[Oncogen localization in simian adenovirus DNA. I. In vitro rat cell transformation using the SV20 virus and its DNA]

Cell transformation by the complete and the incomplete virus SV20 was investigated. To compare the oncogenic properties of human adenoviruses, two types of cell systems--the primary rat embryonic cell culture and the primary rat kidney cell culture--were used. The dependence of DNA concentration on transformation frequency was investigated. With the incomplete virus SV20, the transformation efficiency was more than that with the complete virus (16 and 1-3 percent, resp.). In addition, it has been shown that the primary rat kidney cell culture is more sensitive to transformation than the primary rat embryonic cells culture. The new-born Sirian hamsters being inoculated with virus SV20 DNA, the growth of a tumor being registered in the point of injection 120 days afterwards.

[Acute and chronic Lassa virus infection of Vero cells]

Acute and persistent infections of Vero cells with a cloned Lassa virus were studied. After acute infection at a multiplicity of 2 PFU/cell the latent period was 12-16 hrs and the maximum yield of virus particles in the growth medium was obtained 28-32 hours postinfection. A persistently infected cell line was established by inoculating Vero cells with the cloned Lassa virus followed by subcultivation of the infected cells. The infected cells underwent 36 passages. Lassa virus production by the infected cells followed a cyclic pattern varying from 10(2) to 10(5) PFU/ml. Neither the plating efficiency of the virus nor its growth curves changes at 35 degrees C and 39 degrees C. The replication of the cloned virus in infected cells (superinfection) was markedly depressed in comparison to that of normal Vero cells infected with Lassa virus. The role of defective interfering particles in the establishment of persistent infection is discussed.

Target cell specificity of defective avian leukemia viruses: hematopoietic target cells for a given virus type can be infected but not transformed by strains of a different type

Defective avian leukemia viruses of the avian erythroblastosis (AEV), avian myelocytomatosis (MC29), and avian myeloblastosis (AMV) type induce the proliferation of leukemic cells with properties of erythroblasts, macrophages, and myeloblasts, respectively. Their target cells can be separated and have properties of cells of the erythroid (AEV) and myeloid lineage (MC29 and AMV), respectively. In the present study we have shown that this target cell specificity is not due to the ability of the different strains to infect only certain types of hematopoietic cells. Instead, AEV was found to replicate in macrophages and to induce the expression of p75 AEV, its presumptive transforming protein. Likewise, MC29 was found to replicate in AEV-infected erythroblasts as well as in AMV-infected myeloblasts and to express the p110 MC29 protein in these cells. Superinfection with MC29 or AMV of ts34 AEV-infected erythroblasts did not impair their capacity to accumulate hemoglobin after shift to nonpermissive temperature. Our results support a model in which the transforming proteins of AEV, MC29, and MAV block the differentiation of their target cells by competitively inhibiting the action of a hypothetical homologous cellular differentiation protein synthesized in the corresponding target cells only.

[Interrelationships between the interfering capacity of an "incomplete" virus and its infectivity]

A comparative analysis of UV inactivation curves of the interfering activity of "incomplete" influenza virus and infectivity showed certain differences in the structures responsible for these functions. All the data exclude the role of virus protein and virus-induced interferon of "incomplete" influenza virus and suggest that RNA is responsible for this interference. The size of the "target" of the "incomplete" virus interfering capacity calculated on the basis of sensitivity to UV-light is approximately 40 times as small as that of the "target" responsible for infectivity. The analogous pattern of UV inactivation in the standard influenza virus and the so-called Magnus virus suggests that in the latter the infectivity is due to the presence of complete virions in the preparation.

Persistence and pathogenicity of defective Friend spleen focus-forming virus. Decreased transplantability of hemopoietic cells as a marker for preleukemic change

