Isolation and Some Properties of Cell Envelope Altered Mutants of Escherichia coli

Mutants of Escherichia coli which have a defect in their permeability barrier were selected. The technique used was to employ a strain of E. coli having a deletion in the gene for lactose permease and to select for mutants which can grow on lactose at 40 C. Twenty such mutants were isolated and six of these were found to be more sensitive to actinomycin D, sodium deoxycholate, and sodium dodecyl sulfate than was the parental strain. They were also more sensitive to the antibiotics vancomycin and bacitracin, which inhibit peptidoglycan biosynthesis. These mutants were no more sensitive to several different colicins or phages than was the wild-type strain. One of the mutants selected by this technique has an abnormal morphology when grown on certain carbon sources in minimal medium, and this mutant is more extensively studied in the accompanying paper.     

Escherichia coli Mutants Permissive for T4 Bacteriophage with Deletion in e Gene (Phage Lysozyme)

Escherichia coli mutants have been isolated that are permissive for the infection by T4 phage with deletion in the cistron for the phage lysozyme, the e gene. Some, but not all, of these mutants are simultaneously permissive for the infection by T4 phage defective in the t gene, the product of which has also been implicated in the release of progeny phages. Most of these mutants shared the following properties: temperature sensitivity in growth and cell division, increased sensitivity towards a number of unrelated antibiotics and colicins, and increased sensitivity towards anionic detergents (sodium dodecyl sulfate and sodium deoxycholate). The possible biochemical basis for these phenotypes is discussed.     

Alteration of Host Specificity to Lytic Bacteriophages in Streptococcus cremoris

A mutant of Streptococcus cremoris strain ML1 was isolated based on its resistance to acriflavine. The mutant strain showed resistance to the growth of virulent bacteriophages to which the parental strain was sensitive whereas it became sensitive to a number of other virulent phages to which the parental strain was resistant. At the same time, infection of the mutant strain by another bacteriophage sc607 resulted in killing of cells without production of progeny phages. The phage adsorption appeared normal, suggesting that the killing was a postadsorption event. Such killing of bacterial cells was prevented by chloramphenicol treatment, indicating that involvement of some protein either synthesized by phage or phage-induced cellular protein. Synthesis of ribonucleic acid was abruptly terminated after infection of the mutant strain by phage sc607 but not of the parental strain. The alteration of host specificity in the mutant to different lytic bacteriophages and especially abortive infection by phage sc607 resembles the prophage-mediated interference observed in other bacteria.     

Inhibition of staphylococcal enterotoxin B formation by cell wall blocking agents and other compounds

Enterotoxin B formation by Staphylococcus aureus S6 was inhibited by Tween 80, oleic acid, sodium deoxycholate, penicillin, d-cycloserine, or bacitracin. Toxin formation by strain 243 was sensitive to oleic acid, sodium deoxycholate, sodium lauryl sulfate, d-cycloserine, or bacitracin. The effect of d-cycloserine was reversed by d-alanine with strain 243 but not with strain S6. Neither penicillin nor bacitracin inhibited alpha-hemolysin or coagulase activity of strain S6; however, 0.118 mumoles of d-cycloserine per ml increased the alpha-hemolysin titer more than eightfold. Pigmentation of strain 243 was reduced by oleic acid, sodium deoxycholate, or methicillin, and was completely inhibited by d-cycloserine or bacitracin. Glucose was required for the inhibition by spermine of (14)C-valine incorporation into cellular protein of strain S6. These data indicate that the cell surface may contain sites important to the synthesis of enterotoxin B.     

Properties of adenyl cyclase and cyclic adenosine 3'',5''-monophosphate receptor protein-deficient mutants of Escherichia coli.

