Regulation of Intracellular Proteolysis in Escherichia coli

Individual nitrogenous metabolites have been examined as regulating agents for the breakdown of intracellular proteins in Escherichia coli. Generally, NH(4) (+) is the most effective regulator. Its depletion progressively increases the basal proteolytic rate to maximum in most strains when the doubling time is increased to 2 h. In E. coli 9723, the rate is further increased at longer doubling times. Amino acids have individual effects on intracellular proteolysis. The basal rate in amino acid-requiring auxotrophs of E. coli 9723 is stimulated weakly by starvation for histidine, tryptophan, or tyrosine, moderately by four other amino acid depletions, and more strongly by eight others. The degree of stimulation roughly correlates with the frequency of the amino acid in the cell proteins. Amino acid analogues that incorporate extensively into protein generally slightly inhibit intracellular proteolysis, except for selenomethionine, which is slightly stimulatory. Metabolic inhibitors were studied at graded concentrations. Chloramphenicol inhibits the basal level of intracellular proteolysis when protein synthesis is slightly or moderately inhibited, and stimulates proteolysis slightly at higher levels. Graded inhibition of ribonucleic acid synthesis with rifampin progressively stimulates intracellular proteolysis. Uracil depletion is also stimulatory. Inhibition of deoxyribonucleic acid synthesis with mitomycin C or by thymine starvation slightly inhibits intracellular proteolysis. Intracellular proteolysis is postulated to be regulated primarily by active ribosomal function. At 43 to 45 C, intracellular proteolysis becomes maximally induced and unresponsive to normal regulatory control by metabolites. Most regulation is directed towards the breakdown of the more stable cell proteins. Total proteolysis in all cell proteins is no more than doubled by the most effective conditions of starvation.     

Stringent control of peptidoglycan biosynthesis in Escherichia coli K-12.

[3H]Diaminopimelic acid (Dap) was incorporated exclusively into peptidoglycan by Escherichia coli strains auxotrophic for both lysine and Dap. The rate of [3H]Dap incorporation by stringent (rel+) strains was significantly decreased when cells were deprived of required amino acids. The addition of chloramphenicol to amino acid-starved rel+ cultured stimulated both peptidoglycan and ribonucleic acid synthesis. In contrast, a relaxed (relA) derivative incorporated [3H]Dap at comparable rates in the presence or absence of required amino acids. Physiologically significant concentrations of guanosine 5'-diphosphate 3'-diphosphate (ppGpp) inhibited the in vitro synthesis of both carrier lipid-linked intermediate and peptidoglycan catalyzed by a particulate enzyme system. The degree of inhibition was dependent on the concentration of ppGpp in the reaction mixture. Thus, the results of in vivo and in vitro studies indicate that peptidoglycan synthesis is stringently controlled in E. coli.     

Site of Inhibition of Peptidoglycan Biosynthesis During the Stringent Response in Escherichia coli

The site of inhibition of peptidoglycan synthesis during the stringent response in Escherichia coli was determined in strains which were auxotrophic for both lysine and diaminopimelic acid (DAP). Cells were labeled with [(3)H]DAP for 30 to 60 min in the presence and absence of required amino acids, and the cellular distribution of [(3)H]DAP was determined. In both stringent (rel(+)) and relaxed (relA) strains, amino acid deprivation did not inhibit the incorporation of [(3)H]DAP into the nucleotide precursor and lipid intermediate fractions. The amount of [(3)H]DAP incorporated into the peptidoglycan fraction by the amino acid-deprived relA strain was over 70% of the amount incorporated in the presence of required amino acids. In contrast, the amounts of labeled peptidoglycan in amino acid-deprived rel(+) strains were only 20 to 44% of the amounts synthesized in the presence of amino acids. These results indicate that a late step in peptidoglycan synthesis is inhibited during the stringent response. The components of the lipid intermediate fraction synthesized by rel(+) strains in the presence and absence of required amino acids were quantitated. Amino acid deprivation did not inhibit the synthesis of either the monosaccharide-pentapeptide or the disaccharide-pentapeptide derivatives of the lipid intermediate. Thus, the reaction which is most likely inhibited during the stringent response is the terminal one involving the incorporation of the disaccharide-pentapeptide into peptidoglycan.     

Intracellular Trp repressor levels in Escherichia coli.