A latent form of persistent infection can be established in susceptible adult mice inoculated with a preparation of defective Friend spleen focus-forming virus (SFFV) purified free from standard leukemia-inducing helper virus (LLV-F). SFFV persistence was initially observed using an in vivo rescue technique in which SFFV could be directly rescued to form splenic foci of malignant erythropoiesis in mice. At approximately 30 d after virus inoculation however, SFFV could not be rescued after inoculation of LLV-F indicating that persistently infected (i.e., SFFV+) mice were either immume to exogenous helper virus or able to express SFFV-associated defective-interfering (DI) function(s). Persistent infection by SFFV was further documented using an in vitro rescue technique and ultimately resulted in the induction by SFFV of erythroleukemia in the absence of polycythemia or overt virus production. However, SFFV rescued by LLV-F from persistently infected normal and transformed hemopoietic cells was able to induce polycythemia in adult mice suggesting that this is a helper controlled property of the Friend virus complex. Transplantable SFFV-induced erythroleukemic cells could be retrieved from persistently infected yet histologically normal mice. The duration of SFFV persistence in normal spleen tissue suggests that the SFFV provirus resides in either a long-lived or pluripotent hemopoietic cell. Further, certain changes occurred, presumably in the membranes of persistently infected cells, which preceded the overt development of Friend leukemia and facilitated the definition of an SFFV preleukemic phase. Cell surface alterations were revealed using cell transfer techniques. Hemopoietic cells harboring a rescuable SFFV failed to proliferate when inoculated into lethally irradiated, syngeneic adult mice. In contrast, the transformed progeny of preleukemic cell populations and spleen cells transformed by FV complex (i.e., cells replicating both SFFV and LLV-F) were not rejected. This result suggests that histologically normal SFFV+ preleukemic cells express an antigen recognition site which is not present on overtly transformed cells and which may be a pertinent surveillance target for host anti-leukemogenic reactions.

The effect of helper virus on Abelson virus-induced transformation of lymphoid cells

Abelson murine leukemia virus (A-MuLV)-transformed fibroblast nonproducer cells were used to prepare A-MuLV stocks containing a number of different helper viruses. The oncogenicity of the A-MuLV stocks was tested by animal inoculation and their ability to transform normal mouse bone marrow cells was measured in vitro. All of the A-MuLV stocks transformed fibroblast cells efficiently. However, only A-MuLV stocks prepared with helper viruses that are highly oncogenic were efficient in vivo and in vitro in hematopoietic cell transformation. In addition, inefficient helpers did not establish a stable infection in lymphoid nonproducer cells. Thus, helper virus has a more central role in lymphoid cell transformation than in fibroblast cell transformation.

[Experimental influenza caused by an incomplete form of the agent]

Incomplete form of the influenza virus obtained in accordance with Nayak's method was administered intranasally to mice CBA and C57BL. From the lung tissue of the infected mice the causative agent could be isolated for 45 days, and from the other internal organs--the first hours after the infection only. In morphological investigation of the lungs of animals infected with an incomplete form of the influenza virus a prevalence of the proliferative component against the background of inflammatory changes was noted. Three months after the infection limited lymphoid formations consisting of monomorphic cells with hyperchromic nuclei were defined in the lung tissue. Marked proliferation of the alveolar and bronchial epithelium was observed later; considerable anaplasia of the cells was noted in the papillomatous structure of the alveolar and bronchial epithelium. Glomangioma of the mesentery was observed among affections of other internal organs in 18.7% of mice CBA.

Effect of pseudotype on Abelson virus and Kirsten sarcoma virus-induced leukemia

Nonproducer cells transformed by Kirsten sarcoma virus (KiSV) or Abelson murine leukemia virus (A-MuLV) were infected with N- or NB-tropic helper viruses to rescue the defective transforming virus. The titer of the transforming viruses was determined on NIH/3T3 fibroblast-like cells and cell-free filtrates of virus stock were inoculated into newborn Fv-1nn mice. Friend, Moloney, and Rauscher group of MuLV (FMR) pseudotypes of KiSV induced an erythroid leukemia efficiently, while an endogenous helper (N35-MuLV) pseudotype of KiSV did not. FMR pseudotypes of A-MuLV induced the Abelson lymphoid leukemia, while the N35-MuLV or a Kirsten leukemia virus (Ki-MuLV) pseudotype did not. Pseudotypes of A-MuLV were used to infect bone marrow cells of Fv-1nn mice in vitro. The FMR pseudotypes transformed bone marrow cells at 40-100-fold higher frequency than the N35-MuLV or Ki-MuLV pseudotypes. Mixing experiments demonstrated that the addition of an effective helper, such as M-MuLV did not enhance lymphoid transformation by ineffective A-MuLV (N35-MuLV). The A-MuLV genome is responsible for hematopoietic cell transformation because a nonproducer clone of lymphoid cells, free of helper virus, was isolated. The data indicates that the pseudotype of A-MuLV determines its ability to transform hematopoietic cells.

