Immunocytochemical investigation of the causal agent of cassava mosaic disease in southern Africa

Cassava mosaic disease (CMD) exists throughout Africa, and cassava latent virus (CLV) has been implicated as the etiological agent in Kenya and West Africa. However, in Southern Africa, the causal agent of CMD was not until recently associated with CLV, and the possibility of a second flexuous virus particle has not been ignored. Attempts to isolate and visualize CLV antigen have been successful with Nicotiana benthamiana, an indicator host plant of CLV, but all efforts to isolate and visualize particles in infected cassava plants have failed. Immunocytochemical studies were undertaken in an attempt to localize virus antigen in infected cassava tissue.Cytochemical staining (light microscope) of infected cassava leaf material revealed the presence of inclusion bodies in epidermal and palaside mesophyll cells, and in epidermal collenchyma and outer parenchyma cells from the petiole and stem. However, transmission electron-microscopical (TEM) investigations revealed electron dense bodies in the cytoplasm, and no characteristic CLV nuclear inclusion bodies were evident. Transmission experiments to N. benthamiana and N. tabacum were attempted and leaves, exhibiting symptoms, examined microscopically. The nuclei appeared swollen (in comparison to uninfected leaves), a characteristic of CLV- infected N. benthamiana. However at the TEM level, no characteristic fibrillar-ring inclusion bodies or particles, could be visualized.Further immunocytochemical investigations were initiated, employing antisera raised against CLV isolated from N. benthamiana, and antisera for cassava common mosaic virus (CCMV), cassava brown streak virus (CBSV) and cassava X virus (CsXV). Goat anti-rabbit IgG-gold was used as a direct stain. No labelling occurred with CCMV and CBSV antisera. Intense gold labelling was located in the cytoplasm of phloem, mesophyll and epidermal cells of infected cassava and to a lesser extent in N. tabacum and N. benthamiana using affinity chromatography purified CLV antiserum. Little labelling was observed in nuclei of infected cells. Inconclusive results were obtained with CsXV antiserum.Immunogold labelling located CLV viral antigens in infected cassava leaf tissue. This observation, together with positive ELISA, transmission and DNA hybridization experiments, proves conclusively that CLV viral antigen is present in infected cassava in Southern Africa. However, most viral antigen in infected cassava, unlike N. benthamiana (fibrillar and granular nuclear inclusions) appears to be in the cytoplasm. This may tentatively suggest that the CLV protein is synthesized in the cytoplasm of its natural host, cassava, even though the virus may assemble in the nucleus at the appropriate time. However, as yet no virus inclusions have been observed in nuclei of infected cassava. Due to previous isolation of a flexuous rod and ambiguous staining results, the possibility of two viruses in cassava cannot be ruled out.     

Cytopathology and Ultrastructure of Some African Isolates of Maize Streak and Sugarcane Streak Viruses

Samples of maize leaves naturally infected with maize streak virus (MSV) from Malawi and South Africa, as well as sugarcane leaves naturally infected with sugarcane streak virus (SSV) from Egypt, were examined by light (LM) and transmission electron, microscopy (TEM). Intranuclear inclusions, detectable by both methods, were found mainly in mesophyll and bundle sheath cells, and less frequently in vascular parenchyma and immature phloem cells. At higher TEM magnifications, these inclusions consisted, of crystalline or noncrystalline aggregates of isometric geminivirus–like particles (VLP) that occurred either singly or in geminate arrays. Cytopathological changes in these cells were confined to the nuclei, which were usually larger than normal, with peripheral chromatin and nucleoli. The nuclear envelope of some inclusion–containing nuclei was ruptured, and occasionally a crystal of VLP was found in the cytoplasm of cells in which no intact nuclei were detected. No differences in cytopathology were found between MSV and SSV, or between the two MSV isolates examined.     

