of 55805 and 50164, respectively. ORFs 8 and 9 encode proteins of M r 21558 and 23771 with unknown functions. Using DNA probes to different regions of the GLRaV-1 sequence, three major 3′-coterminal subgenomic RNA species were identified and mapped on the GLRaV-1 genome. Phylogenetic analyses of the individual genes of GLRaV-1 demonstrated a closer relationship between GLRaV-1 and GLRaV-3 than with other closteroviruses.

A full-length cDNA corresponding to the RNA genome of Potato leafroll virus (PLRV) was modified by inserting cDNA that encoded the jellyfish green fluorescent protein (GFP) into the P5 gene near its 3′ end. Nicotiana benthamiana protoplasts electroporated with plasmid DNA containing this cDNA behind the 35S RNA promoter of Cauliflower mosaic virus became infected with the recombinant virus (PLRV-GFP). Up to 5% of transfected protoplasts showed GFP-specific fluorescence. Progeny virus particles were morphologically indistinguishable from those of wild-type PLRV but, unlike PLRV particles, they bound to grids coated with antibodies to GFP. Aphids fed on extracts of these protoplasts transmitted PLRV-GFP to test plants, as shown by specific fluorescence in some vascular tissue and epidermal cells and subsequent systemic infection. In plants agroinfected with PLRV-GFP cDNA in pBIN19, some cells became fluorescent and systemic infections developed. However, after either type of inoculation, fluorescence was mostly restricted to single cells and the only PLRV genome detected in systemically infected tissues lacked some or all of the inserted GFP cDNA, apparently because of naturally occurring deletions. Thus, intact PLRV-GFP was unable to move from cell to cell. Nevertheless, PLRV-GFP has novel potential for exploring the initial stages of PLRV infection.