Mutants of Escherichia coli Defective in Membrane Phospholipid Synthesis: Macromolecular Synthesis in an sn-Glycerol 3-Phosphate Acyltransferase Km Mutant

sn-Glycerol 3-phosphate (G3P) auxotrophs of Escherichia coli have been selected from a strain which cannot aerobically catabolize G3P. The auxotrophy resulted from loss of the biosynthetic G3P dehydrogenase (EC 1.1.1.8) or from a defective membranous G3P acyltransferase. The apparent K(m) of the acyltransferase for G3P was 11- to 14-fold higher (from about 90 mum to 1,000 to 1,250 mum) in membrane preparations from the mutants than those of the parent. All extracts prepared from revertants of the G3P dehydrogenase mutants showed G3P dehydrogenase activity, but most contained less than 10% of the wild-type level. Membrane preparations from revertants of the acyltransferase mutants had apparent K(m)'s for G3P similar to that of the parent. Strains have been derived in which the G3P requirement can be satisfied with glycerol in the presence of glucose, presumably because the glycerol kinase was desensitized to inhibition by fructose 1,6-diphosphate. Investigations on the growth and macromolecular synthesis in a G3P acyltransferase K(m) mutant revealed that upon glycerol deprivation, net phospholipid synthesis stopped immediately; growth continued for about one doubling; net ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and protein nearly doubled paralleling the growth curve; the rate of phospholipid synthesis assessed by labeling cells with (32)P-phosphate, (14)C-acetate, or (3)H-serine was reduced greater than 90%; the rates of RNA and DNA synthesis increased as the cells grew and then decreased as the cells stopped growing; the rate of protein synthesis showed no increase and declined more slowly than the rates of RNA and DNA synthesis when the cells stopped growing. The cells retained and gained in the capacity to synthesize phospholipids upon glycerol deprivation. These data indicate that net phospholipid synthesis is not required for continued macromolecular synthesis for about one doubling, and that the rates of these processes are not coupled during this time period.     

Post-Transcriptional Control of Interferon Synthesis

Low to moderate doses of cycloheximide had a stimulatory effect on interferon production in rabbit kidney cell cultures treated with double-stranded polyinosinate-polycytidylate (poly I:poly C). A very marked stimulation occurred in the presence of a dose of cycloheximide inhibiting amino acid incorporation into total cellular protein by about 75%. Higher doses of cycloheximide caused a shift in interferon release towards later intervals and a gradual decrease in the overall degree of stimulation. An even greater increase in the amount of interferon produced was observed if cells were treated with cycloheximide for only 3 to 4 hr immediately after their exposure to poly I:poly C. Under the latter conditions, a rapid burst of interferon production occurred after the reversal of cycloheximide action. Treatment with a high dose of actinomycin D before the reversal of cycloheximide action caused a further increase and a marked prolongation of interferon production. It is postulated that inhibitors of protein synthesis suppress the accumulation of a cellular regulatory protein (repressor) which interacts with the interferon messenger ribonucleic acid mRNA and thereby prevents its translation. Therefore, active interferon mRNA can apparently accumulate in rabbit kidney cells which, after exposure to poly I:poly C, are kept in the presence of an inhibitor of protein synthesis. Some of this accumulated interferon mRNA can be translated during a partial block of cellular protein synthesis, but its most efficient translation occurs after the reversal of the action of the protein synthesis inhibitor.     

Noncoordinate control of RNA synthesis in eucaryotic cells

Inhibition of protein synthesis in confluent monolayers of chick fibroblasts stimulates selectively the synthesis of 4S RNA, resulting in a net accumulation of 4S RNA in the inhibited cells. Under these conditions, inhibition of ribosomal RNA synthesis and processing occurs, as does a decrease in soluble uridine phosphate concentrations; increased pools of certain amino acids are also apparent. Recovery of cells from inhibition is accompanied by a rapidly increasing rate of protein synthesis that lasts for several hours. The small molecular weight RNA synthesized during inhibition of protein synthesis appears properly methylated, and in the presence of cycloheximide and actinomycin D shows a precursor-product conversion. Radiolabeled RNA synthesized during inhibition of protein synthesis is stable following the recovery of cells from inhibition. Stimulation of uridine incorporation into 4S RNA during arrest of protein synthesis is also demonstrated in high-density cultures of L- and Hep-2 cells, suggesting that this non-coordinate stimulation of 4S RNA may be a general property of eucaryotic cells.     

