水痘-带状疱疹病毒地方分离株在兔脑神经细胞中的形态与形态发生特征

为阐明水痘-带状疱疹病毒济南分离株（VZVJ1）在兔脑神经细胞（RNC）中的形态与形态发生特征,我们利用超薄切片电子显微镜技术对感染VZVJ1的RNC进行了观察研究。结果表明RNC在感染VZVJI6h后核内可见散在的核衣壳,12h后细胞核和细胞质内核衣壳明显增多,24h达高峰,而细胞核和细胞质内的成熟病毒颗粒较少见。病毒大小、形态基本一致,呈圆形或椭圆形,核心直径30～50nm,核衣壳74～96nm,成熟病毒110～180nm。核衣壳内有3种类型的核心,即电子致密核心、部分致密核心和电子透明核心。细胞核和细胞质内均可见核心样电子致密体和布纹样结构。在细胞质内还可见少量“繁殖复合体”,由膜性结构包绕多个囊泡构成。提示VZVJ1在RNC中的形态发生不同于其它性质的细胞。     

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.     

Electron Microscopy of Herpes Simplex Virus: II. Sequence of Development

Examination of infected cells at sequential intervals after infection revealed that the first viral forms to appear were capsids enclosing cores of low density. Not until the 6th hr were dense cores encountered, and at approximately the same time enveloped virus was seen. Envelopment occurred most frequently in close proximity to the nuclear surface, although the process was also encountered within the nuclear matrix and in the cytoplasm. There was often extensive proliferation of the nuclear membrane. Envelopment of the virus by budding from the cell surface was not observed. It was concluded that enveloped virus consitutes the infectious particle and that the unenveloped capsid is unstable outside the cell. Nevertheless, it is likely that capsids enclosing infectious nucleic acid can pass directly from one cell to another after fusion has taken place.     

Micromorphological Aspects of the Development of Rubella Virus in BHK-21 Cells

Sequential effects of rubella virus infection in BHK-21 cells were studied by electron microscopy of thin sections of control and infected cells, 2 to 7 days after infection. Vacuolization of cytoplasm in Golgi areas apparently preceded budding of virions from vacuole membranes and involvement of the endoplasmic reticulum. Newly formed endoplasmic reticulum cisternae encircled and segregated virionforming vacuoles together with other cellular elements. Large vacuolar complexes with numerous virus particles developed, and virus release from these areas occurred with disruption at the cell periphery. The viral particles, with a mean diameter of about 56 nm, consisted of an electron-dense core surrounded by a less dense capsid, enveloped by a typical unit membrane derived from the vacuole membrane.     

Vaccinia Virus Intracellular Mature Virions Contain only One Lipid Membrane

Vaccinia virus (VV) morphogenesis commences with the formation of lipid crescents that grow into spherical immature virus (IV) and then infectious intracellular mature virus (IMV) particles. Early studies proposed that the lipid crescents were synthesized de novo and matured into IMV particles that contained a single lipid bilayer (S. Dales and E. H. Mosbach, Virology 35:564–583, 1968), but a more recent study reported that the lipid crescent was derived from membranes of the intermediate compartment (IC) and contained a double lipid bilayer (B. Sodiek et al., J. Cell Biol. 121:521–541, 1993). In the present study, we used high-resolution electron microscopy to reinvestigate the structures of the lipid crescents, IV, and IMV particles in order to determine if they contain one or two membranes. Examination of thin sections of Epon-embedded, VV-infected cells by use of a high-angular-tilt series of single sections, serial-section analysis, and high-resolution digital-image analysis detected only a single, 5-nm-thick lipid bilayer in virus crescents, IV, and IMV particles that is covered by a 8-nm-thick protein coat. In contrast, it was possible to discern tightly apposed cellular membranes, each 5 nm thick, in junctions between cells and in the myelin sheath of Schwann cells around neurons. Serial-section analysis and angular tilt analysis of sections detected no continuity between virus lipid crescents or IV particles and cellular membrane cisternae. Moreover, crescents were found to form at sites remote from IC membranes—namely, within the center of virus factories and within the nucleus—demonstrating that crescent formation can occur independently of IC membranes. These data leave unexplained the mechanism of single-membrane formation, but they have important implications with regard to the mechanism of entry of IMV and extracellular enveloped virus into cells; topologically, a one-to-one membrane fusion suffices for delivery of the IMV core into the cytoplasm. Consistent with this, we have demonstrated previously by confocal microscopy that uncoated virus cores within the cytoplasm lack the IMV surface protein D8L, and we show here that intracellular cores lack the surface protein coat and lipid membrane.     