Several spontaneous cya and crp mutants of Escherichia coli have been selected as clones simultaneously resistant to phage lambda and nalidixic acid and characterized. Both cya and crp mutants have been found to grow as cocci with increased doubling times. They have increased resistance to some mutagens (methylmethanesulfonate, ultraviolet light, gamma rays), antibiotics (nalidixic acid, ampicillin), phages (lambda, T6), sublethal heat and hypotonic shock, and decreased resistance to neutral detergents (sodium dodecyl sulfate, sodium deoxycholate), a protein synthesis inhibitor (streptomycin), and a respiratory inhibitor (sodium azide). The nature of changes in cell parameters indicate fundamental alterations in the envelope structure of the cya and crp mutant cells. The new cya and crp mutants have been found to be multiply carbohydrate negative and nonmotile in conformity with similar previously isolated mutants. Studies of revertants and phi80 cya+ and phi80 cya transductants indicated that the pleiotropic phenotype is related to a single mutational event at the cya or the crp locus in the mutants.     

Genetic Determination of Resistance to Acriflavine, Phenethyl Alcohol, and Sodium Dodecyl Sulfate in Escherichia coli

Wild-type strains of Escherichia coli K-12 are resistant to acriflavine. Gene acrA(+) which determines resistance to acriflavine is located near the lac region of the chromosome. This gene determines not only resistance to basic dyes but also resistance to phenethyl alcohol. Acriflavine resistance was transmitted, together with phenethyl alcohol resistance, from a resistant Hfr strain to a sensitive recipient by mating. Reversion of the mutant gene acrA1 (phenotypically acriflavine-sensitive) to acriflavine resistance was accompanied by a change from phenethyl alcohol sensitivity to resistance, and conversely the revertants selected for phenethyl alcohol resistance were resistant to acriflavine. A suppressor mutation, sup-100, closely linked to the acr locus, suppresses the acrA1 gene (phenotypically acriflavine-resistant), but does not determine resistance to phenethyl alcohol and basic dyes other than acriflavine. The genetic change in the locus acrA1 to types resistant to basic dyes and phenethyl alcohol was accompanied by an increase in resistance to sodium dodecyl sulfate, a potent solvent of lipopolysaccharide and lipoprotein. It is suggested that gene acrA determines synthesis of a membrane substance. The system seemed to be affected strongly by the presence of inorganic phosphate.     

复合诱变在青霉高产菊粉酶菌株选育中的应用

以Penicillium sp．B01为出发菌株,经吖黄素或DES（硫酸二乙酯）分别与^60Co-γ射线对其孢子悬液进行复合诱变。经过初筛和复筛,在30μg／mL吖黄素诱变时间2h,剂量率为4．11Gy／min的^60Co-γ射线辐射使累计剂量为20．55Gy复合诱变的条件下,筛选出一株菊粉酶活比出发菌株高32％的突变菌株B01-A13-Co31。经同工酶电泳验证,变异株与出发菌株相比酶带有所变化。将此菌种连续传代6次进行产酶性能的稳定性测定,表明此菌株具有良好的遗传稳定性。     

Characterization of an OprL null mutant of Pseudomonas putida.

A Pseudomonas putida oprL null mutant was generated with reverse genetics by using an in vitro-truncated oprL::xylE construct and in vivo allelic exchange. The nature of the mutation introduced in P. putida was confirmed by Southern blotting. Western blots (immunoblots) of peptidoglycan-associated proteins revealed that the OprL protein was not made in the mutant strain, whereas it was detectable as a 19-kDa band in protein preparations of the wild-type strain. The P. putida oprL, mutant exhibited altered cell morphology as revealed by electron microscopy and was more sensitive to sodium dodecyl sulfate, deoxycholate, and EDTA than the wild-type strain. The oprL gene was conserved in a wide variety of the Pseudomonas strains belonging to rRNA group I, which suggests that this gene is important for the maintenance of the cell envelope and cell morphology in this group of microorganisms.     

