The roles of inducer and catabolite repressor in the synthesis of β-galactosidase by Escherichia coli

An Oral Fluorouracil Prodrug, Capecitabine, Mitigates a Gram-Positive Systemic Infection in Mice

New classes of antibiotics are needed to fight bacterial infections, and repurposing existing drugs as antibiotics may enable rapid deployment of new treatments. Screens for antibacterials have been traditionally performed in standard laboratory media, but bacterial pathogens experience very different environmental conditions during infection, including nutrient limitation. To introduce the next generation of researchers to modern drug discovery methods, we developed a course-based undergraduate research experience (CURE) in which undergraduate students screened a library of FDA-approved drugs for their ability, in a nutrient-poor medium, to prevent the growth of the human Gram-negative bacterial pathogen Salmonella enterica serovar Typhimurium. The nine drugs identified all disrupt DNA metabolism in bacteria and eukaryotes. One of the hit compounds, capecitabine, is a well-tolerated oncology drug that is administered orally, a preferred treatment route. We demonstrated that capecitabine is more effective at inhibiting S. Typhimurium growth in nutrient-limited than in standard rich microbiological broth, an explanation for why the antibiotic activity of this compound has not been previously recognized. Capecitabine is enzymatically converted to the active pyrimidine analogue, fluorouracil (5-FU), and Gram-positive bacteria, including Staphylococcus aureus, are significantly more sensitive to 5-FU than Gram-negative bacteria. We therefore tested capecitabine for efficacy in a murine model of S. aureus peritonitis. Oral capecitabine administration reduced the colonization of tissues and increased animal survival in a dose-responsive manner. Since capecitabine is inexpensive, orally available, and relatively safe, it may have utility for treatment of intractable Gram-positive bacterial infections. IMPORTANCE As bacterial infections become increasingly insensitive to antibiotics, whether established, off-patent drugs could treat infections becomes an important question. At the same time, basic research has revealed that during infection, mammals starve pathogens for nutrients and, in response, bacteria dramatically alter their biology. Therefore, it may be fruitful to search for drugs that could be repurposed as antibiotics using bacteria grown with limited nutrients. This approach, executed with undergraduate student researchers, identified nine drugs known to interfere with the production and/or function of DNA. We further explored one of these drugs, capecitabine, a well-tolerated human oncology drug. Oral administration of capecitabine reduced infection with the human pathogen Staphylococcus aureus and increased survival in mice. These data suggest that capecitabine has potential as a therapy for patients with otherwise untreatable bacterial infections.

5-Fluorouracil Treatment Alters the Efficiency of Translational Recoding

5-fluorouracil (5-FU) is a chemotherapeutic agent that has been extensively studied since its initial development in the 1950s. It has been suggested that the mechanism of action of 5-FU involves both DNA- and RNA-directed processes, but this has remained controversial. In this study, using a series of in vivo reporter constructs capable of measuring translational recoding, we demonstrate that cells exposed to 5-FU display a reduced capacity to engage in a variety of translational recoding events, including +1 programmed frameshifting (PRF) and −1 PRF. In addition, 5-FU-treated cells are much less accurate at stop codon recognition, resulting in a significant increase in stop codon-readthrough. Remarkably, while the efficiency of cap-dependent translation appears to be unaffected by 5-FU, 5-FU-treated cells display a decreased ability to initiate cap-independent translation. We further show that knockdown of thymidylate synthase, an enzyme believed to be at the center of 5-FU-induced DNA damage, has no effect on the observed alterations in translational recoding. On the other hand, ribosomal RNA (rRNA) pseudouridylation, which plays an important role in translational recoding, is significantly inhibited. Taken together, our results suggest that the observed effect of 5-FU on recoding is an RNA-directed effect. Our results are the first to show definitely and quantitatively that translational recoding is affected by exposure to 5-FU. Thus, it is possible that a substantial portion of 5-FU cytotoxicity might possibly be the result of alterations in translational recoding efficiency.

