Vesicular stomatitis virus infection reduces the number of active DNA-dependent RNA polymerases in myeloma cells.

Infection of mouse myeloma (MPC-11) cells with vesicular stomatitis virus resulted in rapid loss in activity of cellular RNA polymerases associated with nuclear chromatin. No RNA polymerase inhibitor could be detected in extracts of infected cell nuclei. Reconstitution experiments with solubilized RNA polymerases dissociated from chromatin of infected and uninfected cells demonstrated that vesicular stomatitis viral infection did not affect the ability of the polymerases to function on endogenous or exogenous templates; nor did infection alter the template capability of the chromatin. Measurement of the number of actively growing RNA chains revealed that infected cell nuclei contained fewer active polymerase units; however, the rates of RNA chain elongation were the same in nuclei from infected and uninfected cells. Quantitation of the number of polymerase units active in nuclear chromatin revealed that the alpha-amantin-sensitive polymerase II was more severely reduced by viral infection than were polymerases I and III.     

Induction of host nuclear DNA synthesis in coccidia-infected chicken intestinal cells

When Eimeria maxima (gamonts) infects villus epithelial cells of the chicken duodenum there is extensive cellular enlargement with no alteration in nuclear size. Feulgen DNA microspectrophotometric measurements indicated that the infected host-cell nucleus contains the same amount of DNA as an uninfected cell nucleus. Evidence is presented to indicate that second generation schizonts of E. necatrix develop in crypt epithelial cells that are displaced/migrate into the lamina propria. The developing parasite causes cellular and nuclear hypertrophy in these cells as does E. tenella in cecal cells of the chicken. In these two cases nuclear enlargement is accompanied by induced rounds of DNA synthesis in the host-cell. Analyses indicated that the DNA content of enlarged nuclei does not fall into classes that correspond to a geometric series 2:4:6:8:16: etc. times the DNA content of a 2C equivalent, and that nuclear size and DNA content in infected cells are not significantly correlated. Autoradiographic studies on E. necatrix infected chicks administered ³H-thymidine show that DNA synthesis takes place in the nuclei of cells containing all developing stages but not mature schizonts, and that this synthesis is not a continuous process. The data suggest that intestinal cells that are capable of undergoing cell division and therefore additional rounds of DNA synthesis, can be induced by coccidial infection in the absence of concomitant cell division.     

A nonoccluded virus of the army cutworm

A nonoccluded virus was isolated from larvae of the army cutworm, Euxoa auxiliaris. Infected larvae became lethargic and shrunken, and death usually occurred 12–20 days after infection. The primary site of viral infection and replication appeared to be the nuclei of midgut epithelial cells; however, virus replication also occurred in cells of the tracheal matrix and in muscle. Nuclei in early stages of the infection contained large granular areas with the chromatin scattered near the nuclear membrane. These areas differentiated into viral particles that measured 24 nm and formed crystalline arrays, occasionally 10 μm long. Disruption of the nuclear membrane liberated these arrays of particles into the cytoplasm. Fluorescence microscopy studies indicated that the viral particles contained DNA. The crystalline arrays were Feulgen positive. The virus also infected larvae of the armyworm, Pseudaletia unipuncta, and corn carworm, Heliothis zea, in laboratory tests.     

Reactivation of chick erythrocyte nuclei in young and senescent WI38 cells

The chromatin of the dormant chick nucleus is dispersed in the heterokaryons made by Sendai virus fusion of phase II WI38 cells with chick erythrocyte nuclei. The erythrocyte nucleus resumes RNA synthesis and enters into DNA synthesis with the host nucleus. In the heterokaryons of phase III WI38 cells and chick erythrocytes, the nuclear chromatin is not dispersed and RNA synthesis occurs at a reduced rate. The differences in the physiological state of the young and senescent cells measured by [³H]uridine incorporation into nuclear RNA is reflected in the extent of reactivation of the chick erythrocyte nuclei in the cytoplasm of these cells. The reactivation of the chick nucleus in enucleated fibroblasts parallels the nucleated cells. The results of these studies are interpreted as evidence that there is a specific loss of nuclear function in the senescent cells.     

Fine structure of epithelial cells of Lieberkühn's crypts in feline panleukopenia.

Electron microscopic observation was carried out on epithelial cells of Lieberkühn's crypts of cats naturally affected with feline panleukopenia. The most important change was the replication of feline panleukopenia. The most important change was the replication of feline panleukopenia virus in the nucleus with associated alterations in the lining epithelial cells of the crypts. In these cells in the early stage of infection, virus particles 20 nm in average diameter were found either singly or in small regularly arrayed clusters everywhere in the markedly swollen nucleus. In the course of infection, the nucleus of infected cells became rather atrophic with a marked margination of chromatin granules. Its major portion was occupied with masses of fine fibrillar substance. It was a "viral matrix area" in which appeared a large compact aggregate of virus particles showing a crystalline array. At the same time, the outer membrane of the nuclear envelope partially extended and disrupted. Membranous elements related to it in the cytoplasm were regularly distributed almost always with particles indistinguishable from the virus particles in the nucleus. From these results it was suggested that the major portion of the infected nucleus, or the site of viral replication, might correspond to the amphophilic intranuclear inclusion body revealed by light microscopy.     

