ON THE DIFFERENTIAL CYTOTOXICITY OF ACTINOMYCIN D

Actinomycin D (AMD) at concentrations that inhibit cellular RNA synthesis by 85% or more causes an acute phase of lethal cell degeneration in HeLa cultures beginning as early as 3 hr after drug exposure, resulting in the nearly complete loss of viable cells by 12 hr. The loss of cells during this acute phase of lethality is closely dose dependent. Vero, WI38, or L cells are not susceptible to this early acute cyto-intoxication by AMD, and may begin to die only after 1–2 days. Differential susceptibility to acute cyto-intoxication by AMD, or other inhibitors of RNA synthesis (daunomycin or nogalamycin), among different types of cultured cells is analogous to that observed in vivo in certain tissues and tumors, and cannot be accounted for by differences in the effect of AMD on RNA, DNA, or protein syntheses, or by the over-all loss of preformed RNA. Actinomycin D in a dose that inhibits RNA synthesis causes an equivalent loss of the prelabeled RNA in all the cell types studied. Inhibition of protein synthesis with streptovitacin A or of DNA synthesis with hydroxyurea does not cause acute lethal injury in HeLa cells as does inhibition of RNA synthesis. Furthermore, since Vero or L cells divide at about the same rate as HeLa cells, no correlation can be drawn between the rate of cell proliferation and susceptibility to the cytotoxicity of AMD. Susceptibile cells are most vulnerable to intoxication by AMD in the G₁-S interphase or early S phase. Inhibition of protein synthesis (which protects cells against damage by other agents affecting DNA) does not protect against AMD-induced injury. Although HeLa cells bind more AMD at a given dose than Vero or L cells, the latter cell types, given higher doses, can be made to bind proportionally more AMD without succumbing to acute cyto-intoxication. It is suggested that the differential susceptibility of these cell types to acute poisoning by AMD may reflect differences among various cells in the function or stability of certain RNA species not directly involved in translation whose presence is vital to cells. In HeLa cells, these critical species of RNA are presumed to have a short half-life.     

Effects of Actinomycin D on Generation Time and Morphogenesis in Paramecium*

SYNOPSIS. The sensitivity of Paramecium tetraurelia (=P. aurelia syngen 4) cells to pulse treatments with various doses of Actinomycin D (AMD) was estimated by comparing the generation times of treated and untreated sister cells. It was found that the delay of division in treated cells depended on the concentration of AMD, on their “age” at the time of the pulse treatment, and on their individual sensitivity. Sensitivity of Paramecium to AMD changes during the cell cycle in a predictable way. About 3 1/2 hr before the normally expected cell fission (total generation time ～ 5 1/2 hr) there is a decrease of sensitivity. Thereafter, the cell enters a new stage with a progressive increase of sensitivity. This 2nd phase ends at the “transition point” (～ 2 hr before cell division), when sensitivity drops abruptly. The division process itself may be altered and slowed down by high concentrations of AMD, even if the drug is applied after the transition point, but this process can never be completely annulled. The impairment of the division mechanism may lead to morphologic anomalies in the offspring. Resorption of oral anlagen in P. tetraurelia probably never occurs during the cell cycle after AMD treatment. The reason for individual variability of the cells, mechanisms controlling development, and the question of an obligate sequence of gene action in each cell cycle are discussed.     

Inhibition of measles virus replication and RNA synthesis by actinomycin D

Measles virus replication and RNA synthesis in Vero cells are inhibited by actinomycin at concentrations which inhibit cellular RNA synthesis. Drug present from the 2nd to the 24th hr post infection inhibited infectivity but not hemagglutinating activity or cell fusion. Infectivity was much less sensitive to drug added during the second 24-hr period, and 52S RNA was labeled and incorporated into virions during this later time interval.     

Early activation and cell cycle entry of resting B cells after Fab-anti-Ig treatment: role of receptor crosslinking

Comparison of the effect of goat anti-rabbit Ig (GARIg) and its monovalent fragment (Fab-GARIg) demonstrates that surface Ig (sIg) crosslinking is not necessary to effect G0 to G1 transition in rabbit peripheral blood B cells but is required for induction of DNA synthesis. Five micrograms per milliliter or more of GARIg is sufficient to induce DNA synthesis but up to 50 micrograms/ml of Fab-GARIg is not. However, the monovalent reagent induces microscopically observable cytoplasmic and nuclear changes (blast transformation) in a dose-dependent manner. These differ qualitatively and quantitatively from the morphological changes seen with comparable doses of GARIg; Fab anti-Ig produces "small blasts" whereas complete GARIg induces large blasts. The monovalent reagent, in a wide range of concentrations, is as effective as the complete antibody in modulating sIg from rabbit B cells. Fab-GARIg treatment modulates sIg in a biphasic manner. It clears the high-density sIg within 5 min, whereas the remaining low-density receptors disappear after 4 hr. Cytosolic protein kinase C levels decline equally after treatment with either Fab-GARIg or whole anti-Ig. RNA synthesis, as measured by [3H]uridine incorporation, increases for the first 12 hr in cells activated with either reagent. It declines to basal levels in Fab-GARIg stimulated cells, but a continuous increase occurs in cells stimulated with 5 and 50 micrograms/ml of complete antibody. Simultaneous addition of 50 micrograms/ml Fab-GARIg with 5 microgram/ml of GARIg causes greater RNA synthesis for 12 hr after stimulation than is caused by GARIg alone. After 12 hr the monovalent reagent has an inhibitory effect on RNA synthesis. Fluorescence-activated cell sorter analysis of acridine orange-stained cells shows that Fab anti-Ig-stimulated cells have higher RNA content than resting cells, but lower than GARIg-activated cells. These findings suggest that rabbit B cells can be activated from the G0 stage of cell cycle to G1 by monovalent anti-Ig reagents but further cell cycle progression requires maintenance signals provided by receptor crosslinking. The implications of these results for B cell activation signalling are discussed in the context of the floating receptor model.     