A radioimmunoassay for the Trp repressor protein of Escherichia coli was developed with antisera raised against purified Trp repressor protein. This assay was used to directly measure the intracellular Trp repressor content in several E. coli K-12 and B/r strains. Repressor levels varied from 2.5- to 3-fold in response to L-tryptophan concentration in the growth medium (15 to 44 ng of repressor per mg of protein). Neither cell growth rate nor culture age had a significant effect on repressor concentrations within the cell. Addition of L-tryptophan to the growth medium resulted in lowered intracellular levels of Trp repressor. The absolute amounts of native Trp repressor molecules per cell varied between 120 and 375 dimers in the presence and absence of L-tryptophan in the culture medium, respectively. Assuming an intracellular volume of 7.3 microliters/10(10) E. coli cells, the Trp repressor concentration varied from 270 to 850 nM in response to extracellular tryptophan levels. These findings represent the first direct measurements of Trp repressor levels in E. coli and confirm the autoregulatory nature of the trpR gene.     

Inorganic Polyphosphate in Escherichia coli: the Phosphate Regulon and the Stringent Response

Escherichia coli transiently accumulates large amounts of inorganic polyphosphate (polyP), up to 20 mM in phosphate residues (P_i), in media deficient in both P_i and amino acids. This transient accumulation is preceded by the appearance of nucleotides ppGpp and pppGpp, generated in response to nutritional stresses. Mutants which lack PhoB, the response regulator of the phosphate regulon, do not accumulate polyP even though they develop wild-type levels of (p)ppGpp when subjected to amino acid starvation. When complemented with a phoB-containing plasmid, phoB mutants regain the ability to accumulate polyP. PolyP accumulation requires high levels of (p)ppGpp independent of whether they are generated by RelA (active during the stringent response) or SpoT (expressed during P_i starvation). Hence, accumulation of polyP requires a functional phoB gene and elevated levels of (p)ppGpp. A rapid assay of polyP depends on its adsorption to an anion-exchange disk on which it is hydrolyzed by a yeast exopolyphosphatase.     

Intracellular protein breakdown in growing cells of Escherichia coli

1. When Escherichia coli was grown exponentially in a defined medium at 35 degrees , the rate of protein breakdown was initially rapid, but decreased to 0.6%/hr. after about 30min. The latter rate was maintained for at least 3.5hr. 2. The initial rapid rate may have been due to the presence of a small protein fraction (about 1%) that was degraded with a half-life of 13min. 3. The rate of protein degradation was the same during balanced growth at low rates imposed in a bactogen. However, it increased during the period immediately after a decrease of the growth rate.     

Intracellular protein breakdown in non-growing cells of Escherichia coli

1. When Escherichia coli leu(-) was incubated at 35 degrees in a medium based on minimal medium, but with the omission of phosphate ions, or glucose, or NH(4) (+) ions and leucine, intracellular protein was degraded at a rate of about 5%/hr. in each case. If Mg(2+) ions were omitted, however, the rate of degradation was 2.9%/hr. 2. Under certain conditions of incubation, protein degradation was inhibited. The inhibitor was neither NH(4) (+) ions nor amino acids, and its properties were not those of a protein, but it might be an unstable species of RNA. 3. Although a large part of the cell protein was degraded at about 5%/hr. during starvation of NH(4) (+) ions and leucine, some proteins were lost at more rapid rates, whereas others were lost at lower rates or not at all. 4. In particular, beta-galactosidase activity was lost at about 8%/hr. during starvation of NH(4) (+) ions and leucine, whereas d-serine-deaminase and alkaline-phosphatase activities were stable. During starvation of Mg(2+) ions, all three enzyme activities were stable.     

Identification of the Escherichia coli lytB Gene, Which Is Involved in Penicillin Tolerance and Control of the Stringent Response

The Escherichia coli lytB gene, which is involved in penicillin tolerance and control of the stringent response, was identified as a previously described open reading frame designated orf316 located in the ileS-lsp operon (0.4 min on the linkage map).     

Intracellular location of catalase-peroxidase hydroperoxidase I of Escherichia coli

The catalase-peroxidase hydroperoxidase I of Escherichia coli has been confirmed to be located in the cytoplasm using two independent methods. Catalase activity was found predominantly (> 95%) in the cytoplasmic fraction following spheroplast formation. The cytoplasmic enzyme glucose-6-phosphate dehydrogenase and the periplasmic enzyme alkaline phosphatase were used as controls. The second method of immunogold staining for the enzyme in situ revealed an even distribution of the enzyme across the cell.     

