Mapping of the mecillinam-resistant, round morphological mutants of Escherichia coli

Clinical isolates of Escherichia coli solely resistant to mecillinam: prevalence and epidemiology

In routine susceptibility testing of Gram-negative bacteria, a particular resistance phenotype was observed: an Escherichia coli isolate from a urine sample exhibited resistance solely to mecillinam (MEC) but was fully susceptible to other β-lactam antibiotics (MEC-R-BL-S). The objectives as this study were to determine the prevalence of this phenotype and to describe the phenotype, molecular epidemiology and genetic background. Between 1 January 2014 and 31 January 2016, MEC-R-BL-S E. coli isolates from urine were collected and genes previously reported as mostly involved in MEC resistance were analysed. The genetic relatedness among isolates was investigated by repetitive element sequence-based PCR (rep-PCR) and multilocus sequence typing (MLST). Ten MEC-R-BL-S isolates were collected, accounting for 0.4% (10/2547) of all E. coli obtained from urine samples, 0.9% (10/1135) of ampicillin-susceptible E. coli isolates and 9.6% (10/104) of MEC-R E. coli isolates. The isolates appeared as small colonies with round morphology and had impaired fitness. The isolates were not clonal and belonged to various extraintestinal or commensal E. coli phylogroups. Mutations in the cysB gene were evidenced in all clinical isolates. In conclusion, microbiologists should be aware of these isolates with a particular susceptibility phenotype, which is not due to error in disk diffusion but is a real non-enzymatic antibiotic resistance pattern.

Amdinocillin (Mecillinam) resistance mutations in clinical isolates and laboratory-selected mutants of Escherichia coli

Amdinocillin (mecillinam) is a β-lactam antibiotic that is used mainly for the treatment of uncomplicated urinary tract infections. The objectives of this study were to identify mutations that confer amdinocillin resistance on laboratory-isolated mutants and clinical isolates of Escherichia coli and to determine why amdinocillin resistance remains rare clinically even though resistance is easily selected in the laboratory. Under laboratory selection, frequencies of mutation to amdinocillin resistance varied from 8 × 10(-8) to 2 × 10(-5) per cell, depending on the concentration of amdinocillin used during selection. Several genes have been demonstrated to give amdinocillin resistance, but here eight novel genes previously unknown to be involved in amdinocillin resistance were identified. These genes encode functions involved in the respiratory chain, the ribosome, cysteine biosynthesis, tRNA synthesis, and pyrophosphate metabolism. The clinical isolates exhibited significantly greater fitness than the laboratory-isolated mutants and a different mutation spectrum. The cysB gene was mutated (inactivated) in all of the clinical isolates, in contrast to the laboratory-isolated mutants, where mainly other types of more costly mutations were found. Our results suggest that the frequency of mutation to amdinocillin resistance is high because of the large mutational target (at least 38 genes). However, the majority of these resistant mutants have a low growth rate, reducing the probability that they are stably maintained in the bladder. Inactivation of the cysB gene and a resulting loss of cysteine biosynthesis are the major mechanism of amdinocillin resistance in clinical isolates of E. coli.

Structure-function analysis of MurJ reveals a solvent-exposed cavity containing residues essential for peptidoglycan biogenesis in Escherichia coli

Gram-negative bacteria such as Escherichia coli build a peptidoglycan (PG) cell wall in their periplasm using the precursor known as lipid II. Lipid II is a large amphipathic molecule composed of undecaprenyl diphosphate and a disaccharide-pentapeptide that PG-synthesizing enzymes use to build the PG sacculus. During PG biosynthesis, lipid II is synthesized at the cytoplasmic face of the inner membrane and then flipped across the membrane. This translocation of lipid II must be assisted by flippases thought to shield the disaccharide-pentapeptide as it crosses the hydrophobic core of the membrane. The inner membrane protein MurJ is essential for PG biogenesis and homologous to known and putative flippases of the MOP (multidrug/oligo-saccharidyl-lipid/polysaccharide) exporter superfamily, which includes flippases that translocate undecaprenyl diphosphate-linked oligosaccharides across the cytoplasmic membranes of bacteria. Consequently, MurJ has been proposed to function as the lipid II flippase in E. coli. Here, we present a three-dimensional structural model of MurJ generated by the I-TASSER server that suggests that MurJ contains a solvent-exposed cavity within the plane of the membrane. Using in vivo topological studies, we demonstrate that MurJ has 14 transmembrane domains and validate features of the MurJ structural model, including the presence of a solvent-exposed cavity within its transmembrane region. Furthermore, we present functional studies demonstrating that specific charged residues localized in the central cavity are essential for function. Together, our studies support the structural homology of MurJ to MOP exporter proteins, suggesting that MurJ might function as an essential transporter in PG biosynthesis.

