Isolation and characterization of autolysis-defective mutants of Escherichia coli that are resistant to the lytic activity of seminalplasmin.

Two temperature-sensitive autolysis-defective mutants of Escherichia coli were isolated and shown to be resistant to lysis induced by seminalplasmin, an antimicrobial protein from bovine seminal plasma, as well as to lysis induced by ampicillin, D-cycloserine and nocardicin, at 37 or 42 degrees C but not at 30 degrees C. The mutants were, however, sensitive to inhibition of RNA synthesis by seminalplasmin even at the nonpermissive temperature. Temperature-resistant revertants of the mutants were sensitive to lysis induced by the various antibiotics at 37 or 42 degrees C. The mutations in both strains were mapped at 58 min on the E. coli linkage map. The lysis resistance of the mutants was phenotypically suppressed by the addition of NaCl. Partial suppression of the lysis-resistant phenotype was also observed in a relA genetic background.     

Temperature-sensitive beta-lactam-tolerant mutants of Escherichia coli

Seven temperature-sensitive penicillin-tolerant mutants of Escherichia coli strain LD5 (thi lysA dapD) were isolated and characterized. Treatment with beta-lactams caused lysis of the mutants at 30 degrees C. Although growth of the mutants at 42 degrees C was inhibited by beta-lactams, no lysis occurred. The mutants were also slightly tolerant to D-cycloserine at 42 degrees C but lysed readily when deprived of diaminopimelate or when treated with moenomycin. The minimum inhibitory concentrations of various antibiotics were the same for the mutants and their parent. The mutations conferring penicillin tolerance were phenotypically suppressed in the presence of a variety of compounds which may act as chaotropic or antichaotropic agents. No defects in penicillin-binding proteins and peptidoglycan hydrolases were detected. Temperature-resistant revertants of the mutants were no longer tolerant to penicillin-induced autolysis at 42 degrees C. The mutations in five isolates were localized to the 56 to 61 min region of the E. coli linkage map and to the 44 to 51 min region in the case of two other isolates.     

Escherichia coli Mutants Tolerant to Beta-Lactam Antibiotics

Two types of Escherichia coli mutants tolerant to beta-lactam antibiotics were isolated. One is E. coli chi2452, which showed a tolerant response against beta-lactam antibiotics when grown at 42 degrees C, and the others are the mutants C-80 and C-254, selected from mutagenized E. coli chi1776 by cycles of exposure to ampicillin, cephaloridine, and starvation of the nutritionally required diaminopimelic acid. Beta-lactam antibiotics caused rapid loss of viability and lysis in cultures of chi1776 or in chi2452 grown at 32 degrees C. In contrast, the same antibiotics caused only a reversible inhibition of growth in mutants C-80 and C-254 or in cultures of chi2452 grown at 42 degrees C. Beta-lactam antibiotics that show high affinity for penicillin-binding proteins 2 or 3 (mecillinam and cephalexin, respectively) induced similar morphological effects (ovoid cell formation and filament formation) in both parent and mutant strains. In contrast, beta-lactam antibiotics which have a high affinity for penicillin-binding protein 1 (e.g., cephaloridine or cefoxitin), which cause rapid lysis in the parental strains, caused cell elongation in the tolerant bacteria. In contrast to the parental cells, autolytic cell wall degradation was not triggered by beta-lactam treatment of chi2452 cells grown at 42 degrees C or in mutants C-80 and C-254. The total autolytic activity of mutants C-80 and C-254 was less than 30% that of the parent strain. However, virtually identical autolytic activities were found in cells of chi2452 grown either at 42 or 32 degrees C. Possible mechanisms for the penicillin tolerance of E. coli are considered on the basis of these findings.     

