Guanosine-5‘-diphosphate-3‘-diphosphate (ppGpp) and the regulation of protein breakdown in Escherichia coli

FtsH-mediated coordination of lipopolysaccharide biosynthesis in Escherichia coli correlates with the growth rate and the alarmone (p)ppGpp

The outer membrane is the first line of defense for Gram-negative bacteria and serves as a major barrier for antibiotics and other harmful substances. The biosynthesis of lipopolysaccharides (LPS), the essential component of the outer membrane, must be tightly controlled as both too much and too little LPS are toxic. In Escherichia coli, the cellular level of the key enzyme LpxC, which catalyzes the first committed step in LPS biosynthesis, is adjusted by proteolysis carried out by the essential and membrane-bound protease FtsH. Here, we demonstrate that LpxC is degraded in a growth rate-dependent manner with half-lives between 4 min and >2 h. According to the cellular demand for LPS biosynthesis, LpxC is degraded during slow growth but stabilized when cells grow rapidly. Disturbing the balance between LPS and phospholipid biosynthesis in favor of phospholipid production in an E. coli strain encoding a hyperactive FabZ protein abolishes growth rate dependency of LpxC proteolysis. Lack of the alternative sigma factor RpoS or inorganic polyphosphates, which are known to mediate growth rate-dependent gene regulation in E. coli, did not affect proteolysis of LpxC. In contrast, absence of RelA and SpoT, which synthesize the alarmone (p)ppGpp, deregulated LpxC degradation resulting in rapid proteolysis in fast-growing cells and stabilization during slow growth. Our data provide new insights into the essential control of LPS biosynthesis in E. coli.

Induction of T4 DNA ligase in a recombinant strain of Escherichia coli

The kinetics of cell growth and foreign protein production, as well as factors affecting protein stability, were studied and optimized in batch and fed-batch fermentations of a recombinant strain of Escherichia coli. The pL promoter from bacteriophage lambda under the control of a temperature-sensitive cl represser, with the entire construct integrated into the E. coli chromosome through the use of a defective bacteriophage lambda lysogen, was used to direct the synthesis of T4 DNA ligase. The biphasic fermentations consisted of a primary growth phase at 30 degrees C followed by an induction phase which was initiated by shifting the temperature to 42 degrees C. In the fed-batch fermentations, additional nutrients were added at the time of initiating induction. Maintenance of sufficiently high concentrations of the organic substrates (glucose and casamino acids) during the induction phase was required for continued cell growth at 42 degrees C. Such growth was essential for T4 DNA ligase formation and in vivo stability. Hence, fed-batch fermentations produced the highest yield of the foreign protein Commensurate with providing lower total amounts of substrates. In such cases, high cell densities (6 g dry wt/L) with substantial intracellular levels of T4 DNA ligase (4.6% total cellular protein, or 2.7% of the dry biomass) were achieved.

Importance of anaerobic superoxide dismutase synthesis in facilitating outgrowth of Escherichia coli upon entry into an aerobic habitat

The manganese-containing isozyme of superoxide dismutase (MnSOD) is synthesized by Escherichia coli only during aerobiosis, in accordance with the fact that superoxide can be formed only in aerobic environments. In contrast, E. coli continues to synthesize the iron-containing isozyme (FeSOD) even in the absence of oxygen. A strain devoid of FeSOD exhibited no deficits during either anaerobic or continuously aerobic growth, but its growth lagged for 2 h during the transition from anaerobiosis to aerobiosis. Complementation of this defect with heterologous SODs established that anaerobic SOD synthesis per se is necessary to permit a smooth transition to aerobiosis. The growth deficit was eliminated by supplementation of the medium with branched-chain amino acids, indicating that the growth interruption was due to the established sensitivity of dihydroxyacid dehydratase to endogenous superoxide. Components of the anaerobic respiratory chain rapidly generated superoxide when exposed to oxygen in vitro, suggesting that this transition may be a period of acute oxidative stress. These results show that facultative bacteria must preemptively synthesize SOD during anaerobiosis in preparation for reaeration. The data suggest that evolution has chosen FeSOD for this function because of the relative availability of iron, in comparison to manganese, during anaerobiosis.

Induction of cat-86 by chloramphenicol and amino acid starvation in relaxed mutants of Bacillus subtilis

The chloramphenicol acetyltransferase gene cat-86 is induced through a mechanism that is a variation of classical attenuation. Induction results from the destabilization of an RNA stem-loop that normally sequesters the cat-86 ribosome-binding site. Destabilization of the stem-loop is due to the stalling of a ribosome in the leader region of cat-86 mRNA at a position that places the A site of the stalled ribosome at leader codon 6. Two events can stall ribosomes at the correct location to induce cat-86 translation: addition of chloramphenicol to cells and starvation of cells for the amino acid specified by leader codon 6. Induction by amino acid starvation is an anomaly because translation of the cat-86 coding sequence requires all 20 amino acids. To explain this apparent contradiction we postulated that amino acid starvation triggers intracellular proteolysis, thereby providing levels of the deprived amino acid sufficient for cat-86 translation. Here we show that a mutation in relA, the structural gene for stringent factor, blocks intracellular proteolysis that is normally triggered by amino acid starvation. The relA mutation also blocks induction of cat-86 by amino acid starvation, but the mutation does not interfere with chloramphenicol induction. Induction by amino acid starvation can be demonstrated in relA mutant cells if the depleted amino acid is restored at very low levels (e.g., 2 micrograms/ml). A mutation in relC, which may be the gene for ribosomal protein L11, blocks induction of cat-86 by either chloramphenicol or amino acid starvation. We believe this effect is due to a structural alteration of the ribosome resulting from the relC mutation and not to the relaxed phenotype of the cells.