Morphology and Entry of Enveloped and Deenveloped Equine Abortion (Herpes) Virus

Selective removal of the envelope of equine abortion (herpes) virus was accomplished by utilizing the nonionic detergent Nonidet P-40 followed by sonic treatment. The deenveloped particles differ significantly in size and buoyant density from the enveloped form. The cellular entry of purified enveloped and purified deenveloped virus was examined by electron microscopy during critical time periods. Both forms appeared to enter cells by a viropexis mechanism in which particles were engulfed by pseudopodia which either surround the virus and fuse with the cell membrane or to other pseudopodia, forming fusion vacuoles containing from one to numerous viral particles. This mode of entry was noted extensively at 5 min postinoculation. Deenveloped particles were apparently infectious only for hamsters, with a large inoculum being required. Contamination by enveloped forms was not noted after exhaustive search by electron microscopy.     

Electron microscopic studies of tumor viruses. II. Entry and uncoating of Epstein-Barr virus.

Entry of Epstein-Barr virus into human lymphoblastoid cells (Daudi cells) was studied by electron microscopy. At the site of viral attachment, two distinct interactions conducive to penetration of the virus occurred between the viral envelope and cell membrane, namely, (i) simultaneous dissolution of both the envelope and cell membrane, presumably resulting in passage of viral capsids into the cytoplasm and (ii) dissolution confined to the cell membrane with resulting penetration of enveloped virus. In the latter case envelope dissolution appears to occur subsequently in the cytoplasm with release of capsids. Fusion of the viral envelope with the cell membrane was not observed. The capsids exhibited two distinct structural forms--one dense, the other translucent or light in appearance. The former disrupted near the cell membrane with release of viral cores into the cytoplasm whereas the light capsids containing dense cores migrated toward the nucleus and accumulated in the perinuclear region. Apparently the process of releasing deoxyribonucleic acid (DNA) from the light capsid is slowed down or prevented in Daudi cells. A hypothesis is presented concerning the manner in which these two types of capsids initiate infection.     

Morphological Changes in Productive and Abortive Infection by Feline Herpesvirus

Feline herpesvirus produces characteristic morphological alterations in feline kidney cells. Nucleocapsid particles are formed in infected nuclei and are enveloped as they pass through the modified inner nuclear membrane. Aggregates of dense granular material and filamentous structures also regularly appear in infected nuclei. Infection of human embryonic lung cells by feline herpesvirus results in the appearance of intranuclear inclusion bodies, aggregates of dense granular material, and bundles of parallel filaments but no nucleocapsid particles.     

ASSEMBLY AND AGGREGATION OF TOBACCO MOSAIC VIRUS IN TOMATO LEAFLETS

Cells of tomato leaflets (Lycopersicum esculentum Mill.) were studied by phase and electron microscopy at various intervals after inoculation with a common strain of tobacco mosaic virus (TMV). Forty-eight hours after inoculation, prior to the development of assayable virus, individual TMV particles, and also particle aggregates, were observed in the ground cytoplasm of mesophyll cells. The most rapid synthesis of virus occurred between 80 and 300 hours after inoculation. Cytological changes during this time were characterized by an increased number of individual particles in the cytoplasm, growth of some aggregates, distortion and vacuolation of chloroplasts, and formation of filaments in the cytoplasm which were approximately four times the size of TMV. These filaments were interpreted as possible developmental forms of the TMV particle. Vacuoles in chloroplasts commonly contained virus particles. Evidence indicated that TMV was assembled in the ground cytoplasm and, in some cases, subsequently was enveloped by distorted chloroplasts.     

Herpes Simplex Virus Products in Productive and Abortive Infection III. Differentiation of Infectious Virus Derived from Nucleus and Cytoplasm with Respect to Stability and Size

Approximately 67% of infectivity is associated with the nucleus 8 hr after productive infection of HEp-2 cells with herpes simplex virus. Comparison of nuclear and cytoplasmic infectious virus and macromolecular aggregates labeled with (3)H-thymidine or with (3)H-choline revealed the following. (i) Cytoplasmic infectious virus and macromolecular aggregates banded in CsCl at a density corresponding to enveloped nucleocapsids. The virus was relatively stable; there was only 50% loss of infectivity and only 16% of the virions became disaggregated. (ii) Nuclear macromolecular aggregates banded in CsCl solution at a density corresponding to unenveloped nucleocapsids and, moreover, both the infectious virus and aggregates were highly unstable. (iii) In sucrose density gradients, the nuclear macromolecular aggregates and infectivity sedimented as a single band and migrated more slowly than the corresponding cytoplasmic material. (iv) The infectivity of nuclear and cytoplasmic virus is readily inactivated by digestion with phospholipase C and with pronase. We conclude the following. (i) Cytoplasmic virus consists of enveloped nucleocapsids. (ii) Nuclear virus consists of nucleocapsids covered with lipid or partially enveloped. (iii) The molecular integrity of viral lipids is essential for infectivity. (iv) The envelope protects the nucleocapsid and accelerates adsorption to cells; it is not, however, inherently essential for infectivity.     

