Effect of actinomycin D on viability,sporulation and nucleotide pool ofBacillus megaterium

A transient 7-fold rise of ppGpp concentration, 2-3-fold increase of pppGpp concentration and 50 % drop of the concentration of GTP inBacillus megaterium cells immediately after their transfer to the sporulation medium were observed. Actinomycin D, in concentrations inhibiting RNA synthesis by 95%, blocked the rise of the (p)ppGpp pool and caused an instant several-fold increase of the GTP level. When the cells were exposed to actinomycin D in the sporulation medium for a 1-h period (time 0–1 h, 1–2 h or 2.20–3.20-h), they were able to form colonies on nutrient agar after being kept, in addition for 1–2 h in the sporulation medium free of the antibiotic. The ability of sporulation was, however, markedly limited. The share of cells that could sporulate increased when the irreversible sporulation phase was reached.     

The molecular mechanism of actinomycin D in preventing neointimal formation in rat carotid arteries after balloon injury

Summary The pathological mechanism of restenosis is primarily attributed to excessive proliferation of vascular smooth muscle cells (SMC). Actinomycin D has been regarded as a potential candidate to prevent balloon injury-induced neointimal formation. To explore its molecular mechanism in regulating cell proliferation, we first showed that actinomycin D markedly reduced the SMC proliferation via the inhibition of BrdU incorporation at 80 nM. This was further supported by the G1-phase arrest using a flowcytometric analysis. Actinomycin D was extremely potent with an inhibitory concentration IC₅₀ at 0.4 nM, whereas the lethal dose LD₅₀ was at 260 μM. In an in vivo study, the pluronic gel containing 80 nM and 80 μM actinomycin D was applied topically to surround the rat carotid adventitia; the thickness of neointima was substantially reduced (45 and 55%, respectively). The protein expression levels of proliferating cell nuclear antigen (PCNA), focal adhesion kinase (FAK), and Raf were all suppressed by actinomycin D. Extracellular signal-regulated kinases (Erk) involved in cell-cycle arrest were found to increase by actinomycin D. These observations provide a detailed mechanism of actinomycin D in preventing cell proliferation thus as a potential intervention for restenosis.     

On the regulation of tyrosine transaminase, glutamatic dehydrogenase and aspartic transaminase in Tetrahymena

Aspartic transaminase, tyrosine transaminase, lactic dehydrogenase, and glutamic dehydrogenase were studied in Tetrahymena pyriformis in order to gain a better understanding of the control of the entrance and exit of metabolic intermediates to and from the major carbohydrate pathways. Glucose decreased the activity of aspartic transaminase, tyrosine transaminase and glutamic dehydrogenase but not lactic dehydrogenase. Actinomycin D (6 and 12 μg/ml) blocked the decrease in glutamic dehydrogenase and aspartic transaminase activity caused by glucose; 12 μg/ml partially prevented the decrease in tyrosine transaminase activity. Actinomycin D alone had little effect on enzyme activity. Uracil incorporation into RNA was doubled by 6 μg/ml actinomycin D, a concentration which did not alter the RNA content of the cells. At 12 μg/ml this drug caused a small decrease in RNA spec. act. Cycloheximide at 10 μg/ml, a concentration which inhibited protein synthesis by 70%, caused a three-fold increase in aspartic transaminase and a two-fold increase in glutamic dehydrogenase. In the presence of both cycloheximide and glucose, the drug effect predominated. Thus both actinomycin D and cycloheximide blocked the glucose-induced decrease in enzyme activity. These results suggest that the levels of aspartic transaminase, glutamic dehydrogenase, and probably tyrosine transaminase are regulated at least in part by a degradative control system.     

Intracellular serine proteinase behaves as a heat-stress protein in nongrowing but as a cold-stress protein in growing populations of Bacillus megaterium

A temperature increase from 35° to 40–42°C enhances the rise of cytoplasmic serine proteinase (ISP1) activity in Bacillus megaterium incubated in a sporulation medium. A temperature shift from 27°C in the growth medium to 35°C in the sporulation medium has the same effect. Elevated temperature stimulates the increase of ISP1 level when applied immediately after the transfer of cells from the growth to the sporulation medium (at T₀) or at T₃, when sporulation becomes irreversible. The cytoplasmic PMSF-resistant activity or the proteolytic activity associated with the membrane fraction is stimulated only slightly or not at all. A temperature increase to 45–47°C suppresses the rise of proteolytic activities in all cell fractions. In addition to the elevation of the ISP1 activity by an upward temperature shift, the rise of this enzyme in nongrowing cells is also stimulated by osmotic stress. In growing populations, in contrast to the rise of the ISP1 activity caused by elevated temperature in nongrowing cells, this proteinase is induced by low temperatures (24–27°C). The ISP1 activity roughly correlates with the enzyme protein concentration determined by immunoblotting.     

