Yaba tumor poxvirus synthesis in vitro. 3. Growth kinetics

Yohn, David S. (Roswell Park Memorial Institute, Buffalo, N.Y.), Victoria A. Haendiges, and Etienne de Harven. Yaba tumor poxvirus synthesis in vitro. III. Growth kinetics. J. Bacteriol. 91:1986-1991. 1966.-The infectious synthetic cycle of Yaba poxvirus by BSC-1 cells at 35 C is described and discussed together with related observations obtained by immunofluorescence and electron microscopy. After adsorption of virus at 25 C, at least 6 hr of incubation at 35 C was required before viral eclipse was demonstrable. Infectious progeny appeared after an additional 48 hr of incubation at 35 C. Newly synthesized virus particles were seen at 68 hr but not at 44 hr by electron microscopy. Maximal maturation occurred between 100 and 120 hr. Maximal yields were obtained from the 5th through the 8th day. The differences in kinetics between Yaba and vaccinia poxviruses, as described for the latter in the literature, are discussed. Possible factors accounting for these differences are enumerated.     

Yaba tumor poxvirus synthesis in vitro. I. Cytopathological, histochemical, and immunofluorescent studies

Yohn, David S. (Roswell Park Memorial Institute, Buffalo, N.Y.), Victoria A. Haendiges, and James T. Grace, Jr. Yaba tumor poxvirus synthesis in vitro. I. Cytopathological, histochemical, and immunofluorescent studies. J. Bacteriol. 91:1977-1985. 1966.-Yaba tumor poxvirus synthesis in BSC-1 cell culture was followed sequentially with light microscopy, immunofluorescent microscopy, and various histochemical stains. The first evidence of infection was detected at 24 hr when nucleoli became hypertrophic, reflecting enhanced ribonucleic acid (RNA) synthesis. At 36 hr, deoxyribonucleic acid synthesis was detected in the cytoplasm. This was immediately followed by or associated with antigen synthesis at paranuclear sites and enhanced RNA synthesis in the cytoplasm. Cytoplasmic inclusions were readily apparent at 4 days in initially infected cells. Contiguous spread of virus was judged to have occurred around the third day of infection. The time required to complete the synthetic cycle from time of infection to production of infectious progeny was estimated to be of the order of 60 hr. This cycle is 6 to 10 times longer than for vaccinia virus. By light microscopy, cytopathic effects (CPE) were detectable in 5 days in heavily infected cultures. With 100 units or less of infectious virus, CPE was not readily detected until the 10th to 14th day. At this time, focal areas of infection classified either as microtumors or microplaques were present. Secondary foci appeared during the 4th week of incubation.     

Growth Kinetics of Yaba Tumor Poxvirus After In Vitro Adaptation to Cercopithecus Kidney Cells

Yaba tumor poxvirus has been adapted to continuous in vitro cultivation in monolayers of cercopithecus kidney cells. At 35 C, the minimum replicative cycle, after synchronous infection of CV-1 cells with multiplicity of infection of 135 focusforming units per cell, was 35 hr; however, maximum virus yields were not obtained until 75 hr postinfection (PI). Cytoplasmic incorporation of (3)H-thymidine [viral deoxyribonucleic acid (DNA) synthesis] was detected 3 hr PI and was preceded by synthesis of nonstructural associated antigens (YS). Synthesis of YS antigens was not inhibited by the DNA inhibitor, arabinofuranosyl cytosine (ARA-C). Synthesis of at least two virion structural antigens, although not detected by immunofluorescence until 2 hr after the onset of DNA synthesis, occurred in the presence of ARA-C, indicating potential translation of these structural antigens from parental DNA. The first progeny DNA was completed by 20 hr PI but was not detected in infectious form until 35 hr PI. The maximum rate of progeny DNA completion occurred between 20 and 30 hr PI. DNA synthesis continued 45 to 50 hr PI. The adapted virus retained its oncogenicity and, like the wild type, replicated better at 35 C than at 37 C. A synthetic step associated with viral DNA synthesis appears to be temperature-sensitive.     

