Virus in Trichomonas--an ultrastructural study

Trichomonas vaginalis is a flagellated, parasitic protozoan that inhabits the urogenital tract of humans. Approximately one-half of isolates of T. vaginalis are infected with a double-stranded (ds) RNA virus, which was described in the literature as a homogeneous population of icosahedral virus with isometric symmetry and 33 nm in diameter. The present study describes the heterogeneous virus population found in T. vaginalis isolate 347. This population comprises different virus sizes (33-200 nm) and shape (filamentous, cylindrical, and spherical particles). These observations were made in CsCl-purified virus fractions as well as the thin sections of parasites. Some viruses were only observed after slight changes in the technique where the sample was prepared by the negative staining carbon-film method directly onto freshly cleft mica. The VLPs were found in the cytoplasm closely associated with the Golgi complex, with some VLPs budding from the Golgi, and other VLPs were detected adjacent to the plasma membrane. Unidentified cytoplasmic inclusions were observed in the region close to the VLPs and Golgi. These results indicate that T. vaginalis organisms may be infected with different dsRNA viruses simultaneously and suggest that T. vaginalis may be a reservoir for several viruses. We also showed some steps in the route of T. vaginalis virus and some aspects of the cytopathology of this infection. Purified VLPs were transfected to virus-free T. vaginalis isolates. Our results demonstrate that TVV attach and penetrate into trichomonads through endocytic coated pits and are maintained within vacuoles during batch culture for several daily passages. Immediately after virus transfection, many cells were lysed, whereas some intact reminiscent cells were recruited forming large clusters. Virus particles were found outside the cells, and in coated pits, within vacuoles in the cytoplasm, and infrequently within the nucleus. The Golgi complex showed changes in its electron density and in the cisternae structure. In lysed cells, virus particles were clearly seen over the residual membranes.     

Trichomonas vaginalis: observation of coexistence of multiple viruses in the same isolate

Trichomonas vaginalis is a flagellated, parasitic protozoan that inhabits the urogenital tract of humans. Some isolates of T. vaginalis are infected with a double-stranded RNA (dsRNA) virus, which was described in the literature as homogeneous icosahedral viral particles with an isometric symmetry and 33 nm in diameter. This study examined in detail the viral particles in T. vaginalis isolate 347 and describes a heterogeneous population of viral particles. The different dsRNA viruses were only observed after a change in the technique. The sample was prepared by the negative staining carbon-film method directly onto freshly cleft mica. The detected viruses ranged in size from 33 to 200 nm. Among the shapes observed were filamentous, cylindrical, and spherical particles. These results show that T. vaginalis may be a reservoir for several different dsRNA viruses simultaneously.     

Analysis of double-stranded RNA and virus-like particles in trichothecene-producing strains of<Emphasis Type="Italic">Fusarium graminearum</Emphasis>

Double-stranded RNAs (dsRNAs) have been found in two isolates of the plant pathogenic fungus Fusarium graminearum which produce trichothecene mycotoxins. The isolates 8.2 and 19.2 had dsRNAs in the size of about 2.0 kb and 6.0 kb, respectively, which were associated with capsid proteins and persisted within the cytoplasm of the infected host cells as encapsidated virus-like particles (VLPs). The dsRNAs contained in the VLP pellets were the same size as the dsRNA isolated in total nucleic acid preparations. In the VLP pellets the isolate 19.2 had a second dsRNA with the size of about 1.6 kb. After mycovirus purification one icosahedral particle of about 28 nm in diameter from the isolate 8.2 and two icosahedral particles of about 28 nm and 38 to 40 nm in diameter from the isolate 19.2 could be identified with electron microscopy. SDS-PAGE analysis of the VLPs from the isolate 8.2 revealed one major protein component of approximately 65 kDa, while the isolate 19.2 had two major protein bands at about 94 kDa and 105 kDa. Both isolates were studied for potential trichothecene production. Tox5 PCR showed a 658 bp fragment in each isolate. In addition, both strains were able to produce the trichothecenes deoxynivalenol (DON), the derivatives acetyl-DON (3-A-DON, 15-A-DON) and nivalenol (NIV) in vitro.     

