应用免疫胶体金技术定位感病大麦细胞中的大麦和性花叶病毒

本文报道免疫胶体金标记技术的建立,并用此技术定位大麦叶和根组织超薄切片中大麦和性花叶病毒(BaMMV)。在感染病毒的大麦叶和根细胞中,病毒束、游离病毒颗粒和病毒外壳蛋白多分布于细胞质丰富的细胞中,且以液泡和叶绿体(仅叶组织)周围较多。在细胞器已解体的病根表皮细胞中,有时也可检测到大量游离病毒粒子。少数风轮体或板状集结体上也存在病毒或病毒外壳蛋白。细胞核、叶绿体、线粒体、细胞膜以及其他细胞器上都未见有特异性金颗粒标记。     

The full-length clone of cucumber green mottle mosaic virus and its application as an expression system for Hepatitis B surface antigen

A cucumber green mosaic mottle virus (CGMMV) full-length clone was developed for the expression of Hepatitis B surface antigen (HBsAg). The expression of the surface displayed HBsAg by the chimeric virus was confirmed through a double antibody sandwich ELISA. Assessment of the coat protein composition of the chimeric virus particles by SDS-PAGE analysis showed that 50% of the coat proteins were fused to the HBsAg. Biological activity of the expressed HBsAg was assessed through the stimulation of in vitro antibody production by cultured peripheral blood mononuclear cells (PBMC). PBMC that were cultured in the presence of the chimeric virus showed up to an approximately three-fold increase in the level of anti HBsAg immunoglobulin thus suggesting the possible use of this new chimeric virus as an effective Hepatitis B vaccine.     

The interaction of sodium dodecyl sulfate with cucumber green mottle mosaic virus protein and tobacco mosaic virus protein

The binding of sodium dodecyl sulfate to coat protein subunits of cucumber green mottle mosaic virus and tobacco mosaic virus was studied by equilibrium dialysis. The amount of dodecyl sulfate bound to the cucumber virus protein in 0.1 m phosphate buffer (pH 7.2) was found to be 1.55 g/g, which was the same value as that obtained with the tobacco virus protein. The presence of 8 m urea markedly decreased the degree of binding of dodecyl sulfate to the proteins. The amount of binding to the cucumber virus protein was reduced to 0.56 g/g, and that to the tobacco virus protein decreased to 0.8 g/g. The net charges of both proteins were negative at neutral pH and the amount of negative charge of the cucumber virus protein, obtained from the potentiometric titration curves, was larger than that of the tobacco virus protein, either in the native state or in the denatured state. In dodecyl sulfate/polyacrylamide gel electrophoresis the cucumber virus protein migrated faster than the tobacco virus protein. On the other hand, in the presence of 8 m urea, the electrophoretic migration rate of the cucumber virus protein was equal to that of the tobacco virus protein. Sedimentation equilibrium experiments in 6 m guanidinium chloride gave molecular weights of 17,700 and 17,200 for the tobacco mosaic virus and the cucumber virus proteins, respectively. These results suggest that the effective negative charge density of the cucumber virus protein-dodecyl sulfate complex is higher than that of the tobacco virus proteindodecyl sulfate complex in 0.1% dodecyl sulfate solution. The conformation of both proteins was investigated by circular dichroism measurements. Both proteins have a slightly higher degree of α-helix content in dodecyl sulfate solution than in the native state. The addition of 8 m urea to both proteins while in this solution induced a change in conformation to one having a much smaller degree of ordered structure, although the change in the cucumber virus protein was more intense than that in the tobacco virus protein.     

Coat protein-mediated protection: analysis of transgenic plants for resistance in a variety of crops

Since 1986, research has shown that plants expressing the coat protein gene of a plant virus exhibit degrees of resistance or protection when challenge inoculated with that virus or closely related isolates. This phenomenon, called coat protein-mediated protection, sparked research efforts to develop transgenic plants that resist infection to a range of plant viruses. This report summarizes the research efforts that deal with viral coat protein gene-crop combinations of commercial potential. The viruses include tobacco mosaic, potato virus X and Y, cucumber mosaic and papaya ringspot; the crops include tomato, cucumber, tobacco and papaya.     

Tobacco mosaic virus particle structure and the initiation of disassembly

The structure of an intact tobacco mosaic virus (TMV) particle was determined at 2.9 A resolution using fibre diffraction methods. All residues of the coat protein and the three nucleotides of RNA that are bound to each protein subunit were visible in the electron density map. Examination of the structures of TMV, cucumber green mottle mosaic virus and ribgrass mosaic virus, and site-directed mutagenesis experiments in which carboxylate groups were changed to the corresponding amides, showed that initial stages of disassembly are driven by complex electrostatic interactions involving at least seven carboxylate side-chains and a phosphate group. The locations of these interactions can drift during evolution, allowing the viruses to evade plant defensive responses that depend on recognition of the viral coat protein surface.     

