Virus DNA replication and protein synthesis in Amsacta moorei entomopoxvirus-infected Estigmene acrea cells

Amsacta moorei entomopoxvirus DNA synthesis was detected in Estigmene acrea cells by [³H]thymidine incorporation 12 hr after virus inoculation. Hybridization of ³²P-labeled Amsacta entomopoxvirus DNA to the DNA from virus-infected cells indicated that viral-specific DNA synthesis was initiated between 6 and 12 hr after virus inoculation. A rapid increase in the rate of virus DNA synthesis was detected from 12 to 24 hr after virus inoculation. Amsacta entomopoxvirus protein biosynthesis in E. acrea cells was studied by [su35S]methionine incorporation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Extracellular virus and virus-containing occlusion bodies were first detected in virus-infected cell cultures 18 hr after virus inoculation. Thirty-seven virus structural proteins, ranging in molecular weight from 13,000 to 208,000 were detected in both occluded and nonoccluded forms of the virus. The biosynthesis of virus structural proteins increased rapidly from 18 to 34 hr after infection. A major viral-induced protein corresponding in molecular weight to viral occlusion body protein (110,000) was detected approximately 24 hr after virus inoculation.     

The binding of o-aminoazotoluene to deoxyribonucleic acid, ribonucleic acid and protein in the C57 mouse

1. (3)H-labelled o-aminoazotoluene was synthesized from [G-(3)H]o-toluidine on a semi-micro scale. 2. An association of (3)H with DNA, RNA and protein from the liver, kidney and spleen of female C57b mice was demonstrated after the administration of a single dose of [(3)H]o-aminoazotoluene. 3. This association is judged to represent covalent binding as a result of experiments involving solvent extraction, examination of the acid hydrolysates of the DNA and RNA and administration of [(3)H]water with unlabelled o-aminoazotoluene. 4. Examination of the extents of binding at various times after the administration of a single dose of [(3)H]o-aminoazotoluene showed that there was a peak of binding to liver DNA in the female mice at about 16hr. that was not present in the male mice. 5. The extent of binding to DNA, RNA and protein at 16hr. in the female C57b mouse liver was greater than that in the spleen and kidney.     

Effects of [3H]UdR on the cell-cycle progression of L1210 cells

Tritium-labelled uridine [( 3H]UdR) perturbs progression of L1210 cells through the mitotic cycle. The main effect manifests as a slowdown or arrest of a portion of cells in G2 and is already observed 2 hr after addition of 0.5-5.0 microCi/ml of [3H]UdR into cultures. At 2.5-5.0 microCi/ml of [3H]UdR a slowdown of cell progression through S is also apparent. Additionally, there is an increase in the number of cells with DNA values higher than 4C in cultures growing in the presence of [3H]UdR for 8-24 hr. A pulse of [3H]UdR of 2 hr duration labels predominantly (95%) cellular RNA. The first cell-cycle effects (G2 slowdown) are observed when the amount of the incorporated [3H]UdR is such that, on average there are fewer than thirty-six [3H] decays per cell which corresponds to approximately 12-19 rads of radiation. The S-phase slowdown is seen at a dose of incorporated [3H]UdR twice as high as that inducing G2 effects. The specific localization of [3H]UdR in nucleoli, peripheral nucleoplasm and in cytoplasm, as well as differences in the kinetics of the incorporation in relation to phases of the cell cycle are discussed in the light of the differences between the effects of [3H]UdR and [3H]thymidine. Mathematical modelling of the cell-cycle effects of [3H]UdR is provided.     