Isolation and characterization of a defective measles virus from brain biopsies of three patients in Iran with subacute sclerosing panencephalitis

Three cytopathic strains of subacute sclerosing panencephalitis (SSPE) virus were isolated from brain biopsies of three patients. These strains were isolated and maintained by cocultivation of infected brain cells with fresh Vero cells. The biological characteristics of two strains were studied. It was found that these strains remain cell-associated after repeated cocultivations with Vero cells and produce plaques under fluid medium or tragacanth overlay. The correlation with measles virus was demonstrated by the plaque reduction test as well as by the immunofluorescence test. Large numbers of nucleocapsids were observed in the cytoplasm of infected cells but none in nuclei. Intracerebral inoculation of monkeys, adult guinea pigs, newborn and adult hamsters or mice was followed by acute encephalitis and death.

[Abortive myxovirus infection in Ehrlich's ascitic carcinoma cells. Further study of the nature of the virus-specific structures produced by heterokaryons]

Fowl plague virus-infected cells of Ehrlich ascitic carcinoma produce a noninfectious virus which is defective in fragility of its membranes. An attempt has been made to produce nondefective virus by fusion of infected Ehrlich cells with permissive cells: infected and non-infected chicken fibroblasts. The fusion of FPV-infected and 3H-uridine labeled Ehrlich ascitic carcinoma cells with infected unlabeled chicken fibroblasts using inactivated Sendai virus resulted in production of two types of labeled virus particles: with a buoyant density in cesium chloride gradient of 1.29 g/cm3 characteristic of particles produced by infected Ehrlich cells and buoyant density 1.22 g/cm3 typical of standard influenza virus. Both types of particles has infectious activity which was greater in the virus with the density of 1.22 g/cm3. However, particles with the density of 1.22 g/cm3 are not found upon the fusion of infected Ehrlich cells with uninfected chicken fibroblasts, with chicken fibroblasts early after infection, or with chicken fibroblasts treated with actinomycin D before infection. Infected chicken fibroblasts in hybrids were shown not to use the radioactive pool of Ehrlich cells and, accordingly, the virus with the density of 1.22 g/cm3 if formed from components pre-existing in Ehrlich cells. It is suggested that the standard virus buds on the areas of membranes of permissive cells which are parts of the hybrids.

Induction and biological properties of defective interfering particles of rabies virus

A method for obtaining large quantities of defective interfering (DI) rabies virus particles that fulfill all the criteria delineated by Huang and Baltimore (1970) is described. The purified rabies DI virion was found to be much shorter (60 to 80 nm) than the complete virion (180 nm) and to have a viral genome of about half the size of normal rabies RNA but with all of the structural proteins of standard virions. Rabies DI virions were noninfectious for both cells in culture and for animals. As determined by in vitro and in vivo techniques, interference with the replication of standard virus was specific to rabies virus. The possible role of rabies DI virion in the pathogenicity of rabies virus infection and in the establishment of attenuated strains for use as live rabies vaccines is discussed.

Acute encephalopathy caused by defective virus infection. I. Studies of Newcastle disease virus infections in newborn and adult mice

An acute encephalopathy caused by a defective paramyxovirus infection was studied. Newcastle disease virus (ndv), given intracerebrally, caused neurologic disease and death in mice. Infected newborn mice died by the fourth day after inoculation, and abundant amounts of virus were recovered from their brains. Infected 4-week-old mice died by the eighth day, but only minimal amounts of virus, if any, were recovered. The brains of many moribund 4-week-old mice were histologically normal and contained no NDV antigen on fluorescent antibody staining. No serum antibody to NDV was detected. These features make this infection difficult to distinguish from a metabolic encephalopathy.

Transcriptase activity and genome composition of defective influenza virus

Eight genome RNA segments are present in both normal and von Magnustype influenza virus preparations and all species are transcribed by the virion-associated polymerase. Although the RNA polymerase activity and the amount of the three largest RNA segments are reduced in defective influenza virus preparations, these reductions do not appear to be great enough to account for the much greater loss of infectivity.