Purification and characterization of protease Re, a cytoplasmic endoprotease in Escherichia coli

Protease Re, a new cytoplasmic endoprotease in Escherichia coli, was purified to homogeneity by conventional procedures, using [3H]casein as the substrate. The enzyme consists of a single polypeptide of 82,000 molecular weight. It is maximally active between pH 7 and 8.5 and is independent of ATP. It has a pI of 6.8 and a Km of 10.8 microM for casein. Since diisopropyl fluorophosphate and phenylmethylsulfonyl fluoride inhibited this enzyme, it appears to be a serine protease. Protease Re was sensitive to inhibition by L-1-tosylamido-2-phenylethylchloromethylketone but not to that by 1-chloro-3-tosylamido-7-aminoheptanone, thiol-blocking reagents, chelating agents, or various peptide aldehydes. Re also degraded [125I]globin, [125I]glucagon, and 125I-labeled denatured bovine serum albumin to acid-soluble products (generally oligopeptides of greater than 1,500 daltons), but it showed no activity against serum albumin, growth hormone, insulin, or a variety of fluorometric peptide substrates. It also hydrolyzed oxidatively inactivated glutamine synthetase (generated by ascorbate, oxygen, and iron) four- to fivefold more rapidly than the native protein. Protease Re appears to be identical to the proteolytic enzyme isolated by Roseman and Levine (J. Biol. Chem. 262:2101-2110, 1987) by its ability to degrade selectively oxidatively damaged glutamine synthetase in vivo. Its role in intracellular protein breakdown is uncertain.

Degradation of aspartate transcarbamylase in Bacillus subtilis is deficient in rel mutants but is not mediated by guanosine polyphosphates

Degradation of aspartate transcarbamylase in growing and starved Bacillus subtilis was deficient in relA and relC mutants, but these effects were not correlated with differences in the intracellular level of guanosine polyphosphates.

Isolation and characterization of protease do from Escherichia coli, a large serine protease containing multiple subunits

A new cytoplasmic proteolytic enzyme in Escherichia coli, named protease Do, has been purified to near homogeneity. The enzyme is an endoprotease that degrades casein, denatured bovine serum albumin, and globin but shows little or no hydrolytic activity against insulin, growth hormone, native bovine serum albumin, or a variety of commonly used peptide substrates. The molecular size of the enzyme was large, and it could be isolated in different preparations in either of two forms. One showed a molecular weight of about 500,000 on gel filtration and a sedimentation coefficient of 15.9 S on sucrose gradient centrifugation. The other appeared to be about 300,000 and sedimented at 12.7 S. No interconversion between the two forms and no other difference in the properties was found. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS) shows that both forms contain a major 54,000-dalton band and three additional minor polypeptides with molecular weights of 45,000, 44,000, and 42,000. These minor polypeptides appear to result from autolytic degradation of the major protein as demonstrated by peptide mapping with Staphylococcus aureus V8 protease. Thus, protease Do appears to contain a single subunit of 54,000, and can exist either as a decamer or as a hexamer or pentamer. The enzyme is a serine protease. It is sensitive to diisopropyl fluorophosphate (DFP) but not to metal chelating agents, sulfhydryl blocking groups, certain chloromethyl ketones, or various peptide aldehyde inhibitors. The enzyme covalently binds [3H]DFP, and the labeled subunit was visualized on SDS-polyacrylamide gels by fluorography. When cells growing in rich broth enter stationary phase, the relative concentration of protease Do increases more than twofold.

Involvement of the stringent response in degradation of glutamine phosphoribosylpyrophosphate amidotransferase in Bacillus subtilis

Glutamine phosphoribosylpyrophosphate amidotransferase, the first enzyme of purine biosynthesis, has previously been shown to be rapidly inactivated and degraded in Bacillus subtilis cells at the end of growth. The loss of enzyme activity appears to involve the oxidation of an iron-sulfur cluster in the enzyme. The degradation of the inactive enzyme involves some elements of the stringent response because it is inhibited in relA and relC mutants. Intracellular pools of guanosine tetra- and pentaphosphate were measured by an improved extraction procedure in cells that had been manipulated in various ways to induce or inhibit amidotransferase degradation. The results are consistent with the hypothesis that one or both of these nucleotides stimulates the synthesis of a protein involved in degradation. An elevated level of these nucleotides was not required for the continued degradation of amidotransferase once it had begun.