Developmental changes in transcriptional profiles

Recent advances in quantitation of mRNA by hybridization to microarrayed gene sequences or by deep sequencing of cDNA (RNA-seq) have provided global views of the abundance of each transcript. Analyses of RNA samples taken at 2 or 4 h intervals throughout development of Dictyostelium discoideum have defined the developmental changes in transcriptional profiles. Comparisons of the transcriptome of wild-type cells to that of mutant strains lacking a gene critical to progression through the developmental stages have defined key steps in the progression. The transcriptional response to cAMP pulses depends on the expression of pulse-independent genes that have been identified by transcriptional profiling with microarrays. Similar techniques were used to discover that the DNA binding protein GBF functions in a feed-forward loop to regulate post-aggregation genes and that expression of a set of late genes during culmination is dependent on the DNA binding protein SrfA. RNA-seq is able to reliably measure individual mRNAs present as a single copy per cell as well as mRNAs present at a thousand fold higher abundance. Using this technique it was found that 65% of the genes in Dictyostelium change twofold or more during development. Many decrease during the first 8 h of development, while the rest increase at specific stages and this pattern is evolutionarily conserved as found by comparing the transcriptomes of D. discoideum and Dictyostelium purpureum. The transcriptional profile of each gene is readily available at dictyBase and more sophisticated analyses are available on DictyExpress.

Global regulation of food supply by Pseudomonas putida DOT-T1E

Pseudomonas putida DOT-T1E was used as a model to develop a "phenomics" platform to investigate the ability of P. putida to grow using different carbon, nitrogen, and sulfur sources and in the presence of stress molecules. Results for growth of wild-type DOT-T1E on 90 different carbon sources revealed the existence of a number of previously uncharted catabolic pathways for compounds such as salicylate, quinate, phenylethanol, gallate, and hexanoate, among others. Subsequent screening on the subset of compounds on which wild-type DOT-TIE could grow with four knockout strains in the global regulatory genes Deltacrc, Deltacrp, DeltacyoB, and DeltaptsN allowed analysis of the global response to nutrient supply and stress. The data revealed that most global regulator mutants could grow in a wide variety of substrates, indicating that metabolic fluxes are physiologically balanced. It was found that the Crc mutant did not differ much from the wild-type regarding the use of carbon sources. However, certain pathways are under the preferential control of one global regulator, i.e., metabolism of succinate and d-fructose is influenced by CyoB, and l-arginine is influenced by PtsN. Other pathways can be influenced by more than one global regulator; i.e., l-valine catabolism can be influenced by CyoB and Crp (cyclic AMP receptor protein) while phenylethylamine is affected by Crp, CyoB, and PtsN. These results emphasize the cross talk required in order to ensure proper growth and survival. With respect to N sources, DOT-T1E can use a wide variety of inorganic and organic nitrogen sources. As with the carbon sources, more than one global regulator affected growth with some nitrogen sources; for instance, growth with nucleotides, dipeptides, d-amino acids, and ethanolamine is influenced by Crp, CyoB, and PtsN. A surprising finding was that the Crp mutant was unable to flourish on ammonium. Results for assayed sulfur sources revealed that CyoB controls multiple points in methionine/cysteine catabolism while PtsN and Crc are needed for N-acetyl-l-cysteamine utilization. Growth of global regulator mutants was also influenced by stressors of different types (antibiotics, oxidative agents, and metals). Overall and in combination with results for growth in the presence of various stressors, these phenomics assays provide multifaceted insights into the complex decision-making process involved in nutrient supply, optimization, and survival.

Intracistronic transcriptional polarity enhances translational repression: a new role for Rho

Transcriptional polarity in Escherichia coli occurs when cryptic Rho-dependent transcription terminators become activated as a consequence of reduced translation. Whether this is due to an increased spacing between the RNA polymerase and the leading ribosome or to prior functional inactivation of a subpopulation of the mRNAs has been a matter of discussion. Transcriptional polarity results in decreased synthesis of inefficiently translated mRNAs and therefore in decreased expression of downstream genes in the same operon (intercistronic polarity). By analogy, expression of the gene in which the conditional termination occurs is also expected to decrease, but this has so far not been demonstrated experimentally. To study the relevance of this intracistronic polarity for expression regulation in vivo, the polarity-prone IacZ reporter gene was fused to a range of mutated ribosome binding sites, repressed to different degrees by local RNA structure. Quantitative analysis of protein and mRNA synthesis shows that polarity occurs on functionally active mRNA molecules and that it indeed affects expression of the cistron carrying the terminator, thus enhancing the effect of translational repression. These findings point to a novel regulatory function of transcriptional polarity, reminiscent of transcriptional attenuation but opposite in effect.