Studies on the pathology of a baculovirus in Aedes triseriatus

The pathology of a Baculovirus (BV) in Aedes triseriatus was studied. The virus infected the cardia, gastric caeca, and the entire stomach of larval midgut epithelium. The progression of the disease was similar to that of other Baculoviruses of the nuclear polyhedrosis virus (NPV) type. Rodshaped nucleocapsids were formed within a Feulgen-positive virogenic stroma and along the nuclear envelope. These nucleocapsids were enveloped by a membranous material and occluded randomly in small irregular and polyhedral proteinic inclusions. The disease differed from other BVs of the NPV type in that the small proteinic inclusions gradually coalesced as they grew, forming large fusiform inclusions.     

Analysis of Borna Disease Virus Trafficking in Live Infected Cells by Using a Virus Encoding a Tetracysteine-Tagged P Protein

Borna disease virus (BDV) is a nonsegmented, negative-stranded RNA virus characterized by noncytolytic persistent infection and replication in the nuclei of infected cells. To gain further insight on the intracellular trafficking of BDV components during infection, we sought to generate recombinant BDV (rBDV) encoding fluorescent fusion viral proteins. We successfully rescued a virus bearing a tetracysteine tag fused to BDV-P protein, which allowed assessment of the intracellular distribution and dynamics of BDV using real-time live imaging. In persistently infected cells, viral nuclear inclusions, representing viral factories tethered to chromatin, appeared to be extremely static and stable, contrasting with a very rapid and active trafficking of BDV components in the cytoplasm. Photobleaching (fluorescence recovery after photobleaching [FRAP] and fluorescence loss in photobleaching [FLIP]) imaging approaches revealed that BDV components were permanently and actively exchanged between cellular compartments, including within viral inclusions, albeit with a fraction of BDV-P protein not mobile in these structures, presumably due to its association with viral and/or cellular proteins. We also obtained evidence for transfer of viral material between persistently infected cells, with routing of the transferred components toward the cell nucleus. Finally, coculture experiments with noninfected cells allowed visualization of cell-to-cell BDV transmission and movement of the incoming viral material toward the nucleus. Our data demonstrate the potential of tetracysteine-tagged recombinant BDV for virus tracking during infection, which may provide novel information on the BDV life cycle and on the modalities of its interaction with the nuclear environment during viral persistence.     

Fine Structure of Cellular Inclusions in Measles Virus Infections

Cells which are infected with measles virus have been known for some time to contain inclusion material that is distinguishable from normal cellular components by application of traditional staining methods and observation in the light microscope. The fine structure of the inclusion material contained in HeLa cells infected with Edmonston strain of measles virus has been examined in the electron microscope. Two steps have been found necessary in this study: (1) the recognition by phase-contrast microscopy of the living cell of bodies that are defined as inclusion material when the cells are classically stained; and (2) the recognition in the electron microscope of inclusion-body material that had previously been identified in the living cell. The fine structure of the nuclear and cytoplasmic inclusion material in osmium-treated cells was found to consist mainly of randomly arrayed filaments of low electron density. Dense, highly ordered arrays of filaments were found near the center of the nuclear inclusions, sometimes as a two-dimensional, nearly orthogonal arrangement. If the size of the measles virus is taken to be around 100 mµ in diameter, the strands seen in the inclusions cannot be fully formed virus.     

Intranuclear crystalline inclusions in spermatozoa ofLumbricus terrestris

Summary In the nuclei of atypical spermatids ofLumbricus terrestris granular or filamentous inclusions are surrounded by dense chromatin. Aggregation and condensation of chromatin in nuclei during spermatid differentiation coincide with increase in density, granularity, and the subsequent crystallization of the intranuclear inclusion. In mature spermatozoa, the crystalline inclusion displaying an irregular shape is composed of parallel repeating units measuring 50–80 Å. The subunits sometimes possess a clear central cavity.Atypical spermatozoa, possessing inclusions that distort their normally cylindrical shape, possess typical acrosomes, middle pieces, and flagella. Spermatozoa bearing intranuclear crystals are rarely observed in the seminal receptacles ofLumbricus.These intranuclear inclusions probably represent proteinaceous material that is not eliminated during nuclear differentiation. Their sole existence in the nuclei of spermatozoa, their transformation into crystalline structures during spermiogenesis, and their similarity to crystals in virus infected plant and animal cells suggest a viral origin.Supported by a training grant (GM-00582-07) from the Public Health Service.     