Induction of Cellular Deoxyribonuleic Acid Synthesis by Simian Virus 40

The incorporation of (3)H-thymidine ((3)H-dT) into deoxyribonucleic acid (DNA) has been studied in uninfected confluent monolayer cultures of monkey kidney and mouse kidney cells, simian virus 40 (SV40)-infected cells, and in SV40-transformed mouse kidney cells. Radioautographic measurements revealed that during the period from 28 to 51 hr after productive SV40 infection of monkey kidney cultures about 80% of the cells synthesized DNA, compared to about 16% in uninfected cultures. At 28 to 43 hr after abortive SV40 infection of mouse kidney cultures, 24 to 37% of the cells synthesized DNA, compared to about 6 to 8% in uninfected cultures. The infected monkey kidney and mouse kidney cultures, respectively, incorporated about 5 to 10 times and 3 to 5 times as much (3)H-dT into DNA as did uninfected cultures. Moreover, the net DNA synthesized by SV40-infected monkey kidney cultures, estimated by colorimetric methods, substantially exceeded that of uninfected cultures.Nitrocellulose chromatography and band centrifugation experiments were performed to elucidate the kinds of DNA synthesized in the cultures. In uninfected monkey kidney cultures and at 2 to 12 hr after SV40 infection, almost all of the (3)H-dT labeled DNA sedimented more rapidly than SV40 DNA, and the radioactive DNA was denatured by heating for 12 min at 100 C (cellular DNA). Almost all of the labeled DNA obtained from abortively infected mouse kidney cultures and from SV40-transformed cells also had the properties of cellular DNA. However, approximately one-third to one-half of the labeled DNA obtained from monkey kidney cultures 28 to 51 hr after infection sedimented more slowly than cellular DNA and was not denatured by the heating (SV40 DNA). It is concluded that cellular DNA synthesis was induced during either the productive or abortive SV40 infections.     

Growth Characteristics of Kilham Rat Virus and Its Effect on Cellular Macromolecular Synthesis

Kilham rat virus (KRV) is adsorbed into the rat nephroma cell within 1 hr after infection. There follows a latent period of about 12 hr during which less than 1% of the input infectious virus can be accounted for. New infectious virions can be detected at about 12 hr and the maximal yield of virus is attained by 23 hr after infection. The increase in final virus yield is about 200-fold over that found in the latent period. During this 23-hr period of virus growth, the rate of protein synthesis remains 75 to 100% of that in the uninfected cell. Ribonucleic acid (RNA) synthesis during this period is maintained at 100 to 150% of that found in the control cells. The addition of the inhibitor of deoxyribonucleic acid (DNA) synthesis, 5-fluoro-deoxyuridine (FUDR), up to 8 hr after infection completely suppresses virus production. After 8 hr, viral DNA production has started and FUDR inhibition progressively decreases until by 23 hr the addition of the inhibitor no longer causes a reduced virus yield. Viral DNA synthesis once initiated is required for the remainder of the 23-hr virus cycle. Viral DNA synthesis probably begins about 4 hr before the production of infectious virions. In the KRV-infected cells, DNA synthesis decreased sharply for 6 to 7 hr after infection in comparison to the uninfected cell. At 7 to 8 hr after infection, DNA synthesis in the infected cell increased and was maintained at a higher level than in the control cells for the rest of the virus growth period.     

Cytofluorometry of lymphocytes infected with Epstein-Barr virus: effect of phosphonoacetic acid on nucleic acid.

DNA synthesis in Epstein-Barr virus (EBV)-infected lymphocytes was inhibited by phosphonoacetic acid (PAA) as measured by [3H]thymidine incorporation. PAA, at a concentration of 200 microgram/ml, inhibited [3H]thymidine incorporation by human umbilical cord lymphocytes infected with EBV strain P94 but had little effect on DNA synthesis in mitogen-stimulated cells. Transformed cell lines did not develop from infected cord cell cultures treated with 100 microgram of PAA per ml. Cytofluorometric analysis showed marked increases in cellular nucleic acid content (RNA plus DNA) as early as 9 days after infection of cord cells in the absence of PAA and before significant enhancement of [3H]thymidine incorporation became apparent. Moreover, EBV led to increases in cellular nucleic acid even when 200 microgram of PAA per ml was added to cell cultures before infection. The apparent discrepancy between results obtained by [3H]thymidine incorporation and cytofluorometry is explained either by significant inhibition of cellular DNA polymerases by PAA or by a block at the G2 + M phase of the cell cycle. The data suggest that EBV initiates alterations in cellular nucleic acid synthesis or cell division without prior replication of viral DNA by virus-induced DNA polymerases.     

Incorporation of Iododeoxyuridine into Cellular Deoxyribonucleic Acid Synthesized After Infection with Simian Virus 40

Primary monkey kidney cells (Cerocpithecus aethiops) in the stationary phase of growth were labeled with (14)C-thymidine for 24 hr prior to infection with simian virus 40 (strain 777). (3)H-deoxyadenosine and 5-iodo-2'-deoxyuridine (IUdR) were added to some of the cultures 24, 48, or 72 hr after infection; 24 hr later the deoxyribonucleic acid (DNA) was extracted from these cultures and centrifuged in a CsCl density gradient. The portion of DNA which had become heavier because of incorporation of IUdR could be seen as a second peak in the sedimentation profile. This peak contained (14)C as well as (3)H activity. The possibility that the (14)C-labeled cellular DNA might be degraded and used for the synthesis of viral DNA could be excluded. On the basis of these results, it must be assumed that the infection of monkey kidney cells with simian virus 40 induces the synthesis of cellular DNA.     