Penicillin-resistant temperature-sensitive mutants of Escherichia coli which synthesize hypo- or hyper-cross-linked peptidoglycan

A group of Escherichia coli mutants which are ampicillin resistant at 32 C and which either are unable to grow or lyse at 42 C has been selected. These mutants have been classified by a number of characteristics: total peptidoglycan synthesis measured by [(14)C]diaminopimelic acid incorporation, extent of cross-linking of the peptidoglycan which is synthesized, growth characteristics at the two temperatures, and morphology. Two especially interesting groups of mutants have been described. In one of these, a hypo-cross-linked peptidoglycan was synthesized at the nonpermissive temperature. Most of these organisms lysed at 42 C. In another group, the peptidoglycan synthesized at 42 C was hyper-cross-linked. Many of these organisms were spherical. Studies of revertants indicated that ampicillin resistance, temperature sensitivity, cross-linking, growth characteristics, and morphological changes may be related to a single mutational event in both of these groups.     

Requirement for a functional host cell autolytic enzyme system for lysis of Escherichia coli by bacteriophage phi X174

Escherichia coli VC30 is a temperature-sensitive mutant which is defective in autolysis. Strain VC30 lyses at 30 degrees C when treated with beta-lactam antibiotics or D-cycloserine or when deprived of diaminiopimelic acid. The same treatments inhibit growth of the mutant at 42 degrees C but do not cause lysis. Strain VC30 was used here to investigate the mechanism of host cell lysis induced by bacteriophage phi X 174. Strain VC30 was transformed with plasmid pUH12, which carries the cloned lysis gene (gene E) of phage phi X174 under the control of the lac operator-promoter, and with plasmid pMC7, which encodes the lac repressor to keep the E gene silent. Infection of strain VC30(pUH12)(pMC7) with phage phi X174 culminated in lysis at 30 degrees C. At 42 degrees C, intracellular phage development was normal, but lysis did not occur unless a temperature downshift to 30 degrees C was imposed. Similarly, induction of the cloned phi X174 gene E with isopropyl-beta-D-thiogalactoside resulted in lysis at 30 degrees C but not at 42 degrees C. Temperature downshift of the induced culture to 30 degrees C resulted in lysis even in the presence of chloramphenicol. These results indicate that host cell lysis by phage phi X174 is dependent on a functional cellular autolytic enzyme system.     

Mutations affecting penicillin-binding proteins 2a, 2b and 3 in Bacillus subtilis alter cell shape and peptidoglycan metabolism

Bacillus subtilis mutants with altered penicillin-binding proteins (PBPs), or altered expression of PBPs, were isolated by screening for changes in susceptibility to beta-lactam antibiotics. Mutations affecting only PBPs 2a, 2b and 3 were isolated. Cell shape and peptidoglycan metabolism were examined in representative mutants. Cells of a PBP 2a mutant (UB8521) were usually twisted whereas PBP 2b (UB8524) and 3 (UB8525) mutants produced helices, particularly after growth at 41 degrees C. The PBP 2a mutant (UB8521) had a higher peptidoglycan synthetic activity than its parent strain whereas the opposite applied to the PBP 2b mutant UB8524. The PBP 3 mutant (UB8525) had a similar peptidoglycan synthetic activity to that of the parent strain when grown at 37 degrees C, but 40% higher activity after growth at 41 degrees C. The PBP 2a mutant (UB8521) exhibited the same wall thickening activity as the parent, but the PBP 2b and 3 mutants (UB8524 and UB8525) were partially defective in this respect. The changes in the susceptibility of PBP 2a, 2b and 3 mutants to beta-lactam antibiotics imply that these PBPs are killing targets, consistent with the fact that these PBPs are also important for shape determination and peptidoglycan synthesis.     