Inhibition of the Synthesis of Simian Virus 40 Antigens in Cells Preinfected with Yaba Tumor Virus

The synthesis of tumor and viral antigens after infection of an established line of cynomolgus monkey kidney cells with simian virus 40 (SV40) was compared in cells previously infected with Yaba virus and in cells not preinfected. SV40 failed to induce synthesis of tumor or viral antigens in cells preinfected with Yaba virus. The inhibitory state in preinfected cells was shown to develop sequentially. Increase in the rate of deoxyribonucleic acid synthesis in the nuclei of preinfected cells occurred after infection with SV40. This rate of increase was significantly lower than that which occurred in SV40-infected cells which had not been preinfected. Cytosine arabinoside did not exert significant effect on the development of the inhibitory effect against SV40 in Yaba virus-infected cells.     

A new plaque system for canine distemper: characteristics of the green strain of canine distemper virus.

A Vero cell adapted Green strain of canine distemper virus (CDV) was tested for its plaque-forming capacity in different cell lines. Plaque formation was observed in HEp-2, BS-C-1, and HeLa cells but not in Vero or dog kidney cells even though replication and cytopathology were observed in the latter cell types. In the cells in which the virus was capable of producing plaques, the plaques were observed within 24 h post infection and continued to increase in size with subsequent cellular destruction such that by 72 h postinfection the size of the plaques approached 0.5 mm. With the use of the plaquing technique, it was possible to demonstrate the thermal lability of the virus as well as the kinetics of adsorption. Thus, it was shown that the half-life of the virus was 125 min at 25 degrees C, 75 min at 35 degrees C, and 65 min at 37 degrees C. The rate of adsorption of CDV to HEp-2 cells was 17.2% in 30 min at 37 degrees C and continued slowly for 4 h before completion. Application of this rapid plaque-forming assay to plaque-reduction tests for CDV antibody and for CDV-infected cells by the infectious center assay are described.     

Comparative studies of host-cell reactivation, colony forming ability and excision repair after UV irradiation of xeroderma pigmentosum, normal human and some other mammalian cells

Host-cell reactivation, that is, the degree of survival of Herpes simplex virus after UV irradiation, was high in African green monkey BSC-1 cells, intermediate in normal human fibroblasts and human FL cells, and low in both xeroderma pigmentosum (XP) cells and mouse L cells. However, colony-forming ability after UV was high for FL, normal human fibroblasts and L cells, slightly low for BSC-1 cells and extremely low for XP cells. During the 24-h post-UV incubation period, up to about 50% of the thymine-containing dimers in the acid-insoluble DNA fraction disappeared at an almost equal rate for BSC-1, FL and normal human cells but remained unaltered for the XP cells. Alkaline sucrose gradient centrifugation of DNA after UV irradiation revealed only a slight difference between FL and BSC-1 cells in the kinetics of formation of single-strand breaks and their apparent repair. From these and the previously known characters of L cells possessing reduced excision-repair ability, if any, we may conclude that, if the survival of UV-irradiated Herpes simplex virus on a test line of human or other mammalian cells is as low as that on excisionless XP cells, then it is very probable that the test cell line is defective in excision repair. This reasoning leads to the presumptive conclusion that mouse L cells have an enhanced post-replication repair other than excision repair to deal with UV damage responsible for inactivation of colony-forming ability.     

Protection of Measles Virus by Sulfate Ions Against Thermal Inactivation.

Rapp, Fred (Baylor University College of Medicine, Houston, Tex.), Janet S. Butel, and Craig Wallis. Protection of measles virus by sulfate ions against thermal inactivation. J. Bacteriol. 90:132-135. 1965.-The infectivity of measles virus in water is rapidly destroyed at temperatures of 37 C and above. More than 50% of the infectivity is lost after 1 hr at 25 C, and almost 90% loss of infectivity occurs within 24 hr at 4 C. Magnesium chloride enhances the inactivation of the virus at all temperatures tested. Addition of either magnesium or sodium sulfate protects the virus against thermal inactivation. The stabilizing effect is demonstrable at temperatures ranging from 4 to 56 C, but is especially pronounced through 45 C. Prolonged storage (up to 6 weeks) of the virulent virus at 4 C in 1 m magnesium sulfate permits retention of substantial infectivity, whereas storage at 4 C in either water or 1 m magnesium chloride results in a loss of infectivity approximating 99% after 2 weeks. Magnesium chloride also enhances inactivation of the attenuated vaccine strain of measles virus. The attenuated virus, however, is strongly protected by magnesium sulfate against thermal inactivation, and retention of infectivity for long periods of time at 4 C seems feasible when the virus is kept in 1 m magnesium sulfate.     

