Escherichia coli ppGpp synthetase II activity requires spoT

Escherichia coli has two enzymes catalyzing the synthesis of guanosine tetraphosphate (ppGpp), designated ppGpp synthetase I (PSI = RelA) and II (PSII), whose activities are regulated differently. Until now, the gene for PSII had not been identified. Here, an E. coli relA1 strain that expresses lacZ from an rrnB P1 promoter was used to screen mutants with increased beta-galactosidase activity on 5-bromo-4-chloro-3-indoyl beta-D-galactoside indicator plates at 30 degrees C. About 15% of the mutants obtained in this manner had reduced levels of ppGpp at 30 degrees C and no detectable ppGpp at 43 degrees C. These mutants did not form colonies at 42 degrees C on minimal medium plates and had elevated ribosome concentrations and higher growth rates at 30 degrees C. Genetic mapping by phage P1 transduction and complementation analyses showed that the mutations were located in spoT and that they were recessive. Specific inhibition of SpoT-dependent ppGpp degradation activity with picolinic acid showed that two of the mutants tested were deficient in ppGpp synthesis activity. These results indicate that spoT is required for PSII activity, suggesting that spoT encodes both ppGpp degradation and synthesis activities and that these two functions can be affected independently by mutation.     

ppGpp cycle in Escherichia coli.

Summary Kinetics of accumulation and degradation of ppGpp and pppGpp were analysed in spoT ⁺ and spoT strains of Escherichia coli. The experimental data in this paper indicate that on degradation ppGpp is not converted to pppGpp but instead is converted to GDP which is in turn phosphorylated to GTP. In addition the data are consistent with the idea the pppGpp is a direct precursor of ppGpp. We propose that ppGpp is metabolised according to the following pathway: GTP-pppGpp-ppGpp-GDP-GTP, which we call the ppGpp cycle. Coupled with the observations in spoT strains we assume that ppGpp blocks its own synthesis by inhibiting the synthesis of pppGpp but not the interconversion of the two nucleotides.     

Synthesis of pppGpp by ribosomes from an Escherichia coli spoT mutant and the metabolic relationship between pppGpp and ppGpp.

Both ribosomes and a cell-free extract (S-30) prepared from an Escherichia coli spoT mutant catalyzed the synthesis of guanosine pentaphosphate (pppGpp) and guanosine tetraphosphate (ppGpp) as efficiently as did ribosomes and S-30 from a spoT+ strain. In both cases, the level of pppGpp reached its maximum before ppGpp maximally accumulated. pppGpp added to the ribosome system was rapidly converted to ppGpp. These results indicate that the spoT+ gene product may not have a direct role in the synthesis of pppGpp and that pppGpp is a precursor of ppGpp.     

Mutational analysis of the Escherichia coli spoT gene identifies distinct but overlapping regions involved in ppGpp synthesis and degradation

The spoT gene of Escherichia coli encodes a guanosine 3′,5′-bis(diphosphate) 3′-pyrophosphohydrolase (ppGppase) as well as an apparent guanosine 3′,5′-bis(diphosphate) synthetase (designated PSII). To determine the regions of the SpoT protein that are required for these two competing activities, we analysed plasmid-borne deletion mutations for their ability to complement chromosomal mutations defective in each activity. We found that a region containing the first 203 amino acids of the 702-amino-acid SpoT protein was sufficient for ppGppase activity while an overlapping region containing residues 67–374 was sufficient for PSII activity. These data indicate that the catalytic sites involved in the two activities are separate but closely linked in the primary sequence of the SpoT protein. A ppGppase-defective Δ1–58 deletion mutant strain failed to synthesize ppGpp in response to nutrient limitation, also supporting the notion that PSII activity from wild-type SpoT does not increase in response to nutrient limitation. Using a strain lacking PSII activity but retaining ppGppase activity, we determined the contribution of the RelA protein (ppGpp synthetase I, PSI) to ppGpp synthesis following glucose starvation. We found that the RelA protein activity accounts for the initial burst of ppGpp synthesis at the onset of glucose starvation but that this source of synthesis is absent when amino acids are present during glucose starvation.     