Temperature-Sensitive Cell Division Mutants of Escherichia coli with Thermolabile Penicillin-Binding Proteins

The thermostability of the penicillin-binding proteins (PBPs) of 31 temperature-sensitive cell division mutants of Escherichia coli has been examined. Two independent cell division mutants have been found that have highly thermolabile PBP3. Binding of [(14)C]benzylpenicillin to PBP3 (measured in envelopes prepared from cells grown at the permissive temperature) was about 30% of the normal level at 30 degrees C, and the ability to bind [(14)C]benzylpenicillin was rapidly lost on incubation at 42 degrees C. The other PBPs were normal in both mutants. At 30 degrees C both mutants were slightly longer than their parents and on shifting to 42 degrees C they ceased dividing, but cell mass and deoxyribonucleic acid synthesis continued and long filaments were formed. At 42 degrees C division slowly recommenced, but at 44 degrees C this did not occur. The inhibition of division at 42 degrees C was suppressed by 0.35 M sucrose, and in one of the mutants it was partially suppressed by 10 mM MgCl(2). PBP3 was not stabilized in vitro at 42 degrees C by these concentrations of sucrose or MgCl(2). Revertants that grew as normal rods at 42 degrees C regained both the normal level and the normal thermostability of PBP3. The results provide extremely strong evidence that the inactivation of PBP3 at 42 degrees C in the mutants is the cause of the inhibition of cell division at this temperature and identify PBP3 as an essential component of the process of cell division in E. coli. It is the inactivation of this protein by penicillins and cephalosporins that results in the inhibition of division characteristic of low concentrations of many of these antibiotics.     

Involvement of the relA gene in the autolysis of Escherichia coli induced by inhibitors of peptidoglycan biosynthesis

It is generally assumed that inhibitors of peptidoglycan biosynthesis do not kill nongrowing bacteria. An exceptional case is reported here. The addition of chloramphenicol to amino acid-deprived cultures of relA+ strains of Escherichia coli which were treated with beta-lactam antibiotics, D-cycloserine, or moenomycin resulted in lysis. This phenomenon is termed chloramphenicol-dependent lysis. To be effective, chloramphenicol had to be present at its minimum growth-inhibitory concentration (or higher). Analogs of chloramphenicol which did not bind to ribosomes were completely ineffective. Amino acid deprivation was actually not required to demonstrate chloramphenicol-dependent lysis, and cultures treated with growth-inhibitory levels of chloramphenicol alone were lysed when challenged with inhibitors of peptidoglycan synthesis. Peptidoglycan synthesis has been shown previously to be under stringent (relA+) control, and chloramphenicol is known to be an antagonist of stringent control. Thus, it is proposed that the mechanism of chloramphenicol-dependent lysis is based on the ability of chloramphenicol to relax peptidoglycan synthesis in nongrowing relA+ bacteria. This is also consistent with the observation that treatment of amino acid-deprived relA mutants with inhibitors of peptidoglycan synthesis resulted in lysis, i.e., without the mediation of chloramphenicol.     

Filamentation promotes F'lac loss in Escherichia coli K12.

The stability of plasmid F'lac in Escherichia coli strain SP45 (a temperature conditional mutant which grows as spherical cells at 42 degrees C and as a rod at 30 degrees C) was studied. F'lac elimination was demonstrated when bacteria exposed to subinhibitory concentrations of various chemicals were induced to form filaments. No plasmid loss was found when spherical cells were subjected to the same treatments. Plasmid loss was also observed in dnaA46 and lexA41 mutants when cell filamentation was induced at 42 degrees C, but not when they were cultured at 30 degrees C. Nalidixic acid promoted F'lac elimination at 0.25 micrograms ml-1 in a recA13 mutant and at 1.5 micrograms ml-1 in the recA+ counterpart. A marked difference was found in the rate of F'lac elimination from thermosensitive DNA gyrase mutants [gyrA43(Ts) and gyrB41(Ts)] between rods and their spherical (rodA51) derivatives growing at semipermissive temperature (36.5 degrees C). Plasmids carrying the ccd segment of F in DNA gyrase mutants were lost after 2.5 generations from rods and after 6 generation from spherical cells. Plasmid segregation into non-viable minicell-like elements was found after induction of filaments. These data suggest that plasmid stability is correlated with cell shape and that curing is more easily achieved when bacteria can elongate normally.     