Complex of Virus-Like Particles Containing Double-Stranded RNA from Thielaviopsis basicola

Six randomly selected isolates of Thielaviopsis basicola were found to contain spherical virus-like particles (VLPs) approximately 40 nm in diameter. One isolate, ATCC 34114, selected for further analysis contained a complex of VLPs that sedimented as eight or more bands in sucrose density gradients and contained five size classes of double-stranded RNA. Five discrete precipitation lines were obtained in immunoelectrophoresis, which indicated that this isolate of T. basicola contains five distinct species of VLPs.     

A picornavirus-like pathogen of Cotylogaster occidentalis (Trematoda: Aspidogastrea), an intestinal parasite of freshwater mollusks

Nonoccluded, icosahedral picornavirus-like (PVL) particles, 23 nm in diameter, forming paracrystalline arrays were seen in the cytoplasm of various cells in Cotylogaster occidentalis. Viral inclusions were visible in live specimens and in sections prepared for light and electron microscopy. All worms examined over a 2-year period were found to be infected. Infections were naturally acquired and susceptibility was not associated with any particular developmental stages. Development of viral inclusions involved an increase in the inclusion volume, progressive accumulation and condensation of materials into the interior of the inclusions, and formation of multilamellar membrane networks. Virus particles were observed in the stroma of the inclusions in association with multilamellar spherical bodies. Mature PVL particles aggregated into polygonally shaped paracrystalline arrays. When such arrays occurred in the surface tegument, local disruption of the tegumentary membrane may liberate these particles into the environment. PVL particle production did not exhaust glycogen content of infected cells and did not appear to affect short-term survival of the parasite outside the molluscan host.     

Purification and partial characterization of virus-like particles from Schneider line 2 Drosophila cells

A procedure has been developed for the purification of virus-like particles (VLPs) from Schneider line 2 Drosophila cells. The VLPs were precipitated with polyethylene glycol from the cytoplasmic fraction of lysed cells and further purified by equilibrium centrifugation in CsCl density gradients, in which they band at a density of 1.366 g/ml. Electron micrographs of these preparations revealed polyhedral particles with a diameter of 310–330 Å. We have also found particles of this size in thin sections of the intact cells. Sedimentation of the VLPs through 10–70% sucrose gradients yields a sedimentation coefficient of 235 S. Preliminary studies show that the VLPs contain double-stranded RNA species of 10 S, 14.5 S, 16 S, and 18 S.     

Surface structure of Uukuniemi virus.

Uukuniemi virus, grown in chicken embryo fibroblasts, has been studied by electron microscopy using negative staining, thin sectioning, and freeze-etching techniques. The spherical virus particle measures about 95 nm in diameter. Its envelope consists of a 5-nm thick membrane covered by 8- to 10-nm long surface projections. These are composed of two polypeptides species of about the same size. Both of them can be removed by digestion with the proteolytic enzyme thermolysin except for a small fragment. The enzyme-treated particles are smooth surfaced and extremely deformable. The glycopolypeptides are clustered to form hollow cylindrical morphological units, 10 to 12 nm in diameter, with a 5-nm central cavity. Both negative staining and freeze-etching suggest that these units are penton-hexon clusters arranged in a T = 12, P = 3, icosahedral surface lattice. The membrane to which the surface subunits are attached is probably a lipid bilayer as evidenced by its double-track appearance in thin sections and the tendency of the freeze fracturing to occur within it. The strand-like nucleoprotein appears from thin-sectioning results to be to a large part located in a zone underneath the membrane.     

Morphological and Cytochemical Studies on Lymphocytic Choriomeningitis Virus

Lymphocytic choriomeningitis (LCM) virus was observed by electron microscopy in thin sections of infected tissue cultures. The particles were pleomorphic and varied greatly in size. The smaller particles (50 to 200 nm) appeared to be spherical, whereas the largest (over 200 nm) were often cup-shaped. All particles contained one to eight or more electron-dense granules which were removed by ribonuclease. The particles were formed by budding from the plasma membrane and appeared to have spikes. The morphological evidence suggests that LCM should be considered as belonging to the presently unclassified group of lipoprotein-enveloped ribonucleic acid viruses.     