Inefficiency of the stringent response in the fungus Mucor

Removal of a required amino acid from the growth medium or addition of cycloheximide caused an immediate stoppage of growth and protein synthesis in the fungus $\text{Mucor}\text{racemosus}$. However, RNA synthesis persisted for several hours at rates that only gradually decreased under the same circumstances. An analysis of the major classes of RNA synthesized during the first hour of treatment showed that cycloheximide preferentially inhibited rRNA synthesis, whereas amino acid starvation slowed synthesis of all RNA species uniformly. Neither treatment affected the percentage of mRNA synthesized. The partial and delayed effects of amino acid starvation and cycloheximide treatment on RNA synthesis reported here suggest the absence of or the gross inefficiency of a classical stringent response in $\text{M.}\text{racemosus}$.     

Selective Inhibition of Reovirus Ribonucleic Acid Synthesis by Cycloheximide

Cycloheximide, at a concentration of 10 mug/ml, rapidly blocked protein synthesis in L cells infected with reovirus. When the drug was added before 5 hr postinfection, synthesis of both single- and double-stranded varieties of virus-specific ribonucleic acid (RNA), which normally commences between 6 and 7 hr after infection, was blocked. When the cycloheximide was added at 9 hr after infection, uptake of uridine-H(3) into RNA, for the succeeding 6 hr at least, was similar to that of an infected culture without the drug. This latter uptake of uridine-H(3) in the presence of cycloheximide was largely into single-stranded RNA, since double-stranded RNA synthesis was rapidly and markedly inhibited by the cycloheximide. Single-stranded RNA formed in the presence of cycloheximide was found not to be a precursor of viral progeny, double-stranded RNA. Synthesis of double-stranded RNA in the infected cell probably requires prior synthesis of a new protein, which has a rapid rate of turnover. The possibility that formation of single-stranded RNA is preceded by synthesis of a second new protein is discussed.     

Synthesis of macromolecules by Escherichia coli near the minimal temperature for growth

When a culture of Escherichia coli ML30 growing exponentially at 37 C in a glucose minimal medium was shifted abruptly to 10 C, growth decreased for about 4.5 hr. There was no net synthesis of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein. The cells, however, respired at a rate characteristic of cells growing in the steady state at 10 C and were able to accumulate alpha-methyl-d-glucoside. When growth recommenced at 10 C, protein synthesis started at 4 hr, RNA synthesis, with a burst at 6 hr, and DNA synthesis, with a burst at 7 hr. One synchronous division occurred at about 11 hr after shifting to 10 C. There was no alteration in the steady-state RNA to protein ratio. The results are discussed in relation to other reported effects of shifts in environmental conditions. The lag at 10 C was dependent on prior conditions of growth at 37 C. Growth at 37 C under conditions giving catabolite repression were necessary for the lag to be established on shifting to 10 C.     

Inhibition of Host-Cell Protein and Ribonucleic Acid Synthesis by Newcastle Disease Virus

The mechanisms of Newcastle disease virus-(NDV) induced inhibition of cell protein and ribonucleic acid (RNA) synthesis were investigated. It was observed that the ability of NDV to inhibit cell RNA synthesis is dependent on the virus strain. The inhibitors, azauridine and cycloheximide, were added to cell cultures at different times after infection to study the roles of protein and RNA synthesis in the viral inhibition process. Viral inhibition of cell RNA synthesis and viral inhibition of cell protein synthesis become resistant to cycloheximide at a different time after infection than that in which they become resistant to azauridine. The results indicate that the inhibition of cell RNA synthesis by the Texas strain involves the synthesis of inhibitory proteins which are coded by the viral genome. The Texas and Beaudette strains of NDV appear to employ different mechanisms for the inhibition of host-cell protein synthesis. Viral inhibition of cell protein synthesis does not appear to cause, or be the result of, viral inhibition of cell RNA synthesis.     