[Heterogeneity of an influenza virus population in the manifestation of biological functions (author's transl)]

In a population of influenza virus, virions have different degree of the functional capacities to produce infectious virus, to induce neuraminidase production and to interfere with infectious virus. Fractions of virus were found which had a poor capacity for production of infectious progeny and a relatively high induction of neuraminidase synthesis as well as induction of heterogenous light fractions of RNA in cells. In the population of defective virus a fraction of particles possessing marked interfering activity in the absence of infectivity was found.

Transformation potentials of the noninfectious (defective) component in pools of adenoviruses type 12 and simian adenovirus 7

Pools of adenovirus 12 and simian adenovirus 7 were separated into four or five fractions by density gradient centrifugation in cesium chloride. Each fraction was analyzed for total in vitro infectivity units, total transformation activity, and for total virus particle (VP) content. Two major subpopulations were separated with mean densities of 1.30 +/- 0.02 and 1.34 +/- 0.02 g/ml, respectively. Virions in the 1.34 g/ml range were highly infectious (10(2) to 10(3) VP per infectivity unit) in contrast to virions at 1.30 g/ml density (10(4) to 10(5) VP per infectivity units). Transformation capacity was evenly distributed throughout fractions of both viruses, indicating that genetically incomplete or defective virus particles were not deficient in their ability to induce transformation. The average VP per transformation unit for adenovirus 12 (2.85 x 10(6)) and for simian adenovirus 7 (4.00 x 10(6)) did not vary significantly from fraction to fraction. These values were obtained with optimal input multiplicities of 16 to 64 VP per cell. At higher multiplicities the apparent increase in VP per transformation unit was attributable to the viral cytocidal effect on hamster cells. These studies revealed that quantitation of in vitro transformation based on VP multiplicities was more reliable than on the basis of infectious units. These estimates were independent of method of virus production, extraction, and purification.

Studies of hamster cells transformed by adenovirus 2 and the nondefective Ad2-SV40 hybrids

Adenovirus 2 does not produce tumors when injected into newborn hamsters, and this failure is not corrected by the acquisition of the portion of the SV40 genome present in any of the nondefective Ad2-SV40 hybrid viruses. However, nonhybrid Ad2 will transform hamster cells in vitro, and these transformed cells will produce tumors when injected into newborn hamsters. This finding, taken in conjunction with other studies (Graham et al., this volume; McAllister et al., 1969; McDougall et al., this volume; Williams 1973), suggests that the categorization of Ad2 and Ad5 as "nononcogenic" viruses is a reflection of host response rather than an intrinsic property of the viruses. However, transformation of hamster cells by Ad2 is inefficient, requiring 10(7)-10(8) PFU to produce a focus of transformed cells. Transformation of hamster kidney cells by the nondefective hybrids cannot be associated with portions of the SV40 genome. During the transformation process, complex interactions must occur between the hamster cell genome and the viral genome of Ad2 or the nondefective hybrids. Thus while it appears that there is very little Ad2 DNA in one nonhybrid Ad2-transformed cell line, there is a larger amount of Ad2 DNA in all of the hybrid virus-transformed cell lines. Moreover, while one Ad2+ND2-transformed line has apparently lost the SV40 portion of the viral genome, it is present and transcribed in another line transformed by the same virus. Finally, in the lines of nondefective hybrid-transformed cells examined thus far, there is extensive transcription from the Ad2 H strand. This pattern of transcription differs from transcription of the viral genome in most hybrid Ad2-transformed hamster and rat cells in which L-strand transcripion predominates.

Murine sarcoma virus: the question of defectiveness

Infection of mouse and rat cells by the murine sarcoma virus (Moloney isolate) showed two-hit kinetics for focus production in mouse cells but one-hit kinetics in rat cells. Antiserum added to cultures after infection suppressed focus formation in mouse cells but not in rat cells. These studies suggest that, in rat cells infected with murine sarcoma virus, leukemina virus is not needed for focus formation and that these foci result from proliferation of the transformed rat cell; in mouse cells, on the other hand, leukemia virus is needed as "helper," and focus formation requires spread of virus. The term "defectiveness" then, if used, should not be applied to RNA tumor viruses without qualification for the viral function studied and the cell system employed.