Motion of variable-length MreB filaments at the bacterial cell membrane influences cell morphology

The maintenance of rod-cell shape in many bacteria depends on actin-like MreB proteins and several membrane proteins that interact with MreB. Using superresolution microscopy, we show that at 50-nm resolution, Bacillus subtilis MreB forms filamentous structures of length up to 3.4 μm underneath the cell membrane, which run at angles diverging up to 40° relative to the cell circumference. MreB from Escherichia coli forms at least 1.4-μm-long filaments. MreB filaments move along various tracks with a maximal speed of 85 nm/s, and the loss of ATPase activity leads to the formation of extended and static filaments. Suboptimal growth conditions lead to formation of patch-like structures rather than extended filaments. Coexpression of wild-type MreB with MreB mutated in the subunit interface leads to formation of shorter MreB filaments and a strong effect on cell shape, revealing a link between filament length and cell morphology. Thus MreB has an extended-filament architecture with the potential to position membrane proteins over long distances, whose localization in turn may affect the shape of the cell wall.

Beta-lactam antibiotics: from antibiosis to resistance and bacteriology

This review focuses on the era of antibiosis that led to a better understanding of bacterial morphology, in particular the cell wall component peptidoglycan. This is an effort to take readers on a tour de force from the concept of antibiosis, to the serendipity of antibiotics, evolution of beta-lactam development, and the molecular biology of antibiotic resistance. These areas of research have culminated in a deeper understanding of microbiology, particularly in the area of bacterial cell wall synthesis and recycling. In spite of this knowledge, which has enabled design of new even more effective therapeutics to combat bacterial infection and has provided new research tools, antibiotic resistance remains a worldwide health care problem.

Dynamic localization and interaction with other Bacillus subtilis actin-like proteins are important for the function of MreB

Bacterial actin-like proteins play a key role in cell morphology and in chromosome segregation. Many bacteria, like Bacillus subtilis, contain three genes encoding actin-like proteins, called mreB, mbl and mreBH in B. subtilis. We show that MreB and Mbl colocalize extensively within live cells, and that all three B. subtilis actin paralogues interact with each other underneath the cell membrane. A mutation in the phosphate 2 motif of MreB had a dominant negative effect on cell morphology and on chromosome segregation. Expression of this mutant allele of MreB interfered with the dynamic localization of Mbl. These experiments show that the interaction between MreB and Mbl has physiological significance. An mreB deletion strain can grow under special media conditions, however, depletion of Mbl in this mutant background abolished growth, indicating that actin paralogues can partially complement each other. The membrane protein MreC was found to interact with Mbl, but not with MreB, revealing a clear distinction between the function of the two paralogues. The phosphate 2 mutant MreB protein allowed for filament formation of mutant or wild-type MreB, but abolished the dynamic reorganization of the filaments. The latter mutation led to a strong reduction, but not complete loss, of function of MreB, both in terms of chromosome segregation and of cell morphology. Our work shows that that the dynamic localization of MreB is essential for the proper activity of the actin-like protein and that the interactions between MreB paralogues have important physiological significance.

Bacterial cell shape

Bacterial species have long been classified on the basis of their characteristic cell shapes. Despite intensive research, the molecular mechanisms underlying the generation and maintenance of bacterial cell shape remain largely unresolved. The field has recently taken an important step forward with the discovery that eukaryotic cytoskeletal proteins have homologues in bacteria that affect cell shape. Here, we discuss how a bacterium gains and maintains its shape, the challenges still confronting us and emerging strategies for answering difficult questions in this rapidly evolving field.