Rifampicin Inhibition of Ribonucleic Acid and Protein Synthesis in Normal and Ethylenediaminetetraacetic Acid-Treated Escherichia coli

The kinetics of ribonucleic acid (RNA) and protein synthesis in rifampicin-inhibited normal and ethylenediaminetetraacetic acid (EDTA)-treated Escherichia coli was measured. Approximately 200-fold higher external concentrations of rifampicin were needed to produce a level of inhibition in normal cells comparable to that observed in EDTA-treated cells. The rates of RNA and protein synthesis in both kinds of cells decreased exponentially, after an initial lag phase, at all rifampicin concentrations tested. The lag phase was longer and the final exponential slope less for protein synthesis than for RNA synthesis at a given rifampicin concentration. Below certain rifampicin concentrations, both the lag phase and the subsequent exponential decrease in the rates of RNA and protein synthesis were found to be rifampicin concentration dependent. At greater concentrations only the time of the lag phase was decreased by higher rifampicin concentrations, whereas the slope of the exponential decrease in the rates of RNA and protein synthesis was unaffected. In all cases, the exponential decrease continued to at least a 99.8% inhibition of the original rate of synthesis. These in vivo results are consistent with the mode of rifampicin action determined from in vitro studies; rifampicin prevents initiations of RNA polymerase on deoxyribonucleic acid, but not its propagation, by binding the enzyme essentially irreversibly. The results also indicate the size distribution of messenger RNA molecules in E. coli under our conditions.     

Differential effects of analogs of cycloheximide on protein and RNA synthesis in Achlya

Analogs of the glutarimide antibiotic cycloheximide were tested for their effect on growth and incorporation of proline and uridine into acid-insoluble material in Achlya bisexualis. Each of the compounds tested had reduced antibiotic activity as compared to cycloheximide. The effects of the antibiotics on protein and RNA synthesis were varied. While cycloheximide inhibited both protein and RNA synthesis immediately, two of the analogs inhibited proline incorporation without effect on uridine incorporation, while three, each representing a modification of the hydroxyl of cycloheximide, stimulated uridine incorporation and either had no effect on or inhibited protein synthesis. These results indicate that the control of RNA synthesis by protein synthesis in Achlya can be released by glutarimide antibiotics.     

The effect of amino acid starvation on nucleoside uptake and RNA synthesis in Tetrahymena

The uptake of nucleosides and the synthesis of RNA in Tetrahymena thermophila were examined following amino acid starvation. Omission of leucine, phenylalanine, or arginine from the medium resulted in a rapid decrease in the incorporation of [3H]uridine into the acid-soluble pool and acid-insoluble material (RNA). Amino acid starvation inhibited the uptake of all ribo- and deoxyribonucleosides tested but did not affect the uptake of amino acids or glucose. In addition, under the conditions used, the omission of an amino acid did not result in a large decrease in amino acid incorporation into total protein. Treatment of cells with cycloheximide or emetine gave results similar to the effects of amino acid starvation, but in these experiments the inhibition of protein synthesis was essentially complete. Nucleotide pool sizes were also measured following amino acid starvation. ATP and UTP levels were essentially unchanged, but the dTTP pool size was decreased by 40%. The decrease in RNA synthesis in vivo in the absence of an essential amino acid was reflected in the endogenous RNA synthetic activity of isolated nuclei. However, when solubilized RNA polymerase activity was measured with calf thymus DNA as template, no significant difference was observed between control and amino acid-starved cells.     

Effect of cordycepin (3''-deoxyadenosine) on virus-specific RNA species synthesized in Newcastle disease virus-infected cells.

Cordycepin (3'-deoxyadenosine) has no effect on the size or relative proportions of Newcastle disease virus-specific 18-22S mRNA species nor on the amount or size of the polyadenylic acid associated with them. Cordycepin does, however, cause an inhibition of incorporation of [3H]uridine into 50S virus-specific RNA relative to 18-22S RNA. This inhibition is probably not a direct effect of the drug on the synthesis of 50S viral RNA. Like cycloheximide, another drug which inhibits 50S RNA accumulation in paramyxovirus-infected cells, cordycepin inhibits protein synthesis as measured by amino acid incorporation. It is likely that the inhibition of 50S RNA accumulation is a secondary effect of protein synthesis inhibition. This is supported by the finding that concentrations of cordycepin and cycloheximide, which inhibit protein synthesis to the same extent, have the same effect on the ratio of 50 to 18-22S virus-specific RNA.     