Interruption by Rifampin of an Early Stage in Vaccinia Virus Morphogenesis: Accumulation of Membranes Which Are Precursors of Virus Envelopes

Assembly of vaccinia virus envelopes and immature vaccinia particles was interrupted in HeLa cells treated with rifampin (rifampicin). The primary action of rifampin on vaccinia morphogenesis appeared to occur during the stage of envelope formation. When envelopes and immature particles were already present, maturation could continue, even in the presence of rifampin. It was demonstrated that the trilaminar membranes of irregular contour which accumulate in the presence of rifampin are precursors of virus envelopes. When rifampin was removed under controlled conditions, synchronous transitions were observed as the precursor membranes rapidly converted into uniformly curved envelope units with a 10- to 12-nm coat on the convex surface. These experiments provided an opportunity to examine the sequence of some early events in vaccinia morphogenesis. Initially, nascent envelopes remained in clusters around dense viroplasm. Large numbers of single immature particles appeared within 10 min. Nucleation of immature particles was the first evidence of core differentiation and began within 5 to 10 min. Development of lateral bodies and modeling of the biconcave cores was observed within 30 min, and structurally mature virions were present by 2 hr after the removal of rifampin. High resolution autoradiography showed that viral deoxyribonucleic acid, which labeled with (3)H-thymidine during rifampin treatment, was incorporated by the mature vaccinia which formed after rifampin was removed. Concentration of the viral deoxyribonucleic acid in core material evidently occurred after envelope assembly, probably coincident with nucleoid formation. Cytoplasmic crystalloid bodies accumulated during rifampin treatment; they appeared morphologically identical to vaccinia nucleoids and were heavily labeled by (3)H-thymidine.     

A new entomopoxvirus from a cockroach: light and electron microscopy

The cockroach entomopoxvirus caused a chronic infection in cultures of the German cockroach Blattella germanica. Heavily infected specimens showed a reduced mobility. Ellipsoid virus occlusion bodies (8 x 5 to 19 x 12 microm) were found intracellularly in tracheole cells, in the hypodermis, in fat body cells, and in muscles. Several hundred virus particles were integrated in a single occlusion body (OB), their long axis being oriented axially. Ovoid viroids measured 320 x 190 nm and possessed a unilateral, concave core and one lateral body. Starting occlusion, small granules attached to the virus particles which later transformed to a beaded, wavy envelope. An initial halo around the occluded virions disappeared in more central regions of the OB. Virus particles were formed either in a dense cytoplasmic area containing electron-dense viroids, or in a loosely aggregated viroplasm. In the latter, developmental stages were mainly represented by spheres with double membranes enclosing granular material. Spindles and larger crystal-like virus-free inclusion bodies occurred in the cytoplasm. The cytoplasm of infected cells appeared degenerated and the chromatin of the nuclei condensed at the periphery or disintegrated. Taxonomically, the described virus exhibits features of both EPV genus A and EPV genus B. Provisory it is named Blattella germanica EPV (BgEPV). A possible use of the cockroach EPV as a biological control agent is discussed.     

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.     

Ultrastructural pathology of leaf cells of ryegrass (Lolium multiflorum) infected with ryegrass mosaic virus.

Ryegrass mosaic virus particles and virus induced lamellar inclusions were found in mesophyll and epidermal cells of virus infected ryegrass leaves. The lamellar inclusions were occasionally found in phloem cells also. Virus particles occurred in cytoplasm, inside plasmodesmata and often in membrane bound sacs embedded in a matrix between plasmalemma and cell wall at or near plasmodesmata. Electron dense plugs protruding from plasmodesmata, finger-like cell wall outgrowths and cell wall deposits usually at plasmodesmata were also observed. Cytopathological changes in organelles in infected cells included dense deposits in the cisternae of endosplasmic reticulum and Golgi apparatus, mitochondria with electron-dense or opaque matrix, proliferating cristae and deteriorating unit membrane; and disintegrating chloroplasts.     

Nonoccluded baculovirus- and filamentous virus-like particles in the spotted cucumber beetle,diabrotica undecimpunctata (coleoptera: chrysomelid)

Nonoccluded baculovirus-and filamentous virus-like particles were found in nuclei of hemocytes or midgut cells of field-collected spotted cucumber beetles. Each type of particle was associated with a different type of virogenic stroma containing various viral components similar to those referred to as capsid, nucleocapsid, viroplasm, and viral envelope in other known baculovirus infections. Nucleocapsids of the virus which occured only in hemocytes were rod-shaped particles approximately 230 nm long and 52 nm wide and were enveloped singly by a trilaminar unit membrane. Enveloped and partly enveloped particles appeared to be released from the nucleus to the cytoplasm by budding through the nuclear envelope acquiring additional membranes. The nucleocapsids of the virus which occurred only in nuclei of midgut cells were filamentous particles with an average diameter of 25 nm and variable length up to 2 μm. Some extremely long particles were bent almost 360° near the middle, resulting in a hairpin-like configuration. The particles were always enveloped singly. No particles budding through the nuclear envelope were observed.     