The effect of estradiol-17β and actinomycin D on the release of PGF and PGE from separated cells of human endometrium

Estradiol-17β selestively stimulated the release of PGF from separated glandular but not stromal cells of human secretory endometrium (p<0.025) but had no effect on PGF release from either type of cells obtained from proliferative endometrium. PGE release was not affected by estradiol-17β. Actinomycin D did not antagonise the effect of estradiol-17β on PGF release from secretory, glandular cells. Basal release of PGF from these cells was stimulated by actinomycin D alone (100 ng/ml) (p<0.025) and PGE release stimulated in the presence of estradiol-17β. Actinomycin D had no effect on PGF or PGE release from proliferative endometrium. These findings suggest that estradiol-17β stimulates PGF release by a mechanism that does not affect PGE release and which is not dependent on the synthesis of new protein. The basal release of PGF and PGE by glandular cells of secretory endometrium in vitro is regulated by protein/proteins which reduce PG release.     

Temperature-dependent actinomycin D effect on RNA synthesis during synchronous development in Neurospora crassa

Actinomycin D at a concentration of 5 g/ml of medium inhibited DNA-dependent RNA synthesis by 92% at 35 C, 42% at 30 C, and 28% at 25 C in Neurospora crassa. This concentration also inhibited the development of conidiophores and conidia at 35 C, but not at 30 or 25 C. Mycelia which were induced to synchronous development formed conidiophores in 2.5 hr and conidia in 4.5 hr at 35 C in the absence of drug additives. Addition of actinomycin D to synchronously developing mycelia at zero time and at 0.5-hr intervals thereafter at 35 C indicated that RNA synthesis required for conidiophores occurred before 0.5 hr and for conidia before 2 hr. Addition of cycloheximide at the same times to another synchronous mycelial series at 35 C indicated that protein synthesis required for conidiophores occurred before 2 hr and for conidia before 3.5–4 hr.This work was supported in part by U.S. Public Health Service Training Grant 1 TO1 GM 01968 01.     

Clostridium cellulolyticum Viability and Sporulation under Cellobiose Starvation Conditions

Depending on the moment of cellobiose starvation, Clostridium cellulolyticum cells behave in different ways. Cells starved during the exponential phase of growth sporulate at 30%, whereas exhaustion of the carbon substrate at the beginning of growth does not provoke cell sporulation. Growth in the presence of excess cellobiose generates 3% spores. The response of C. cellulolyticum to carbon starvation involves changes in proteolytic activities; higher activities (20% protein degradation) corresponded to a higher level of sporulation; lower proteolysis (5%) was observed in cells starved during the beginning of exponential growth, when sporulation was not observed; with an excess of cellobiose, an intermediate value (10%), accompanied by a low level of sporulation, was observed in cells taken at the end of the exponential growth phase. The basal percentage of the protein breakdown in nonstarved culture was 4%. Cells lacking proteolytic activities failed to induce sporulation. High concentrations of cellobiose repressed proteolytic activities and sporulation. The onset of carbon starvation during the growth phase affected the survival response of C. cellulolyticum via the sporulation process and also via cell-cellulose interaction. Cells from the exponential growth phase were more adhesive to filter paper than cells from the stationary growth phase but less than cells from the late stationary growth phase.     

Abortive Infection of Bacillus subtilis Bacteriophage PBS1 in the Presence of Actinomycin D

Actinomycin D caused the irreversible loss of PBS1 phage infectious centers and PBS1-mediated transductants. The loss of infectious centers occurred only within the first 4 min after the addition of phage to cells. Actinomycin did not inactivate free phage or inhibit phage adsorption. Electron micrographs indicated that phage adsorbed to cells in the presence of actinomycin ejected their deoxyribonucleic acid (DNA) normally. However, when cells were infected in the presence of actinomycin, 15 to 22% of their (32)P-labeled DNA appeared in the medium, whereas only 1.5 to 7.2% of the (32)P-labeled DNA appeared in the medium during normal infection. Neither 8-azaguanine nor chloramphenicol caused a similar loss of PBS1 infectious centers or transductants. Actinomycin also caused the loss of SP10 infectious centers but it had no effect on SP01 or phi29 infections. We conclude that actinomycin causes abortion of PBS1 infection by inhibiting the uptake or retention of phage DNA into host cells. The immunity of SP01 and phi29 infections to actinomycin probably reflects differences in the penetration mechanisms of these phages.     