Cloning the spoT gene of Escherichia coli: identification of the spoT gene product.

We have isolated five specialized transducing lambda bacteriophages (lambda dpyrE spoT) carrying the pyrE and spoT genes of Escherichia coli. A fragment from one of these phages was used as the source of DNA to clone the spoT and pyrE genes on a multicopy plasmid, pBR322. Insertions and deletions in this plasmid were obtained. These plasmids were used to transform a minicell-producing strain, and the gene products synthesized were determined. Our experiments demonstrate that the spoT and pyrE genes are separated by about 4 magadaltons and suggest that the spoT gene product is a protein whose molecular weight is 80,000. The strain in which the spoT+ allele is carried on a plasmid produced nine times more spoT gene activity than a normal spoT+ strain when assayed in crude extracts. This strain was used to prepare partially purified gene product, guanosine 5'-diphosphate, 3'-diphosphate pyrophosphatase. The enzyme has the following characteristics. (i) It hydrolyzes pyrophosphate from the 5'-pyrophosphate of guanosine 5'-diphosphate, 3'-diphosphate, yielding GDP and pyrophosphate. (ii) Its activity is strongly stimulated by Mn2+ and slightly stimulated by salt. (iii) Its activity is inhibited by uncharged tRNA. There are also two additional activities in the cell extract which degrade guanosine in 5'-diphosphate, 3'-diphosphate in vitro but which are not specified by the spoT gene.     

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.     

Breakdown of DNA in X-Irradiated Escherichia coli

A comparison of differences in incorporation and loss of radio-activity between two strains of Escherichia coli shows that: (a) three times as much irradiation is necessary to produce the same reduction in incorporation of H³-thymidine in B/r, the resistant strain, as in B_{s - 1}, the sensitive one; (b) radioactivity is lost from the DNA of previously labeled bacteria during the first few cell generations after X-ray exposure, and even though the initial rate of loss is similar for all strains, the sensitive one loses much more label; (c) loss of DNA is a complicated function of dose. Losses increase with dose up to 25 or 50 kr in both strains; with higher doses, losses decrease in B_{s - 1} but are unchanged in B/r. Since in both strains labeled RNA is retained in irradiated cells, lysis has not occurred but the DNA is broken down into small pieces which leak from each cell. Losses from either strain do not occur at ice-bath temperature, indicating that breakdown is a function of metabolic processes. A proposed mechanism for X-ray damage and repair is advanced.     

Iron limitation induces SpoT-dependent accumulation of ppGpp in Escherichia coli

In Escherichia coli the beta-lactam mecillinam specifically inhibits penicillin-binding protein 2 (PBP2), a peptidoglycan transpeptidase essential for maintaining rod shape. We have previously shown that PBP2 inactivation results in a cell division block and that an increased concentration of the nucleotide ppGpp, effector of the RelA-dependent stringent response, confers mecillinam resistance and allows cells to divide as spheres in the absence of PBP2 activity. In this study we have characterized an insertion mutation which confers mecillinam resistance in wild-type and DeltarelA strains but not in DeltarelADeltaspoT strains, devoid of ppGpp. The mutant has an insertion in the fes gene, coding for enterochelin esterase. This cytoplasmic enzyme hydrolyses enterochelin-Fe(3+) complexes, making the scavenged iron available to the cells. We show that inactivation of the fes gene causes iron limitation on rich medium plates and a parallel SpoT-dependent increase of the ppGpp pool, as judged by the induction of the iron-regulated fiu::lacZ fusion and the repression of the stringently controlled P1(rrnB)::lacZ fusion respectively. We further show, by direct ppGpp assays, that iron starvation in liquid medium produces a SpoT-dependent increase of the ppGpp pool, strongly suggesting a role for iron in the balance of the two activities of SpoT, synthesis and hydrolysis of (p)ppGpp. Finally, we present evidence that ppGpp exerts direct or indirect positive control on iron uptake, suggesting a simple homeostatic regulatory circuit: iron limitation leads to an increased ppGpp pool, which increases the expression of iron uptake genes, thereby alleviating the limitation.