Kinetics of penicillinase induction and variation of penicillinase translation in Staphylococcus aureus

At neutral pH, the rate of penicillinase synthesis by staphylococci declines gradually after removal of free inducer, while at pH 5.4 enzyme formation is generally linear for an extended period. Linear synthesis of penicillinase was observed at neutral pH in nonsaturating concentrations (1mug/ml) of actinomycin D. The rate of enzyme synthesis, corrected for inhibition of growth caused by the antibiotic, was relatively independent of the time of actinomycin addition. The lag preceding linear enzyme formation increased with the interval between induction and the addition of actinomycin. The findings are consistent with the concept that, at neutral pH, "operons" activated by induction are rapidly repressed, while at pH 5.4, this process is delayed. At a concentration of 4mug/ml, actinomycin D blocked penicillinase messenger synthesis and also elicited a short-lived acceleration of the increase of penicillinase activity in uninduced and, late after induction, in induced cultures. This effect did not require a functional genomic repressor mechanism since it occurred also in a penicillinase-constitutive strain. It required protein synthesis and could not be attributed to a greater enzyme stability in the presence of actinomycin. The results suggest enhanced penicillinase translation after addition of actinomycin D.

IONIZING RADIATION: EFFECT ON GENETIC TRANSCRIPTION

Cells of Escherichia coli grown on maltose can be induced by the addition of thiomethyl galactoside to produce beta-galactosidase. If cells are irradiated shortly after induction, the transcription of the DNA ceases, and the enzyme produced by the messenger RNA is observed to reach a maximum. From these data the calculated half-life of unstable messenger RNA is given over a temperature range from 8.1 minutes at 10 degrees C to 0.7 minute at 45 degrees C. The kinetics of cessation of transcription give information on both meassenger RNA decay and rate of transcription. Arrhenius graphs for both these rates are given, and the activation energies mtieasured are 11,000 calories per mole for decay and 22,000 calories per mole for transcription. This relation to temperature is characteristic of enzymatic behavior.

BETA-GALACTOSIDASE OF STREPTOCOCCUS LACTIS

Citti, J. E. (Oregon State University, Corvallis), W. E. Sandine, and P. R. Elliker. beta-Galactosidase of Streptococcus lactis. J. Bacteriol. 89:937-942. 1965.-Synthesis of beta-galactosidase by several strains of Streptococcus lactis was induced by lactose. The rate of hydrolysis of o-nitrophenyl-beta-d-galactopyranoside was used to measure enzyme activity. The enzyme of all but one strain was unstable when whole cells were sonic-treated or treated with toluene; the enzyme of one strain of S. lactis was stable to these treatments, which resulted in at least a fivefold increase in activity over that found in whole cells. The optimal assay conditions for toluene-treated cells of this strain involved incubation at 37 C in pH 7.0 sodium phosphate buffer. Lactose was the most effective inducer of enzyme synthesis. Methyl-beta-d-thiogalactopyranoside, isopropyl-beta-d-thiogalactopyranoside, and galactose were also inducers of the enzyme, but were not as effective as lactose. Melibiose, maltose, and calcium lactobionate were poor inducers of enzyme synthesis. Exogenously supplied glucose repressed enzyme synthesis. The means of control of induced beta-galactosidase synthesis in S. lactis was similar to that in Escherichia coli.

Metabolism and mechanism of action of 5-fluorouracil

This is a review on the mechanism of action of FUra. Three main areas are addressed: metabolism, RNA-directed actions of FUra, and DNA-directed actions of FUra. Key words for bibliographic purposes: metabolism, RNA, rRNA, mRNA, tRNA, DNA primase, DNA, thymidylate synthetase, uracil N-glycosylase, FUra, FUrd, FdUrd, FdUMP, RNA splicing, 5,10-methylene tetrahydrofolate, FUTP.