Prevalence of virus-like particles within a staghorn scleractinian coral (<Emphasis Type="Italic">Acropora muricata</Emphasis>) from the Great Barrier Reef

Transmission electron microscopy (TEM) was used to determine whether Acropora muricata coral colonies from the Great Barrier Reef (GBR), Australia, harboured virus-like particles (VLPs). VLPs were present in all coral colonies sampled at Heron Island (southern GBR) and in tagged coral colonies sampled in at least two of the three sampling periods at Lizard Island (northern GBR). VLPs were observed within gastrodermal and epidermal tissues, and on rarer occasions, within the mesoglea. These VLPs had similar morphologies to known prokaryotic and eukaryotic viruses in other systems. Icosahedral VLPs were observed most frequently, however, filamentous VLPs (FVLPs) and phage were also noted. There were no clear differences in VLP size, morphology or location within the tissues with respect to sample date, coral health status or site. The most common VLP morphotype exhibited icosahedral symmetry, 120–150 nm in diameter, with an electron-dense core and an electronlucent membrane. Larger VLPs of similar morphology were also common. VLPs occurred as single entities, in groups, or in dense clusters, either as free particles within coral tissues, or within membrane-bound vacuoles. VLPs were commonly observed within the perinuclear region, with mitochondria, golgi apparatus and crescent-shaped particles frequently observed within close proximity. The host(s) of these observed VLPs was not clear; however, the different sizes and morphologies of VLPs observed within A. muricata tissues suggest that viruses are infecting either the coral animal, zooxanthellae, intracellular bacteria and/or other coral-associated microbiota, or that the one host is susceptible to infection from more than one type of virus. These results add to the limited but emerging body of evidence that viruses represent another potentially important component of the coral holobiont.     

The maturation process of pVP2 requires assembly of infectious bursal disease virus capsids

Infectious bursal disease virus (IBDV) is a nonenveloped avian virus with a two-segment double-stranded RNA genome. Its T=13 icosahedral capsid is most probably assembled with 780 subunits of VP2 and 600 copies of VP3 and has a diameter of about 60 nm. VP1, the RNA-dependent RNA polymerase, resides inside the viral particle. Using a baculovirus expression system, we first observed that expression of the pVP2-VP4-VP3 polyprotein encoded by the genomic segment IBDA results mainly in the formation of tubules with a diameter of about 50 nm and composed of pVP2, the precursor of VP2. Very few virus-like particles (VLPs) and VP4 tubules with a diameter of about 25 nm were also identified. The inefficiency of VLP assembly was further investigated by expression of additional IBDA-derived constructs. Expression of pVP2 without any other polyprotein components results in the formation of isometric particles with a diameter of about 30 nm. VLPs were observed mainly when a large exogeneous polypeptide sequence (the green fluorescent protein sequence) was fused to the VP3 C-terminal domain. Large numbers of VLPs were visualized by electron microscopy, and single particles were shown to be fluorescent by standard and confocal microscopy analysis. Moreover, the final maturation process converting pVP2 into the VP2 mature form was observed on generated VLPs. We therefore conclude that the correct scaffolding of the VP3 can be artificially induced to promote the formation of VLPs and that the final processing of pVP2 to VP2 is controlled by this particular assembly. To our knowledge, this is the first report of the engineering of a morphogenesis switch to control a particular type of capsid protein assembly.     