Inhibition of simian virus 40 DNA synthesis in Yaba virus-preinfected cells.

The effect of Yaba virus preinfection on DNA synthesis in SV40-infected Jinet cells was studied. Time-course synthesis studies were conducted using the incorporation of labeled thymidine. Yaba virus preinfection resulted in the inhibition of SV40 DNA synthesis when the elapsed time between Yaba virus and SV40 infections was three days. This inhibition was demonstrated by hybridization studies and sedimentation analysis. In addition, the usual stimulation of cellular DNA synthesis induced by SV40 infection was inhibited. This inhibition occurred at a time in Yaba virus infection when no cytoplasmic Yaba virus-specific DNA synthesis occurred.     

Surface membrane redistribution and stabilization of concanavalin A-specific receptors following Yaba tumor poxvirus infection

Monkey kidney cells productively infected with Yaba tumor poxvirus clearly exhibit plasma membrane alterations when treated with both fluorescein-labeled and unlabeled concanavalin A. The convanavalin A-mediated cytoagglutination reaction for Yaba-infected Jinet and CV-1 cells increased linearly from 12 to 16 h post-infection, reaching a maximum by 24-28 h. Treatment of either Yaba-infected CVC-1 or Jinet cells with methyl-D-glucopyranoside before or after addition of concanavalin A completely blocked or reversed the cytoaglutination response. Trypsin treatment of uninfected CV-1 or Jinet cells enhanced concanavalin A-mediated cytoagglutination properties. Conversely, trypsin treatment of Yaba-infected Jinet cells resulted in a reduced cytoagglutination response. Increasing temperature and lectin concentration enhance concanavalin A-mediated cytoagglutination for uninfected, trypsin-treated and Yaba-infected CV-1 cells. Cytosine arabinoside has little or no effect on the Yaba-induced cell cytoagglutination reaction while cycloheximide blocks the cytoagglutinatin response if added prior to 12 h post-infection. Fluorescein-labeled concanavalin A binding studies have revealed that at 4 degrees C, Yaba-infected CV-1 cells display a predominantly 'patchy' pattern of topological fluorescence, while trypsin-treated and uninfected CV-1 cells at 4 degrees C display a uniform pattern of fluorescence binding. Patchy fluorescence, indicative of concanavalin A-suspeptible, receptor-site clustering on the surface membrane, was reduced 50% if Yaba-infected CV-1 cells were treated with glutaraldehyde (2.5%) before addition of fluorescein-labeled concanavalin A at 4 degrees C. Similar pre-fixatin of trypsin-treated CV-1 cells resulted in uniform, fluorescent labelling patterns at all assay temperatures.     

Activation of a Latent Measles Virus Infection in Hamster Cells

The characteristics of infectious measles virus released from latently infected hamster embryo fibroblast cells are described. Low levels of virus were released spontaneously when the cultures were incubated at 37 C; this phenomenon was observed 19 passages after the cells had been exposed to the virus and has continued through cell passage 45. The virus yield could be significantly increased by cocultivation of the hamster cells with BSC-1 cells or incubation of the latently infected cells at 33.5 C rather than at 37 C. Measles virus released after cocultivation demonstrated increased cytopathology in cell culture and reduced temperature sensitivity when compared to the virus released at 33.5 C. After cell passage 45, there was an increase in spontaneous release of virus. However, the viruses recovered by cocultivation or temperature release after cell passage 45 were nearly identical. These observations suggest a possible mechanism for measles virus activation in cells latently infected with this virus.     