Human cytomegalovirus labeled with green fluorescent protein for live analysis of intracellular particle movements

Human cytomegalovirus (HCMV) replicates in the nuclei of infected cells. Successful replication therefore depends on particle movements between the cell cortex and nucleus during entry and egress. To visualize HCMV particles in living cells, we have generated a recombinant HCMV expressing enhanced green fluorescent protein (EGFP) fused to the C terminus of the capsid-associated tegument protein pUL32 (pp150). The resulting UL32-EGFP-HCMV was analyzed by immunofluorescence, electron microscopy, immunoblotting, confocal microscopy, and time-lapse microscopy to evaluate the growth properties of this virus and the dynamics of particle movements. UL32-EGFP-HCMV replicated similarly to wild-type virus in fibroblast cultures. Green fluorescent virus particles were released from infected cells. The fluorescence stayed associated with particles during viral entry, and fluorescent progeny particles appeared in the nucleus at 44 h after infection. Surprisingly, strict colocalization of pUL32 and the major capsid protein pUL86 within nuclear inclusions indicated that incorporation of pUL32 into nascent HCMV particles occurred simultaneously with or immediately after assembly of the capsid. A slow transport of nuclear particles towards the nuclear margin was demonstrated. Within the cytoplasm, most particles performed irregular short-distance movements, while a smaller fraction of particles performed centripetal and centrifugal long-distance movements. Although numerous particles accumulated in the cytoplasm, release of particles from infected cells was a rare event, consistent with a release rate of about 1 infectious unit per h per cell in HCMV-infected fibroblasts as calculated from single-step growth curves. UL32-EGFP-HCMV will be useful for further investigations into the entry, maturation, and release of this virus.     

ELECTRON MICROSCOPIC STUDY OF THE CYTOPATHOLOGY OF ECHO VIRUS INFECTION IN CULTIVATED CELLS

The cultivated monkey kidney cell is subject to changes when infected with ECHO viruses 6, 9, and 19. The electron microscope reveals three stages of infection: (a) initial stage. The nucleus appears granular with chromatin condensation on the nuclear envelope. The cytoplasm contains electron transparent vesicles and vacuoles forming nests. (b) Intermediate stage. The nucleus seems to diminish, appearing more pycnotic and displaced toward the periphery. The cytoplasm is filled with electron transparent vacuoles and vesicles, and dense masses as well as some spiral bodies are seen. The mitochondria retain their shape. Dense particles are seen, which are possibly of viral nature. (c) Final stage. The nucleus is contracted to a narrow strip close to the cellular membrane or is completely destroyed. The cytoplasm shows no apparent changes. Crystals are frequently observed in cells infected with ECHO viruses 6 and 19, consisting of dense particles with an average diameter of 14.4 mµ ranging from approximately 13.2 to 15.6 mµ for ECHO virus 6, and 14.5 mµ ranging from approximately 12.5 to 16.5 mµ for ECHO virus 19. These particles are clustered in hexagonal packages forming angles of 75° and 105°. The particles in most crystals are arranged in rows separated by a constant distance, the latter varying from one crystal to another and being approximately 1.5 and 2.5 times the distance between particles. Other particles were observed which, however, are not considered to be of viral nature.     

Influenza virus infection in multinucleated skeletal myofibers

We examined the progression of the WSN influenza virus infection in isolated, multinucleated rat skeletal myofibers. Contrary to mononucleated cells, the adsorbed virions showed markedly delayed entry kinetics. Viral budding occurred on the sarcolemma, but the hemagglutinin envelope glycoprotein matured inefficiently and was poorly cleaved. Compatible with this, plaque assays indicated that infective viral particles were not formed. In situ hybridization studies showed that at low-dose infection, viral RNA production was restricted to one or a few nuclei within a myofiber. Dual in situ hybridization indicated that two different viral RNAs usually co-localized in the same nucleus or nuclei, suggesting that different viral genome segments replicated in the same nucleus. Newly synthesized viral ribonucleoprotein particles (vRNPs) did not re-enter virgin nuclei. Therefore, a single infected nucleus was able to support viral protein production, and notably, these proteins could reach hundreds of micrometers from the nucleus of origin. These results suggest that after viral disassembly in the endosome, the genome segments remained glued together and entered a myonucleus as a package. Spreading of the infection into virgin nuclei either by vRNPs or newly made virions did not occur, and thus the infection was abortive.     