Survival of Escherichia coli and Salmonella spp. in estuarine environments

Survival of Escherichia coli and Salmonella spp. in estuarine waters was compared over a variety of seasonal temperatures during in situ exposure in diffusion chambers. Sublethal stress was measured by both selective-versus-resuscitative enumeration procedures and an electrochemical detection method. E. coli and Salmonella spp. test suspensions, prepared to minimize sublethal injury, were exposed in a shallow tidal creek and at a site 7.1 km further downriver. Bacterial die-off and sublethal stress in filtered estuarine water were inversely related to water temperature. Salmonella spp. populations exhibited significantly less die-off and stress than did E. coli at water temperatures of less than 10 degrees C. Although the most pronounced reductions (ca. 3 log units) in test bacteria occurred during seasonally warm temperatures in the presence of the autochthonous microbiota, 10(2) to 10(4) test cells per ml remained after 2 weeks of exposure to temperatures of greater than 15 degrees C. Reductions in test bacteria were associated with increases in the densities of microflagellates and plaque-forming microorganisms. These studies demonstrated the survival potential of enteric bacteria in estuarine waters and showed that survival was a function of interacting biological and physical factors.

Modulation of gene expression in Escherichia coli infected with single-stranded bacteriophage phi X174

Synthesis of tryptophanase, D-serine deaminase and alkaline phosphatase in Escherichia coli C was repressed as the result of infection with the single-stranded DNA bacteriophage phi X174. However, the degree of repression differed, the more catabolite-sensitive the operon was, the more severe was the repression. For the catabolite-sensitive enzymes it was found that cyclic adenosine 3'5' monophosphate (cyclic AMP or cAMP) was unable to release or reduce the phage-induced inhibition. Experiments with amber mutants of phi X174 revealed that A, product of cistron A, was responsible for the inhibition. The cistron A product probably acted at the level of transcription. The possible role of A in the observed modulation of gene expression is discussed.

In situ development of sublethal stress in Escherichia coli: effects on enumeration

Development of sublethal stress in Escherichia coli exposed in situ to estuarine waters was examined during various seasons. An electrochemical detection technique was utilized to derive a stress index based upon the difference between a predicted electrochemical response time in Trypticase soy broth or EC medium at 44.5 degrees C estimated from a standard curve for unstressed cells and an observed response time for cells exposed to seawater. This stress index was related to recovery efficiencies of seawater-exposed cells, using a variety of standard and resuscitative enumeration procedures. Stress was further studied by determination of the adenylate energy charge. Sublethal stress as measured by the electrochemical detection method was an inverse function of water temperature, with maximum stress occurring after exposure to temperatures below 10 degrees C. Total adenylates and ATP decreased dramatically at low temperatures, although energy charge remained relatively constant under various environmental conditions. Decreases in E. coli ATP suggest that ATP may not be an adequate measure of biomass for in situ stressed cells. Discrepancies in enumeration efficiency were most pronounced at temperatures below 10 degrees C. Resuscitative procedures for solid-media techniques increased the recovery of stressed cells under cold water conditions but were not as effective as the standard most-probable-number procedure.

Evidence for long-lived mRNA during fruiting body formation in myxococcus xanthus

Half-lives of Myxococcus xanthus mRNA were determined by inhibiting RNA polymerase with rifampin and then measuring the rate of [35S]methionine incorporation into protein. Vegetative cells resuspended in clone fruiting liquid culture showed an average mRNA half-life of approximately 3.5 min. Developmental cells (24 or 48 hr) exhibited biphasic decay curves with apparent mRNA half-lives of approximately 3.5 min and 20-30 min. The more-stable mRNA species accounted for about 30% of all mRNA present in 24-hr cells and as much as 40% of all mRNA of 48-hr cells. Analysis of the 35S-labeled proteins by NaDodSO4/polyacrylamide gel electrophoresis showed that only 5-10 major polypeptides are synthesized after 30 min of rifampin treatment. One of these is protein S, the spore surface coat protein, because immunoprecipitation of the 35S-labeled proteins with antisera specific for protein S showed continued synthesis of protein S in the presence of rifampin. The half-life for its mRNA was calculated to be 15-30 min. RNA from vegetative and developing cells was pulse labeled with 32PO4 followed by rifampin treatment. Analysis of the labeled RNA on 3% NaDodSO4/polyacrylamide gels showed 5-10 long-lived mRNA bands in developing cells. These results show that there are several abundant mRNA species synthesized developmentally that are exceptionally long lived. The fact that the majority of the mRNA species show the shorter half-life suggests that developing cells retain the normal mechanism for mRNA degradation.