Acclimation of photosystem II to high temperature in a suspension culture of soybean (Glycine max) cells requires proteins that are associated with the thylakoid membrane

In a study of the responses of photosystem II (PSII) to high temperature in suspension-cultured cells of soybean (Glycine max L. Merr.), we found that high temperatures inactivated PSII via two distinct pathways. Inactivation of PSII by moderately high temperatures, such as 41°C, was reversed upon transfer of cells to 25°C. The recovery of PSII required light, but not the synthesis of proteins de novo. By contrast, temperatures higher than 45°C inactivated PSII irreversibly. An increase in the growth temperature from 25 to 35°C resulted in an upward shift of 3°C in the profile of the heat-induced inactivation of PSII, which indicated that the thermal stability of PSII had been enhanced. This acclimative response was reflected by the properties of isolated thylakoid membranes: PSII in thylakoid membranes from cells that had been grown at 35°C exhibited greater thermal stability than that from cells grown at 25°C. Disruption of the vesicular structure of thylakoid membranes with 0.05% Triton X-100 decreased the thermal stability of PSII to a similar level in both types of thylakoid membrane. Proteins released by Triton X-100 from thylakoid membranes from cells grown at 35°C were able to increase the thermal stability of Triton-treated thylakoid membranes. These observations suggest that proteins that are associated with thylakoid membranes might be involved in the enhancement of the thermal stability of PSII.     

Titration and Extensive Serial Passages of Yaba Virus In Vitro

A sensitive assay system of Yaba virus (YV) was established in a cynomolgus monkey kidney cell line, JINET, in which the virus caused multilayered cellular foci countable even with the unaided eye. The specificity of the foci induced by YV in these cells was demonstrated by (1) the focus-forming ability was destroyed by heating at 60 C for 12 min; (2) the focus formation was inhibited by specific antiserum; (3) specific fluorescence was detected only in cells composing the foci when tested by fluorescent antibody technique; (4) a linear relationship was observed between the virus concentration and the number of foci formed; (5) YV preparation passed 20 times in JINET cells still possessed “tumorigenicity” in cynomolgus monkeys. The sensitivity of JINET cells to YV was comparable to that of cynomolgus monkeys, and YV was successively propagated in JINET cells with 2 log increase in infectivity titer during over 40 serial passages. Application of this assay system to growth kinetic studies of YV and quantitation of neutralizing antibody to YV is also discussed.     

Some Physiochemical Properties of Yaba Poxvirus Deoxyribonucleic Acid

Yaba tumor poxvirus deoxyribonucleic acid (DNA) has a density of 1.6905 in CsCl and its T(m) value in 0.015 m citrate in saline is 82.3. The guanine plus cytosine content estimated from these properties was taken to be 32.5 +/- 0.5%, a value 2 to 3% less than for DNA from other poxviruses reported to date.     

Complete genomic sequence and comparative analysis of the tumorigenic poxvirus Yaba monkey tumor virus

The Yatapoxvirus genus of poxviruses is comprised of Yaba monkey tumor virus (YMTV), Tanapox virus, and Yaba-like disease virus (YLDV), which all have the ability to infect primates, including humans. Unlike other poxviruses, YMTV induces formation of focalized histiocytomas upon infection. To gain a greater understanding of the Yatapoxvirus genus and the unique tumor formation properties of YMTV, we sequenced the 134,721-bp genome of YMTV. The genome of YMTV encodes at least 140 open reading frames, all of which are also found as orthologs in the closely related YLDV. However, 13 open reading frames found in YLDV are completely absent from YMTV. Common to both YLDV and YMTV are the unusually large noncoding regions between many open reading frames. To determine whether any of these noncoding regions might be functionally significant, we carried out a comparative analysis between the putative noncoding regions of YMTV and similar noncoding regions from other poxviruses. This approach identified three new gene poxvirus families, defined as orthologs of YMTV23.5L, YMTV28.5L, and YMTV120.5L, which are highly conserved in virtually all poxvirus species. Furthermore, the comparative analysis also revealed a 40-bp nucleotide sequence at approximately 14,700 bases from the left terminus that was 100% identical in the comparable intergene site within members of the Yatapoxvirus, Suipoxvirus, and Capripoxvirus genera and 95% conserved in the Leporipoxvirus genus. This conserved sequence was shown to function as a poxvirus late promoter element in transfected and infected cells, but other functions, such as an involvement in viral replication or packaging, cannot be excluded. Finally, we summarize the predicted immunomodulatory protein repertoire in the Yatapoxvirus genus as a whole.     