Purification and characterization of protease So, a cytoplasmic serine protease in Escherichia coli

A new cytoplasmic endoprotease, named protease So, was purified to homogeneity from Escherichia coli by conventional procedures with casein as the substrate. Its molecular weight was 140,000 when determined by gel filtration on Sephadex G-200 and 77,000 when estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Thus, it appears to be composed of two identical subunits. Protease So had an isoelectric point of 6.4 and a K(m) of 1.4 muM for casein. In addition to casein, it hydrolyzed globin, glucagon, and denatured bovine serum albumin to acid-soluble peptides but did not degrade insulin, native bovine serum albumin, or the "auto alpha" fragment of beta-galactosidase. A variety of commonly used peptide substrates for endoproteases were not hydrolyzed by protease So. It had a broad pH optimum of 6.5 to 8.0. This enzyme is a serine protease, since it was inhibited by diisopropyl fluorophosphate and phenylmethylsulfonyl fluoride. Although it was not inhibited by chelating agents, divalent cations (e.g., Mg(2+)) stabilized its activity. Protease So was sensitive to inhibition by N-tosyl-l-phenylalanine chloromethyl ketone but not by N-tosyl-l-lysine chloromethyl ketone. Neither ATP nor 5'-diphosphate-guanosine-3'-diphosphate affected the rate of casein hydrolysis. Protease So was distinct from the other soluble endoproteases in E. coli (including proteases Do, Re, Mi, Fa, La, Ci, and Pi) in its physical and chemical properties and also differed from the membrane-associated proteases, protease IV and V, and from two amino acid esterases, originally named protease I and II. The physiological function of protease So is presently unknown.

Nutritional regulation of degradation of aspartate transcarbamylase and of bulk protein in exponentially growing Bacillus subtilis cells

The rate of degradation of aspartate transcarbamylase in exponentially growing Bacillus subtilis cells was determined by measurement of enzyme activity after the addition of uridine to repress further enzyme synthesis and by specific immunoprecipitation of the enzyme from cells grown in the presence of [3H]leucine. Aspartate transcarbamylase was degraded with a half-life of about 1.5 h in cells growing on a glucose-salts medium with NH4+ ions as the sole source of nitrogen. Replacement of NH4+ in this medium with a combination of the amino acids aspartate, glutamate, isoleucine, proline, and threonine reduced the degradation rate to an undetectable level. Various other amino acids and amino acid mixtures had smaller effects on the rate of degradation. The carbon source also influenced the degradation rate, but to a smaller extent than the nitrogen source. The effects of these nutritional variables on the rate of bulk protein turnover in growing cells were generally similar to their effects on degradation of aspartate transcarbamylase. Since the degradation of aspartate transcarbamylase has been shown to be 10 to 20 times faster than bulk protein turnover, the results suggest that a substantial portion of protein turnover in growing cells represents regulable, rapid degradation of a number of normal proteins, of which aspartate transcarbamylase is an example.

Effects of starvation for potassium and other inorganic ions on protein degradation and ribonucleic acid synthesis in Escherichia coli

Starvation of Escherichia coli for potassium, phosphate, or magnesium ions leads to a reversible increase in the rate of protein degradation and an inhibition of ribonucleic acid (RNA) synthesis. In cells deprived of potassium, the breakdown of the more stable cell proteins increased two- to threefold, whereas the hydrolysis of short-lived proteins, both normal ones and analog-containing polypeptides, did not change. The mechanisms initiating the enhancement of proteolysis during starvation for these ions were examined. Upon starvation for amino acids or amino acyl-transfer RNA (tRNA), protein breakdown increases in relA+ (but not relA) cells as a result of the rapid synthesis of guanosine-5'-diphosphate-3'-diphosphate (ppGpp). However, a lack of amino acyl-tRNA does not appear to be responsible for the increased protein breakdown in cells starved for inorganic ions, since protein breakdown increased in the absence of these ions in both relA+ and relA cultures, and since a large excess of amino acids did not affect this response. In bacteria in which energy production is restricted, ppGpp levels also rise, and protein breakdown increases. The ion-deprived cultures did show a 40 to 75% reduction in adenosine-5'-triphosphate levels,l similar to that seen upon glucose starvation. However, this decrease in ATP content does not appear to cause the increase in protein breakdown or lead to an accumulation of ppGpp. No consistent change in intracellular ppGpp levels was found in relA+ or relA cells starved for these ions. In addition, in relX mutants, removal of these ions led to accelerated protein degradation even though relX cells are unable to increase ppGpp levels or proteolysis when deprived of a carbon source. In the potassium-, phosphate-, and magnesium-deprived cultures, the addition of choramphenicol or tetracycline caused a reduction in protein breakdown toward basal levels. Such findings, however, do not indicate that protein synthesis is essential for the enhancement of protein degradation, since blockage of protein synthesis by inactivation of a temperature-sensitive valyl-tRNA synthetase did not restore protein catabolism to basal levels. These various results and related studies suggest that the mechanism for increased protein catabolism on starvation for inorganic ions differs from that occurring upon amino acid or arbon deprivation and probably involves an enhanced susceptibility of various cell proteins (especially ribosomal proteins) to proteolysis.