Novel S-benzylisothiourea compound that induces spherical cells in Escherichia coli probably by acting on a rod-shape-determining protein(s) other than penicillin-binding protein 2

Random screening for inhibitors of chromosome partitioning in Escherichia coli was done by the anucleate cell blue assay. A novel S-benzylisothiourea derivative, S-(3,4-dichlorobenzyl)isothiourea, tentatively named A22, was found to induce spherical cells and spherical anucleate cells in E. coli. Mecillinam, a specific inhibitor of penicillin-binding protein 2, which induces spherical cells in E. coli, also caused anucleate cell production. Spherical cells induced by treatment with either A22 or mecillinam varied in size, and anucleate cells seemed to be more frequent among the smaller cells. These results suggest that loss of the rod shape in E. coli leads to asymmetric cell division that results in production of anucleate cells. No competition was observed even in the presence of a 10-fold excess A22 in an in vitro assay of 14C-penicillin G binding, but mecillinam specifically inhibited binding of 14C-penicillin G to penicillin-binding protein 2. Simultaneous treatment with mecillinam and cephalexin, a specific inhibitor of penicillin-binding protein 3, induced lysis of E. coli cells, but a combination of A22 and cephalexin did not. These results suggest that the target molecule(s) of A22 was not penicillin-binding protein 2. A22 may act on a rod-shape-determining protein(s) other than penicillin-binding protein 2, such as RodA or MreB.

Constitutive septal murein synthesis in Escherichia coli with impaired activity of the morphogenetic proteins RodA and penicillin-binding protein 2

The pattern of peptidoglycan (murein) segregation in cells of Escherichia coli with impaired activity of the morphogenetic proteins penicillin-binding protein 2 and RodA has been investigated by the D-cysteine-biotin immunolabeling technique (M. A. de Pedro, J. C. Quintela, J.-V. Höltje, and H. Schwarz, J. Bacteriol. 179:2823-2834, 1997). Inactivation of these proteins either by amdinocillin treatment or by mutations in the corresponding genes, pbpA and rodA, respectively, leads to the generation of round, osmotically stable cells. In normal rod-shaped cells, new murein precursors are incorporated all over the lateral wall in a diffuse manner, being mixed up homogeneously with preexisting material, except during septation, when strictly localized murein synthesis occurs. In contrast, in rounded cells, incorporation of new precursors is apparently a zonal process, localized at positions at which division had previously taken place. Consequently, there is no mixing of new and old murein. Old murein is preserved for long periods of time in large, well-defined areas. We propose that the observed patterns are the result of a failure to switch off septal murein synthesis at the end of septation events. Furthermore, the segregation results confirm that round cells of rodA mutants do divide in alternate, perpendicular planes as previously proposed (K. J. Begg and W. D. Donachie, J. Bacteriol. 180:2564-2567, 1998).

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Identification of several rod loci and cloning of the rodD locus of Streptococcus mutans

Previous work has shown that Streptococcus mutans is normally a short rod or a sphere, depending on its environment. This paper describes two distinct genetic approaches used to identify multiple loci and isolate one locus, rodD, controlling S. mutans rod shape. The first method involved isolation of a group of rod- mutants caused by transposon Tn916 insertion, and analysis of the inactivated genes by Southern hybridization. The second method involved mutagenesis via a shotgun insertion-duplication technique, isolation of a rod- mutant, and cloning the intact rod locus, employing an integration shuttle plasmid, pVA891. These approaches have led to the identification of multiple rod loci involved in determining the rod shape of S. mutans, and also cloning of one rod locus, rodD. The cloning strategy may also be useful for cloning other streptococcal genes which cannot be detected by their expression in Escherichia coli.

Ion channel activities in the Escherichia coli outer membrane

The electrical properties of Escherichia coli cells were examined by the patch-clamp technique. Giant cells or giant spheroplasts were generated by five different methods. By electron micrographic and other criteria we determined that the patches are most likely from the outer membrane. We regularly observed currents through at least two types of channels in this membrane. The first current is mechanosensitive and voltage-dependent, and can be observed in single gene mutants of the known major porins (ompF, ompC, phoE, lamB); this channel may represent a minor porin or a new class of outer membrane protein. The possible identity of the second, voltage-sensitive channel with one of the known outer membrane proteins is being explored. The high-resistance seals consistently formed on these patches and the presence of gated ion channels suggest that most of the pores of the outer membrane are not statically open, as commonly held, but are closed at rest and may be openable by physiological stimuli.

