Turnover as a control of ribonucleic acid accumulation in bacteria undergoing stepdown.

The synthesis of ribosomes was compared in rel+ and rel- strains of Escherichia coli undergoing "stepdown" in growth from glucose medium to one with lactate as principal carbon source. Two strains (CP78 and CP79), isogenic except for rel, showed similar behaviour with respect to (1) the kinetics of labelling total RNA and ribosomes with exogenous uracil, (2) the proportion of newly formed protein that could be bound with nascent rRNA in mature ribosomes, and (3) the rate of induction of enzymically active beta-galactosidase (relative to the rate of ribosome synthesis). It was concluded that, as there was no net accumulation of RNA during stepdown in either strain, rRNA turnover must be occurring at a high rate. The general features of ribosome maturation in rel+ and rel- cells were almost identical with those found in auxotrophic rel+ organisms starved of required amino acids. In both cases, there was a considerable delay in the maturation of new ribosomal particles, owing to a relative shortfall in the rate of synthesis of ribosome-associated proteins. Only about 4-5% of the total protein labelled during stepdown was capable of binding with newly formed rRNA. This compared with 3.5% for rel+ and 0.5% for rel- auxotrophs during amino acid starvation. The turnover rate for newly formed mRNA and rRNA was virtually the same in "stepped-down" rel+ and rel- strains and was similar to that of the same fraction in amino acid-starved rel+ cells. The functional lifetime of mRNA was also identical. It seems that in the rel- strain many of the characteristics typical of the isogenic rel+ strain are displayed under these conditions, at least as regards the speed of ribosome maturation and the induction of beta-galactosidase. Studies on the thermolability of the latter enzyme induced during stepdown indicate that inaccurate translation, which occurs in rel- strains starved for only a few amino acids, is less evident in this situation than in straightforward amino acid deprivation.     

Mutants of Salmonella typhimurium with an Altered Leucyl-Transfer Ribonucleic Acid Synthetase

Two trifluoroleucine-resistant mutants of Salmonella typhimurium, strains CV69 and CV117, had an altered leucyl-transfer ribonucleic acid (tRNA) synthetase. The mutant enzymes had higher apparent K(m) values for leucine (ca. 10-fold) and lower specific activities (ca. twofold) than the parent enzyme when tested in crude extracts. Preparations of synthetase purified ca. 60-fold from the parent and strain CV117 differed sixfold in their leucine K(m) values. In addition, the mutant enzyme was inactivated faster than the parent enzyme at 50 C. The growth rates of strains CV69 and CV117 at 37 C were not significantly different from that of the parent, whereas at 42 C strain CV69 grew more slowly than the parent. Leucine-, valine-, and isoleucine-forming enzymes were partially derepressed when the mutants were grown in minimal medium; the addition of leucine repressed these enzymes to wild-type levels. During growth in minimal medium, the proportion of leucine tRNA that was charged in the mutants was about 75% of that in the parent. The properties of strain CV117 were shown to result from a single mutation located near gal at minute 18 on the genetic map. These studies suggest that leucyl-tRNA synthetase is involved in repression of the enzymes required for the synthesis of branched-chain amino acids.     

Pleiotropic effect of a rifampin-resistant mutation in Bacillus subtilis.

Rifampin-resistant (Rifr) mutants were isolated spontaneously from Bacillus subtilis strain 168. A fraction of the mutants did not grow on a minimal medium. A high concentration of one of the L-amino acids (glutamic acid, glutamine, arginine, proline, aspartic acid, or asparagine) was required to restore their growth on the medium. Further analysis of one of the mutants (strain RF 161) suggested that the mutant is unable to use ammonia as a nitrogen source and requires amino acids instead. Activity of glutamate synthase was not detected in the crude extract of the mutant. The Rifr mutation was closely located to cysA and the drug resistance was cotransformed with the property of amino acid requirement at 100% frequency. All revertants to prototrophy tested showed the rifampin-sensitive (Rifs) property. The activity of the DNA-dependent RNA polymerase of the mutant was resistant to rifampin. It is concluded that some alteration of RNA polymerase may cause absence of the activity of an enzyme involved in the nitrogen metabolism.     