Low cetyltrimethylammonium bromide concentrations induce reversible amorphous aggregation of tobacco mosaic virus and its coat protein at room temperature

Ordered and amorphous protein aggregation causes numerous diseases. Tobacco mosaic virus coat protein for many decades serves as the classical model of ordered protein aggregation ("polymerization"). It was also found to be highly prone to heat-induced amorphous aggregation and the rate of this aggregation could be easily manipulated by changes in solution ionic strength and temperature. Here, we report that rapid amorphous aggregation of this protein can be induced at 25 degrees C in phosphate buffer by low micromolar (start at about 15 microM) concentrations of cationic surfactant cetyltrimethylammonium bromide. At equilibrium four surfactant molecules bound to the protein subunit. As judged by circular dichroism and fluorescence spectroscopy data, the coat protein molecules retained their native structure upon the cetyltrimethylammonium bromide induced aggregation. No aggregation was observed at the higher surfactant concentrations (above 300 microM). Micromolar concentrations of anionic surfactant sodium dodecylsulfate rapidly reversed the cetyltrimethylammonium bromide induced aggregation of the coat protein due to formation of mixed surfactant-surfactant micelles. Cetyltrimethylammonium bromide (100-300 microM) also induced the reversible intact tobacco mosaic virus virion aggregation. The possible liability to the cetyltrimethylammonium bromide induced amorphous aggregation of other ordered aggregate-producing proteins has been discussed.     

A Recombinant Rotavirus Antigen Based on the Coat Protein of Alternanthera Mosaic Virus

Thanks to their strong immunostimulating properties and safety for humans, plant viruses represent an appropriate basis for the design of novel vaccines. The coat protein of Alternanthera mosaic virus can form virus-like particles that are stable under physiological conditions and have adjuvant properties. This work presents a recombinant human rotavirus A antigen based on the epitope of rotavirus structural protein VP6, using Alternanthera mosaic virus coat protein as a carrier. An expression vector containing the gene of Alternanthera mosaic virus (MU strain) coat protein fused to the epitope of rotavirus protein VP6 was designed. Immunoblot analysis showed that the chimeric protein was effectively recognized by commercial polyclonal antibodies to rotavirus and therefore is a suitable candidate for development of a vaccine prototype. Interaction of the chimeric recombinant protein with the native coat protein of Alternanthera mosaic virus and its RNA resulted in the formation of ribonucleoprotein complexes that were recognized by anti-rotavirus antibodies.     

A point mutation in the coat protein gene affects long distance transport of the tobacco mosaic virus

A mutation resulting in substitution of positively charged Lys53 with negatively charged Glu in the coat protein was introduced in the infectious cDNA copy of the genome of wild-type tobacco mosaic virus strain U1. Kinetic analysis of long-distance virus transport in plants showed that systemic distribution of the mutant virus was delayed by 5-6 days as compared with the wild-type one. On evidence of RNA sequencing in the mutant progeny, Glu50 of the coat protein was substituted with Lys after passage I to compensate for the loss of the positive charge at position 53. Electron microscopy revealed atypical inclusions (rodlike structures, multiple electron-dense globular particles) in the nuclear interchromatin space of leaf mesophyll cells infected with the mutant but not with the wild-type virus.     

Natural Infection of Cucumbers by Zucchini Yellow Mosaic Virus in Lebanon

An elongated virus was isolated in the Sin-El-Fil Area east of Beirut from cucumber plants showing severe mottling. The particles were 799 nm long after fixation in glutaraldehyde, but were degraded to shorter pieces in unfixed preparations. Infected cells contained cylindrical inclusions with pinwheel and scroll elements accompanied by proliferated endoplasmic reticulum. The virus was purified and an antiserum was prepared. Different serological tests (slide precipitin test, immunoelectronmicroscopical decoration test, immunosorbent electron microscopy) indicated that it was closely related or identical with zucchini yellow mosaic virus (ZYMV) and more distantly related to watermelon mosaic virus 2 and bean yellow mosaic virus. ZYMV isolates from Italy, France and the Lebanon differ in some host reactions.     

A Point Mutation in the Coat Protein Gene Affects Long-Distance Transport of the Tobacco Mosaic Virus

A mutation resulting in substitution of positively charged Lys53 with negatively charged Glu in the coat protein was introduced in the infectious cDNA copy of the genome of wild-type tobacco mosaic virus strain U1. Kinetic analysis of long-distance virus transport in plants showed that systemic spread of the mutant virus was delayed by 5–6 days as compared with the wild-type one. On evidence of RNA sequencing in the mutant progeny, Glu50 of the coat protein was substituted with Lys after passage I to compensate for the loss of the positive charge at position 53. Electron microscopy revealed atypical inclusions (rodlike structures, multiple electron-dense globular particles) in the nuclear interchromatin space of leaf mesophyll cells infected with the mutant but not with the wild-type virus.     