Selective growth of sympathetic nerve fibers to explants of normally densely innervated autonomic effector organs in tissue culture

The synthesis of both total and electrophoretically fractionated proteins was studied in the wing epidermis of developing silkmoths, using a simple organ culture system which maintains the cells in synthetically normal condition for approximately 2 days. Differences were detected in the electrophoretic profile of proteins synthesized at different developmental stages, and correlated with transition from growth-related to differentiation-related products. Actinomycin D induced an apparently exponential decay in incorporation into total protein; the half-life of the decay ranged from 10 to 13 hr, depending on the stage of development. Double-label experiments indicated that decay of protein synthesis in the presence of actinomycin is not uniform, but proceeds at different rates for different components. Putative differentiation-specific products may be associated with differential resistance to actinomycin. At a specific developmental stage, actinomycin induced a transient secondary stimulation of overall incorporation. Measurements of leucine specific activity suggested that protein synthesis (rather than merely incorporation) is affected, and that “superinduction” is not limited to a few protein species.     

ACTINOMYCIN D-INDUCED CHANGES IN GROWTH AND RIBONUCLEIC ACID METABOLISM IN THE GAMETOPHYTES OF BRACKEN FERN

Actinomycin D affected the morphological type of growth in the gametophytes of Pteridium aquilinum and the distribution of RNA and protein in their particulate fractions. Increasing concentrations of the drug progressively inhibited two-dimensional growth at the end of a period during which controls had formed typical two-dimensional plants. RNA was lost maximally from the nuclei-rich and ribosome-rich fractions of plants growing in a concentration of actinomycin D which inhibited two-dimensional growth. The magnitude of changes in protein content of the plants was less striking. Presence of actinomycin D in the medium also suppressed incorporation of uridine-H³ into cytoplasmic fractions of gametophytes. The possibility that two-dimensional growth in the gametophytes is under control of a newly synthesized messenger RNA, which is sensitive to actinomycin D, is discussed.     

Effects of serum,cycloheximide and actinomycin D on protein secretion by quiescent mouse embryo fibroblasts

Quiescent secondary cultures of Swiss mouse embryo fibroblasts secrete several proteins in response to the addition of 20% fetal calf serum (FCS). Of these proteins, a polypeptide of molecular weigth (Mr) 48 000 (48 K) was identified in the medium within an hour of mitogenic stimuli. In the next hour an additional protein of Mr 26000 (26 K) appeared in the medium. These two proteins were absent in the conditioned medium of quiescent cells. A third protein of molecular weight 45,000 (45 K) was found in small quantities in the conditioned medium of quiescent cells but a 2–3 fold increase in the level of this protein was observed in the medium of stimulated cells. The level of the serum-induced 45 K protein was much higher in the medium of cells that were treated with cycloheximide (CH) and FCS than that found in the medium of cells treated with FCS alone. A 40000 dalton protein was found to be a quiescence specific protein which was observed in large amounts in the medium of quiescent cells; the level of this protein gradually declined in the conditioned medium as the cells entered into the proliferative phase. Actinomycin D specifically inhibited the level of the 45 K secreted protein and a 29 K intracellular protein when added along with CH. In contrast to the inhibition of the synthesis of mitogen induced proteins, actinomycin D super-induced the intracellular and extracellular levels of the matrix proteins fibronectin and procollagens.     

Zinc stimulates sporulation inClostridium botulinum 113B

The presence of 0.5–1.0 mM zinc (Zn) in a complex sporulation medium stimulated spore formation in certain strains ofClostridium botulinum. Zinc increased both the titer of free refractile spores (spores per liter) and the percentage conversion of vegetative cells to spores. Certain other transition metals including iron (Fe) and manganese (Mn) also improved sporulation, but not so effectively as zinc. Sporulation was drastically decreased by the addition to the medium of 0.5–1.0 mM copper (Cu). Copper was shown to compete with the acquisition of zinc by the sporulating cells. Spores were separated from their progenitor vegetative cells to 98% homogeneity by incorporation of a density-separation step in the extensive washing procedure. Analysis of the metal contents of the purified spores showed that zinc levels in spores were reduced considerably in culture media containing excess copper. The results imply that either the availability of zinc or the limitation of copper stimulates sporulation inC. botulinum. In addition toC. botulinum 113B, zinc also increased sporulation in several type A, B, and E strains and one proteolytic type F strain ofC. botulinum.     