Structure and assembly of a T=1 virus-like particle in BK polyomavirus

In polyomaviruses the pentameric capsomers are interlinked by the long C-terminal arm of the structural protein VP1. The T=7 icosahedral structure of these viruses is possible due to an intriguing adaptability of this linker arm to the different local environments in the capsid. To explore the assembly process, we have compared the structure of two virus-like particles (VLPs) formed, as we found, in a calcium-dependent manner by the VP1 protein of human polyomavirus BK. The structures were determined using electron cryomicroscopy (cryo-EM), and the three-dimensional reconstructions were interpreted by atomic modeling. In the small VP1 particle, 26.4 nm in diameter, the pentameric capsomers form an icosahedral T=1 surface lattice with meeting densities at the threefold axes that interlinked three capsomers. In the larger particle, 50.6 nm in diameter, the capsomers form a T=7 icosahedral shell with three unique contacts. A folding model of the BKV VP1 protein was obtained by alignment with the VP1 protein of simian virus 40 (SV40). The model fitted well into the cryo-EM density of the T=7 particle. However, residues 297 to 362 of the C-terminal arm had to be remodeled to accommodate the higher curvature of the T=1 particle. The loops, before and after the C-terminal short helix, were shown to provide the hinges that allowed curvature variation in the particle shell. The meeting densities seen at the threefold axes in the T=1 particle were consistent with the triple-helix interlinking contact at the local threefold axes in the T=7 structure.     

Lipoprotein secretion by rat liver Golgi apparatus. Lipoprotein particles and lipase activity.

Lipoprotein particles of the size range of very low density lipoproteins in smooth endoplasmic reticulum, peripheral elements of the Golgi apparatus, and secretory vesicles of the immature Golgi apparatus face are 55 to 80 nm in diameter. Particles in mature secretory vesicles are smaller (45 nm). Concomitant with the change in particle size, the lumina of mature vesicles increase in electron density. A technique to fractionate immature and mature secretory vesicles was based on precipitation of a cupric-ferrocyanide complex (Hatchett's brown) through the action of a NADH-ferricyanide oxido-reductase resistant to glutaraldehyde which is characteristic of the membranes of mature secretory vesicles and of the plasma membrane of liver. Mature secretory vesicle fractions so isolated were enriched in cholesterol and depleted in triglycerides relative to immature vesicles on a phospholipid basis. Lipase activity was present in secretory vesicle fractions of the Golgi apparatus as shown by biochemical analysis and by cytochemistry. Cytochemical studies showed lipase to be present in both mature and immature vesicles but most evident in immature vesicles. The findings suggest that some very low density lipoprotein particles are converted to particles of smaller diameter during transit through Golgi apparatus. A lipase-mediated hydrolysis of triglycerides may relate to the transformation.     

Appearance of virus-like particles in Tritrichomonas foetus after drug treatment

Tritrichomonas foetus is a parasitic protist that infects the urogenital tract of cattle causing bovine trichomonosis. Virus-like particles (VLPs) in protozoa have been reported in several parasites including Trichomonas vaginalis, a human flagellate, but viruses were never described in T. foetus so far. Herein we show for the first time the presence of VLPs in T. foetus after several drug treatments. They were detected by electron microscopy and were confirmed by immunofluorescence microscopy using antibodies anti-virus proteins. These VLPs were always observed in clusters of variable size. Their preferential locations were at the cell periphery, close to the axostyle, and interestingly in some cases, inside the nucleus. Their appearance occurred when the parasites were under drug-treatments, such as cytoskeleton-affecting drugs (colchicine, vinblastine, taxol, nocodazole, and griseofulvin) or drugs inducing cell death, such as lactacystin and H(2)O(2). We propose that cytoskeleton participates in trichomonads of the process of virus release or maturation. These virus particles were not described previously probably because they were either in low amount or in a latent state.     

Cryo-electron microscopy structure of yeast Ty retrotransposon virus-like particles.

The virus-like particles (VLPs) produced by the yeast retrotransposon Ty1 are functionally related to retroviral cores. These particles are unusual in that they have variable radif. A paired mass-radius analysis of VLPs by scanning transmission electron microscopy showed that many of these particles form an icosahedral T-number series. Three-dimensional reconstruction to 38-A resolution from cryo-electron micrographs of T = 3 and T = 4 shells revealed that the single structural protein encoded by the TYA gene assembles into spiky shells from trimeric units.     