Restricted viral RNA synthesis in establishment of persistent infection in Vero cells with a Sendai virus mutant

It was previously shown that a temperature-sensitive mutant of Sendai virus, ts-23, readily establishes persistent infection in Vero cells at 37 C, a permissive temperature for growth of the mutant. In the present study, it was demonstrated that the virus yield from ts-23-infected Vero cells at 37 C began to decrease 48 to 72 hr postinfection, after an initial phase of high virus production. Before the decrease in virus production, the formation of viral nucleoprotein declined, although synthesis of all species of viral protein continued. It was suggested that the limited formation of viral nucleoprotein and the decrease in virus production were due to the restriction of viral RNA synthesis which began to occur early after infection in ts-23-infected cells at 37 C. The mutant has a temperature-sensitive defect in RNA polymerase activity and the temperature 37 C, used for establishment of persistent infection, would be a semi-permissive temperature for the RNA polymerase activity of the mutant. The ts-23 mutant interfered with the replication of the parental wild virus in Vero cells at 37 C.     

Effects of inhibition of RNA or protein synthesis on CHO cell cycle progression

Chinese hamster ovary (CHO) cells, synchronized by selective detachment at mitosis, were treated with various concentrations of actinomycin D (AMD) or cycloheximide (CHX) either immediately, or 1, 2, or 3 hr after mitosis. Since the minimum duration of G₁ phase in these cultures was 3.4 hr, the addition of RNA or protein synthesis inhibitors took place at the beginning, first third, second third, or end (G₁–S boundary) of G₁ phase. The kinetics of exit from G₁ phase, the rate and extent of traverse of S phase, and the reaccumulation of RNA were estimated under each set of growth conditions by flow cytometry of acridine orange-stained cells. A mathematical model was constructed to describe the trajectories of the cell populations with respect to their increase in RNA and DNA content in the absence or presence of the inhibitor. The chronologic synchrony imposed on the CHO cell population began to decay within 3 hr, resulting in stochastic entrance of cells into S phase in the absence of inhibitor. Addition of AMD or CHX at 0, 1, 2, or 3 hr after mitosis, regardless of the inhibitor concentration, did not provide evidence of a critical restriction point in G₁ beyond which cells were committed to enter S phase and were no longer sensitive to moderate suppression of RNA or protein synthesis. The observed kinetics of cell entrance into and traverse of S phase were consistent with an inherently heterogenous response to serum stimulation occurring at or just after cell division.     

DNA SYNTHESIS AND MITOSIS IN MERISTEMS: REQUIREMENTS FOR RNA AND PROTEIN SYNTHESIS

Following provision of sucrose to starved, stationary phase pea root meristems, G₁ and G₂ cells enter DNA synthesis and mitosis, respectively. Puromycin (450 μg/ml) and cycloheximide (5 μg/ml) completely prevent this initiation of progression through the cell cycle. Actinomycin D (10 μg/ml) has no effect on the initial entry of G₁ and G₂ cells into S and mitosis, although later entry is prevented. The resistance of the cells to actinomycin D is lost slowly with time in medium without sucrose, suggesting that an RNA required for the resumption of proliferative activity is being gradually lost. The effects of the inhibitors on transitional and proliferative phase meristem cells indicate that such dividing cells do indeed have sufficient of the requisite RNA for 8-12 hr progression through the cycle, but that protein synthesis is required continuously. It is suggested that this RNA is the one lost slowly during starvation, allowing starved cells to reinitiate progression through the cycle in the presence of actinomycin D.     