Influence of glucose starvation on the pathway of death in insect cell line Sl: apoptosis follows autophagy

The relation between autophagy and apoptosis has not been clearly elucidated. Here, we reported that apoptosis followed autophagy in insect Spodoptera litura cells (Sl) undergoing glucose starvation. Sl cells have been adapted to Leibovitz-15 medium supplemented with glucose (1.0 g/l) and 5% fetal bovine serum (FBS), used for mammalian cell cultures. If glucose (1 g/l) or glutamine (1.6 g/l) had not been supplemented in L-15 medium with 5% FBS, Sl cells began to form many vacuoles and these vacuoles gradually enlarged in the cytoplasm, which were autophagic vacuoles. However, these large vacuoles began to disappear gradually after 48 h of glucose starvation, accompanied with remarkable apoptosis without apoptotic bodies, which was demonstrated by DNA fragmentation and activation of caspase-3-like. During glucose starvation, Sl cell ATP concentrations gradually decreased. Interestingly, if the conditioned L-15 medium without glucose was replaced with fresh L-15 medium supplemented with glucose or glutamine after the cultures had been starved seriously for 48 h or longer, the formation of apoptotic bodies was initiated. These data suggested that the partial depletion of cell ATP triggered apoptosis following autophagy in glucose-starved Sl cells and the formation of apoptotic bodies required higher level of ATP than DNA fragmentation and activation of caspase-3-like activity. Additionally, the disappearance of autophagic vacuoles, negative staining of neutral red, green staining of acridine orange and diffusion of acid phosphatase activity in Sl cells at the late stage of starvation (over 48 h) suggested that the dysfunction of lysosome was more likely to involve in apoptosis. The facts that Actinomycin D-induced apoptosis was partially inhibited and cyclosporin A, blocking the opening of mitochondrial permeability transition (MPT) pores, inhibited partially apoptosis in glucose-starved Sl cells, suggested the pathway of glucose starvation-induced apoptosis seemed to be different from that induced by actinomycin D and the opening of MPT pores on mitochondria probably involved in apoptosis triggered by glucose starvation, respectively.     

Degradation and replenishment of the labile protein fraction in non-growing cells of the asporogenic mutant ofBacillus megaterium

Kinetics of degradation of labelled proteins was followed in two asporogenic mutants ofBacillus megaterium during incubation in a sporulation medium. Both the mutant producing exocellular protease (KM 1prn ⁺) and the mutant not producing the enzyme (KM 12prn) were found to contain a labile protein fraction, whose proportion decreases with prolonged time of labelling and whose half-life is about 1 h. Most proteins were relatively stable and were degraded at a rate of 1 %/h and 2 %/h in strains KM 1 and KM 12, respectively (half life 70–80 h and 35–40 h in strains KM 1 and KM 12, respectively). The intracellular proteolytic activity of the KM 12 mutant remains practically the same during incubation in the sporulation medium or slowly increases. The labile protein fraction practically disappears from the cells after a 3.5-h incubation. When such a culture is then subjected to a shift-up and transferred again to the sporulation medium, the rate of protein turnover temporarily increases. The temporary increase of the turnover rate is caused by a partial replenishment of the labile protein fraction rather than by an accelerated degradation of the relatively stable fraction. The intracellular proteolytic activity does not increase under these conditions. The wild sporogenic strain ofB. megaterium also contains the labile protein fraction. Its half protein life is 1 h or less. However, the second protein fraction is degraded much more rapidly than in the asporogenic mutants and its half life is 6–7 h.     

Spore Refractility in Variants of Bacillus cereus Treated with Actinomycin D

Refractility as indicated by light microscopy, electron microscopy of thin sections, and freeze fracture etching was increased and maintained in a cortexless mutant, A(-)1, of Bacillus cereus var. alesti by the addition during sporulation stage 4 of actinomycin D, which prevents the terminal lysis of spore core associated with sporulation in this organism. (45)Calcium uptake levels and dipicolinic acid (DPA) content were similarly maintained. The location of these components appears to be in the spore protoplast. In the parent A(-), treated with actinomycin D during stage 4, spore particles with similar morphology to the mutant, that is without a cortex and with the characteristics of refractility, were obtained. A major difference in sensitivity to actinomycin D between the processes of (45)Ca uptake and DPA synthesis was observed. Some heat resistance in A(-) made cortexless by actinomycin D could be observed. These studies indicate that the role of the cortex is not to produce the dehydrated refractile spore state but to maintain it.