Field resistance of transgenic burley tobacco lines and hybrids expressing the tobacco vein mottling virus coat protein gene

Fifty transgenic lines expressing the tobacco vein mottling virus (TVMV) coat protein (CP) gene in five genetic backgrounds were evaluated under field conditions for response to mechanic inoculation with TVMV, tobacco etch virus (TEV) and potato virus Y (PVY). TVMV CP transgenic lines conferred resistance to TVMV, TEV and PVY under field conditions. Combining two strategies, coat protein-mediated resistance (CPMR) coupled with an endogenous resistance gene (Virgin A Mutant, VAM) significantly extended the range and magnitude of virus resistance and provided a potential valuable new source of protection against potyviruses. CP transgenic lines lacking the VAM gene had high resistance to TEV, medium resistance to PVY, and a recovery phenotype to TVMV. A series of hybrids involving transgenic lines were generated and tested under field conditions for response to virus inoculation. One copy of TVMV-CP gene presented in lines homozygous for the VAM gene provided effective resistance to all three potyviruses. These studies also suggested that selection of a suitable recipient genotype was critical and that field evaluation was necessary in order to select elite resistant transgenic lines. Engineering viral CP genes into genotypes possessing some level of virus resistance could be critical to achieve an effective level of resistance.     

Efficient production of transgenic citrus plants expressing the coat protein gene of citrus tristeza virus

 The coat protein gene of citrus tristeza virus (CTV) has been introduced into Mexican lime (Citrus aurantifolia Swing.) plants by using an improved Agrobacterium-mediated genetic transformation system. Internodal stem segments from greenhouse-grown seedlings were co-cultivated with A. tumefaciens strain EHA 105 carrying the binary plasmid pBI 121/CTV-CP in a medium rich in auxins that provided the explant cells with the proper treatment to shift them to a competent state for transformation. The transformation frequency was enhanced, and this allowed us to recover 42 transgenic plants from 1200 explants. Regenerated shoots were identified as transformants by performing β-glucuronidase (GUS) assays and subsequently by PCR amplifications of the CTV-CP transgene. Southern analyses revealed that at least one copy of the CTV-CP gene was integrated in all PCR positive plants. Interestingly, 70% of them had linked T-DNAs arranged at one locus. Copy number of the CTV-CP gene varied from one to six among the transgenic lines. Half of them showed truncated T-DNAs in which the left border was lost. Expression of the CTV-CP transgene was demonstrated in 38 out of 42 plants by western analysis and DASI-ELISA. No correlation was found between coat protein expression and transgene copy number or integration pattern. Received: 7 April 1999 / Revision received: 17 June 1999 · Accepted: 24 June 1999     

Primary structure of belladonna mottle virus coat protein

The coat protein of belladonna mottle virus (a tymovirus) was cleaved by trypsin and chymotrypsin, and the peptides were separated by high performance liquid chromatography using a combination of gel permeation, reverse phase, and ion pair chromatography. The peptides were sequenced manually using the 4-N, N-dimethylaminoazobenzene-4'-isothiocyanate/phenyl isothiocyanate double-coupling method. The chymotryptic peptides were aligned by overlapping sequences of tryptic peptides and by homology with another tymovirus, eggplant mosaic virus. The belladonna mottle virus is more closely related to eggplant mosaic virus than to turnip yellow mosaic virus, the type member of this group, as evident from the sequence homologies of 57 and 32%, respectively. The accumulation of basic residues at the amino terminus implicated in RNA-protein interactions in many spherical plant viruses was absent in all the three sequences. Interestingly, the amino-terminal region is the least conserved among the tymoviruses. The longest stretch of conserved sequence between belladonna mottle virus and eggplant mosaic virus was residues 34-44, whereas it was residues 96-102 in the case of belladonna mottle virus and turnip yellow mosaic virus. A tetrapeptide in the region (residues 154-157) was found to be common for all the three sequences. It is possible that these conserved regions (residues 34-44, 96-102, 154-157) are involved in either intersubunit or RNA-protein interactions.     

Recovery of transgenic rice plants expressing the rice dwarf virus outer coat protein gene (S8)

 The coding region of the eighth largest segment (S8) of the rice dwarf virus (RDV) was obtained from a RDV Fujian isolate. It was then cloned into pTrcHisA for expression in E. coli and into vector pE3 for plant transformation. By using callus derived from mature rice embryos as the target tissue, we obtained regenerated rice plants after bombardment of the former with plasmid pE3R8 containing the RDV S8 gene and the marker gene neomycin phosphotransferase (NPT II). Southern blotting confirmed the integration of the RDV S8 gene into the rice genome. The expression of the outer coat protein in both E. coli and rice plants was confirmed by western blotting. The recovery of transgenic rice plants expressing S8 gene is an important step towards studying the function of the RDV genes and obtaining RDV-resistant rice plants. Received: 1 March 1996 / Accepted: 2 August 1996     

Specifics of the coat protein gene in Russian strains of the cucumber green mottle mosaic virus

The primary structure of the coat protein (CP) gene was examined for pathogenic strain MS-1 and vaccine strain VIROG-43M of the cucumber green mottle mosaic virus (CGMMV). In CP amino acid composition, strains MS-1 and VIROG-43M are typical representatives of CGMMV: their CPs have 98–100% homology to CPs of other tobamoviruses of the group. The CP gene has the same nucleotide composition in pathogenic MS-1 and vaccine VIROG-43M, indicating that strain attenuation is not determined by this gene. The CP amino acid sequences of the two Russian strains are fully identical to the CP sequences of two Greek strains, GR-3 and GR-5. However, the nucleotide sequences of their genes differ in 13 bp, testifying to the difference between the Russian and Greek strains.     

Specifics of the coat protein gene in Russian strains of the cucumber green mottle mosaic virus

The primary structure of the coat protein (CP) gene was examined for pathogenic strain MS-1 and vaccine strain VIROG-43M of the cucumber green mottle mosaic virus (CGMMV). In CP amino acid composition, strains MS-1 and VIROG-43M are typical representatives of CGMMV: their CPs have 98-100% homology to CPs of other tobamoviruses of the group. The CP gene has the same nucleotide composition in pathogenic MS-1 and vaccine VIROG-43M, indicating that strain attenuation is not determined by this gene. The CP amino acid sequences of the two Russian strains are fully identical to the CP sequences of two Greek strains, GR-3 and GR-5. However, the nucleotide sequences of their genes differ in 13 bp, testifying to the difference between the Russian and Greek strains.