Structural modifications of macrophages initiated by tick-borne encephalitis virus

Macrophages are cells of natural immunity and play a key role in pathogenesis of viral infections. Results of ultrastructural research on macrophages infected with tick-borne encephalitis virus (TBEV), an agent that causes dangerous infections affecting nervous system in human beings and belongs to the Flaviviridae family, were shown here. Using virology methods, it was ascertained that the TBEV is consumed by macrophages and multiplies in them. Ultrastructural research showed that the virus penetrates into the cytoplasm by means of local plasmalemma lysis and newly synthesized virus particles escape from the cell by the same path. At the same time, induration of the perinuclear space of cytoplasm was observed, where ribosomes, microfilaments, ribonucleoprotein threats, and virus-specific structures, namely, nucleocapsids, tube formations, and viroplasts, were found in large quantities. On the surface of viroplasts, newly synthesized virus particles were visualized. Thus, evidence was presented that microphages can play certain role in spreading of TBEV and are the target of the virus. Like active antigen-presenting cells, such macrophages can modulate the protective response of an organism and affect the pathogenesis of tick-borne encephalitis.     

Morphogenesis of Bittner Virus

The morphogenesis of Bittner virus (mouse mammary tumor virus) was studied in sectioned mammary tumor cells. Internal components of the virus (type A particles) were seen being assembled in virus factories close to the nucleus and were also seen forming at the plasma membrane. The particles in virus factories became enveloped by budding through the membrane of cytoplasmic vacuoles which were derived from dilated endoplasmic reticulum. Complete virus particles were liberated from these vacuoles by cell lysis. Particles budding at the plasma membrane were released into intercellular spaces. Maturation of enveloped virus occurred after release, but mature internal components were rarely seen in the cytoplasm before envelopment. Direct cell-to-cell transfer of virus by pinocytosis of budding particles by an adjacent cell was observed, and unusual forms of budding virus which participated in this process are illustrated and described. There was evidence that some virus particles contained cytoplasmic constituents, including ribosomes. Certain features of the structure of internal components are discussed in relation to a recently proposed model for the internal component of the mouse leukemia virus. Intracisternal virus-like particles were occasionally seen in tumor cells, but there was no evidence that these structures were developmentally related to Bittner virus.     

A possible iridovirus in erythrocytes of Bufo marinus in Costa Rica

Icosahedral viral particles were found in the cytoplasm of erythrocytes and splenic reticular cells of a marine toad (Bufo marinus) collected from Costa Rica. Capsids had a maximum diameter of 312 nm and a spherical core with biphasic electron density. Viruses in erythrocytes were associated with cytoplasmic assembly areas and vacuoles in cytoplasm. Nuclei had finely granular material of decreased electron density located centrally, but contained no viral particles. A group of unenveloped viral particles was seen extracellularly in a splenic vessel. The virus was consistent with an iridovirus. In a blood smear stained with Giemsa round basophilic bodies with average diameters of 1.70 microns and morphologically similar to Pirhemocyton sp. were seen in the cytoplasm of erythrocytes and occasionally in the cytoplasm of monocytes or extracellularly. Erythrocytes containing these bodies had vacuoles and irregular pale-staining areas in the cytoplasm and pale-staining areas in the nucleus. These changes corresponded to the viral particles, assembly areas, vacuoles and nuclear changes at the ultrastructural level.     

The ultrastructure of mouse lung: the alveolar macrophage

Free alveolar macrophages of normal mouse lung have been studied in the electron microscope. The tissue was obtained from several young adult white mice. One other animal was instilled intranasally with diluted India ink 1(1/2) hours prior to the removal of the lung. Thin sections of the osmium-fixed, methacrylate-embedded tissue were examined either in an RCA EMU 2 electron microscope or in a Siemens and Halske Elmiskop I b. A few thick sections obtained from the same embeddings were stained for iron. The normal alveolar macrophages, which are usually in contact with the alveolar epithelium, were found to contain a variety of inclusion bodies, along with the usual cytoplasmic components like mitochondria, endoplasmic reticulum, and Palade granules. Another typical component of the cytoplasm of these cells which appears as small ( approximately 6 mmicro) very dense granules of composite fine structure is interpreted as ferritin. It is assumed that this ferritin is formed from red blood cells ingested by the alveolar macrophages. The macrophages in the alveoli were found to phagocytize intranasally instilled India ink particles. Such cells, with engulfed India ink particles, were often of more rounded form and the particles were frequently seen lying inside membrane-bound vacuoles or vesicles of the cytoplasm. The membrane of a few vesicles containing India ink particles was seen as the invaginated portion of the cell plasma membrane, and in one instance these same vesicles were seemingly interconnected with a rough surfaced cisterna of the endoplasmic reticulum. The process of phagocytosis is recognized as related to the "normal" process of pinocytosis.     