Translation of poly U by ribosomes from rel+ and rel- E. coli strains]

A translation of polyU in a cell-free system from CP78 (relA+) and CP79 (relA-) E. coli strains is investigated. The strains studied no not differ in misreading at Mg2+ concentration of 20 mM and concentrations of 16 mM (optimal for phenylalanine incorporation) and 18-22 mM (optimal for leucine incorporation) respectively. It is found that leucine incorporation increases similarly in both strains under conditions simulating an amino acid deficience (in phenylalanine-free incubation medium): the ratio leucine(-phenylalanine)/leucine (+phenylalanine) is 3.5-4 at a concentration of enzymatic fraction protein being 15-30 mkg per example, and it is 2 st a concentration of enzymatic fraction of 60-180 mkg of protein. It is suggested that differences in activities of a number of enzymes under amino acid starvation in Rel+ and Rel- cells are not due to differences in the precision of mRNA translation, but depend on the activity of respective genes.     

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.     

The control of ribonucleic acid synthesis in bacteria. Polymerization rates for ribonucleic acids in amino acid-starved relaxed and stringent auxotrophs of Escherichia coli

Polymerization rates of newly formed chains of various RNA fractions were measured in Escherichia coli CP78 (RC(str)) and CP79 (RC(rel)) multiple amino acid auxotrophs, deprived of four amino acids essential for growth. Immediately after the onset of severe amino acid deprivation, in RC(str) strains the rate of labelling of RNA by exogenous nucleotide bases was greatly diminished. At first, the initiation of new RNA chains declined faster than the rate of polymerization in RC(str) organisms, but as starvation proceeded the rate of polymerization was eventually lowered to about 10% of that found during normal growth. In strain CP79 (RC(rel)), on the other hand, chain-polymerization rates were unaffected by amino acid withdrawal. Artificial depletion of the intracellular purine nucleotide pools in RC(str) or RC(rel) strains by trimethoprim, before the onset of amino acid deprivation, showed that in the RC(str), but not the RC(rel) strain, amino acid withdrawal gave rise to an inability of the cells to utilize exogenously supplied purine or pyrimidine bases for RNA synthesis. During a prolonged starvation, the observed 100-fold decrease in the total rate of incorporation of exogenous nucleotide bases into the RNA of RC(str) organisms was ascribed to a combination of a tenfold decrease in the overall rate of RNA chain polymerization, at least a fivefold decrease in the ability of the cells to utilize exogenous bases and a preferential inhibition of initiation of stable RNA chains. None of these changes occurred in the corresponding RC(rel) strain.     

Effects of amino acids on polysaccharide synthesis ofEscherichia coli K-12lon + andlon − strains

Ultraviolet-sensitivelon ^? mutant ofEscherichia coli K-12 produced abundant polysaccharide when grown in a minimal medium at 37 C, but not when grown in a broth medium. The repression of polysaccharide synthesis in the broth-grownlon ^? andlon ⁺ cells was studied. The effects were largely dependent on the amino acid concentrations and on the requirements of the strain used. At 200 μg per ml of each of the essential amino acids, histidine, proline, and threonine, there was complete inhibition of polysaccharide synthesis. At 200 μg per ml the required amino acids, tryptophane and tyrosine promoted polysaccharide synthesis. Most amino acids inhibited cell growth at 200 μg per ml but the inhibiting effect was smaller at 400 μg per ml. Polysaccharide synthesis of cells was not correlated with the growth rate, and occurred even under non-growing conditions.     

flrB, a Regulatory Locus Controlling Branched-Chain Amino Acid Biosynthesis in Salmonella typhimurium