Bacteriophage-resistant mutants of Bacillus thuringiensis with decreased virulence in pupae of Hyalophora cecropia

Starting from a crystal-negative parental strain of Bacillus thuringiensis, we isolated certain bacteriophage-resistant mutants which showed decreased virulence in pupae of the cecropia moth (Hyalophora cecropia). These strains (class I mutants) were highly pleiotropic and showed resistance to seven or eight different phages, sensitivity to methicillin, and loss of flagella. They were also more sensitive to cecropia immune hemolymph in vitro. In addition, the export of at least three proteins was reduced. Revertants (class II mutants) were sensitive to phages, virulent, and resistant to penicillin derivatives. One class II mutant was a complete revertant in all properties examined. The other class II mutant was an incomplete revertant still susceptible to immune hemolymph and with repressed export of proteins. Virulence was not coupled to phage resistance as such or to lack of flagella because other mutants affected in these properties were virulent. Other factors which could be excluded as causes of virulence were production of extracellular protease and hemolysin.     

Membrane Mutation Associated with Sensitivity to Acriflavine in Escherichia coli

The role of plasma membrane on the acriflavine sensitivity of Escherichia coli was studied. (14)C-uracil incorporation into ribonucleic acid fraction by spheroplasts was more sensitive to acriflavine in the acriflavine-sensitive strain (genotype acrA) than in the acriflavine-resistant (genotype acrA(+)) strain. There was no difference between two types of cells in the response to osmotic shock, phage sensitivity, and other treatments used to investigate the structure and stability of cell wall. Differences in the electron-microscopic figures between acrA and acrA(+) cells was found in the plasma membrane, surface area just below the membrane, and ribosomal aggregation, when cells were treated with acriflavine. It is concluded that a primary site of acriflavine action is on the plasma membrane, and the acrA mutation is mediated by it. On the basis of the present results, it is evident that differences in the acriflavine binding and the sensitivity to phenethyl alcohol and sodium dodecyl sulfate between the acrA and acrA(+) strains, previously reported, are attributable to a structural difference in the plasma membrane between the two strains.     

Mechanism of adhesion of Alysiella bovis to glass surfaces

Alysiella bovis adheres to surfaces by means of short, ruthenium red-staining, rod-like fimbriae. The fimbriae remain associated with the cell envelope of A. bovis, even when sonicated or exposed sequentially to toluene, Triton X-100, lysozyme, ribonuclease, and deoxyribonuclease. Adhesion of outer membrane-derived cell wall ghosts of A. bovis to glass was inhibited by IO4-, sodium dodecyl sulfate, urea, pronase, and trypsin. Protease treatment digested the fimbriae from the distal end, and exposure to sodium dodecyl sulfate depolymerized the fimbriae. Exposure of ghosts to 1% sodium dodecyl sulfate preferentially solubilized a 16,500-dalton protein which was subsequently purified by gel filtration and demonstrated to be a glycoprotein (ca. 17% carbohydrate). Antibodies raised against the 16,500-dalton glycoprotein agglutinated whole cells and inhibited adhesion of ghosts to glass.     

Isolation, and morphological and chemical properties of an autolysis-deficient mutant of Clostridium botulinum type A.

An autolysis-deficient mutant was isolated from Clostridium botulinum type A 190L by treatment with ethyl methanesulfonate. The cell wall prepared from the mutant autolyzed at much slower rate than that from the parent strain, accompanying with much less liberation of both amino terminals and reducing groups. Electron microscopic observation revealed that the mutant strain was converted to short rod or curved spherical form with thickened cell walls when the growth temperature was shifted from 37 to 45 C. The mutant had a significantly larger amount of non-peptidoglycan-carbohydrate complexes than did the parent strain and became markedly resistant to the autolysin partially purified from the parent, compared with the parent strain. Furthermore, the mutant was fairly tolerant to killing by penicillin. These results suggest that the autolysis deficiency of the mutant was due not only to the deficient production of autolysin but also to the excess accumulation of carbohydrate in the cell wall.     