Heterologous RNA encapsidated in Pariacoto virus-like particles forms a dodecahedral cage similar to genomic RNA in wild-type virions

The genome of some icosahedral RNA viruses plays an essential role in capsid assembly and structure. In T=3 particles of the nodavirus Pariacoto virus (PaV), a remarkable 35% of the single-stranded RNA genome is icosahedrally ordered. This ordered RNA can be visualized at high resolution by X-ray crystallography as a dodecahedral cage consisting of 30 24-nucleotide A-form RNA duplex segments that each underlie a twofold icosahedral axis of the virus particle and interact extensively with the basic N-terminal region of 60 subunits of the capsid protein. To examine whether the PaV genome is a specific determinant of the RNA structure, we produced virus-like particles (VLPs) by expressing the wild-type capsid protein open reading frame from a recombinant baculovirus. VLPs produced by this system encapsidated similar total amounts of RNA as authentic virus particles, but only about 6% of this RNA was PaV specific, the rest being of cellular or baculovirus origin. Examination of the VLPs by electron cryomicroscopy and image reconstruction at 15.4-A resolution showed that the encapsidated RNA formed a dodecahedral cage similar to that of wild-type particles. These results demonstrate that the specific nucleotide sequence of the PaV genome is not required to form the dodecahedral cage of ordered RNA.     

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.     

Electron Microscopy of Equine Infectious Anemia Virus

Equine infectious anemia (EIA) virus was observed in thin sections of infected cultured horse leukocytes by electron microscopy. The virus particles had a spherical shape and were between 80 and 120 nm in diameter. Most of them contained an electron-dense nucleoid 40 to 60 nm in diameter. They were observed to form by a process of budding from the plasma membrane and appeared to have thin surface projections. The particles described were not detected in uninfected cultured cells, and their appearance could be prevented by adding EIA immune serum to the inoculum. The implications of these findings in the classification of EIA virus are discussed.     

感染病毒的小麦全蚀菌的超微结构

将感染病毒的小麦全蚀菌山东烟台株培养 20天的菌体细胞,进行超微结构的研究。于电镜下观察到球状病毒颗粒,平均直径23—30nm,多是无规则松散的分布于胞质中;或紧密聚集于液泡、线粒体周围;或排列成线状;或7—8个颗粒排列成环状。病毒仅分布于细胞质中,细胞核、脂肪体内均未见病毒颗粒。病毒浓度在较老的菌体内有增加的趋势。全蚀菌的菌丝细胞壁有三层,外层电子致密内含纤维状物,内层电子较为透明,中层为一电子致密度很深的狭窄夹层。壁的厚度不均,外缘不规则;在菌丝体产生隔膜的早期阶段,于隔膜附近有1—3个外被膜结构的沃罗宁体 Woronin body,隔膜形成的后期,见电子致密物质沉积在核膜孔上,形成中的隔膜顶端为尖状突起向基部逐渐增宽略成金字塔形。     

ISOLATION OF A NON‐PHAGE‐LIKE LYTIC VIRUS INFECTING AUREOCOCCUS ANOPHAGEFFERENS1

We have been working to characterize viruses that infect the HAB‐forming pelagophyte Aureococcus anophagefferens Hargraves et Sieburth. Field samples were collected during brown‐tide events in 2002 and tested for the presence of lytic agents. Here, we describe a recently isolated, lytic virus‐like particle (VLP) that is morphologically similar to particles observed in thin sections of infected A. anophagefferens cells from natural samples. TEM and SEM have revealed VLPs consistent with the morphological characteristics of previously described Phycodnaviridae. Large icosahedral particles (～140 nm) of similar shape and morphology dominate cell lysates and are accompanied by smaller phage‐like particles and heterotrophic prokaryotes that appear to be incurable from our cultures. To determine which of these particles interacts with the Aureococcus cells, we preserved cultures during the early stage of infection so that SEM could be used to visualize those particles that attach to the surface of naïve cultures. SEM revealed that 63% of the large icosahedral‐shaped particles attached to A. anophagefferens cells after only 30 min of exposure, while no significant frequency of attachment to the alga was observed for the phage‐like particles. The results of these observations are in contrast to previous studies, where phage‐like particles were reported to infect cells. When considered in conjunction with field observations, the results suggest that this newly isolated virus represents the dominant virus‐morphotype associated with bloom collapse and termination.