A gene involved in the metabolic control of ppGpp synthesis

Summary A genetic locus has been identified which controls the basal synthesis of ppGpp in growing E. coli. Cells carrying a recessive allele of the relX gene have a very low concentration of ppGpp during balanced growth, and fail to accumulate ppGpp in response to carbon/energy source downshift. Moreover, the recessive relX allele renders the cells unable to grow at 42° C and, when coupled with relA, makes the cells sensitive to the presence of leucine in minimal medium. RelX is cotransduced with fuc and relA and located at approximately 59.4 min on the E. coli genetic map.     

The stringent response to unacylated tRNA,energy- and temperature-downshift in Bacillus stearothermophilus

The response of the thermophile Bacillus stearothermophilus to inhibition of tRNA acylation, energy starvation and temperature downshift was characterized. We found that B. stearothermophilus, like other prokaryotic organisms, reacts with the so-called stringent response, which includes the accumulation of the unusual nucleotides guanosine 3′,5′ bis (dipphosphate) [ppGpp] and guanosine 3′-diphosphate, 5′-triphosphate [pppGpp] and concomitantly the reduction of RNA synthesis and growth rate. The amount of (p)ppGpp formed depended on the cause of the stringent response: when tRNA acylation was inhibited (p)ppGpp synthesis was much higher than after energy starvation or temperature downshift whereas RNA synthesis was totally blocked in each case.     

Anomalous synthesis of ppGpp in growing cells.

In E. coli cells, accumulation of ppGpp is normally triggered by conditions that restrict the aminoacylation of tRNA or interfere with carbon/energy source metabolism; in both cases, the nucleotide's accumulation is associated with control of stable RNA synthesis and is generally believed to bring it about. We have found an anomalous situation wherein vigorously growing cells accumulate a high level of ppGpp and there is no restriction of stable RNA synthesis. This occurs when wild-type cells are shifted up from an abnormally low growth temperature to one in the optimal range (35 degrees C-40 degrees C). The effect is partly, but not entirely, dependent upon the presence of a functional relA gene product. These results appear to call into question the simpler interpretations of the role of ppGpp in the control of stable RNA synthesis.     

Basal ppGpp level adjustment shown by new spoT mutants affect steady state growth rates and rrnA ribosomal promoter regulation in Escherichia coli

Summary This work describes an approach towards analyzing the regulatory effects of variation of guanosine 3,5-bispyrophosphate (ppGpp) basal levels in Escherichia coli during steady state growth. A series of strains was derived by mutating the spoT gene (which encodes the major cellular ppGppase) so as to obtain systematic increments in ppGpp basal levels. These strains differ genetically at the spoT locus and, in some cases, also at the relA locus because of the severity of spoT mutant alleles. Measurements of ppGpp revealed a ten-fold range of basal levels during growth on minimal medium. The empirical relationship between ppGpp concentration and growth rate is a simple linear inverse correlation. Tandem rrnA ribosomal RNA promoters, present on a multicopy plasmid, are shown to be differentially regulated over this range of basal levels. The upstream P ₁ promoter activity shows an inverse exponential relation to ppGpp concentration whereas the downstream P ₂ promoter is only weakly affected. We conclude that there are systematic regulatory consequences associated with small changes in ppGpp basal levels during steady state growth that probably are part of a continuum with more dramatic effects observed during the stringent response to amino acid deprivation.     

Excretion of metabolites by hydrogen bacteria II. Influences of aeration,pH, temperature,and age of cells

Summary The effects of the aeration rate, the pH value, the temperature of the culture medium and of the age of cells on the excretion of metabolites by mutant strains of Alcaligenes eutrophus were studied. With lactate or gluconate as substrates, ethanol, 3-hydroxybutanoate, succinate, cis-aconitate, 2-oxo-3-methylbutanoate and 2-oxoglutarate were excreted, each at a distinct low aeration rate. Maximum concentrations of metabolites were found at pH 7.0 at 30°C when ammonia was growth limiting and the carbon substrate was present in excess. Excretion occurred only by viable intact cells.     