Resistance of Escherichia coli to penicillins. 8. Physiology of a class II ampicillin-resistant mutant

Class II ampicillin-resistant mutants of Escherichia coli are defined as having a twofold increase in penicillinase-mediated ampicillin resistance when determined by colony formation tests on plates. In this paper, one class II mutant has been compared to its parent strain. In liquid medium, the mutant was less resistant than the parent strain both in the absence and in the presence of R1 and R-factor mediating penicillinase activity. The penicillinase activity was found to be almost completely bound to the cells in the parent strain, whereas it was excreted to a great extent in the class II mutant strain. In liquid medium, resistance was well correlated to the cell-bound penicillinase activity, whereas the excreted penicillinases were also of great importance for survival on ampicillin plates. The mutant also had a changed resistance to a great number of other antibacterial drugs. The mutant was found to be more sensitive than the parent strain to osmotic shock, especially when treated with ethylenediaminetetraacetic acid or washed with sodium ions. However, the osmotic stability was restored by the presence of 1 mm Mg(2+) ions. The class II mutant was more sensitive than the parent strain to sodium cholate, and it adsorbed the phages T4 and T3-1 at a slower rate than did the parent strain. The two strains adsorbed T6 at the same rate. The class II phenotype could be gradually reversed by increasing concentrations of divalent cations. The pleiotropic changes in the phenotype are apparently unrelated to the specific targets for the antibacterial agents tested. They are secondary consequences of a cell envelope mutation. The findings indicate that the class II mutation mediates a structural change in the lipopolysaccharide of the cell envelope.     

Autolytic defective mutant of Streptococcus faecalis.

Properties of a variant of Streptococcus faecalis ATCC 9790 with defective cellular autolysis are described. The mutant strain was selected as a survivor from a mutagenized cell population simultaneously challenged with two antibiotics which inhibit cell wall biosynthesis, penicillin G and cycloserine. Compared to the parental strain, the mutant strain exhibited: (i) a thermosensitive pattern of cellular autolysis; (ii) an autolytic enzyme activity that had only a slightly increased thermolability when tested in solution in the absence of wall substrate; and (iii) an isolated autolysin that had hydrolytic activity on isolated S. faecalis wall substrate indistinguishable from that of the parental strain, but that was inactive when tested on walls of Micrococcus lysodeikticus as a substrate. These data indicate an alteration in the substrate specificity of the autolytic enzyme of the mutant which appears to result from the synthesis of an altered form of autolytic enzyme.     

A polypeptide bacteriophage receptor: modified cell wall protein subunits in bacteriophage-resistant mutants of Bacillus sphaericus strain P-1

Bacillus sphaericus strain P-1 has previously been shown to have a tetragonally arrayed (T layer) protein which forms the outer layer of the cell wall. The T layer was quantitatively extracted from whole cells by 6 M urea, and the T layer subunits were purified by electrophoresis of the extracts on acrylamide gels containing 0.1% sodium dodecyl sulfate or 6 M urea. Using ethylene diacrylate cross-linked gels, the T layer was found to make up 16% of the total cellular protein. A virulent bacteriophage which is inactivated by purified T layer was isolated from soil. Twenty-four phage-resistant mutants were isolated, of which 17 had T layer subunits of increased mobility on sodium dodecyl sulfate acrylamide gels. No mutants devoid of T layer were found. Mutants were grouped into six classes according to the molecular weight of their T layer subunits. These ranged from that of the wild type, 150,000 down to 86,000. Two mutants from different classes were examined in detail. Cells of the mutant strains did not adsorb phage nor did cell walls isolated from these mutants inactivate phage. The amino acid composition of the T layers from mutants differed little from that of the wild-type T layer.     

Exchange of colicin receptor capacity between strains of Escherichia coli sensitive or resistant to colicin K-K235

Phage and colicin-resistant mutants were derived from Escherichia coli K-12P678. Two classes of phage T6 and colicin K-resistant mutants (genotype tsx) were isolated. Tsx-2 mutants, which demonstrated mucoid growth and increased sensitivities to many antibiotics, became sensitive to colicin K when pretreated with ethylenediaminetetraacetate (EDTA), whereas Tsx-1 mutants did not. Reassociation of EDTA-released material partially restored resistance to colicin K for Tsx-2 mutants. When EDTA-released material from strain P678 was associated with either class of K-resistant mutant, an increase in colicin K sensitivity resulted. Observations suggest that colicin K can act on its target site once it penetrates the cell surface. In addition, results suggest that functional colicin K receptors can be transferred from sensitive to resistant strains, thus conferring colicin sensitivity.Non-standard Abbreviations SDS sodium dodecyl sulfate     