Simian Virus 40 Deoxyribonucleic Acid Replication: I. Effect of Cycloheximide on the Replication of SV40 Deoxyribonucleic Acid in Monkey Kidney Cells and in Heterokaryons of SV40-transformed and Susceptible Cells

Infectious deoxyribonucleic acid (DNA) was extracted from green monkey kidney (CV-1) cultures at various times after the cultures were infected with simian virus 40 (SV40) at input multiplicities of 0.01 and 0.1 plaque-forming unit (PFU) per cell. A pronounced decrease in infectious DNA was observed from 3 to 16 hr after virus infection, suggesting that structurally altered intracellular forms may have been generated early in infection. Evidence is also presented that SV40 DNA synthesis requires concurrent protein synthesis. DNA replication was studied in the presence and absence of cycloheximide in: (i) SV40-infected and uninfected cultures of CV-1 cells; (ii) cultures synchronized with 1-β-d-arabinofuranosylcytosine (ara-C) for 24 to 30 hr prior to the addition of cycloheximide; and (iii) in heterokaryons of SV40-transformed hamster and susceptible monkey kidney cells. DNA synthesis was determined by pulse-labeling the cultures with ³H-thymidine at various times from 24 to 46 hr after infection. In addition, the total infectious SV40 DNA was measured. Addition of cycloheximide, even after early proteins had been induced, grossly inhibited both SV40 and cellular DNA syntheses. The activities of thymidine kinase, DNA polymerase, deoxycytidylate deaminase, and thymidylate kinase were measured; these enzyme activities remained high for at least 9 hr in the presence of cycloheximide. SV40 DNA prelabeled with ³H-thymidine before the addition of cycloheximide was also relatively stable during the time required for cycloheximide to inhibit further DNA replication.     

Arginine deprivation in KB cells: I. Effect on cell cycle progress

When exponentially growing KB cells were deprived of arginine, cell multiplication ceased after 12 h but viability was maintained throughout the experimental period (42-48 h). Although tritiated thymidine ([(3)H]TdR) incorporation into acid-insoluble material declined to 5 percent of the initial rate, the fraction of cells engaged in DNA synthesis, determined by autoradiography, remained constant throughout the starvation period and approximately equal to the synthesizing fraction in exponentially growing controls (40 percent). Continous [(3)H]TdR-labeling indicated that 80 percent of the arginine-starved cells incorporated (3)H at some time during a 48-h deprivation period. Thus, some cells ceased DNA synthesis, whereas some initially nonsynthesizing cells initiated DNA synthesis during starvation. Flow microfluorometric profiles of distribution of cellular DNA contents at the end of the starvation period indicated that essentially no cells had a 4c or G2 complement. If arginine was restored after 30 h of starvation, cultures resumed active, largely asynchronous division after a 16-h lag. Autoradiographs of metaphase figures from cultures continuously labeled with [(3)H]TdR after restoration indicated that all cells in the culture underwent DNA synthesis before dividing. It was concluded that the majority of cells in arginine-starved cultures are arrested in neither a normal G1 nor G2. It is proposed that for an exponential culture, i.e. from most positions in the cell cycle, inhibition of cell growth after arginine with withdrawal centers on the ability of cells to complete replication of their DNA.     

Deoxyribonucleic Acid Synthesis in Synchronized Mammalian KB Cells Infected with Herpes Simplex Virus

We examined the patterns of host cell and virus deoxyribonucleic acid (DNA) synthesis in synchronized cultures of KB cells infected at different stages of the cell cycle with herpes simplex virus (HSV). We found that the initiation of HSV DNA synthesis, we well as the production of new infectious virus, is independent of the S, G1, and G2 phases of the mitotic cycle of the host cell. This is in contrast to data previously found with equine abortion virus. Because HSV replicates independently of the cell cycle, we were able to establish conditions that would permit the study of rates of HSV DNA synthesized in logarithmically growing cells in the virtual absence of cellular DNA synthesis. This eliminates the need for separation of viral and cellular DNA by isopycnic centrifugation in CsCl. We found that HSV DNA synthesis was initiated between 2 to 3 hr after infection. The rate of DNA synthesis increased rapidly, reaching a maximum 4 hr after infection, and decreased to 50% of maximum by 8 hr. Evidence is also presented which suggests that HSV infection can inhibit both the ongoing synthesis of host DNA as well as the initiation of the S phase.     