Macromolecular Synthesis in Saccharomyces cerevisiae in Different Growth Media

Synthesis of ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and protein was determined in Saccharomyces cerevisiae during amino acid and pyrimidine starvation and during shift-up and shift-down conditions. During amino acid starvation, cell mass, cell number, and RNA continued to increase for varying periods. During amino acid and pyrimidine starvation, cell mass and RNA showed little increase, whereas total DNA increased 11 to 17%. After a shift from broth medium to a minimal defined medium, increase in RNA and protein remained at the preshift rate before assuming a lower rate. DNA increase remained at an intermediate rate during shift-down, and then dropped to a low rate. During shift-up from minimal to broth medium, increase in cell number, protein, and DNA showed varying lag periods before increasing to the new rate characteristic of broth medium; each of these quantities exhibited a step sometime in the first 2 hr after transfer to rich medium, suggesting a partial synchronous division. Immediately after shift-up, RNA synthesis assumed a high rate, and then dropped to a rate characteristic of growth in the rich medium after about 1 hr.     

Ribonucleic Acid Synthesis During Morphogenesis in Myxococcus xanthus

Ribonucleic acid synthesis was measured during the morphogenesis of Myxococcus xanthus. After induction of microcyst formation by the addition of glycerol to an exponential culture, net ribonucleic acid (RNA) synthesis was immediately terminated (measured either chemically or by the accumulation of acid-insoluble radioactivity). Extensive RNA turnover did take place, however, including RNA made both before and after induction. Sucrose gradient centrifugation revealed that ribosomes and ribosomal RNA were synthesized during microcyst formation even though there was no net RNA synthesis. Base analyses of the total RNA of vegetative cells and 120-min microcysts were indistinguishable.     

Macromolecular synthesis, differentiation and cell division in Tetrahymena pyriformis, mating type I variety 1

In Tetrahymena pyriformis, mating type I, variety 1, cycloheximide rapidly and completely inhibited incorporation of ¹⁴C-L-leucine into protein. Actinomycin D (25 μg per ml) inhibited incorporation of ¹⁴C-uracil into cold-TCA-insoluble material, after a 5–10 minute lag. Frequently a subsequent decline in the amount of radioactivity was observed. Protein synthesis continued in actinomycintreated cultures for a variable time after cessation of RNA synthesis. Oral development was affected by cycloheximide virtually immediately, and by actinomycin D after a 10–15 minute lag. Cells affected by either drug before the onset of oral membranelle formation were permanently arrested in the stomatogenic field phase. Cells affected in the early and middle stages of membranelle formation completed development of membranelles, but did not invariably complete cell division. Cycloheximide, when added at the beginning of membranelle formation, brought about arrest or resorption of membranelles after they were completed. Actinomycin did not elicit resorption, but sometimes brought about blockage during cell division. Cells affected by either drug after membranelles were fully formed (and cell division was just beginning) completed oral development, nuclear divisions, and cell division. These results suggest that concurrent RNA and protein synthesis are essential for the initiation but not for the completion of membranelle differentiation. The results also suggest that a specific messenger RNA(s) with a very short half-life is required for the synthesis of proteins involved in the initiation of membranelle differentiation.     

Macromolecular syntheses and the course of cell cycle events in the chlorococcal algaScenedesmus quadricauda under nutrient starvation: Effect of nitrogen starvation

Daughter cells of the chlorococcal algaScenedesmus quadricauda incubated under photosynthesizing conditions in a nitrogen-free medium did not make any progress in the cell cycle. Photosynthetic starch formation continued for a period corresponding to a half of the cell cycle and then levelled off. Protein synthesis was very slow and it did not surpass double the initial amount. RNA content decayed from the start of treatment and approached about 2 pg/cell. When a synchronous population was deprived of nitrogen or of light in the middle of the cell cycle RNA synthesis stopped immediately or very soon afterwards and, in spite ofabundant intracellular nitrogen reserves, RNA content slowly declined. This degradation was much extensive in nitrogen starved cells where, eventually, the RNA content attained about half the starting value. In both experimental variants, DNA replications started at the same time as in control culture, but the final amount of DNA attained only half the control value. Protein synthesis stopped immediately in the dark. In the nitrogen-starved cells, it continued for several hours and protein content increased about 70 % of the amount present at the start of starvation. The number of daughter cells formed was proportional to the final protein content in the nitrogen-and light-deprived cells (corresponding division numbers were 6 and 4, respectively). Upon refeeding of daughter cells formed under nitrogen starvation, RNA synthesis started immediately, while protein synthesis displayed a lag of about 5 h. DNA replications were triggered at the time when the ratio of RNA to DNA content attained the same value as in the control culture.