Interaction of alleles of therelA, relC andspoT genes inEscherichia coli: Analysis of the interconversion of GTP, ppGpp and pppGpp

Summary Mutants in thespoT gene have been isolated as stringent second site revertants of therelC mutation. These show varying degrees of the characteristics associated with thespoT1 gene,viz relative amount and absolute levels of both pppGpp and ppGpp and the decay rate of the latter. The entry of³H-guanosine into GTP and ppGpp pools inspoT ⁺ andspoT1 cells either growing exponentially or during amino acid starvation was determined, and the rate of ppGpp synthesis and its decay constant calculated. During exponential growth the ppGpp pool is 2-fold higher, its decay constant 10-fold lower, and its synthesis rate 5-fold lower inspoT ^- than inspoT ⁺ cells; during amino acid starvation the ppGpp pool is 2-fold higher, its decay constant 20-fold lower, and its synthesis rate 10-fold lower inspoT than inspoT ⁺ cells. In one of the “intermediate”spoT mutants the rate of entry of³H-guanosine into GTP, ppGpp and pppGpp was measured during amino acid starvation. The data form the basis of a model for the interconversion of the guanosine nucleotides in which the flow is:GDP→GTP→pppGpp→ppGpp→Y. Calculations of the rates of synthesis and conversion of pppGpp and ppGpp under various conditions in variousspoT ⁺ andspoT ^- strains indicate that the ppGpp concentration indirectly controls the rate of pppGpp synthesis. ThespoT1 allele was introduced into various relaxed mutants. It was shown that many phenomena associated with the relaxed response ofrelC and “intermediate”relA mutants were phenotypically suppressed when thespoT1 allele was introduced into these mutants. These double mutants exhibit ppGpp accumulation, rate of RNA accumulation, rate of β-galactosidase synthesis, and heat lability of β-galactosidase synthesized during amino acid starvation similar to the stringent wild-type. It is concluded that the relaxed response is due directly to the lack of ppGpp and that the stringest response is due directly to ppGpp.     

ppGpp is the major source of growth rate control in E. coli

It is widely accepted that the DNA, RNA and protein content of Enterobacteriaceae is regulated as a function of exponential growth rates; macromolecular content increases with faster growth regardless of specific composition of the growth medium. This phenomenon, called growth rate control, primarily involves regulation of ribosomal RNA and ribosomal protein synthesis. However, it was uncertain whether the global regulator ppGpp is the major determinant for growth rate control. Therefore, here we re-evaluate the effect of ppGpp on macromolecular content for different balanced growth rates in defined media. We find that when ppGpp is absent, RNA/protein and RNA/DNA ratios are equivalent in fast and slow growing cells. Moreover, slow growing ppGpp-deficient cells with increased RNA content, display a normal ribosomal subunit composition although polysome content is reduced when compared with fast growing wild-type cells. From this we conclude that growth rate control does not occur in the absence of ppGpp. Also, artificial elevation of ppGpp or introduction of stringent RNA polymerase mutants in ppGpp-deficient cells restores this control. We believe these findings strongly argue in favour of ppGpp and against redundant regulation of growth rate control by other factors in Escherichia coli and other enteric bacteria.     

Role of a hisU gene in the control of stable RNA synthesis in Salmonella typhimurium

We have previously reported a fivefold reduction in expression of the ilvGEDA operon in a hisU mutant (hisU1820) originally isolated as a histidine regulatory mutant that exhibited derepressed (deattenuated) expression of the his operon. More recently, we have reported that a unitary explanation of the effect of this mutant on amino acid control is complicated by the observation of relaxed control of stable RNA synthesis during carbon/energy source downshifts. In the present study, we report the results of an analysis of the relaxation in control of RNA synthesis in relation to the accumulation of the guanosine polyphosphates, ppGpp and pppGpp. Unexpectedly, we observed that, despite the inability to restrict RNA accumulation upon carbon/energy downshifts, this mutant formed ppGpp at the normal rate. Further, the evidence clearly indicates that the defective control of RNA in this hisU mutant is not owing to an alteration in the spoT gene and that the relA-mediated RNA control is unaltered. However, relaxed RNA synthesis in hisU is suppressed by hyper-elevated levels of ppGpp; thus, an inverse correlation between RNA accumulation and ppGpp level during carbon/energy downshifts is still demonstrable in the hisU mutant. These data led us to the observation that the increased accumulation of stable RNA upon a carbon/energy downshift is apparently the consequence of a hisU-conferred increase in RNA stability.     