Ribitol dehydrogenase messenger RNA from an enzyme superproducer strain of Klebsiella aerogenes. Purification, cell-free translation and studies in vitro and in vivo

1. Ribitol dehydrogenase messenger RNA, from a strain of Klebsiella aerogenes that had been evolved to superproduce this enzyme, has been purified in a single step by labelling extracted polysomes with rabbit anti(ribitol dehydrogenase) and immunoprecipitating with sheep anti-(rabbit IgG). 2. The extracted mRNA is stable in a protein synthesis system in vitro and directs synthesis 35-40-times more efficiently than RNA from coliphages MS2 or Q beta, to give ribitol dehydrogenase as sole major product. 3. Its size distribution shows a major band of 1500 nucleotides plus fragments 400-1400 nucleotides, with only traces of size 2400-3000 nucleotides. Only the latter could encode both proteins of the operon: ribitol dehydrogenase and D-ribulokinase. 4. Ribitol dehydrogenase mRNA represents 24% of total mRNA in cells harvested just after a 'switch' point' in mid-exponential phase. About half of the polysomes containing this mRNA are unattached to DNA, whereas only 3% of other mRNAs are unattached to DNA. 5. This mRNA is not outstandingly stable in vivo, though there are indications that it may be more stable than average. Hence the high level of synthesis of ribitol dehydrogenase (up to 30% of total protein in an extract) seems to be due to very efficient transcription and translation from multiple copies of a constitutive rbtD gene.

A novel form of suppression due to an altered RNA polymerase

A group of mutants isolated from E coli K12(tif-1) display a very pleiotropic phenotype. The main characteristic of these mutants, temporarily designated 'S' strains, is their ability to suppress a large number of mutations. High efficiency of suppression is correlated with increased thermolability of cellular proteins, indicating an impairment in the fidelity of protein synthesis. Efficient suppression is also accompanied by the appearance of new characteristics like simultaneous resistance to several antibiotic drugs (Sm, Spc, and Mer), and plasmid-like DNA circles. Genetic studies show that the suppressor character is located in the rpoBC region. In a large number of spontaneous Rifr mutants, isolated from these strains, suppression or resistance to drugs is lost. The findings suggest that the phenotype of 'S' strains is due to an altered RNA polymerase causing erroneous transcription.

Unusual stability and translation kinetics of an Escherichia coli lac messenger RNA synthetized during amino-acids deprivation

Escherichia coli, cultured on minimal medium and deprived of its required amino-acids, was induced for lac genes transcription. After inducer removal and restoration of growth, beta-galactosidase synthesis was measured. Two different kinetics of enzyme synthesis were observed depending on the starvation conditions employed during the induction period: 1. beta-galactosidase synthesis was immediately obtained and a plateau was reached, in 20 min after restoration of growth, when cells had been induced during deprivation of amino-acids and carbon source. 2. beta-galactosidase displayed an unusually long rate of synthesis, and plateau was not reached before two doubling times, when cells had been induced during the deprivation of the sole amino-acids. The latter result points out a problem of messenger stability during those long translation kinetics and led us to study the behaviour of strains carrying lac genetic determinants on different replicative structures; chromosomic and plasmidic. In those two situations, induction of lac messenger RNA was obtained and ratify our previous observations. However, their translation kinetics suggest a DNA linkage of this induced messenger.

The mechanism of catabolite inhibition of invertase by glucose in Saccharomyces cerevisiae

Saccharomyces cerevisiae -136ts synthesized invertase in media containing maltose and sucrose. In the presence of glucose synthesis of enzyme took place when the sugar concentration was lower than 1%. At higher concentrations enzyme formation was repressed. Analysis of the glucose effect before RNA inhibition showed that the hexose interfered with the transcription of DNA into invertase messenger RNA. Translation of invertase messenger already formed was also inhibited and the kinetics of this effect was similar to that produced by cycloheximide. Invertase activity was independent of glucose suggesting that the hexose produces no catabolite inhibition of invertase activity. Inhibition of invertase translation by glucose turned out to be reversible but the amount of enzyme produced was dependent on duration of treatment. It is suggested that the catabolite repression of invertase synthesis produced by glucose operates at the levels of transcription and translation and produces an increase in the rate of mRNA degradation. The catabolite repression has no effect on secretion and does not interfere with the catalytic activity of invertase.