Salmonella typhimurium strain CV123 (ara-9 gal-205 flrB1), isolated as a mutant resistant to trifluoroleucine, has derepressed and constitutive levels of enzymes forming branched-chain amino acids. This strain grows more slowly than the parent at several temperatures, both in minimal medium and nutrient broth. It overproduces and excretes sizeable amounts of leucine, valine, and isoleucine in comparison with the parental strain. Both leuS (coding for leucyl-transfer ribonucleic acid [tRNA]synthetase) and flrB are linked to lip (min 20 to 25) by P1 transduction, whereas only leuS is linked to lip by P22 transduction. Strain CV123 containing an F' lip(+) episome from Escherichia coli has repressed levels of leucine-forming enzymes, indicating that flrB(+) is dominant to flrB. Leucyl-tRNA synthetase from strain CV123 appears to be identical to the leucyl-tRNA synthetase in the parent. No differences were detected between strain CV123 and the parent with respect to tRNA acceptor activity for a number of amino acids. Furthermore, there was no large difference between the two strains in the patterns of leucine tRNA isoaccepting species after fractionation on several different columns. Several other flrB strains exhibited temperature-sensitive excretion of leucine, i.e., they excreted leucine at 37 C but not 25 C. In one such strain, excretion at 37 C was correlated with derepression of some enzymes specified by ilv and leu. These latter results suggest that flrB codes for a protein.     

Polyamine Synthesis and Accumulation in Escherichia coli Infected with Bacteriophage R17

We have studied the biosynthesis of polyamines during the multiplication of the RNA bacteriophage R17. R17-sensitive strains of Escherichia coli were derived from the stringent CP78 and the relaxed mutant derivative CP79. The cells were infected with R17 in the presence or absence of arginine, a required amino acid, and both the RNA and polyamine contents of the bacteria were determined before and after the infection. The uninfected CP79 rel derivative accumulated RNA and spermidine in the absence of arginine, unlike the stringent organism that accumulated neither under these conditions. After R17 infection, the stringent strain accumulated RNA and spermidine in the presence or absence of arginine. The data indicate a close correlation between the synthesis of RNA and spermidine, suggesting a significant role for this polyamine in the multiplication of phage R17.     

The effect of alcohols on guanosine 5'-diphosphate-3'-diphosphate metabolism in stringent and relaxed Escherichia coli

The effects of a series of alcohols on the stringent response system of Escherichia coli were studied. The alcohols used could be divided into two groups on the basis of the response of pppGpp and ppGpp to the growth downshift induced by the alcohols. The cells responded to the alcohols, methanol, ethanol, and propanol, as if they were being starved of amino acids. In the stringent strain CP78 these alcohols induced pppGpp and ppGpp accumulation and curtailed RNA synthesis, whereas in the relaxed strain CP79, both of these responses were absent. It was determined that this response was most likely due to an interference by these alcohols with the uptake of amino acids required by these strains. By contrast both stringent and relaxed cells elevated their level of ppGpp and decreased RNA accumulation when treated with butanol or pentanol. This response is similar to the effect of carbon source limitation. It was determined that the elevation of ppGpp in the stringent strain was primarily the result of increased ppGpp synthesis in response to these alcohols. In the relaxed strain the rise in ppGpp was dependent on a decrease in ppGpp degradation coupled with a moderate increase in ppGpp synthesis. This stimulation of ppGpp synthesis in relaxed cells, although small, suggests the existence of an enzyme distinct from stringent factor which is capable of synthesizing ppGpp. Data are presented which suggest that the activity of this enzyme is coupled to the potential for protein synthesis and energy availability of the cell, perhaps being regulated by the overall ratio of unchanged to amino-acylated tRNA.     

Postirradiation recovery dependent on the uvr-1 locus in Bacillus subtilis.