Kinetics of Nucleic Acid Synthesis in Human Embryonic Kidney Cultures Infected with Adenovirus 2 or 12: Inhibition of Cellular Deoxyribonucleic Acid Synthesis

Infection of human embryonic kidney (HEK) cell cultures with adenovirus types 2 or 12 resulted in an initial drop in the rate of incorporation of (3)H-thymidine into deoxyribonucleic acid (DNA) during the early latent period of virus growth, followed by a marked rise in label uptake. It was shown by cesium chloride isopycnic centrifugation that, after adenovirus 2 infection, there was a decrease in the rate of incorporation of thymidine into cellular DNA. Moreover, DNA-DNA hybridization experiments revealed that, by 28 to 32 hr after infection with either adenovirus 2 or 12, the amount of isolated pulse-labeled DNA capable of hybridizing with HEK cell DNA was reduced by approximately 60 to 70%. Autoradiographic measurements showed that the inhibition of cellular DNA synthesis was due to a decrease in the ability of an infected cell to synthesize DNA. The adenovirus-induced inhibition of host cell DNA synthesis was not due to degradation of cellular DNA. (3)H-thymidine incorporated into cellular DNA at the time of infection remained acid-precipitable, and labeled material was not incorporated into viral DNA. Furthermore, when zone sedimentation through neutral or alkaline sucrose density gradients was employed, no detectable change was observed in the sedimentation rate of this cellular DNA at various times after infection with adenovirus 2 or 12. In addition, there was no increase in deoxyribonuclease activity in cells infected with either virus. Cultures infected for 38 hr with adenovirus 2 or 12 incorporated three to four times as much (3)H-uridine into ribonucleic acid (RNA) as did non-infected cultures. Furthermore, the net RNA synthesized by infected cultures substantially exceeded that of control cultures. The activity of thymidine kinase was induced, but there was no stimulation of uridine kinase.     

Deoxyribonucleic Acid Synthesis During the Division Cycle of Escherichia coli: a Comparison of Strains B/r, K-12, 15, and 15T− Under Conditions of Slow Growth

The rates of deoxyribonucleic acid (DNA) synthesis during the division cycles of the Escherichia coli strains B/r, K-12 3000, 15T(-), and 15 have been measured in synchronous cultures, under several conditions of slow growth. These synchronous cultures were obtained by sucrose gradient centrifugation of exponentially growing cultures, after which the smallest cells were removed from the gradient and allowed to grow. Sucrose gradient centrifugation did not adversely affect the cell cycle, since an experiment in which an exponentially growing culture was pulsed with [(3)H]thymidine prior to the periodic separation and assay of the smallest cells resulted in the same conclusions, as given below. In the strains of E. coli that were studied, a decreased rate of [(3)H]thymidine incorporation was seen late in the cell cycle, prior to cell division. No decrease in the rate of [(3)H]thymidine incorporation was seen at or near the beginning of the cell cycle. Thus, all these strains appear to regulate DNA synthesis in a similar fashion during slow growth. In addition, a correlation between the appearance of cells with visible cross-walls and the start of a new round of DNA synthesis was seen, indicating that these two events might be related.     

Inhibition of Mitosis and Macromolecular Synthesis in Rat Embryo Cells by Kilham Rat Virus

The effects of Kilham rat virus multiplication were studied in cultured rat embryo cells to examine the mechanisms by which virus infection might be related to developmental defects in rats and hamsters. The virus was found to inhibit motosis and deoxyribonucleic acid (DNA) synthesis within 2 to 10 hr after infection. However, total ribonucleic acid synthesis was relatively unaffected until about 20 hr after infection, and total protein synthesis did not decline significantly until loss of viable cells was apparent in the cultures. No effect on chromosomes was detected. The effect of Kilham rat virus on DNA synthesis appears to be due to inhibition of macromolecular synthesis rather than to an inhibition of uptake of precursors into cells. The effect of the virus on mitosis may be an addition to the effect on DNA synthesis, since mitosis is inhibited even in cultures in which cells are able to divide at the time of infection and which have presumably completed DNA synthesis.     