Deoxyribonucleic Acid Replication in Simian Virus 40-Infected Cells: III. Comparison of Simian Virus 40 Lytic Infection in Three Different Monkey Kidney Cell Lines

A comparative study of simian virus 40 (SV40) lytic infection in three different monkey cell lines is described. The results demonstrate that viral deoxyribonucleic acid (DNA) synthesis and infectious virus production begin some 10 to 20 hr earlier in CV-1 cells and primary African green monkey kidney (AGMK) cells than in BSC-1 cells. Induction of cellular DNA synthesis by SV40 was observed in CV-1 and AGMK cells but not with BSC-1 cells. Excision of large molecular weight cellular DNA to smaller fragments was easily detectable late in infection of AGMK cells. Little or no excision was observed at comparable times after infection of CV-1 and BSC-1 cells. The different kinds of responses of these three monkey cell lines during SV40 lytic infection suggest the involvement of cellular functions in the virus-directed induction of cellular DNA synthesis and the excision of this DNA from the genome.     

Effect of high temperature on the development of nuclear polyhedrosis virus in the silkworm,Bombyx mori

Effect of a high temperature on the development of nuclear polyhedrosis and nuclear polyhedrosis virus (NPV) was studied employing pupae and isolated pupal abdomens of the silkworm, Bombyx mori. It was shown that pupae inoculated with an NPV and incubated at 35°C survived longer than those incubated at 25°C. At lower dosages of virus, pupae at 35°C escaped death from NPV. When inoculated pupae were incubated at 35°C for varying periods and then transferred to 25°C, the longer the pupae had been kept at 35°C the longer they survived. In contrast, when inoculated pupae were transferred from 25° to 35°C, the longer the pupae had been kept at 25°C the sooner after inoculation they died. Essentially the same results were obtained in isolated abdomens which were in an arrested state of development, excluding the possibility that observed thermal inhibition of viral diseases is dependent upon the altered developmental processes at high temperatures. Virus titration experiments showed that, under experimental conditions utilized, no detectable accumulation of infectious NPV was present in abdomens inoculated with an NPV and incubated at 35°C. When inoculated abdomens were shifted up from 25° to 35°C at 3 days postinoculation, NPV accumulation was inhibited almost immediately, and when inoculated abdomens were shifted down from 35° to 25°C, infectious NPV started to accumulate as early as 1 day after the shift. It was also shown that the pattern of infectious NPV accumulation and that of nucleic acid increase in infected abdomens gave a rough correlation. These results indicate that the thermal inhibition of viral diseases is attributed, at least in part, to the restricted accumulation of infectious progeny and suggest that the virus replication mechanism itself is more sensitive to high temperatures than that related to other events necessary for viral replication to be initiated.     

Relationship between hemagglutinin stability and influenza virus persistence after exposure to low pH or supraphysiological heating

The hemagglutinin (HA) surface glycoprotein is triggered by endosomal low pH to cause membrane fusion during influenza A virus (IAV) entry yet must remain sufficiently stable to avoid premature activation during virion transit between cells and hosts. HA activation pH and/or virion inactivation pH values less than pH 5.6 are thought to be required for IAV airborne transmissibility and human pandemic potential. To enable higher-throughput screening of emerging IAV strains for “humanized” stability, we developed a luciferase reporter assay that measures the threshold pH at which IAVs are inactivated. The reporter assay yielded results similar to TCID50 assay yet required one-fourth the time and one-tenth the virus. For four A/TN/09 (H1N1) HA mutants and 73 IAVs of varying subtype, virion inactivation pH was compared to HA activation pH and the rate of inactivation during 55°C heating. HA stability values correlated highly with virion acid and thermal stability values for isogenic viruses containing HA point mutations. HA stability also correlated with virion acid stability for human isolates but did not correlate with thermal stability at 55°C, raising doubt in the use of supraphysiological heating assays. Some animal isolates had virion inactivation pH values lower than HA activation pH, suggesting factors beyond HA stability can modulate virion stability. The coupling of HA activation pH and virion inactivation pH, and at a value below 5.6, was associated with human adaptation. This suggests that both virologic properties should be considered in risk assessment algorithms for pandemic potential.     