Effect of Mengovirus Replication on Choline Metabolism and Membrane Formation in Novikoff Hepatoma Cells

Infection of Novikoff rat hepatoma cells (subline NlSL-67) with mengovirus resulted in a two- to threefold increase in the rate of choline incorporation into membrane phosphatidylcholine at about 3 hr after infection, without affecting the rate of transport of choline into the cell or its phosphorylation. The time course of virus-stimulated phosphatidylcholine synthesis was compared with the time courses of other virus-induced processes during a single cycle of replication. The formation of viral ribonucleic acid (RNA) polymerase and of viral RNA commenced about 1 hr earlier than the virus-stimulated choline incorporation. Further, isopycnic centrifugation of cytoplasmic extracts indicated that the excess of phosphatidylcholine synthesized by infected cells is not located in the membrane structures associated with the viral RNA replication complex, but with structures of a lower density (1.08 to 1.14 g/cc). These membrane structures probably represent the smooth vesicles which accumulate in the cytoplasm of infected cells during the period of increased phosphatidylcholine synthesis between 3 and 5 hr after infection. They are formed with both newly synthesized phosphatidylcholine and phosphatidylcholine present prior to infection. However, concomitant protein synthesis is not required for the stimulated synthesis of membranes; the effect was not inhibited by treating the cells with inhibitors of protein synthesis at 3 hr after infection, although virus production was inhibited about 90% and virus-induced cell degeneration was markedly reduced and delayed. Production of mature virus began normally at about the same time as the stimulation of phosphatidylcholine synthesis. Treatment of infected cells with puromycin at 2 hr, on the other hand, completely inhibited the stimulation of phosphatidylcholine synthesis.     

MICRONUCLEAR RNA SYNTHESIS IN PARAMECIUM CAUDATUM

In a generation time of 8 hr in Paramecium caudatum, the bulk of DNA synthesis detected by thymidine-³H incorporation takes place in the latter part of the cell cycle. The micronuclear cycle includes a G₁ of 3 hr followed by an S period of 3–3½ hr. G₂ and division occupies the remaining period of the cycle. Macronuclear RNA synthesis detected by 5'-uridine-³H incorporation is continuous throughout the cell cycle. Micronuclear RNA synthesis is restricted to the S period. Ribonuclease removes 80–90% of the incorporated label. Pulse-chase experiments showed that part of the RNA is conserved and released to the cytoplasm during the succeeding G₁ period.     

The synthesis of acidic chromosomal proteins during the cell cycle of HeLa S-3 cells. II. The kinetics of residual protein synthesis and transport

The kinetics of acidic residual chromosomal protein synthesis and transport were studied throughout the cell cycle in HeLa S-3 cells synchronized by 2 mM thymidine block and selective detachment of mitotic cells. Pulse labeling the cells with leucine-³H for 2 min and then "chasing" the radioactive proteins for up to 3 hr showed that the amount of protein synthesized, transported, and retained in the acidic residual chromosomal protein fraction is greater immediately after mitosis and later in G₁ than in the S or G₂ phases of the cell cycle. During S, only 20–25% of the proteins synthesized and transported to the acidic residual chromosomal protein fraction are chased during the first 2 hr after pulse labeling, whereas up to 40% of the material entering the residual nuclear fraction in mitosis, G₁, and G₂ leaves during a 2 hr chase. Polyacrylamide gel electrophoretic profiles of these proteins, at various times after pulse labeling, reveal that the turnover of individual polypeptides within this fraction has kinetics of synthesis and turnover which are markedly different from one another and undergo stage-specific changes.     

Growth of Rio Bravo Virus in Cell Cultures

The growth of Rio Bravo virus (RBV) in eight cell culture systems was studied. Highest yields of virus were produced in BHK-21 (C13), L, and Vero cell lines, but L cells were resistant to low doses of virus. LLC-MK(2), HeLa, and human embryo skin cells produced moderate amounts of virus, but FL amnion and primary chick embryo fibroblasts supported little virus growth. Virus was rapidly inactivated by exposure to pH values below 7.0. Single-cycle growth in BHK-21, L, and LLC-MK(2) cell monolayers was characterized by a latent period of about 12 hr followed by rapid virus production that peaked at 36 to 48 hr. Vero cell cultures can remain chronically infected with RBV for more than 100 days. Such cultures show evidence of cell destruction, and their supernatant fluids contain virus at 10(4) to 10(5) log(10) per ml.     

Replication of measles virus in Vero cells at elevated temperatures

In one-step growth experiment of measles virus (MV) in Vero cells at 39 C, the appearance of MV infectivity was delayed for 24 hr and the maximum titer was reduced by approximately 1,000-fold, when compared with those at 35 C. MV infectivity was thermolabile at the high temperature. Penetration was rather enhanced at 39 C. By Northern blot hybridization, viral RNAs including 50S genome-sized RNA and mRNAs were first detectable 24 hr post-infection (PI) at 35 C and 36 hr PI at 39 C, respectively. Rapid degradation of viral mRNAs was not observed in the infected cells at 39 C. The synthesis of N, F, and M proteins was relatively reduced at the high temperature and appearance of the other viral protein was delayed, in agreement with the time course of viral RNA synthesis. All these data suggest that less efficient synthesis of viral RNA, restriction of synthesis of N, F, and M proteins at translational level and thermolability of infectivity are all involved in the suppressed MV production in Vero cells at 39 C.