A mutant (uvr-1) of Bacillus subtilis that is deficient in excision of ultraviolet (UV)-induced pyrimidine dimers from deoxyribonucleic acid (DNA) shows a marked increase in ability to survive UV irradiation when plated on amino acid-supplemented agar medium compared with its survival ability when plated on nutrient plating medium, the effect is considered to be one of growth-dependent lethality. Irradiated stationary phase uvr-1 cells, incubated in liquid medium lacking amino acids required for growth, recover from this sensitivity to rich medium within 3 to 4 h after irradiation. Recovery is greatly reduced in the absence of glucose oiminated. Exponentially growing cells have a limited ability to recover from sensitivity to rich medium. Growth-dependent lethality can also occur in liquid medium. In nutrient broth the ability of irradiated stationary-phase uvr-1 cells to form colonies on defined agar medium decreases during postirradiation incubation, but treatmeth with chloramphenicol inhibits the loss of colony-forming ability. Recovery from sensitivity to rich media is inhibited by caffeine but not by 6-(p-hydroxyphenylazo)-uracil, and inhibitor of DNA replication. Alkaline sucrose gradient profiles show that conditions allowing recovery also favor maintaining intact DNA strands, whereas DNA strand breakage or degradation is associated with loss of viability. Recovery from sensitivity to rich medium has not been observed in the Ur+ parent or in strains carrying the mutations uvs-42 (another deficiency in dimer excision), recA1, or polA59. A uvr-1 recA1 mutants shows a higher level of recovery than does the recA1 single mutant, but a much lower level than the uvr-1 single mutant. Apparently, both the uvr-1 defect and Rec+ and PoII+ functions are essential for recovery from sensitivity to rich medium. For optimal recovery, growth immediately after irradiation must be delayed. The process requires energy, apparently involves recombination, and probably results in rejoining of DNA strands in which incision but not excision has occurred.     

Defined minimal media for the growth of prototrophic and auxotrophic strains of Bacillus stearothermophilus

Minimal chemically defined media for Bacillus stearothermophilus were developed at 60°C and quantitative requirements for each nutrient were determined. A prototrophic strain of B. stearothermophilus was grown in medium containing only glucose and mineral salts whereas auxotrophic strains in addition required biotin, thiamine, nicotinic acid and DL-methionine. Metabolic interaction between L-valine and L-leucine was observed with auxotrophic organisms. The presence of L-leucine in minimal medium necessitated the addition of L-valine. Growth took place in the absence of both amino acids.     

5-Bromouracil-tolerant mutants of Bacillus subtilis

5-Bromouracil (BU)-tolerant mutants of Bacillus subtilis 23 (thy his) have been isolated. Several classes of tolerant mutants were obtained by a sequential selection procedure. The classes can be distinguished by their relative BU tolerance as well as several other phenotypic characteristics. The mutants can grow for an extended period of time in minimal medium supplemented with amino acids and BU, in which the sensitive parental strain (Bu(+)) undergoes rapid cell death. Both mutants But-1 and But-1310 have a greater rate of deoxyribonucleic acid (DNA) synthesis by a factor of two in the presence of BU than Bu(+), But-1 being somewhat faster than But-1310. The preferential incorporation of thymine to BU of But-1 is about half that of the Bu(+) strain during DNA replication in minimal medium supplemented with 10 mug of BU/ml and 1 mug of thymine/ml. It is not known at what step or steps this reduction in selectivity occurs.     

Development of Defined, Minimal, and Complete Media for the Growth of Hyphomicrobium neptunium

A complete synthetic medium containing 15 amino acids, a minimal synthetic medium (GAMS) containing 4 amino acids, and a supplemented minimal medium (GAMS + calcium pantothenate) have been developed for the cultivation of Hyphomicrobium neptunium ATCC 15444. Depending on the complexity of the synthetic media, generation times were approximately 2 to 3 times longer, and maximum cell densities were 0.3 to 0.9 log₁₀ lower than in ZoBell marine broth 2216. The fates of ¹⁴C-labeled amino acids in GAMS were monitored. Results suggested that H. neptunium was auxotrophic for methionine, utilized glutamic acid as a primary energy source, and readily anabolized and catabolized serine and aspartic acid. Individual amino acid concentrations above 125 mM induced prolonged lag periods, whereas only methionine was not growth limiting at a concentration as low as 2 mM.     

Replication of bacteriophage G13 DNA in dna mutants of Escherichia coli.