Penicillin-binding protein 2 is essential in wild-type Escherichia coli but not in lov or cya mutants

Penicillin-binding protein 2 (PBP2), target of the beta-lactam mecillinam, is required for rod morphology and cell wall elongation in Escherichia coli. A new temperature-sensitive PBP2 allele and an in vitro-constructed insertion deletion allele were shown to be lethal in wild-type strains, establishing that the activity of this protein is essential. Mutations in the lov or cya genes, conferring mecillinam resistance, compensated for the deleterious effect of the absence of PBP2. The resulting double mutants grew as spheres. In a cya mutant lacking PBP2, the restoration of a Cya+ phenotype by addition of cyclic AMP caused lethality and a block in cell division. These results show that in wild-type cells, PBP2 is essential for growth and division.

Nucleotide sequence of the rodA gene, responsible for the rod shape of Escherichia coli: rodA and the pbpA gene, encoding penicillin-binding protein 2, constitute the rodA operon

The rodA gene, which is responsible for the rod shape of Escherichia coli, was located 5 nucleotides downstream of another rod-shape-determining gene, pbpA, encoding penicillin-binding protein 2. The coding region for the RodA protein was 1,110 base pairs in length. Two plasmids, carrying a rodA-lacZ gene fusion with and without the pbpA promoter upstream of the gene fusion, were constructed. On the basis of the difference between the expression levels of the beta-galactosidase activity dependent on and independent of the pbpA promoter, we concluded that the pbpA and rodA genes constitute a single transcriptional unit called the rodA operon.

Identification, cloning, and expression of bolA, an ftsZ-dependent morphogene of Escherichia coli

A newly found morphogene of Escherichia coli, bolA, mapping at min 10 of the genetic map, was cloned in a 7.2-kilobase BamHI fragment and identified by its ability to produce osmotically stable spherical cells when overexpressed. This gene codes for a polypeptide of 13 kilodaltons. Overexpression of bolA+ was achieved in low-copy-number vectors with operon fusions to the tet and lac promoters, indicating a clockwise direction of transcription. While no modification of any of the penicillin-binding proteins was observed, morphological effects due to overexpression of bolA+ were shown to be dependent on the presence of an active ftsZ gene product. Our results suggest the existence of a mechanism mediated by FtsZ for modifying the conformation of nascent murein in the early steps of septum formation.

Determinations of the DNA sequence of the mreB gene and of the gene products of the mre region that function in formation of the rod shape of Escherichia coli cells

The 6.5-kilobase mre region at 71 min in the Escherichia coli chromosome map, where genes involved in formation of a rod-shaped cell form a gene cluster, was analyzed by in vivo protein synthesis in a maxicell system and by base sequencing of DNA. An open reading frame that may code for a protein with an Mr of about 37,000 on sodium dodecyl sulfate-polyacrylamide gels was found and was correlated with the mreB gene. N-terminal amino acid sequencing of the hybrid mreB-lacZ protein confirmed the production by mreB of a protein of 347 amino acid residues with a molecular weight of 36,958. The amino acid sequence of this protein deduced from the DNA sequence showed close similarity with that of a protein of the ftsA gene which is involved in cell division of E. coli. Three other contiguous genes that formed three proteins with Mrs of about 40,000, 22,000, and 51,000, respectively, were detected downstream of the mreB gene by in vivo protein synthesis. The mreB protein and some of these three proteins may function together in determination of cell shape.

Mutant isolation and molecular cloning of mre genes, which determine cell shape, sensitivity to mecillinam, and amount of penicillin-binding proteins in Escherichia coli