Second lytic target of beta-lactam compounds that have a terminal D-amino acid residue

A new biochemical mechanism of lysing bacterial cells by treatment with certain beta-lactam compounds that possess a terminal D-amino acid moiety in their side chain was demonstrated. The two functions of the molecule, the beta-lactam and terminal D-amino acid moiety, are both involved in the activity of lysing gram-negative bacteria, which is characterized by very rapid lysis of the cells in the first few hours after their contact with the compound. This mechanism was proved by studies on one such compound, named MT-141, which contains a terminal D-cysteine moiety with free amino and carboxyl groups in the 7 beta-side chain of the 7 alpha-methoxy-cephalosporin skeleton. This compound bound to the cell-wall peptidoglycan of Escherichia coli through the D-amino group of its terminal D-amino acid moiety and this seemed to cause rapid cell lysis. Both activities, of binding to peptidoglycan and of causing rapid cell lysis, were inhibited by certain D-amino acids, but not by L-amino acids. Mutants were isolated that had simultaneously gained decreased sensitivity to this kind of beta-lactam compound and supersensitivity to globomycin, an inhibitor of formation of lipoproteins which function in linking the peptidoglycan to the outer membrane. These results suggest that binding of the terminal D-amino acid moiety of the beta-lactam compound to peptidoglycan somehow influences formation of the linkage between the outer membrane and the peptidoglycan and consequently enhances the cell lytic activity of the beta-lactam portion of the molecule.     

The balance between different peptidoglycan precursors determines whether Escherichia coli cells will elongate or divide.

The rodA(Sui) mutation allows cell division to take place at 42 degrees C in ftsI23 mutant cells, which produce a thermolabile penicillin-binding protein 3 (PBP3, the septation-specific peptidoglycan transpeptidase). We show here that the mutation in rodA is a single-base change from a glutamine to a chain termination (amber) codon, and that an amber suppressor (supE) present in the strain restores the ability to produce a reduced level of normal RodA protein. The reduced level of RodA is accompanied by an increase in the levels of two other proteins (PBP2 and PBP5) encoded by genes in the rodA operon. We show that an increased level of PBP5 is by itself sufficient to restore cell division to ftsI23 cells at 42 degrees C. Two other treatments were found to restore division capacity to the mutant: an increase in PBP6 (which is a D-alanine carboxypeptidase like PBP5) or suitable concentrations of D-cycloserine. All of the above treatments have the effect of reducing the number of pentapeptide side chains in peptidoglycan and increasing the number of tripeptides. We conclude that the effect of the rodA(Sui) mutation is to indirectly increase the availability of tripeptide side chains, which are used preferentially by PBP3 as acceptors in transpeptidation. A change in the proportions of different kinds of peptide side chain in the peptidoglycan can therefore determine whether cells will divide.     

Conditional Lethality of recA and recB Derivatives of a Strain of Escherichia coli K-12 with a Temperature-Sensitive Deoxyribonucleic Acid Polymerase I

We have isolated a strain of Escherichia coli K-12 carrying a mutation, polA12, that results in the synthesis of a temperature-sensitive deoxyribonucleic acid (DNA) polymerase I. The double mutants polA12 recA56 and polA12 recB21, constructed at 30 C, are inviable at 42 C. About 90% of the cells of both double mutants die after 2 hr of incubation at 42 C. Both double mutants filament at 42 C and show a dependence on high cell density for growth at 30 C. In polA12 recB21 cells at 42 C, DNA and protein synthesis gradually stop in parallel. In polA12 recA56 cells, DNA synthesis continues for at least 1 hr at 42 C, and there is extensive DNA degradation. The results suggest that the primary lesion in these double mutants is not in DNA replication per se.     

Suppressors of mutations in the bacteriophage T4 gene coding for both RNA ligase and tail fiber attachment activities.