Isolation of Carnation Ringspot Virus from a Canal Near a Sewage Plant: cDNA Hybridization Analysis, Serology and Cytopathology

A small water sample of only 60 ml from the Oker Aue canal near Braunschweig was ultracentrifuged. The resuspended pellet was rubbed on Chenopodium quinoa leaves which responded with the formation of almost 200 local lesions. The virus causing these lesions was identified as carnation ringspot virus (CarRSV) by means of dot blot hybridization using random-primed cDNAs to the viral nucleic acids and by means of serology. Northern blot analysis revealed that the two RNA species of the virus which consisted of c. 3.7 and 1.5 Kb, respectively, have little or no base sequence homology. In immunoelectrophoresis at pH 7.0 the virus migrated towards the cathode. The isometric particles were 33 nm in diameter, round to slightly angular in outline, and showed a distinct granular or knobly surface structure. Virus particles occurred in the cytoplasm, nuclei, and vacuoles of infected cells which in addition contained amorphous granules in the cytoplasm and/or proliferated endoplasmic reticulum. Heavily, affected cells were necrotized and contained large virus particle aggregates which sometimes were crystallized. CarRSV is the third carnation virus, after carnation mottle and carnation Italian ringspot viruses, which was identified in a natural water.     

An Unconventional Role for Cytoplasmic Disulfide Bonds in Vaccinia Virus Proteins

Previous data have shown that reducing agents disrupt the structure of vaccinia virus (vv). Here, we have analyzed the disulfide bonding of vv proteins in detail. In vv-infected cells cytoplasmically synthesized vv core proteins became disulfide bonded in the newly assembled intracellular mature viruses (IMVs). vv membrane proteins also assembled disulfide bonds, but independent of IMV formation and to a large extent on their cytoplasmic domains. If disulfide bonding was prevented, virus assembly was only partially impaired as shown by electron microscopy as well as a biochemical assay of IMV formation. Under these conditions, however, the membranes around the isolated particles appeared less stable and detached from the underlying core. During the viral infection process the membrane proteins remained disulfide bonded, whereas the core proteins were reduced, concomitant with delivery of the cores into the cytoplasm. Our data show that vv has evolved an unique system for the assembly of cytoplasmic disulfide bonds that are localized both on the exterior and interior parts of the IMV.     

Electron Microscopy of Herpes Simplex Virus III. Effect of Hydroxyurea

The effect of hydroxyurea on the development of herpes virus is mediated through its inhibitory action on deoxyribonucleic acid (DNA) synthesis. Concentrations of the drug that suppress the production of infectious virus cause typical developmental anomalies: failure in formation of the normally dense cores or "complete" viral particles, and either faulty or no envelopment of viral capsids by membranes. The synthesis of viral capsids and virus-stimulated nuclear and cytoplasmic membranes, however, is not interrupted. Combining these results with those of time sequence experiments, the following hypotheses can be presented regarding viral development. Protein synthesis, which is characterized by capsids enclosing cores of low density, precedes DNA synthesis, which is characterized by the appearance of dense cores. Capsids with dense cores are selectively transported to the cytoplasm. Envelopment generally takes place as capsids pass from the nucleus to the cytoplasm. The process of envelopment is also selective, with the result that the majority of particles that have an envelope contain a full quota of DNA.     

Amorphous mineral phases in magnetotactic multicellular aggregates

Magnetotactic multicellular aggregates consist of several bacteria that produce iron sulfide magnetosomes through a complex and poorly understood process. We observed new amorphous mineral particles within the cytoplasm of magnetotactic multicellular aggregates. Elemental mapping and electron energy loss spectroscopy detected iron and oxygen, but not sulfur, in these particles. These amorphous particles were about the same size as mature magnetosomes, around 50-70 nm in diameter. No membranes were observed surrounding the amorphous minerals. Partially crystalline inclusions composed of a crystalline core and an amorphous region around them similar in texture to the amorphous particles were also present. The shape of these amorphous regions followed the shape of the crystalline cores they enveloped. These regions also contained oxygen and iron. The crystalline phase, as previously reported, contained sulfur and iron. The presence of independent amorphous particles has not been reported before in magnetotactic multicellular aggregates.