Ultrastructural investigation on a strain of a cytoplasmic-polyhedrosis virus with nuclear inclusions

A strain of a cytoplasmic-polyhedrosis virus causes the formation of crystalline inclusions almost entirely in the nucleus, and only rarely in the cytoplasm, of the midgut epithelial cells of the silkworm Bombyx mori. It also differs from the typical strain in causing the hypertrophy of the nucleoli and the formation of dense reticulum and spherical bodies in the nucleus. The virus particles and the virogenic stromata of the new strain resemble those of the typical strain. The cytoplasmic inclusions contain virus particles, while the nuclear inclusions do not. When the infected larvae are kept at 30°C for 15 hr or at 35°C for 3–15 hr, the nuclear inclusions break up into particles of 70–250 nm in diameter. The particles are dispersed in the cells but not present in the spaces previously occupied by the decomposed inclusions.     

Sonchus Yellow Net Rhabdovirus Nuclear Viroplasms Contain Polymerase-Associated Proteins

We have initiated a study of the cytopathology of nucleorhabdoviruses by analyzing the subcellular localization of sonchus yellow net virus (SYNV) genomic and antigenomic RNAs and the encoded polymerase proteins. In situ hybridizations demonstrated that the minus-strand genomic RNA sequences are restricted to the nuclei of infected cells, while the complementary plus-strand antigenomic RNA sequences are present in both the nuclei and the cytoplasm. Immunofluorescence and immunogold labeling experiments also revealed that the nucleocapsid (N) protein and phosphoprotein (M2) are primarily localized to discrete regions within the nuclei and in virus particles that accumulate in perinuclear spaces. The N protein antiserum specifically labeled the nuclear viroplasms, whereas the M2 antiserum was more generally distributed throughout the nuclei. Antibody detection also indicated that the polymerase (L) protein is present in small amounts in the viroplasm. When the N and M2 proteins were expressed individually from the heterologous potato virus X (PVX) vector, both proteins preferentially accumulated in the nuclei. In addition, viroplasm-like inclusions formed in the nuclei of cells infected with the PVX vector containing the N gene. Fusions of the carboxy terminus of β-glucuronidase to N and M2 resulted in staining of the nuclei of infected cells following expression from the PVX vector. Deletion analyses suggested that multiple regions of the N protein contain signals that are important for nuclear localization.     

Light and electron microscopy of virus inclusions inAmaranthus lividus cells

Summary Amaranthus plants infected with a virus of rod-shaped particles showed under the light microscope intracytoplasmic amorphous and crystalline inclusions.The submicroscopic organization of mesophyll cells from infectedAmaranthus leaves by electron microscopy is described. Besides big crystalline inclusions, long dark inclusions correspondent to needle-like inclusions observed by light microscopy are definable in the cytoplasm. The amorphous inclusion bodies were formed by an overgrown protrusion of vacuolate cytoplasm containing virus particles, long very dark stained inclusions forming dense bands and rings, normal elements of the cytoplasm such as mitochondria, endoplasmic reticulum and ribosomes, and some spherosomes. Inclusions and virus particles were not found in chloroplasts, mitochondria or nuclei of infected cells.     

RELATION OF TOBACCO MOSAIC VIRUS TO THE HOST CELLS

The relation of tobacco mosaic virus (TMV) to host cells was studied in leaves of Nicotiana tabacum L. systemically infected with the virus. The typical TMV inclusions, striate or crystalline material and ameboid or X-bodies, which are discernible with the light microscope, and/or particles of virus, which are identifiable with the electron microscope, were observed in epidermal cells, mesophyll cells, parenchyma cells of the vascular bundles, differentiating and mature tracheary elements, and immature and mature sieve elements. Virus particles were observed in the nuclei and the chloroplasts of parenchyma cells as well as in the ground cytoplasm, the vacuole, and between the plasma membrane and the cell wall. The nature of the conformations of the particle aggregates in the chloroplasts was compatible with the concept that some virus particles may be assembled in these organelles. The virus particles in the nuclei appeared to be complete particles. Under the electron microscope the X-body constitutes a membraneless assemblage of endoplasmic reticulum, ribosomes, virus particles, and of virus-related material in the form of wide filaments indistinctly resolvable as bundles of tubules. Some parenchyma cells contained aggregates of discrete tubules in parallel arrangement. These groups of tubules were relatively free from components of host protoplasts.     