The Ultrastructure of Mouse Lung: The Alveolar Macrophage

Free alveolar macrophages of normal mouse lung have been studied in the electron microscope. The tissue was obtained from several young adult white mice. One other animal was instilled intranasally with diluted India ink 1½ hours prior to the removal of the lung. Thin sections of the osmium-fixed, methacrylate-embedded tissue were examined either in an RCA EMU 2 electron microscope or in a Siemens and Halske Elmiskop I b. A few thick sections obtained from the same embeddings were stained for iron. The normal alveolar macrophages, which are usually in contact with the alveolar epithelium, were found to contain a variety of inclusion bodies, along with the usual cytoplasmic components like mitochondria, endoplasmic reticulum, and Palade granules. Another typical component of the cytoplasm of these cells which appears as small (~6 mµ) very dense granules of composite fine structure is interpreted as ferritin. It is assumed that this ferritin is formed from red blood cells ingested by the alveolar macrophages. The macrophages in the alveoli were found to phagocytize intranasally instilled India ink particles. Such cells, with engulfed India ink particles, were often of more rounded form and the particles were frequently seen lying inside membrane-bound vacuoles or vesicles of the cytoplasm. The membrane of a few vesicles containing India ink particles was seen as the invaginated portion of the cell plasma membrane, and in one instance these same vesicles were seemingly interconnected with a rough surfaced cisterna of the endoplasmic reticulum. The process of phagocytosis is recognized as related to the "normal" process of pinocytosis.     

C-type virus-lymphocyte interactions in developing mouse thymus.

The appearance of C-type virus particles in thymus cells of Swiss mouse embryos, 11.5 to 15.5 days post-conception age (PCA), was studied with the electron microscope. In thymic rudiments of all specimens examined, virus particles were seen in epithelial cytoplasm, budding from epithelial cell surfaces and in extracellular spaces. Lymphoid cells were first seen in thymic rudiments of 13.5 days PCA, and did not display virus particles at this stage. At 14.5 days PCA, thymic lymphocytes had localized plasmalemmal thickenings of high electron-density which were adjacent to extracellular virus particles. Viruses appeared to be penetrating thymic lymphocytes by viropexis in embryos of 15.5 days PCA. At this stage, many lymphocytes also had cytoplasmic virus-containing vesicles and viral buds at their surfaces. These observations suggest the possibility that, in embryos, C-type viruses are transmitted horizontally from thymic epithelium to early populations of thymic lymphocytes.     

The entry of the Picornaviridae virus family in resident macrophages

For viruses, the following mechanisms of penetration into cells are typical: clathrin- or dinaminmediated endocytosis, the formation of caveolae, local lysis of cell membranes, and macropinocytosis. It is accepted that (those nonenveloped viruses in the Picornaviridae family) enter cells mostly through the local lysis of their membranes. The purpose of the present study is to research the mechanisms of penetration into resident macrophages of viruses of the indicated family, including poliovirus, Echol1 and Coxsackie B1 viruses, and Type 71 enterovirus. It has been detected that, at the adhesion sites of the Coxsackie B1 virus and Type 71 enterovirus on a macrophage surface, invaginations of the plasma membranes of cells appear, followed by the consequent formation of endocytoplasmatic vesicles, i.e., caveolae. The penetration of poliovirus into macrophages occurs both through the formation of caveolae and the local lysis of the plasmolemma of cells; during the later terms (after 45 min), macropinocytosis is observed in the viral particles during the first 15 min after the Echol1 virus penetrated the cytoplasm of macrophages through the local lysis of their plasmolemma. Thereafter, the formation of endocytic vacuolae including viral particles was observed in the cytoplasm of infected macrophages. The exit of the Echol1 virus from endocytic vacuoles was performed by the local lysis of cell membrane.     

Subcellular localization of the coat protein in tobacco cells infected by cucumber mosaic virus isolated from Catharanthus roseus

Electron microscopy and immunolabelling with antiserum specific to cucumber mosaic virus coat protein were used to examine tobacco leaf cells infected by cucumber mosaic virus isolated from Catharanthus roseus (CMV-Cr). Crystalline and amorphous inclusions in the vacuoles were the most obvious cytological modifications seen. Immunogold labelling indicated that the crystalline inclusion was made up of virus particles and amorphous inclusions contained coat protein. Rows of CMV-Cr particles were found between membranes of dictyosomes, but membranous bodies and tonoplast-associated vesicles were not evident. Virus particles and/or free coat protein were easily detected in the cytoplasm by immunolabelling. No gold labelling was found within nuclei, chloroplasts and mitochondria.     