Increased RNA polymerase availability directs resources towards growth at the expense of maintenance

Nutritionally induced changes in RNA polymerase availability have been hypothesized to be an evolutionary primeval mechanism for regulation of gene expression and several contrasting models have been proposed to explain how such ‘passive’ regulation might occur. We demonstrate here that ectopically elevating Escherichia coli RNA polymerase (Eσ⁷⁰) levels causes an increased expression and promoter occupancy of ribosomal genes at the expense of stress‐defense genes and amino acid biosynthetic operons. Phenotypically, cells overproducing Eσ⁷⁰ favours growth and reproduction at the expense of motility and damage protection; a response reminiscent of cells with no or diminished levels of the alarmone guanosine tetraphosphate (ppGpp). Consistently, we show that cells lacking ppGpp displayed markedly elevated levels of free Eσ⁷⁰ compared with wild‐type cells and that the repression of ribosomal RNA expression and reduced growth rate of mutants with constitutively elevated levels of ppGpp can be suppressed by overproducing Eσ⁷⁰. We conclude that ppGpp modulates the levels of free Eσ⁷⁰ and that this is an integral part of the alarmone's means of regulating a trade‐off between growth and maintenance.     

DNA-dependent in vitro synthesis of ribosomal proteins,protein elongation factors,and RNA polymerase subunit α: Inhibition by ppGpp

We have previously shown that the synthesis of ribosomal proteins (r proteins) in E. coli cells is under stringent control (Dennis and Nomura, 1974). Since guanosine tetraphosphate (ppGpp) had been implicated in stringent control, we examied the effects of ppGpp on the in vitro synthesis of r proteins directed by DNA from transducing phage λfus3 and λrif^d18. λfus3 carries genes for protein elongation factors EF-Tu and EF-G, and RNA polymerase subunit α, in addition to genes for approximately 27 r proteins. λrif^d18 carries genes for EF-Tu, RNA polymerase subunits β and β^I, and a set of rRNAs, in addition to genes for approximately five r proteins. We have shown that low concentrations of ppGpp (0.2–0.3 mM) specifically inhibit DNA-dependent r protein synthesis in this system, and that this inhibition takes place directly, rather than as a consequence of the inhibition of rRNA synthesis by ppGpp. In addition, we have also shown that ppGpp inhibits the synthesis of EF-G, EF-Tu, and RNA polymerase subunit α, as well as rRNAs.     

Degradation of Benzene,Toluene and Xylene by Pseudomonas aeruginosa Engineered with the Vitreoscilla Hemoglobin Gene

This study concerns the potential use of Pseudomonas aeruginosa expressing the Vitreoscilla hemoglobin gene for the degradation of important harmful aromatic compounds such as benzene, toluene, and xylene (BTX). The use of these compounds by both strains was determined as the production of cell mass (viable cell number) in a minimal medium containing any one of the BTX compounds as the sole carbon and energy source. Furthermore, the BTX degradation capability of both strains was monitored by measuring the production of 3‐methylcatechol, a common intermediate. For the cells of the logarithmic phase, which were grown at high aeration/high agitation or low aeration/low agitation, the engineered strain showed a better growth rate than the host strain. With the benzene in the medium, the recombinant strain exhibited a higher (up to 4‐fold) cell density than the parental wild‐type strain at this phase. In contrast, regarding the cells of the late stationary phase under high aeration/high agitation conditions, the host strain had generally higher viable cell numbers than the recombinant strain. At this phase this difference was, however, less significant under the conditions of low aeration/low agitation. Similarly, in toluene containing medium (at high aeration/high agitation) the recombinant strain showed a higher cell density which was from a 15‐fold to almost one order of magnitude greater than its parental strain during the logarithmic phase where the cell density of P. aeruginosa remained nearly constant. Contrary to the results with benzene and toluene, both strains exhibited similar growth characteristics when they were grown in the presence of xylene. The positive effect of the oxygen uptake by the recombinant system on the BTX metabolizing activity was also apparent in a high accumulation of 3‐methylcatechol in the cultures of the recombinant strain. At certain points of incubation, the hemoglobin expressing strain showed a significantly (p < 0.05) higher 3‐methylcatechol accumulation than the host strain. These results demonstrated the possible potential of the Vitreoscilla hemoglobin as an efficient oxygen uptake system for the bioremediation of some compounds of environmental concern.     