Cell-Dependent Differences in the Production of Infectious Herpes Simplex Virus at a Supraoptimal Temperature

The replication of herpes simplex virus (HSV) was compared in rabbit and hamster cells at optimal and supraoptimal temperatures. Replication occurred in cells of either species at 33 C, but the total infectious virus yield was routinely about 10-fold greater in rabbit cells than in hamster cells. At 39 C, this difference was exaggerated to greater than 100,000-fold. Whereas infectious virus was produced and plaques formed in rabbit kidney cell monolayers at the higher temperature, neither developed in those derived from hamster embryos. Elevating the temperature from 33 C to 39 C at various time intervals after exposure of the cultures to virus revealed that production of infectious virus in hamster cells was completely heat-sensitive up to 6 hr after infection. Specific viral antigens and viral deoxyribonucleic acid (DNA) were synthesized in both rabbit and hamster cell cultures. In addition, cellular DNA synthesis was depressed and cytopathic effects occurred in both cell systems. These cytopathic effects were not observed in cell cultures treated with HSV previously inactivated with ultraviolet light. Compared with parallel cultures at 33 C, the amount of viral DNA synthesized at 39 C was greatly reduced in both systems. In hamster cells, the reduction was twofold greater than in rabbit cells. This cell-dependent thermal inhibition of HSV replication in hamster cells did not occur with vaccinia virus.     

Effect of cell physiological state on infection by rat virus

Infection by rat virus has been studied in cultures of rat embryo cells to evaluate the Margolis-Kilham hypothesis that the virus preferentially infects tissues with actively dividing cells. An enhancement of infection was seen in cultures infected 10 hr after fresh medium was added as compared to infection of stationary cultures (infected before addition of fresh medium). Since addition of fresh medium stimulates deoxyribonucleic acid (DNA) synthesis, the number of cells per culture synthesizing DNA at the time of infection was compared with the proportion of cells which synthesized viral protein. Cells were infected before the medium change and 10 or 24 hr after the medium change and were pulse-labeled with ³H-thymidine at the time virus was added. The cells were allowed to initiate viral protein synthesis before they were fixed and stained with fluorescein-conjugated anti-rat virus serum. Fluorescence microscopy permitted both labels to be counted simultaneouly and showed that the greatest proportion of cells synthesizing viral protein were those which had incorporated ³H-thymidine at the time of infection.     

Kinetics of Viral Deoxyribonucleic Acid, Protein, and Infectious Particle Production and Alterations in Host Macromolecular Syntheses in Equine Abortion (Herpes) Virus-infected Cells

Infection of exponential-phase suspension cultures of mouse fibroblast cells (L-M) with equine abortion virus (EAV) resulted in inhibition of cell growth and marked alterations in host metabolic processes. The synthesis of deoxyribonucleic acid (DNA) and ribonucleic acid was inhibited within 4 hr after infection and was suppressed by more than 90% by the time of maximal virus replication (14 to 18 hr). The overall rate of protein synthesis, however, was similar in uninfected and virus-producing cells as determined by measurements of net protein and isotope incorporation. The time course of viral DNA and protein synthesis and assembly into mature virus was determined with the inhibitors 5-fluorodeoxyuridine (FUdR) and cycloheximide, respectively. Thus, viral DNA synthesis was essentially completed at 14 hr, and viral protein and infectious virus synthesis was completed at 18 hr. Although the number of plaque-forming units (PFU) produced by FUdR-treated cells (10(3) to 10(4) PFU/ml) was at least 3 logs less than that produced by untreated cells, the yield of physical particles (as determined by electron microscopy) was approximately the same at 30 hr after infection. Besides being relatively non-infective, the particles produced in FUdR-treated cells appeared morphologically incomplete as they contained little or no nucleoid material.     

Variation of Interferon Production During the Cell Cycle

The capacity of cells to produce interferon has been found to depend on the phase in the cell cycle at which virus infection took place. Monolayer cultures of L cells were synchronized by the double thymidine-block method. Such synchronously growing cultures were used to study the ability of cells to produce interferon when they were infected with ultraviolet-inactivated Newcastle disease virus (UV-NDV) at different phases of the cell cycle. In all instances, interferon was detected early and reached a maximum at about 16 hr after infection. However, the levels of interferon found in medium of cultures infected at early post-deoxyribonucleic acid (DNA) synthetic (G2) and to some extent at late G2 phases of the cell cycle were comparatively lower than those found in cultures infected at the early DNA synthetic (S) phase. There appeared also in these infected growing cultures a transient period when interferon production was apparently delayed. This period corresponded interestingly with the time of mitotic burst. Infection of thymidine- or 1-beta-d-arabino-furanosylcytosine-inhibited cultures with UV-NDV also led to similar interferon response as that observed in growing cultures infected at early S. However, no transient delay of interferon production was demonstrated in these cultures.     