Synthesis of inducible enzyme in Escherichia coli recovering from prolonged energy starvation

A marked breakdown of ribosomes and rRNA occurs in Escherichia coli cells during prolonged deprivation of a carbon source (energy starvation). In E. coli recovering from energy starvation: (a) synthesis of RNA started immediately, total protein synthesis showed a delay of 5 to 10 minutes; (b) beta-galactosidase, tryptophanase and serine deaminase could not be induced in the first 50--70 min; (c) a lag of 60 min in the synthesis of beta-galactosidase was observed in a lac constitutive mutant of E. coli; synthesis of the constitutive enzyme malate dehydrogenase did not shown any delay. RNA synthesized in the early stages of recovery contained a higher percentage of low molecular weight molecules than RNA synthesized after 70 min of recovery or during exponential growth. Messenger RNA specific for beta-galactosidase was not synthesized for the first 50--60 min of recovery even when the specific inducer was added to the cultures.

Regulation of penicillin acylase in Escherichia coli by cyclic AMP

1. Cyclic AMP was found to stimulate penicillin acylase activity. 2. It also overcame the repression of glucose and restored enzyme synthesis to the non-repressed levels. 3. The conversion of inactive enzyme precursor into active enzyme was not stimulated by cyclic AMP in cells in which protein synthesis was inhibited by chloramphenicol. 4. Cyclic AMP failed to stimulate enzyme production in cells in which messenger RNA synthesis was arrested by rifampicin or inducer removal. 5. Cyclic AMP appears to participate in the regulation of this enzyme at the transcriptional level.

Level of redox potential as a possible contributing influence in the pathogenicity of oral anaerobes

Dental plaque anaerobes may be associated with the etiology of periodontal disease. This has created an interest in the potential pathogenicity of oral anaerobes. We compared the metabolic activity of anaerobic corynebacteria (C. parvum, C. anaerobium) and corresponding aerobic species (C. diphtheriae, C. xerosis). The anaerobes exhibited lower levels of RNA synthesis, ranging from 5 to 10 fold over the aerobes. We further examined these anaerobes, plus Actinomyces naeslundi N16 (isolated from the anaerobic region of periodontally-diseased tissues), for the influence of redox potential on RNA level and antigenic function. Notable increases in RNA were found at specific Eh levels; the extent and direction of the changes varied with the different organisms. This environmental feature appeared to effect corresponding changes in agglutinability and PCA reactivity with antisera against the anaerobes cultured at different redox potentials. For example, while antisera against certain organisms (C. parvum, A. naeslundi) cultured under the most reuced conditions showed an intense PCA reaction, other antisera against the same organism cultured under less reduced conditions were non-reactive. Hence, alterations in redox potential may lead to alteredetabolism and to altered antigencity. Our results imply such a microbial response to environmental stress.

An adenosine 3',5'-monophosphate-requiring mutant of the luminous bacteria Beneckea harveyi

We have isolated a mutant of the luminous bacterium Beneckea harveyi, which requires exogenous adenosine 3',5'-monophosphate (cyclic AMP) to synthesize luciferase and emit light. The mutant was pleiotropic, lacking not only the ability to luminesce, but also the capacities to form flagella and the ability to utilize a variety of carbohydrates for growth. All these deficiencies could be corrected by added cyclic AMP. The cyclic AMP-induced de novo synthesis of luciferase was possible only after autoinduction had occurred. The induction time by cyclic AMP ranged between 6 and 10 min at 27 degrees C.

Very stable prokaryotic messenger RNA in chromosomeless Escherichia coli minicells

E. coli minicells lack DNA, yet they make protein, the synthesis of which is sensitive to chloramphenicol but insensitive to rifamycin. This protein is coded for by very stable cellular mRNA with an estimated half-life of 40-80 min. In an R factor-containing minicell, two very different species of mRNA are observed: (i) R factor-specific mRNA with a short half-life whose synthesis is rifamycin-sensitive and (ii) cellular mRNA with a long half-life whose synthesis is rifamycin-insensitive. These findings indicate that minicells contain normal degradative mechanisms for mRNA and point out the existence of a unique class of very stable cellular mRNA. Greater than 80% of the rifamycin-insensitive protein synthesized goes into the outer minicell membrane. Relatively stable mRNA, half-life 5.5-11.5 min, for outer membrane protein in whole cells has been reported [Hirashima et al. (1973) J. Mol. Biol. 79, 373-389]. The stability of minicell mRNA is significantly greater. This and other observations suggest that there are two functional species of mRNA for outer membrane protein perhaps in different sites in the cell. Furthermore, these studies suggest that a class of cellular proteins is synthesized in bacteria without concomitant transcription and in the absence of association with chromosomal DNA.