ComGA‐RelA interaction and persistence in the Bacillus subtilis K‐state

The bistably expressed K‐state of Bacillus subtilis is characterized by two distinct features; transformability and arrested growth when K‐state cells are exposed to fresh medium. The arrest is manifested by a failure to assemble replisomes and by decreased rates of cell growth and rRNA synthesis. These phenotypes are all partially explained by the presence of the AAA⁺ protein ComGA, which is also required for the binding of transforming DNA to the cell surface and for the assembly of the transformation pilus that mediates DNA transport. We have discovered that ComGA interacts with RelA and that the ComGA‐dependent inhibition of rRNA synthesis is largely bypassed in strains that cannot synthesize the alarmone (p)ppGpp. We propose that the interaction of ComGA with RelA prevents the hydrolysis of (p)ppGpp in K‐state cells, which are thus trapped in a non‐growing state until ComGA is degraded. We show that some K‐state cells exhibit tolerance to antibiotics, a form of type 1 persistence, and we propose that the bistable expression of both transformability and the growth arrest are bet‐hedging adaptations that improve fitness in the face of varying environments, such as those presumably encountered by B. subtilis in the soil.     

Effect of <Emphasis Type="Italic">m</Emphasis>-carbonyl cyanide 3-chlorophenylhydrazone on inorganic polyphosphates synthesis in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> under different growth conditions

The effects of different concentrations of the protonophore uncoupler m-carbonyl cyanide 3-hchlorophenylhydrazone (CCCP) on the synthesis of inorganic polyphosphates (polyP) during the first 0.5 h of hypercompensation in the yeast Saccharomyces cerevisiae VKM Y-1173 growing on media with 2% glucose under low (hypoxia) or high aeration or with 1% (vol/vol) ethanol under high aeration were studied. It was shown that the yeast growth on ethanol was completely inhibited by 5 μM CCCP, while growth on glucose was inhibited by 25 μM CCCP, independently of aeration of the medium. The maximum rate of H2 absorption was shown at 2, 5, and 25 μM CCCP for the cells grown on ethanol, on glucose under high aeration, and on glucose under hypoxia, respectively. Against the decrease of total ATP level and total polyP, CCCP had a nonuniform effect on the synthesis of individual polyP fractions. CCCP maximally inhibited synthesis of the most actively formed fractions: polyPI during growth on glucose under hypoxia, polyPIII during growth on glucose under aeration, and polyPIII and polyPV during growth on ethanol. CCCP had no substantial effect on the synthesis of polyPII and polyPIV fractions, the formation of which seems to be less related to the electrochemical potential gradient of H⁺ ions.     

Regulation of stable RNA synthesis and ppGpp levels in growing cells of Escherichia coli

Under the balanced condition of growth of E. coli cells, no distinct difference is observed in stable RNA and protein synthesis between CP78 (rel⁺) and CP79 (rel⁻), whereas a considerable difference is present in RNA accumulation between NF161 (rel⁺) and NF162 (rel⁻), where NF161 < NF162. The RNA content of NF161 is lower than that of NF162 in four different cultures with different growth rates. These two sets of isogenic pairs of rel⁺ and rel⁻ strains are commonly used in the study of rel gene function; however, NF161 is a mutant in the spoT gene whose product may be responsible for the degradation of ppGpp. The basal levels of ppGpp in these four strains growing with three different growth rates were examined: NF161 (rel⁺spoT⁻) has a much higher content of ppGpp than do other strains. Furthermore, the contents of ppGpp tend to be lower when the above four strains are growing at a faster rate. Thus a close correlation seems to exist between the content of RNA and the basal level of ppGpp under the condition of balanced growth.     

Temperature dependence of RNA synthesis parameters in Escherichia coli

For Escherichia coli B/r growing in glucose minimal medium, the following parameters of RNA synthesis remained invariant between 20 and 40 degrees C: RNA polymerase concentration (RNA polymerase/mass), rRNA and tRNA concentration (RNA/mass), RNA polymerase activity (fraction of total RNA polymerase actively engaged in RNA chain elongation), and stable RNA synthesis relative to total RNA synthesis. The following parameters increased 3.4-fold over the same temperature range: rRNA chain elongation rate, guanosine tetraphosphate (ppGpp) concentration, and culture growth rate. Above 40 degrees C, the changes became more complex, and the growth rate began to decrease. The observation that most RNA synthesis parameters are temperature invariant despite the increase of ppGpp suggests that the mechanism of RNA synthesis control by ppGpp, assumed to involve an interaction of RNA polymerase wtih ppGpp, is itself temperature dependent such that, with increasing temperature, higher concentrations of ppGpp are required to affect the RNA polymerase.