Phospholipase A-deficient mutants of Escherichia coli B

Phospholipase A-deficient mutants were isolated from Escherichia coli B/SM as follows. Replica plates were incubated to allow formation of colonies and then overlayed with soft agar containing washed sheep erythrocytes, lecithin Ca++, colistin, lysozyme and streptomycin. The mutant colonies were detected as colonies without hemolytic zones. Two or three cycles of treatment with mutagen and selection were necessary for their isolation. The mutants obtained could grow in a synthetic medium with glucose as the sole carbon source, and their phospholipid compositions were similar to that of the parent. They also gave the same agglutination titer as the parent with rabbit antiserum against the parent strain. They supported the growth of all members of the T-series of bacteriophages as effectively as the parent. Some hemolytic substance was produced from either lecithin or bacterial constituents when the mutants were infected with T even phages, but not with T odd phages. When the parent strain was infected with either T1 or T4, free fatty acids (FFA) were produced in the cell debris. Only a trace of FFA was formed in the debris of one of these mutants on infection with T4 and no FFA was formed on infection with T1.     

Mutant of Escherichia coli K-12 Deficient for Detergent-Resistant Phospholipase A

A mutant deficient for detergent-resistant (DR) phospholipase A was isolated from Escherichia coli K-12. Because the enzyme is membrane-bound and the substrate is a lipid, a special procedure was developed for isolating mutants deficient for the enzyme from agar plates. A sodium dodecyl sulfate (SDS)-sensitive mutant was used as a parental strain for the isolation of DR phospholipase A-deficient mutant. Soft agar containing an unsaturated fatty acid auxotroph and SDS was poured over colonies of the parental strain. The cells were easily solubilized with SDS, and phospholipids were efficiently digested by DR phospholipase A from the colonies on an agar plate. Fatty acids released supported the growth of the indicator bacteria. After the cells of the parent were mutagenized with nitrosoguanidine, colonies which could not support the growth of an unsaturated fatty acid auxotroph in the presence of SDS were selected. Four mutants were isolated after in vitro scre[UNK]ning of DR phospholipase A activity of 30 halo-less clones. Since an extract of the parent strain mixed with that of a mutant strain was still active, it was concluded that the inability to hydrolyze phospholipids was not due to the accumulation of inhibitory substance; the activity of DR phospholipase A in the mutant was less than 1% of the parental activity. Physiological studies indicated that DR phospholipase A is not essential for the growth of E. coli.     

Attenuation of penicillin resistance in a peptidoglycan O-acetyl transferase mutant of Streptococcus pneumoniae

The level of penicillin resistance in clinical isolates of Streptococcus pneumoniae depends not only on the reduced affinity of penicillin binding proteins (PBPs) but also on the functioning of enzymes that modify the stem peptide structure of cell wall precursors. We used mariner mutagenesis in search of additional genetic determinants that may further attenuate the level of penicillin resistance in the bacteria. A mariner mutant of the highly penicillin-resistant S. pneumoniae strain Pen6 showed reduction of the penicillin minimum inhibitory concentration (MIC) from 6 to 0.75 microg ml(-1). Decrease in penicillin MIC was also observed upon introduction of the mutation (named provisionally adr, for attenuator of drug resistance) into representatives of major epidemic clones of penicillin-resistant pneumococci. Attenuation of resistance levels was specific for beta-lactams. The adr mutant has retained unchanged (low affinity) PBPs, unaltered murM gene and unchanged cell wall stem peptide composition, but the mutant became hypersensitive to exogenous lysozyme and complementation experiments showed that both phenotypes--reduced resistance and lysozyme sensitivity--were linked to the defective adr gene. DNA sequence comparison and chemical analysis of the cell wall identified adr as the structural gene of the pneumococcal peptidoglycan O-acetylase.