Comparison of Subacute Sclerosing Panencephalitis and Measles Viruses: an Electron Microscope Study

The ultrastructure of CV-1 cells infected with subacute sclerosing panencephalitis (SSPE) viruses was compared with that of CV-1 cells infected with the wild or Edmonston strain of measles virus. Both SSPE viruses and the measles viruses produced two types of nucleocapsid structures: smooth filaments, 15 to 17 nm in diameter, and granular filaments, 22 to 25 nm. The smooth and granular filaments produced by SSPE and measles virus did not differ in appearance. In CV-1 cells infected with SSPE viruses, smooth filaments formed large intranuclear inclusions and granular filaments occupied a large area of the cytoplasm, but always spared the area under the cell membrane. Particles budding from the surface of these cells contained no nucleocapsids. In CV-1 cells infected with measles virus, only small aggregates of smooth filaments were seen in the nuclei. Granular filaments in the cytoplasm predominantly occupied the area under the cell membrane, and were aligned beneath the cell membrane in a parallel fashion and assembled into budding particles. These differences between SSPE and measles virus may be regarded as quantitative, but they do distinguish SSPE viruses from measles virus. Moreover, the formation of large nuclear inclusions filled with smooth filaments appears to be a characteristic process of SSPE, but not of measles, since this type of inclusion is invariably seen in SSPE brain tissues, brain cultures derived from them, and CV-1 cells infected with SSPE viruses.     

Cytopathology and release of an RNA virus from a strain of Trichomonas vaginalis

A strain of Trichomonas vaginalis infected with a double-stranded RNA virus showed pronounced cytopathology in the form of giant syncytia generated by the recruitment of single cells. The giant cells ultimately lysed, releasing virus into the culture medium. In the infected cells, clusters of electron-dense particles resembling viral structures were found in the cytoplasm. In addition, distinctive inclusions composed of similar particles were present in the nuclei of some cells. Double-stranded viral RNA of 5.5 kbp was demonstrated in both cytoplasmic and nuclear fractions from these cells. Viral particles collected from the cell-free culture supernatant were of the same shape and size as the RNA virus isolated from a strain of T. vaginalis described previously (Wang & Wang, Journal of Biological Chemistry, 260: 3697–3702, 1985; Wang & Wang, Proceedings of the National Academy of Sciences of the U.S.A. 83: 7956–7986) which does not show this cytopathology.     

Cytopathology of satellite tobacco mosaic virus and its helper virus in tobacco

Ultrastructural responses of tobacco cells infected with a newly discovered satellite virus (STMV) that has an isometric morphology and is associated with rigid rodshaped tobacco mosaic virus (TMV) were studied in situ. In cells infected with TMV alone,TMV particles occurred as crystalline arrays in the cytoplasm and were usually associated with TMV-characteristic X bodies. In cells infected with both TMV and STMV, particles of STMV occurred only in cells that contained TMV particles, which suggests a correlation between the satellite and helper virus presence. However, the replication and/or accumulation sites of STMV appear to be independent from its helper virus. Unlike TMV particles, STMV particles were associated with several cytopathic structures such as granular inclusions, membranous vesicles of 50–80 nm, and myelin-like bodies which were all bounded by a single common membrane, No X bodies occurred in cells containing STMV particles, and the mitochondria possessed abnormal tubular structures containing flocculent material.     