Assay for Epstein-Barr virus based on stimulation of DNA synthesis in mixed leukocytes from human umbilical cord blood.

Relationships between the rate of DNA synthesis in cultured human umbilical cord leukocytes and the multiplicity of added Epstein-Barr virus (EBV) were studied. At low multiplicities of approximately 0.1 transforming units/cell (approximately 10 physical particles/cell), inoculated cultures demonstrated increased rates of DNA synthesis, by comparison to uninoculated cultures, 3 days after inoculation. Stimulation of DNA synthesis was evident of progressively longer intervals after inoculations of 10-fold dilutions of virus. The rate of DNA synthesis, determined by short [-3H]thymidine pulses, reflected as small as twofold changes in multiplicity and thus can serve as a quantitative assay for the virus. Changes in the rate of DNA synthesis were evident before increases in cell number or alteration in morphology. Stimulation of DNA synthesis in umbilical cord leukocytes was inhibited by treatment of EBV with antibody and also in graded fashion, by progressive doses of UV irradiation to the virus. Induction of DNA synthesis by EBV was serum dependent. Estimates of the number of cells transformed were obtained by extrapolation from a standard curve relating known numbers of transformed cells to [-3H]thymidine incorporation and also by cloning cells after exposure to virus. At the low multiplicities of infection used in these experiments approximately 0.04 to 0.002 of the total cellular population was transformed. The high efficiency of cell transformation by EBV by comparison to other DNA tumor viruses is emphasized.     

Enlargement of Escherichia coli After Bacteriophage Infection I. Description of the Phenomenon

Cycloheximide addition at various times from 24 to 36 hr after virus infection markedly inhibits the rate of simian virus 40 (SV40) deoxyribonucleic acid (DNA) synthesis in monkey kidney (CV-1) cultures. To determine whether superhelical (form I) SV40 DNA was synthesized in the cycloheximide-inhibited cultures, extracts were prepared by the method of Hirt from cultures labeled with (3)H-thymidine ((3)H-dT) and were analyzed by cesium chloride-ethidium bromide (CsCl-EtBr) equilibrium centrifugation and by velocity sedimentation in neutral sucrose gradients. When control or cycloheximide-treated cultures were labeled for 2 or 4 hr with (3)H-dT at 36 or 37 hr after infection, 71 to 83% of the radioactivity soluble in 1 m NaCl was detected in closed-circular SV40 DNA (form I). Cycloheximide treatment did not generate an increase of higher multiple circular forms of SV40 DNA. In pulse-chase experiments with or without cycloheximide treatment, radioactivity first appeared in nicked molecular forms sedimenting faster than open-circular SV40 DNA (form II), and then was chased into superhelical form I SV40 DNA. These results suggest that in cycloheximide-treated SV40-infected cultures: (i) polynucleotide ligase concentrations are adequate, and (ii) duplication errors causing formation of circular oligomers of SV40 DNA are not enhanced.     

Deoxyribonucleic Acid of Marek''s Disease Virus in Virus-Induced Tumors

DNA was extracted from [(3)H]thymidine-labeled Marek's disease virus (MDV) and purified by two cycles of CsCl gradient centrifugation in a fixed-angle rotor. The DNA was transcribed in vitro into (32)P-labeled complementary RNA (cRNA). MDV cRNA did not hybridize with DNA from chicken embryo fibroblast cultures or from chicken spleen, but hybridized efficiently with DNA from MDV particles or MDV-infected cell cultures. Five Marek's disease tumors from different chickens and different organs (ovary, liver, testis) were all found to contain MDV DNA sequences. The relative amount of MDV DNA varied from tumor to tumor and was between 3 and 15 virus genome equivalents per cell. The content of virus DNA per cell in spleens from tumor-bearing chickens was much lower than in tumors from the same animals. MDV-infected cell cultures contained a large proportion (28-59%) of virus antigen-positive cells, as measured by immunofluorescence, but tumor cells were negative in this respect (<0.02% positive cells). These data indicate that MDV is present in a provirus form in tumor cells.