A chromosomal region of Escherichia coli contiguous to the fabE gene at 71 min on the chromosomal map contains multiple genes that are responsible for determination of the rod shape and sensitivity to the amidinopenicillin mecillinam. The so-called mre region was cloned and analyzed by complementation of two closely related but distinct E. coli mutants characterized, respectively, by the mutations mre-129 and mre-678, that showed a rounded to irregular cell shape and altered sensitivities to mecillinam; the mre-129 mutant was supersensitive to mecillinam at 30 degrees C, but the mre-678 mutant was resistant. The mre-678 mutation also caused simultaneous overproduction of penicillin-binding proteins 1Bs and 3. A chromosomal region of the wild-type DNA containing the total mre region and the fabE gene was first cloned on a lambda phage; a 7-kilobase (kb) fragment containing the whole mre region, but not the fabE gene, was then recloned on a mini F plasmid, pLG339; and finally, a 2.8-kb fragment complementing only mre-129 was also cloned on this low-copy-number plasmid. The whole 7-kb fragment was required for complementing the mre-678 mutant phenotypes. Fragments containing fabE but not the mre-129 region could be cloned on a high-copy-number plasmid. Southern blot hybridization indicated that the mre-678 mutant had a large deletion of 5.25 kb in its DNA, covering at least part of the mre-129 gene.

Conditional transduction of Salmonella typhimurium envB mutations

Joint transduction of the argR and envB genes was observed, at a frequency of 24.5%, when four envB strains were transduced to tetracycline resistance (Tetr) with bacteriophage P22 grown on an argR372::Tn10 envB+ donor. When round-cell argR372::Tn10 derivatives of those envB strains were used as donors, two of them did not produce envB transductants in wild-type LT2 and other envB+ recipients, even though large numbers of Tetr transductants were obtained. This apparent exclusion of envB mutations did not occur when mecillinam-resistant derivatives of those envB+ strains were used as recipients. Mutations conferring partial resistance to mecillinam were found, unlinked to the argR-envB region, in three of the four envB strains studied; envB+ derivatives of the four strains were competent to accept envB mutations excluded by wild-type recipients. It is suggested that some envB mutations are lethal in the absence of suppressor mutations, some of which increase resistance to mecillinam.

Penicillin-binding proteins and role of amdinocillin in causing bacterial cell death

The activity of penicillins against bacteria is in large part related to binding to specific receptor proteins involved in cell wall biosynthesis. These proteins have been designated penicillin-binding proteins. They can be separated into distinct entities through the use of acrylamide gel electrophoresis and binding of radioactive 14C-labeled penicillin G. Six major proteins have been defined in the Enterobacteriaceae, penicillin-binding proteins 1 to 6. Selection of mutants has shown that there are three essential proteins: penicillin-binding protein 1, which is divided into penicillin-binding protein 1Bs, a peptidoglycan transpeptidase, and penicillin-binding protein 1A, which acts as a replacement for penicillin-binding protein 1Bs. Penicillin-binding protein 2 is a murein-elongation initiating enzyme and penicillin-binding protein 3 is a septal murein-synthesizing enzyme. Penicillin-binding proteins 4, 5, and 6 are not essential for bacterial survival. Binding of penicillins to penicillin-binding protein 1Bs produces lysis, binding to penicillin-binding protein 2 produces round cells, and binding to penicillin-binding protein 3 produces long filaments. Amdinocillin is a beta-amidino penicillanic acid derivative that binds specifically to penicillin-binding protein 2. The compound is more beta-lactamase stable than ampicillin and has no major delay in entry into the periplasmic space as do some penicillins. Amdinocillin inhibits most of the Enterobacteriaceae, with the exception of some indole-positive Proteus species, but it does not inhibit gram-positive cocci or Pseudomonas aeruginosa. Amdinocillin produces spherical bacterial cells that eventually lyse. Its activity in vitro is markedly affected by ionic content of media. This agent acts synergistically with many penicillins, such as ampicillin, carbenicillin, and the like, and with cephalosporins, cefazolin, cefamandole, or cefoxitin to inhibit gram-negative bacilli, probably on the basis of binding to different proteins needed for the production of the peptidoglycan of the bacterial cell wall. Amdinocillin possesses a number of the essentials for effective antimicrobial activity and, by virtue of its enhancement of the activity of other beta-lactams, may prove to be a useful agent in the chemotherapy of certain infections.