Aspects of the Encapsidation of Simian Virus 40 Deoxyribonucleic Acid

Growing subcloned CV1-cells were infected with simian virus 40, and the time course of virus formation was determined. When infected cells were fractionated into cytoplasmic and nuclear fractions, most of the progeny virus particles were recovered in the cytoplasmic extract and not in the nuclei. This result was independent of the technique used for the preparation of nuclei and of the time after infection at which the extracts were prepared. Leakage of the virions from the nucleus occurred during the course of cell fractionation, suggesting that the nuclear membrane of the infected cells is damaged. Virions were found to accumulate in a nonlinear fashion, at the time when the number of viral deoxyribonucleic acid (DNA) molecules increases linearly with time after infection. This suggests that the size of the intracellular pool of capsid proteins increases constantly during the late phase of virus replication. Progeny viral DNA to become encapsidated is withdrawn at random from the pool of replicated DNA molecules.     

Vaccinia virus RNA polymerase associated with nuclei of infected HeLa cells.

Though vaccinia virus DNA and RNA replication take place predominantly in the cytoplasm of an infected cell, virus formation requires the presence of a functional nucleus in a yet undefined manner. When the nuclei from cells infected for 3 h are isolated and purified, they are found to synthesize five times more RNA in vitro than do corresponding nuclei from noninfected cells. Fifty percent of the RNA synthesized in vitro by nuclei from infected cells is vaccinia specific, and this vaccinia RNA synthesis is resistant to alpha-amanitin concentrations up to 100 micrograms/ml. Furthermore, when the RNA polymerase activities of these nuclei are separated on DEAE-Sephadex columns, 56% of the total nuclear enzyme activity is found to be the vaccinia-specific RNA polymerase known to be alpha-amanitin resistant. The nucleus associated vaccinia RNA polymerase represents 18% of the total cellular vaccinia RNA polymerase. This synthesis of vaccinia RNA in the nucleus may explain the nuclear requirement for vaccinia virus maturation.     

The effect of sodium butyrate on Tipula iridescent virus synthesis in insect suspension cell cultures

The effect of sodium butyrate on Tipula iridescent virus (TIV) synthesis in suspension-cultured cells of Estigmene acrea was investigated. Sodium butyrate reduces viral-induced cell fusion but this is reversible with the removal of butyrate. At 7 mM sodium butyrate, TIV replicates in cells within 8 hr, but does not replicate in this time with 10–20 mm butyrate in the cell medium; cells so treated contain large vesicles with inoculum. Upon removal of the inhibitor, TIV replication appears normal, but large inoculum vesicles can still be found in the cytoplasm, and many infected cells have highly condensed chromatin in their nuclei. Sodium butyrate causes a lag of at least 2 hr in viral DNA synthesis as detected by [³H]thymidine incorporation into viroplasmic centres and at 7 mm butyrate viral DNA synthesis is reduced by 50–60%. In comparison, butyrate at 7 and 10 mm concentration does not inhibit host DNA synthesis, but at 15 and 20 mm, nuclear DNA synthesis is markedly reduced.     

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.     

Simian virus 40 associates with nuclear superstructures at early times of infection.

The association of infecting simian virus 40 with insoluble nuclear structures was assayed by disrupting infected nuclei and assaying insoluble fractions for virus. Three methods were used which lyse nuclei but maintain the insolubility of residual nuclear structures: sonication, high-salt-Triton-EDTA extraction, and low-salt-lithium diiodosalicylate extraction. After each type of nuclear extraction, infecting simian virus 40 remained associated with the residual nuclear structures. This association depended strictly on natural viral infections and on the use of buffers containing moderate amounts of salt and Mg2+ for the isolation of infected nuclei. These viral interactions exhibited behavior similar to host cell DNA interactions studied by analogous assays. Both viral DNA and coat proteins were found associated with the host cell nuclear superstructure. We concluding that at early times after infection the viral templates mimic the state of the host cell chromatin by attaching to the cellular nuclear matrix.     

Phage formation in Staphylococcus muscae cultures. IX. Effect of multiple infection on virus synthesis in the absence and presence of specific substrates