Stimulation of derepressed enzyme synthesis in bacteria by growth on sublethal concentrations of chloramphenicol

Culturing of Salmonella typhimurium or Escherichia coli cells in the presence of low concentrations (</=1 mug/ml) of chloramphenicol (CAP) permitted exponential growth, but at doubling times up to twice those of controls. When such cultures were subsequently starved for uracil or arginine, derepression of aspartate transcarbamylase (ATCase) or ornithine transcarbamylase, respectively, was enhanced three- to 10-fold as compared to cultures not exposed to CAP. Enhancement of beta-galactosidase synthesis by prior exposure to CAP was also observed in uracil-starved E. coli cultures. Stimulation of enzyme synthesis appeared to be a specific effect of CAP; low levels of erythromycin, puromycin, sparsomycin, tetracycline, and rifampin did not show such effects. Derepression of ATCase synthesis in exponentially growing cells in the presence of CAP did not result in stimulation of enzyme synthesis by CAP. A prior history of growth of a culture in the presence of CAP was shown to be necessary for enhancement of enzyme synthesis by CAP; furthermore, continued presence of CAP in the medium during starvation was not necessary for enhanced enzyme synthesis and inhibited it in some instances. Enhanced enzyme synthesis in starving, CAP-treated cultures could be blocked by rifampin, which suggested that CAP treatment allows prolonged or more extensive messenger ribonucleic acid synthesis.

Strain of Escherichia coli with a temperature-sensitive mutation affecting ribosomal ribonucleic acid accumulation

A mutant of Escherichia coli has been isolated that has a temperature-sensitive mutation that results in specific loss of ribosomal ribonucleic acid (RNA) synthesis and some reduction in messenger RNA synthesis. When the strain was grown in glucose medium at a restrictive temperature, RNA accumulation ceased, but both messenger RNA and protein synthesis continued for an extended time. Because carbon metabolism was slowed drastically when strain AA-157 was placed at the restrictive temperature, this phenotype can be compared with carbon depletion conditions present during diauxic lag. However, the phenotype of mutant AA-157 differs from shift-down conditions in that guanosine-3',5'-tetraphosphate levels are unaffected; therefore, a different site is affected. This mutant strain (AA-157) thus shows many characteristics similar to an aldolase mutant previously reported (Böck and Neidhardt, 1966). However, the mutation occurred in a different position on the E. coli genetic map, and furthermore, aldolase was not temperature sensitive in strain AA-157. In this paper we present a study of macromolecular biosynthesis in this mutant.

Streptomycin-induced synthesis of abnormal protein in an Escherichia coli mutant

To determine directly the effects of streptomycin on translational fidelity in intact cells, we studied the synthesis of beta-galactosidase and of the coat protein of bacteriophage R17 in an Escherichia coli mutant in which the bactericidal effects of streptomycin are delayed. After the addition of streptomycin to exponentially growing mutant cells, protein synthesis continues at an undiminished rate for approximately an hour; however, as measured by enzyme assays, little functional protein is produced. Serological assays designed to detect beta-galactosidase and bacteriophage R17 coat protein show that substantial amounts of the protein synthesized can react with antisera prepared against active beta-galactosidase and phage R17, indicating the aberrance of the protein produced in the presence of the antibiotic. The polypeptides synthesized in the presence of streptomycin are degraded in the cell to a much greater extent than protein synthesized in the absence of the antibiotic. The proteolytic attack on this protein is not affected by inhibitors of serine proteases, suggesting that enzymes other than those involved in "normal turnover" of cellular protein are responsible. In this strain, certain of the multiple effects of streptomycin are separated in time and the production of abnormal protein (enzymatically inactive and susceptible to proteolytic attack) could be studied in the absence of the lethal effect of the drug.