Electron Microscopy of Cells Infected with Semliki Forest Virus Temperature-Sensitive Mutants: Correlation of Ultrastructural and Physiological Observations

Cells infected at the permissive temperature with three temperature-sensitive mutants of Semliki Forest virus were not significantly different in appearance from cells infected, at either the permissive or nonpermissive temperature, with wild-type virus. Virus particles, nucleocapsids, spherules, and tubules were seen in the cytoplasm. But replication of the mutants was inhibited in cells infected at the nonpermissive temperature. This was evidenced by the absence of virus particles and nucleocapsids (except in one case) and the absence or limited production of spherules and tubules. These observations are discussed with reference to the physiological defects of the mutants.     

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.     

Detection and localisation of picorna-like virus particles in tissues of Varroa destructor, an ectoparasite of the honey bee, Apis mellifera

Virus-like particles, 27 nm in diameter, were observed in extracts of individual Varroa destructor mites and in sections of mite tissue. Application of a purification procedure resulted in virus preparations that were used to prepare an antiserum to detect the virus in individual mites. Immunohistology studies showed that the gastric caecae were heavily infected, whereas no immunostaining could be detected in other mite tissues or organs, like the salivary glands, brain, rectum or reproductive organs. By electron microscopy large aggregates of virus-like particles in para-crystalline lattices were found in cells of the gastric caecae. The particles, reminiscent to picorna-like viruses, occurred mainly in the cytoplasm, whereas some virus particles were sparsely scattered in vacuoles. Occasionally, particles were observed in membrane-bound vesicles or in long tubular membrane structures in the cytoplasm. The accumulation of the picorna-like virus particles in the cytoplasm and the presence of the virus in membrane structures give a strong indication that the virus replicates in the mite.     

A POSSIBLE VIRUS INFECTION IN THE GREEN ALGA OEDOGONIUM1

Developing germlings of the green alga Oedogonium have been sectioned and some were found to contain particles presumed to be those of a virus. Fully formed particles were hexagonal in a 2-dimensional section, about 240 nm in diameter with a densely stained surface layer and core; what appear to be different stages in their assembly were also seen. Many of the particles were clustered together in groups surrounded by aggregations of ribosomes. In cells containing many of the particles, the germlings' cytoplasm and organelles showed considerable evidence of disruption and breakdown. These particles have only been detected in germlings, so infection by this presumed virus was probably initiated in the naked, motile zoospore.     

Electron Microscopic Study of the Phagocytosis Process in Lung

Diluted India ink was instilled into the nasal cavity of mice and the lungs of some animals were fixed with osmium tetroxide at various intervals after one instillation. The lungs of other animals were fixed after 4, 7, 9, 16, or 18 daily instillations. The India ink was found to be phagocytized almost exclusively by the free alveolar macrophages. A few particles are occasionally seen within thin portions of alveolar epithelium, within the "small" alveolar epithelial cells, or within occasional leukocytes in the lumina of alveoli. The particles are ingested by an invagination process of the plasma membrane resulting in the formation of intracellular vesicles and vacuoles. Ultimately large amounts of India ink accumulate in the cell, occupying substantial portions of the cytoplasm. The surfaces of phagocytizing macrophages show signs of intense motility. Their cytoplasm contains numerous particles, resembling Palade particles, and a large amount of rough surfaced endoplasmic reticulum. These structures are interpreted as indicative of protein synthesis. At the level of resolution achieved in this study the membranes of this reticulum appear as single dense "lines." On the other hand, the plasma membrane and the limiting membranes of vesicles and of vacuoles often exhibit the double-line structure typical of unit membranes (Robertson, 37). The inclusion bodies appear to be the product of phagocytosis. It is believed that some of them derive from the vacuoles mentioned above, and that they correspond to similar structures seen in phase contrast cinemicrographs of culture cells. Their matrix represents phagocytized material. Certain structures within this matrix are considered as secondary and some of these structures possess an ordered form probably indicative of the presence of lipid. The possible origin and the fate of alveolar macrophages are briefly discussed.     

RBSDV在玉米叶脉细胞内的侵染状态与灰飞虱传毒活力的关系

根据水稻黑条矮缩病毒(RBSDV)侵染玉米(Zea mays L.)的症状发展过程先后取叶脉做超薄切片,在透射电镜下观察病毒在细胞内的侵染状态,并存取样前用灰飞虱无毒若虫进行饲毒和传毒试验。结果显示RBSDV侵入玉米叶细胞后先出现在细咆壁附近,个别粒子似与胞间连丝相连;细胞质内产生病毒基质,病毒粒子先增殖并分布其周边,后向病毒基质内扩展;当病毒粒子布满病毒基质后在细胞质中出现直径约90nm的管状结构,病毒成串排列在该管状结构中;随后管状结构逐渐消失,最终形成晶格状聚集排列。用灰飞虱无毒若虫在细胞内病毒基质出现和病毒增殖期饲毒的,到成虫时分别有2．93％和7．83％个体传毒率;在细胞内病毒成串分布于管状结构和品格状聚集排列期饲毒的,到成虫时均不能传毒。     