Virological, Immunochemical, and Cytochemical Studies of Four HeLa Cell Lines Infected with Two Strains of Influenza Virus

The production of infectious virus, hemagglutinin, and viral (V) antigens and the changes in ribonucleoprotein (RNP) and lipoprotein metabolism have been studied in four sublines of HeLa cells infected with the PR8 and a PR8 recombinant strain of influenza virus. Much greater amounts of infectious virus and much less hemagglutinin were produced by the PR8 recombinant than by PR8 virus in all four cell lines. Different amounts of infectious virus per infected cell were produced by the recombinant in the four cell lines, whereas very little infectious virus was produced by the PR8 strain in any of the HeLa cells. In all cell lines infected with both strains of virus, "soluble" (S) antigen appeared early in the nucleolus. In cells infected with PR8 recombinant, S antigen subsequently filled the nucleus and later appeared in the cytoplasm. In most cells infected with PR8 virus, nuclear S antigen did not fuse to fill the nucleus, and S antigen was not detected in the cytoplasm. V antigen was observed in the cytoplasm of cells when diffuse nuclear S antigen had formed. The earliest and most frequent change in the RNP of the infected cells was a decrease in stainable RNP spherules (nucleolini) in the nucleolus. This was followed, in a smaller proportion of cells, by the appearance of nuclear and cytoplasmic inclusions containing RNP. There was a characteristic difference in the morphology of the cytoplasmic inclusions produced by the two strains of virus, but the same types of inclusions were observed in all four HeLa lines. A significant increase in lipoprotein was observed only in association with the cytoplasmic inclusions produced by PR8 recombinant virus. There was a striking difference in the proportion of cells with cytochemical changes in RNP in the four cell lines. A significant cytopathic effect (CPE) was observed only in three virus-cell systems in which a high proportion of cells exhibited changes in nucleolinar RNP. It is suggested that disappearance of RNP in the nucleolini may be an indication of shutdown of host ribonucleic acid synthesis and that this in turn results in a CPE. Virus infection resulted in a C-mitotic block that was followed by karyorrhexis. Infection of the cell did not always result in the production of infectious virus, in changes in the RNP of the nucleolini, in the development of nuclear or cytoplasmic RNP inclusions, or in CPE. The results suggest that production of infectious virus, shutdown of cellular RNP synthesis with accompanying CPE, and the formation of inclusions appear to be independent events.     

Occurrence of Mitochondria in the Nuclei of Tobacco Sperm Cells

Tobacco sperm cells contain intact mitochondria within their nuclei with a frequency of 0.35 [plusmn] 0.13 per cell. These inclusions appear to originate from mitochondria found among chromatids in the highly elongated metaphase plate of the dividing generative cell. These organelles are apparently captured during the reconstitution of the nuclear envelope. Only sperm cells were observed to contain these nuclear mitochondria; generative cells, vegetative pollen cells, transmitting tissue cells, unfertilized egg cells, and central cells lacked them. Nuclear mitochondria were also seen in the nuclei of the egg and central cell after fusion with sperm nuclei, suggesting that nuclear mitochondria are transmitted into the zygote and primary endosperm cells during double fertilization. Organellar inclusions in the sperm nucleus provide a potential mechanism for transmitting organellar DNA into the next generation and could potentially facilitate the transfer of genetic material between the nucleus and other organelles.     

犬传染性肝炎病毒在体外细胞质内的发生

通过对犬传染性肝炎病毒（ＩＣＨＶ）在犬肾传代细胞内形态发生及其抗原定位的电镜和免疫胶体金电镜研究,发现ＩＣＨＶ除了在宿主细胞核内发生外,还有一条细胞质内的发生途径。在细胞质内病毒核壳体的装配是以均质致密包涵体和副晶格包涵体为“基地”,这与人们熟知的细胞核内形态发生方式相似。免疫胶体金标记显示,细胞质包涵体中含有大量的ＩＣＨＶ抗原成分,显核壳体在细胞质内装配病毒的结构蛋白来源。此外,在感染的细胞质内还观察到与核内相同的病毒核心样结构。     

Is There a Relationship between Infection by Rhizobia and Occurrence of Disomatic Nuclei in Nodules of Alfalfa (Medicago sativa L.)?