Host functions required for replication of microvirid phage G13 DNA were investigated in vivo, using thermosensitive dna mutants of Escherichia coli. In dna+ bacteria, conversion of viral single-stranded DNA into double-stranded replicative form (stage I synthesis) was resistant to 150 microgram/ml of chloramphenicol or 200 microgram/ml of rifampicin. Although multiplication of G13 phage was severely inhibited at 42--43 degrees C even in dna+ host, considerable amount of parental replicative form was synthesized at 43 degrees C in dna+, dnaA or dnaE bacteria. In dnaB and dnaG mutants, however, synthesis of parental replicative form was severely inhibited at the restrictive temperature. Interestingly enough, stage I replication of G13 DNA was, unlike that of phiX174, dependent on host dnaC(D) function. Moreover, the stage I synthesis of G13 DNA in dnaZ was thermosensitive in nutrient broth but not in Tris/casamino acids/glucose medium. In contrast with the stage I replication, synthesis of G13 progeny replicative form was remarkably thermosensitive even in dna+ or dnA cells.     

Dependence of Ribonucleic Acid Synthesis on Continuous Protein Synthesis in Yeast

Using an auxotrophic strain of Saccharomyces cerevisiae, we examined the kinetics of ribonucleic acid (RNA) synthesis following inhibition of protein synthesis caused by amino acid starvation or cycloheximide. Removal of a required amino acid immediately stopped net protein synthesis. After a brief lag, RNA synthesis also ceased. Cycloheximide, a ribosome-inhibiting drug, also immediately halted net protein synthesis. Again RNA synthesis stopped after a brief lag. Although cycloheximide and amino acid starvation affect different steps in protein biosynthesis, both inhibited RNA synthesis in identical fashion. This indicates that amino acids do not play a unique role in the control of RNA production in rapidly growing yeast; rather, it suggests that RNA synthesis is responsive to the overall rate of protein synthesis itself.     

Replication and expression of plasmid pBR 322 during discontinuous culture of a stringent and relaxed Escherichia coli strain

The E. coli strains CP78 and CP79 carrying the plasmid pBR 322 display similar growth kinetics in discontinuous culture. During limitation of amino acids the stringent strain CP78 is able to synthesize guanosine-5'diphosphate-3'-diphosphate (ppGpp) and guanosine-5'-triphosphate-3' diphosphate, but the relaxed strain can not produce highly phosphorylated guanosine nucleotides. During the logarithmic phase of growth both strains contain similar amounts of plasmid DNA. During amino acid starvation plasmid DNA is amplified in the relaxed strain only, whereas in the stringent strain the plasmid content per cell remains constant. In stationary phase cells of CP78 a higher activity of plasmid-coded beta-lactamase than in CP79 cells was detected. Furthermore, remarkable differences between both strains were observed in the composition of proteins derived from the periplasmic fraction and separated by polyacrylamide gel electrophoresis. Our results might indicate a negative control of pBR 322 DNA replication by ppGpp during amino acid starvation.     

Dissecting complex metabolic integration provides direct genetic evidence for CodY activation by guanine nucleotides

The global regulator CodY controls the expression of dozens of metabolic genes and genes mediating adaptation to nutrient availability in many low-G+C Gram-positive bacteria. Branched-chain amino acids L-isoleucine, L-leucine, and L-valine (ILV) activate CodY both in vivo and in vitro, and genes that direct their synthesis (ilv, ybgE, and ywaA) are highly repressed by CodY, creating a potential negative feedback loop. The nucleoside triphosphate GTP also activates CodY in vitro, but the evidence for activation by GTP in vivo is limited and indirect. We constructed a Bacillus subtilis strain (ybgE bcd ywaA) that is unable to convert branched-chain α-keto acids to ILV or to use ILV as a precursor for branched-chain fatty acid synthesis. Unexpectedly, the strain was not viable on rich medium. Supplementing rich medium with short, branched-chain fatty acids or derepressing expression of genes for de novo ILV synthesis bypassed the original lethality, restoring growth and showing that the lack of viability was due to insufficient intracellular production of the precursors of branched-chain fatty acids. Spontaneous extragenic suppressor mutants that arose in the triple mutant population proved to have additional mutations in guaA or guaB or codY. Expression of ILV biosynthetic genes in codY mutants was increased. The gua mutations caused guanine/guanosine auxotrophy and led to partial derepression of direct CodY-repressed targets, including ILV biosynthetic genes, under conditions similar to those that caused the original lethality. We conclude that a guanine derivative, most likely GTP, controls CodY activity in vivo.