The protein product of T4 gene 63 catalyzes both the attachment of tail fibers to fiberless phage particles and the ligation of single-stranded RNA (Snopek at al., Proc. Natl. Acad. Sci. U.S.A. 74:3355-3359, 1977). To investigate whether the gene 63 product has a role in nucleotide metabolism, we isolated false revertants of amM69 in gene 63. We screened for revertants that could grow at 30 degrees C but not at 43 degrees C on Escherichia coli OK305 when nucleotides were limiting. These false revertants contained the original mutation in gene 63 and new suppressor mutations. Some of these suppressor mutations caused temperature sensitivity by themselves, allowing single mutants carrying the suppressor to be recognized and isolated. The results of mapping and complementation studies indicated that most of these ts suppressors were in the t gene (lysis), one was in gene 5 (baseplate), and one was in gene 18 (sheath). The mutation in gene 18, tsDH638, suppressed three different amber mutations in gene 63 but did not suppress amber mutations in several other genes. None of the suppressors that were characterized were in genes with known functions in nucleotide metabolism. However, an intriguing property of these false revertants was that they were very sensitive to hydroxyurea, an inhibitor of nucleotide metabolism.     

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.     

Isolation and characterization of fusidic acid-resistant, sporulation-defective mutants of Bacillus subtilis.

Fusidic acid-resistant, sporulation-defective mutants were isolated from Bacillus subtilis 168 thy trp. About two-thirds of the fusidic acid-resistant (fusr) mutants were defective in sporulation ability and fell into three classes with respect to sporulation character. The representative mutants FUS426 and FUS429 were characterized in detail. FUS426 [fusr spo (Ts)], a temperature-sensitive sporulation mutant, grew well at 30 and 42 degrees C but did not sporulate at 42 degrees C. FUS429 [fusr spo (Con)], conditional sporulation mutant, grew and sporulated normally in the absence of fusidic acid, but its sporulation and growth rates decreased in the presence of fusidic acid, depending on the concentration of the drug. Although electron microscopic observation showed that both mutants were blocked at stage I of sporulation, the physiological analyses indicate that these mutants belong to the SpoOB class. Both mutants formed a thickened cell wall as compared with that of the parental strain. Genetic and in vitro protein synthesis analyses led to the conclusion that the sporulation-defective character of mutants FUS426 and FUS429 resulted from an alteration in elongation factor G caused by a single lesion in the fus locus. The possible role of elongation factor G in sporulation is discussed.     

Isolation and characterization of dnaJ null mutants of Escherichia coli.

Bacteriophage lambda requires the lambda O and P proteins for its DNA replication. The rest of the replication proteins are provided by the Escherichia coli host. Some of these host proteins, such as DnaK, DnaJ, and GrpE, are heat shock proteins. Certain mutations in the dnaK, dnaJ, or grpE gene block lambda growth at all temperatures and E. coli growth above 43 degrees C. We have isolated bacterial mutants that were shown by Southern analysis to contain a defective, mini-Tn10 transposon inserted into either of two locations and in both orientations within the dnaJ gene. We have shown that these dnaJ-insertion mutants did not grow as well as the wild type at temperatures above 30 degrees C, although they blocked lambda DNA replication at all temperatures. The dnaJ-insertion mutants formed progressively smaller colonies at higher temperatures, up to 42 degrees C, and did not form colonies at 43 degrees C. The accumulation of frequent, uncharacterized suppressor mutations allowed these insertion mutants to grow better at all temperatures and to form colonies at 43 degrees C. None of these suppressor mutations restored the ability of the host to propagate phage lambda. Radioactive labeling of proteins synthesized in vivo followed by immunoprecipitation or immunoblotting with anti-DnaJ antibodies demonstrated that no DnaJ protein could be detected in these mutants. Labeling studies at different temperatures demonstrated that these dnaJ-insertion mutations resulted in altered kinetics of heat shock protein synthesis. An additional eight dnaJ mutant isolates, selected spontaneously on the basis of blocking phage lambda growth at 42 degrees C, were shown not to synthesize DnaJ protein as well. Three of these eight spontaneous mutants had gross DNA alterations in the dnaJ gene. Our data provide evidence that the DnaJ protein is not absolutely essential for E. coli growth at temperatures up to 42 degrees C under standard laboratory conditions but is essential for growth at 43 degrees C. However, the accumulation of extragenic suppressors is necessary for rapid bacterial growth at higher temperatures.     