Identification of the rodA gene product of Escherichia coli

Plasmids that carry the Escherichia coli cell shape gene rodA directed the synthesis of a cytoplasmic membrane protein (Mr, 31,000 [31K protein] ) in minicells, maxicells, and an in vitro-coupled transcription-translation system. The 31K protein was identified as the rodA gene product, because it was not synthesized from the vector plasmids or from a plasmid in which the rodA gene was inactivated by insertion of Tn1000. Furthermore, a purified 1.6-kilobase KpnI-BamHI DNA fragment that contained the intact rodA gene directed the synthesis of only the 31K protein in an in vitro system. The apparent molecular weight of the protein was identical whether synthesized in vivo or in vitro, indicating that the rodA gene product is not made as a preprotein. The direction of transcription of rodA was from the KpnI site towards the BamHI site. The 31K protein was unusual in that it could only be detected when cell membranes were solubilized at low temperature (e.g., 37 degrees C) before sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Apparently the rodA gene product aggregates after being boiled in sodium dodecyl sulfate and fails to enter a polyacrylamide gel.

Murein synthesis and beta-lactam antibiotic susceptibility during rod-to-sphere transition in a pbpA(Ts) mutant of Escherichia coli

The conditional morphology mutant of Escherichia coli SP45 grows as a rod at 30 degrees C and assumes a spherical shape after 90 min of incubation at 42 degrees C. The rod-to-sphere morphological transition has been found to be associated with the disappearance of penicillin-binding protein 2 (PBP-2), the progressive reduction (as much as 50%) of murein synthesis, as measured both in intact cells and ether-permeabilized bacteria, and alterations in the structure of the cell envelope, including detachment of the outer membrane from the underlying structures. The detachment was initially localized at the poles of the cells and then spread over the entire surface. Shape transition was also linked to increased susceptibility to beta-lactam antibiotics which preferentially bound to PBP-1A (cephalothin, cephaloridine) or to PBP-3 (furazlocillin, piperacillin). Treatment with beta-lactams possessing a high affinity for PBP-1A, although inducing a low degree of peptidoglycan synthesis inhibition (5 to 10%), was associated with a marked loss of cell viability and massive lysis. On the other hand, the simultaneous absence of PBP-2 and inhibition of PBP-3 causes a significant reduction of peptidoglycan synthesis, yet only slightly affected cell viability. Whereas PBP-1A inhibition during shape transition had no effect on morphology, addition of antibiotics binding to PBP-3 30 min after the temperature shift-up caused formation of elongated cells with a centrally located bulge, not observed in similarly treated cells grown at 30 degrees C. Inhibition of PBP-3 in round cells 90 min after temperature shift caused formation of giant cells, indicating complete loss of elongation ability. The different effects of the simultaneous inhibition of two PBPs, combining mutational loss with specific binding in vivo of another PBP by beta-lactams, provide new insight into the role of these proteins and the killing mechanisms of this class of antibiotics.

Mecillinam susceptibility of Escherichia coli K-12 mutants deficient in the adenosine 3',5'-monophosphate system

The mecillinam resistance of Escherichia coli K-12 mutants deficient in the enzyme responsible for the synthesis of adenosine 3',5'-monophosphate, adenylate cyclase, has been investigated. The results suggest that resistance to this antibiotic may be a consequence of the slow growth rate of these mutants rather than an intrinsic property of their genetic lesion.

Purification of penicillin-binding protein 2 of Escherichia coli

Penicillin-binding protein 2 (PBP-2) of Escherichia coli K-12 was purified by covalent affinity chromatography using 6-aminopenicillanic acid covalently coupled to carboxymethyl-Sepharose (6-APA-CM-Sepharose). Purification of PBP-2 was accomplished by prebinding the methoxy cephalosporin, cefoxitin, to the Triton X-100-solubilized PBPs of E. coli and then incubating the PBPs with 6-APA-CM-Sepharose. Cefoxitin readily binds to all the E. coli PBPs except PBP-2 and, thus, in the presence of cefoxitin, only PBP-2 could bind to the 6-APA-CM-Sepharose. The purification of a mixture of all of the PBPs of E. coli by affinity chromatography is also described.