Cytological examination of nodules from diploid, tetraploid, and octoploid alfalfa (Medicago sativa L.) plants revealed that the proportion of nodule cells infected by rhizobia was not significantly affected by nuclear ploidy of the host plant. Flow cytometry was used to determine the influence of host plant nuclear ploidy on the nuclear ploidy of infected cells. In nodules from diploid plants, most of the nuclei were tetraploid, whereas in nodules from tetraploid plants, about half of the nodule nuclei were tetraploid and half were octoploid; in octoploid plants, most of the nodule nuclei were octoploid. The occurrence of disomatic nuclei was independent of infection of nodule cells by rhizobia, because diploid plants had mostly disomatic nodule nuclei, and octoploid plants had mostly monosomatic nodule nuclei, whereas all nodules maintained a constant proportion of infected to uninfected cells. These results do not support the earlier hypothesis that infected nodule cells contain disomatic nuclei.     

Effects of Substituting Granulin or a Granulin-Polyhedrin Chimera for Polyhedrin on Virion Occlusion and Polyhedral Morphology in Autographa californica Multinucleocapsid Nuclear Polyhedrosis Virus

Substitution of granulin from the Trichoplusia ni granulosis virus (TnGV) for polyhedrin of the Autographa californica multinucleocapsid nuclear polyhedrosis virus (AcMNPV) yielded a few very large (2 to 5 μm) cuboidal inclusions in the cytoplasm and nucleus of infected cells. These polyhedra lacked the beveled edges characteristic of wild-type AcMNPV polyhedra, contained fractures, and occluded few virions. Placing a nuclear localization signal (KRKK) in granulin directed more granulin to the nucleus and resulted in more structurally uniform cuboidal inclusions in which no virions were observed. A granulin-polyhedrin chimera produced tetrahedral occlusions with more virions than granulin inclusions but many fewer than wild-type polyhedra. Despite the unusual structure of the granulin and granulin-polyhedrin inclusions, they interacted with AcMNPV p10 fibrillar structures and electron-dense spacers that are precursors of the polyhedral calyx. The change in inclusion shape obtained with the granulin-polyhedrin chimera demonstrates that the primary amino acid sequence affects occlusion body shape, but the large cuboidal inclusions formed by granulin indicate that the amino acid sequence is not the only determinant. The failure of granulin or the granulin-polyhedrin chimera to properly occlude AcMNPV virions suggests that specific interactions occur between polyhedrin and other viral proteins which facilitate normal virion occlusion and occlusion body assembly and shape in baculoviruses.     

Electron Microscopy of Monkey Kidney Cell Cultures Infected with Rubella Virus

Two rubella virus strains isolated in this laboratory were investigated in terms of their growth in LLC-MK(2) cell cultures and their effect on cell morphology. Rubella virus grew readily in LLC-MK(2) cells, but cytopathic effects of the virus were not observed in infected cultures. Such infected cultures can be subcultured indefinitely and continue to shed virus. Examination of rubella-infected cell cultures by electron microscopy showed the presence of annulate lamellae in the cytoplasm of 15% of the cells. No changes were evident in the nuclei. These membranous inclusions varied in complexity from parallel arrays of annulate lamellae to large lamellar structures of complex morphology. An occasional cell contained a crystal lattice structure in association with the lamellae. Larger inclusions, consisting of disorganized arrays of "unit" membranes, were also found. Uninfected cells were devoid of annulate lamellae, crystals, and complex membranous inclusions. No viruslike particles were observed in any part of the cells from infected cultures. The significance of the structures observed has not been determined.     

Sorghum chlorotic spot virus binds to potyvirus cylindrical inclusions in tobacco leaf cells

Nicotiana benthamiana can be doubly infected with either potato virus Y or tobacco etch virus and sorghum chlorotic spot virus (SCSV). Immunogold labeling showed that cylindrical inclusions of either potyvirus bind virions of the unrelated rod-shaped furovirus SCSV. Not all cells in doubly infected N. benthamiana plants contained both viruses. In cells infected by the potyviruses but not by SCSV, cylindrical inclusions did not label with the antiserum to SCSV. Numbers of cells infected with SCSV did not increase in doubly infected plants compared to those in plants infected with SCSV alone. Systemic infection of N. benthamiana by either potyvirus was not prevented by SCSV infections. This provides further evidence that unrelated rod-shaped viruses can bind to potyvirus cylindrical inclusion bodies, and that this phenomenon is not limited to graminaceous hosts.