Similarities in the genomic sequence and coat protein structure of plant virsuses

The genomic sequences of several RNA plant viruses including cucumber mosaic virus, brome mosaic virus, alfalfa mosaic virus and tobacco mosaic virus have become available recently. The former two viruses are icosahedral while the latter two are bullet and rod shaped, respectively in particle morphology. The non-structural 3a proteins of cucumber mosaic virus and brome mosaic virus have an amino acid sequence homology of 35% and hence are evolutionarily related. In contrast, the coat proteins exhibit little homology, although the circular dichroism spectrum of these viruses are similar. The non-coding regions of the genome also exhibit variable but extensive homology. Comparison of the brome mosaic virus and alfalfa mosaic virus sequences reveals that they are probably related although with a much larger evolutionary distance. The polypeptide folds of the coat protein of three biologically distinct isometric plant viruses, tomato Bushy stunt virus, southern bean mosaic virus and satellite tobacco necrosis virus have been shown to display a striking resemblance. All of them consist of a topologically similar 8-standard β-Barrel. The implications of these studies to the understanding of the evolution of plant viruses will be discussed.     

Ultrastructural Alteration of Host Plants Infected with Tomato Mosaic Virus

The ultrastructural aheration of two host plants infected with tomato mosaic virus (ToMV) were studies with transmission electron microscopy. A large number of virus particles were found being accumulated in different cells such as epidermis, parenchyma cells and vascular bundle cells of Lycopersicon esculentum Mill. grown at 25℃ Crystalline inclusions and paracrystal inclusions composed of ToMV particles were observed in the cytoplasm or vacuoles. Some muhivesicular bodies and myeloid bodies protming into the vacuole and vires-specific vesicles associated with the tonoplast were also observed. The ultrastructuml alteration of Nicotiana tabacum L. tv. Xanthinn was similar to that in tomato infected by ToMV grown at 25 cE. In addition to the aggregate inclusions described above, some cytoplasmic angularly-layered aggregates and abnormal chloroplasts with small peripheral vesicles were observed in the parenchyma cells. The densely stained amorphous material was seen in the cytoplasm of N. tabacum L. cv. Xanthiun grown at 35℃. No X- body was observed in the cytoplasm of the ToMV infected tomato and tobacco grown at 25℃ or 35℃. The authors' results suggest a significant difference between the cytopathological effects of ToMV and tobacco mosaic virus (TMV). These characteristic difference may be useful in the virus diagnosis and identification virus infections in plants.     

Cytopathology of Anthers and Pollen From Lettuce Plants Infected by Lettuce Mosaic Virus

Thin sections of mature anthers and pollen grains from three lettuce (Lactuca sativa) plants infected with lettuce mosaic potyvirus (LMV) were studied by immunogold labelling. Labelled LMV particles were present externally on the exine of pollen grains from all plants, but were observed internally in the pollen grains from only one plant. Within mature pollen grains the virus particles were associated with the cytoplasmic bundle inclusions typical of infection by potyviruses. The tapetal plasmodium and the epidermal and endothecial layers of mature anthers from all infected plants also contained labelled virus particles, together with pinwheel and bundle inclusions.     

Calanthe Mild Mosaic Virus, a New Potyvirus Causing a Mild Mosaic Disease of Calanthe Orchid in Japan

Calanthe mild mosaic potyvirus (CalMMV), a previously undescribed virus found in several locations in Japan, causes mild leaf mosaic and flower colour breaking of Calanthe plants. CalMMV was mechanically transmitted only to Calanthe sp., Phalaenopsis sp. and Tetragonia expansa of 50 plant species tested and was transmitted by the aphid Myzus persicae in a nonpersistent manner. The virus has flexuotis particles about 764 nm long and induced the formation of intracellular cytoplasmic cylindrical inclusions. The virus particles contain a single poly-peptide of 32.0 kDa and a single RNA of mol. weight 3.1 × 10⁶. As determined by immuno-electron microscopy, CalMMV is distantly related to the Japanese isolate of dendrobium mosaic potyvirus (DeMV-J), but it showed no serological relationship to any of seven other potyviruses. The sequence of the 3'-terminal 1306 nucleo-tides of the viral genome was determined. The coat protein (CP) coding sequence is predicted to be 804 nucleotides in length, encoding a protein of 268 amino acids with a calculated mol. weight of 30 389. The 3' noncoding region is 169 nucleotides long and is followed by a polyadenylate tract. The amino acid sequence of the CP of CalMMV was 73% homologous to that of DeMV-J, but less than 66% to other potyviruses.     