Stringent and growth control of rRNA synthesis in Escherichia coli are both mediated by ppGpp

Weak stringent or relaxed responses were induced in Escherichia coli (relA+), using mild amino acid starvation or treatment with chloramphenicol at low concentrations, respectively, such that the growth rate was barely reduced. In this manner, the intracellular concentration of the nucleotide guanosine tetraphosphate, ppGpp, could be varied in any desired range between 0 and 1000 pmol of ppGpp per OD460 unit of culture mass. At the same time, the rate of synthesis of stable RNA (rs; rRNA and tRNA) was measured, relative to the total instantaneous rate of RNA synthesis (rt). The correlation between the cytoplasmic concentration of ppGpp and stable RNA gene activity (rs/rt) was the same as that observed previously with relA+ and relA strains growing exponentially at different rates in different media. This suggests that the distinction between growth control and stringent control of stable RNA synthesis is arbitrary, and that both kinds of control reflect the same ppGpp-dependent phenomenon. By increasing the stable RNA gene dosage, using high copy number plasmids carrying an rrn gene, we have tested the idea that ppGpp partitions the bacterial RNA polymerase into two forms with different probabilities to initiate at stable RNA and mRNA promoters. The relaxed response was not significantly altered, but the extent of the stringent response was reduced by the presence of extra rrn genes. The results agree with quantitative predictions derived from the RNA polymerase partitioning hypothesis.     

Intracellular activation of albomycin in Escherichia coli and Salmonella typhimurium.

The antibiotic albomycin is actively taken up by Escherichia coli via the transport system for the structurally similar iron complex ferrichrome. Albomycin is cleaved, and the antibiotically active moiety is released into the cytoplasm, whereas the iron carrier moiety appears in the medium. Besides transport-negative mutants, additional albomycin-resistant mutants were isolated. The mutations were mapped outside the transport genes close to the pyrD gene at 21 min. The mutants were devoid of peptidase N activity. The molecular weight, sensitivity to inhibitors, and cytoplasmic location of the enzyme hydrolyzing albomycin in vitro corresponded to the known properties of peptidase N. The aminoacyl thioribosyl pyrimidine moiety of albomycin apparently has to be cleaved off the iron chelate transport vehicle to inhibit growth. Peptidase N is the major hydrolyzing enzyme. In Salmonella typhimurium peptidase N and peptidase A were equally active in hydrolyzing and activating albomycin.     

Intracellular location of catabolite activator protein of Escherichia coli.

The catabolite activator protein was assayed in extracts from the minicell-producing Escherichia coli strain P678-54. The level of catabolite activator protein was found to be the same in both parent cells and purified minicells, regardless of whether the bacteria were grown on glucose (which leads to low intracellular cyclic adenosine monophosphate levels) or on glycerol-yeast extract or LB broth (which lead to high cyclic adenosine monophosphate concentrations in the cell). Thus, at any given time most catabolite activator protein molecules are found in the cytoplasm. The implications of this for the mechanism of catabolite activator protein action at catabolite-sensitive operons are discussed.     

Superoxide Dismutases of Escherichia coli: Intracellular Localization and Functions

Escherichia coli B contains two superoxide dismutases which differ with respect to their localization within the cell, the nature of their prosthetic metals, their responses to changes in (p)O(2), and their functions. One of these enzymes, which was liberated from the cells by osmotic shock and which was therefore presumed to be localized in the periplasmic space, is an iron-containing superoxide dismutase. The amount of this iron enzyme did not vary in response to changes in (p)O(2) during growth. In contrast, the other superoxide dismutase was not solubilized by osmotic shock, was a mangano-protein, and was found in greater amounts in cells which had been grown at high (p)O(2). E. coli, which had low levels of the iron-enzyme and high levels of the mangano-enzyme, as a consequence of growth in iron-deficient aerated medium, was killed by exposure to an exogenous flux of O(2) (-) which was generated either photochemically or enzymatically. The addition of bovine superoxide dismutase to the suspending medium protected these cells against this stress. On the other hand, E. coli, which had high levels of the iron-enzyme and low levels of the mangano-enzyme, as a consequence of growth in iron-rich anaerobic medium, was resistant to exogeneous O(2) (-). On the basis of these and of previously reported results (4a, Yost, F. J. and I. Fridovich, J. Biol. Chem., 1973, in press), it appears that the iron superoxide dismutase, of the periplasmic space, serves as a defense against exogenous O(2) (-), whereas the mangano-superoxide dismutase, in the matrix of these cells, serves to counter the toxicity of endogenous O(2) (-).