1. A strain of S. muscae which requires a substance present in certain acid-hydrolyzed proteins (AHPF) for virus liberation when singly infected in Fildes' synthetic medium no longer needs this substance when multiply infected. 2. In the absence of the AHPF under conditions of multiple infection the amount of phage released is approximately equal to the number of infecting particles between two to ten. Over ten particles per cell has no further effect on the yield of virus. 3. The experimental evidence indicates that it is the phage particle and not some other component in the lysate which can replace the AHPF. 4. The minimum latent period and rise period of cells singly infected in the presence of the AHPF and multiply infected in the absence of the AHPF are the same. 5. The desoxynucleic acid synthesis of cells, infected with a very few virus particles in the presence of excess AHPF and multiply infected with ten particles in the absence of the AHPF, occurs at approximately the same rate, with both infected samples synthesizing about the same amount of desoxynucleic acid and liberating the same yields of virus. 6. A strain of S. muscae which requires aspartic acid for virus synthesis when singly infected does not need this substance when multiply infected, the burst size under the latter conditions depending upon the multiplicity of infection between 3 to 12 particles per cell. 7. The data indicate that the virus released from multiply infected cells in the absence of added AHPF or aspartic acid is newly synthesized virus and not the original infecting particles. 8. The phage particle contains the AHPF and aspartic acid. 9. As a tentative working hypothesis, it is assumed that the AHPF and aspartic acid for phage formation under conditions of multiple infection, in the absence of added AHPF, or of aspartic acid, are contributed by the original infecting particles. 10. Ultraviolet-inactivated phage is adsorbed to the host cell and kills the cell although little virus is released under the experimental conditions. 11. Ultraviolet-inactivated phage particles, if added before the active particle is adsorbed, will greatly inhibit the liberation of new virus particles; but does not do so if added a few minutes after the active particle has been adsorbed. 12. Under the experimental conditions, reactivation of phage when present in multiply infected cells does not occur; and such ultraviolet-inactivated phage cannot serve as a source of the AHPF or aspartic acid, although the AHPF can be liberated from such inactivated particles by acid hydrolysis. 13. The results are discussed in relation to Luria's experiments with ultraviolet-treated phage and to his "gene pool" hypothesis of phage formation.     

Influenza virus ribonucleoprotein complexes gain preferential access to cellular export machinery through chromatin targeting

In contrast to most RNA viruses, influenza viruses replicate their genome in the nucleus of infected cells. As a result, newly-synthesized vRNA genomes, in the form of viral ribonucleoprotein complexes (vRNPs), must be exported to the cytoplasm for productive infection. To characterize the composition of vRNP export complexes and their interplay with the nucleus of infected cells, we affinity-purified tagged vRNPs from biochemically fractionated infected nuclei. After treatment of infected cells with leptomycin B, a potent inhibitor of Crm1-mediated export, we isolated vRNP export complexes which, unexpectedly, were tethered to the host-cell chromatin with very high affinity. At late time points of infection, the cellular export receptor Crm1 also accumulated at the same regions of the chromatin as vRNPs, which led to a decrease in the export of other nuclear Crm1 substrates from the nucleus. Interestingly, chromatin targeting of vRNP export complexes brought them into association with Rcc1, the Ran guanine exchange factor responsible for generating RanGTP and driving Crm1-dependent nuclear export. Thus, influenza viruses gain preferential access to newly-generated host cell export machinery by targeting vRNP export complexes at the sites of Ran regeneration.     

The relationship of polyoma virus-induced tumor (T) antigen to activation of DNA synthesis in rat myotubes

Rat myotubes infected with polyoma virus (PV) introduced into the multinucleated cells by virus-bearing myoblasts at the time of cell fusion incorporate ³H-TdR and exhibit mitotic-type figures. The infected myotubes also produce a viral-specific nuclear antigen, tumor (T) antigen, which appears in groups of adjacent nuclei or in all nuclei of the myotubes. The proportion of myotubes which synthesize DNA, T-antigen and exhibit mitotic-type figures is related to the multiplicity of virus infection.Intact myotubes which are resistant to infection with PV by virus absorption can be infected by microinjection of the virus into the cells. Myotubes thus infected produce T-antigen which appears in multiple nuclei, but do not incorporate ³H-TdR or contain mitotic-type figures. The data suggest that the resistance of myotubes to infection with PV might be due to a change in the cell surface membrane during differentiation so that virus cannot penetrate the cell. The T-antigen apparently has no bearing on the activation of the DNA-synthesizing apparatus in multinucleated muscle cells.     

Localization of viral-specific 21 kDa protein in nucleoli of herpes simplex infected cells

Viral-encoded 21 kDa protein has been localized in herpes simplex virus type 1 (HSV-1) infected cells by immunocytochemical techniques using peroxidase and colloidal gold as markers. During early infection, 21 kDa protein was shown to be in cytoplasmic areas rich in ribosomes located near the nucleus and in the viral DNA-containing fibrillo-granular material of the virus-specific electron-translucent region in the nucleus. Late in infection, an additional marked accumulation occurred in both fibrillar and granular components of the nucleolus. Host chromatin and the nuclear dense bodies remained unlabeled. No immunolabeling was obtained in the absence of DNA replication. In contrast, inhibition of RNA synthesis did not modify the distribution of the protein. On the other hand, persistence of cytoplasmic and nuclear immunolabeling following the inhibition of protein synthesis performed late in infection indicated that the distribution of 21 kDa protein represented, at least in part, sites of accumulation and retention of preexisting molecules.