杭州地区发生的玉米花叶病由甘蔗花叶病毒引起

从杭州地区呈现玉米矮花叶典型症状的玉米病组织中提纯得到大量线状病毒粒子,大多数长度为750?nm。病组织中含有大量风轮状内含体和板状集结体。病毒外壳蛋白为33.6 kD。病毒RNA13’端序列(1.8 kb)与甘蔗花叶病毒(SCMV)同源性最高,达71.5%～99.1%,与高梁花叶病毒(SrMV)同源性次之,为67.8%～68.5%,与玉米矮花叶病毒(MDMV)同源性最低,仅为38.4%～48.4%,从而初步认为此病害由SCMV引起。根据已发表的SCMV外壳蛋白氨基酸序列作亲缘性分析,表明SCMV可分为美国、南非、澳大利亚;德国和中国三大类。     

侵染香蕉的黄瓜花叶病毒分离物衣壳蛋白的肽链分析

香蕉花叶病为华南香蕉生产的重要限制因素之一［‘1。特别是随着组培苗应用面积的扩大,发生越来越严重,一般地块发病率为20—40％,个别重病地块高达90％,损失严重。此病病原虽在1930年【’1就被鉴定为黄瓜花叶病毒（Cucumbermosaicvirus,CMV）,但至今对其研究不多。从有限的文献看,大多数作者【’·’嘟认为其病原为CMV的一个株系,即香蕉株系。但也有认为为二个株系［‘］、或三个株系的［’］。因此有关病原的调查鉴定就成为当前迫切需要解决的一个重要问题。1991～1993年我｛I’J在广东省广州市天河和黄埔区,以及顺德、番禹…     

Optical rotatory dispersion by 5 viruses of the tobacco mosaic virus group and their components

Optical rotatory dispersion (ORD) spectra in 250 to 350 nm region were measured for preparations of five TMV-like viruses (TMV vulgare, HR and U2 strains of TMV dolihosenation mosaic virus and cucumber virus 4) and also for RNA and protein preparations of these viruses. The data obtained testify against the possibility that the double peak with maxima at 286 and 293 nm observed in ORD of all the five viruses is due to interaction of tryptophan residues in virus coat protein with the RNA of the virul particle. The spectra of intravirus RNA of the five viruses, calculated as the difference between ORD of the intact virus and of its coat protein, were found to differ significantly from each other and from ORD of free RNA. ORD spectra of hybrid viruses, reconstituted from RNA of one virus and coat protein of another, proved to be identical to the ORD of the virus, whose protein was used in reconstitution. We suppose that the difference in ORD of the intravirus RNA of the five viruses reflect differences of RNA-protein interactions in them.     

Cucumber mosaic virus genome is encapsidated in alfalfa mosaic virus coat protein expressed in transgenic tobacco plants

The expression of viral coat protein (CP) in transgenic plants has been shown to be very effective in virus plant protection. However, the introduction of CP genes into plants presents the potential risk of the encapsidation of a superinfecting viral genome in the transgenic protein, an event which could change the epidemiology of the disease. To detect the potential heterologous encapsidation of the cucumber mosaic virus (CMV) genome by alfalfa mosaic virus (AIMV) CP expressed in transgenic tobacco plants, a system of immunocapture (IC) and amplification by polymerase chain reaction (PCR) was optimized. This provided high sensitivity and reliable selection of the heterologously encapsidated CMV genome in the presence of natural CMV particles. As little as 2 pg of virus could be detected by immunocapture/polymerase chain reaction (IC/PCR) technique. Evidence for heterologous encapsidation of the CMV genome was found in 11 of the 33 transgenic plants tested two weeks after CMV inoculation. This demonstrates a significant rate of heterologous encapsidation events between two unrelated viruses in transgenic plants. Since CP is involved in the interactions of the virus particle with its vector, the release in the field of such transgenic plants could alter the transmission properties of some important viruses.     

Plant virus satellite RNAs and their role in engineering resistance to virus diseases

The mechanism of satellite RNA (Sat-RNA) mediated attenuation of virus disease was suggested to be the result of competition between satellite RNAs and their helper viral RNAs for replication. Subcellular distribution of viral coat protein in cucumber mosaic virus (CMV) infected leaf tissues shows that the presence of Sat-RNAs interferes with the movement of CMV coat protein into chloroplants. As a strategy for controlling virus diseases, the expression of Sat-RNAs in transgenic plants confers some extent of resistance that may not be strong enough to protect the plants from natural virus infections. Transgenic plants expressing both the Sat-RNA and the coat protein of CMV exhibit enhanced resistance to the virus.