Semliki Forest Virus in HEp-2 Cell Cultures

The growth and development of Semliki Forest virus (SFV), an arbovirus of serological group A, in HEp-2 cells in tissue culture was examined by various techniques at frequent intervals. Infectivity and fluorescent-antibody studies demonstrated the presence of infective virus and viral antigens within the cells at 8 hr after infection. The antigen was particulate and distributed throughout the cytoplasm. Thereafter, there was rapid progression of virus production and cell destruction. By electron microscopy, tubular structures bounded by a fine membrane were observed in cytoplasm at 12 hr. Rows of small (25 mmu) virus particles were often present on the outer surface of these membranes, and at later times they became progressively more encrusted with the small virus particles. These structures subsequently increased rapidly in number, size, and complexity, and the space between the membrane and the tubules increased, thus forming vacuoles which contained tubules and were covered with the small particles. At later times (24 hr and later) larger (42 to 50 mmu) particles were observed, usually inside of the vacuoles. These larger particles (and occasionally the smaller ones) were also seen at the cell periphery and in the extracellular space. The large SFV particles appear to form by three distinct processes: (i) from the smaller particles, (ii) by development on an intravacuolar membrane, and (iii) at the ends of the tubules. The mode of development of SFV is unique among viruses studied to date, but in some characteristics it resembles that of other group A arboviruses. Its development differs from that of most arboviruses of group B and other serological groups.     

Ultrastructure of Measles Virus in Cultures of Hamster Cerebellum

Replication of Edmonston strain of measles virus in cultures of hamster central nervous system tissue was studied by electron microscopy of ultrathin sections. Infected cultures were fixed from 3 hr to 39 days postinoculation (PI). Measles nucleocapsid was first seen within the cytoplasm of giant cells, the latter appearing 5 to 6 days PI. Measles virus particles were most abundant at 10 days PI and appeared to bud off from areas of the cell membrane along which nucleocapsid was aligned. Intranuclear nucleocapsid was more abundant at later stages, and by 39 days PI entire nuclei were seen to be occupied. By this time, the cytoplasmic formations, which had been sequestered by membranes, appeared to lose their regular structure. Budding viral particles at 39 days PI were of a much simplified structure and did not involve the alignment of nucleocapsid about their periphery.     

Ultrastructure of Soybean Leaf Cells Infected with Cowpea Mild Mottle Virus

Cowpea mild mottle virus (CMMV), a whitefly-transmitted, rod-shaped virus isolated in Thailand, induced feather-like structures in the cytoplasm of infected soybean cells. These structures were the results of a complex arrangement of virus particles and occurred in all types of cells observed. An organized arrangement of virus particles in the form of layers was also observed in the cytoplasm of the infected cells. In ultrathin sections, the particles measured about 10 nm wide and more than 600 nm long, which corresponded to the size reported for the purified preparations of CMMV. No feather-like structures or virus particles were observed in the comparable healthy tissues.     

The predominant virus antigen burden is present in macrophages in Theiler's murine encephalomyelitis virus-induced demyelinating disease.

Theiler's murine encephalomyelitis virus (TMEV) produces a persistent central nervous system infection and chronic, inflammatory demyelinating disease in susceptible mice. TMEV antigen(s) and RNA genome have been detected in astrocytes, oligodendrocytes, and macrophages during persistence. Whether there is a predominant cell type in which TMEV persists has not been resolved. Since TMEV-induced demyelinating lesions are infiltrated with macrophages and a number of other persistent viruses show near-exclusive tropism for these phagocytic cells, we used two-color immunofluorescent staining with conventional and confocal microscopy to colocalize TMEV to cells that stain with monoclonal antibodies (MOMA-2) [unknown antigen], Mac-1 [CD11b], FA-11 [CD66], and 2F8 [scavenger receptor]) to macrophages in BeAn-infected SJL mice. A predominant virus antigen burden within macrophages infiltrating demyelinating lesions was seen. A dichotomy of cells staining for virus antigen(s) was found with infected cells containing either a large or small virus antigen load. Ninety percent of cells with a large virus antigen load were large phagocytes (20 to 50 microns) that were readily detected at low power (5x objective). Cells with smaller amounts of virus antigen(s) turned out to be either these same large phagocytic cells or much smaller cells, approximately equal to 10 microns in diameter. Forty percent of cells with a small virus antigen load were macrophages. The unidentified approximately equal to 10-microns cells that are virus antigen positive and macrophage negative in this study could still be macrophages, or they may be oligodendrocytes. The fact that virus was detected in the cytoplasm and not phagolysosomes of macrophages and the sheer mass of fluorescently stained virus proteins in some macrophages suggest that TMEV persists in these phagocytic cells by active virus replication.