Thermosensitive omsA mutation of Escherichia coli that causes thermoregulated release of periplasmic proteins.

A mutant of Escherichia coli with a thermosensitive defect, possibly in the outer membrane (omsA mutant), was isolated from E. coli K-12 by mutagenization and selection for thermosensitivity and beta-lactam supersensitivity of growth. The mutant also showed very high sensitivity to other antibiotics, such as macarbomycin, midecamycin, rifampin, and bacitracin. The mutation was recessive to the wild type and was mapped at about 4 min on the E. coli chromosome between fhuA and metD. The mutation caused rapid release into the medium of periplasmic enzymes such as RTEM penicillinase but practically no cytoplasmic enzyme when cells grown at 30 degrees C were transferred to 37 or 42 degrees C. Electron microscopic observations showed many large double-layered vesicles attached to the surface of cells incubated at 42 degrees C. We conclude that the mutant had a mutation that caused a temperature-dependent defect in the outer membrane structure or its assembly (named an oms mutation). The omsA mutant may be useful for production of periplasmic proteins, which it releases into the culture medium on shift up of temperature.     

Biosynthesis and secretion of several enzymes in Escherichia coli dnaK and dnaJ mutants

Escherichia coli null dnaJ and dnaKdnaJ mutants were defective in the biosynthesis and secretion of several enzymes. The synthesis of beta-galactosidase induced in delta dnaJ and delta dnaKdnaJ mutants was abolished at 42 degrees C and significantly decreased at 30 and 37 degrees C. The activity of alkaline phosphatase in the periplasm in both mutant strains at high temperature was lower than in the wild-type strain. The synthesis of b-type cytochromes was defective in two deletion mutants while the synthesis of nitrate reductase-A at 42 degrees C was influenced by dnaK mutation only. The lack of DnaK and DnaJ does not impair the activity of catechol 2,3-dioxygenase irrespective of growth temperature.     

Physiological Effects of Growth of an Escherichia coli Temperature-Sensitive dnaZ Mutant at Nonpermissive Temperatures

The physiological effects of incubation at nonpermissive temperatures of Escherichia coli mutants that carry a temperature-sensitive dnaZ allele [dnaZ(Ts)2016] were examined. The temperature at which the dnaZ(Ts) protein becomes inactivated in vivo was investigated by measurements of deoxyribonucleic acid (DNA) synthesis at temperatures intermediate between permissive and nonpermissive. DNA synthesis inhibition was reversible by reducing the temperature of cultures from 42 to 30 degrees C; DNA synthesis resumed immediately after temperature reduction and occurred even in the presence of chloramphenicol. Inasmuch as DNA synthesis could be resumed in the absence of protein synthesis, we concluded that the protein product of the dnaZ allele (Ts)2016 is renaturable. Cell division, also inhibited by 42 degrees C incubation, resumed after temperature reduction, but the length of time required for resumption depended on the duration of the period at 42 degrees C. Replicative synthesis of cellular DNA, examined in vitro in toluene-permeabilized cells, was temperature sensitive. Excision repair of ultraviolet light-induced DNA lesions was partially inhibited in dnaZ(Ts) cells at 42 degrees C. The dnaZ(+) product participated in the synthesis of both Okazaki piece (8-12S) and high-molecular-weight DNA. During incubation of dnaZ(Ts)(lambda) lysogens at 42 degrees C, prophage induction occurred, and progeny phage were produced during subsequent incubation at 30 degrees C. The temperature sensitivity of both DNA synthesis and cell division in the dnaZ(Ts)2016 mutant was suppressed by high concentrations of sucrose, lactose, or NaCl. Incubation at 42 degrees C was neither mutagenic nor antimutagenic for the dnaZ(Ts) mutant.