Composting for avian influenza virus elimination

Effective sanitization is important in viral epizootic outbreaks to avoid further spread of the pathogen. This study examined thermal inactivation as a sanitizing treatment for manure inoculated with highly pathogenic avian influenza virus H7N1 and bacteriophages MS2 and 6. Rapid inactivation of highly pathogenic avian influenza virus H7N1 was achieved at both mesophilic (35°C) and thermophilic (45 and 55°C) temperatures. Similar inactivation rates were observed for bacteriophage 6, while bacteriophage MS2 proved too thermoresistant to be considered a valuable indicator organism for avian influenza virus during thermal treatments. Guidelines for treatment of litter in the event of emergency composting can be formulated based on the inactivation rates obtained in the study.     

Recurring defective variants of simian virus 40 containing monkey DNA segments.

Four independently and newly isolated defective variants of simian virus 40 have been characterized. All four are very similar, if not identical, to two previously and independently isolated variants (Wakamiya et al., J. Biol. Chem. 254:3584-3591, 1979; J. Papamatheakis, E. Kuff, E. Winocour, and M. F. Singer, J. Biol. Chem. 255:8919-8927, 1980). The documented similarities include restriction endonuclease maps and the presence of the same monkey DNA segments covalently linked to simian virus 40 DNA sequences. Each of the newly described variants was first detected upon serial passaging of wild-type simian virus 40 at a high multiplicity of infection at 33 degrees C as recently described (M. F. Singer and R. E. Thayer, J. Virol. 35:141-149, 1980). A variety of experiments support the idea that the various isolates were independent and do not reflect inadvertent cross-contamination. Two of the new isolates arose during passage of wild-type strain 777 virus in BSC-1 cells, one during passage of strain 776 in BSC-1 cells, and one during passage of strain 776 in primary African green monkey kidney cells. The two variants obtained after passage of strain 776 were shown to contain a particular recognition site for restriction endonuclease MboII within their simian virus 40 DNA segments, as do the two previous isolates. This site is not present in wild-type strain 776 DNA but is shown here to be present in wild-type strain 777 DNA. The surprising recurrence of closely related variants and particularly the unexpected presence of the endo R.MboII site in variants derived from passaging strain 776 suggest that these variants may arise by mechanisms other than recombination between the initial infecting viral genome and the host DNA.     

Latency of Human Measles Virus in Hamster Cells

A latent system employing measles virus (Schwarz strain) was developed in hamster embryo fibroblasts (HEF). Measles virus-specific antigen was detected by immunofluorescence in 30 to 50% of HEF cells, and these cells released infectious virus when co-cultivated with a susceptible monkey cell line, BSC-1 cells. No infectious virus could be detected in the cells when measures were taken to exclude passage of viable latent cells onto the indicator BSC-1 cells. Infectious center assays demonstrated that about 1 in 10 of the latently infected cells in the population could release infectious virus. Infectious virus appeared within 6 hr after co-cultivation of the HEF cells with BSC-1 cells, as compared to 24 hr required for normal replication of measles virus in the BSC-1 cells. Furthermore, labeling of progeny virus ribonucleic acid (RNA) by using tritiated uridine, and inhibition of RNA or protein synthesis by 5-azacytidine or cycloheximide suggested that neither additional RNA nor protein synthesis is required after co-cultivation of the cells to effect early virus release. It can therefore be postulated that there is a block at a late step in virus replication in the latently infected hamster cells. The most obvious site would concern maturation of infectious virions at the cell membrane.