Effect of beta-lactamase and salt on mecillinam susceptibility of enterobacterial strains

Out of 15 selected enterobacterial strains resistant to ampicillin, 12 were able to transfer resistance to mecillinam to Escherichia coli K-12. This resistance to mecillinam was found to be coupled to the presence of beta-lactamase. One strain contained a beta-lactamase characterized as a class IV beta-lactamase, whereas the other 14 strains possessed a class III (TEM-like) beta-lactamase. The specific activity of the class IV beta-lactamase against mecillinam was 55%, and those of the class III beta-lactamase sensitivity of mecillinam, the minimal inhibitory concentrations were lower than might be expected. However, after enzymatic hydrolysis of mecillinam, no antibacterial activity was found. At increasing salt or buffer concentrations the minimal inhibitory concentrations of mecillinam increase to a varying extent for all strains, independently of beta-lactamase production. This study indicates that the increase in minimal inhibitory concentration is dependent on the salt concentration. The study also shows that this increase is not due to salt-mediated hydrolysis or to stimulation either of beta-lactamase activity or of beta-lactamase production. To explain the difference between ampicillin and mecillnam resistance in the beta-lactamase-positive strains, a hypothetical model is presented and discussed.

Defective and plaque-forming lambda transducing bacteriophage carrying penicillin-binding protein-cell shape genes: genetic and physical mapping and identification of gene products from the lip-dacA-rodA-pbpA-leuS region of the Escherichia coli chromosome

A series of defective lambda transducing phage carrying genes from the lip-leuS region of the Escherichia coli chromosome (min 14 on the current linkage map) has been isolated. The phage defined the gene order as lac---lip-dacA-rodA-pbpA-leuS---gal. These included the structural genes for penicillin-binding protein 2 (pbpA) and penicillin-binding protein 5 (dacA) as well as a previously unidentified cell shape gene that we have called rodA. rodA mutants were spherical and very similar to pbpA mutants but were distinguishable from them in that they had no defects in the activity of penicillin-binding protein 2. The separation into two groups of spherical mutants with mutations that mapped close to lip was confirmed by complementation analysis. The genes dacA, rodA, and pbpA lie within a 12-kilobase region, and represent a cluster of genes involved in cell shape determination and peptidoglycan synthesis. A restriction map of the lip-leuS region was established, and restriction fragments were cloned from defective transducing phage into appropriate lambda vectors to generate plaque-forming phage that carried genes from this region. Analysis of the proteins synthesized from lambda transducing phage in ultraviolet light-irradiated cells of E. coli resulted in the identification of the leuS, pbpA, dacA, and lip gene products, but the product of the rodA gene was not identified. The nine proteins that were synthesized from the lip-leuS region accounted for 57% of its coding capacity. Phage derivatives were constructed that allowed about 50-fold amplification of the levels of penicillin-binding proteins 2 and 5 in the cytoplasmic membrane.

Control of cell septation by lateral wall extension in a pH-conditional morphology mutant of Klebsiella pneumoniae

The pH-conditional morphology mutant of Klebsiella pneumoniae strain MirM7 grows as cocci at pH 7 and as rods at pH 5.8. The mutant has a high-level mecillinam resistance (50% lethal dose greater than 200 micrograms/ml) in both forms. When broth cultures of the rod-shaped mutant were grown with 0.7 microgram of mecillinam per ml, cells assumed a round shape and continued to divided at a higher rate than the untreated control. A MirM7 rod-shaped revertant (MirA12), when treated with the same antibiotic concentration, changed to coccal shape and stopped dividing. The penicillin-binding proteins (PBPs) of strains MirA12 and MirM7 were analyzed. K. pneumoniae had six major PBPs quite similar to those of Escherichia coli. No differences were seen in the PBPs of MirM7 cocci and rods and MirA12 cells. In particular, PBP2 was found to be present and similar in MirM7 rods and cocci and MirA12 cells. We suggest that that in gram-negative rods, a control mechanism exists which prevents further septation in the absence of lateral cell wall elongation. The unique behavior of MirM7 is due to the fact that the control mechanism is not active in this strain. This model allows us to explain the preservation of shape in bacterial rods under various conditions of growth and the mechanism of bacterial killing by mecillinam.

Cluster of mrdA and mrdB genes responsible for the rod shape and mecillinam sensitivity of Escherichia coli

Two closely linked genes, mrdA and mrdB, located at ca. 14.2 min on the Escherichia coli chromosomal linkage map, seen to be responsible for the normal rod shape and mecillinam sensitivity of E. coli. The product of mrdA was concluded to be penicillin-binding protein 2, because mrdA mutations caused formation of thermosensitive penicillin-binding protein 2. The product of the mrdB gene is unknown. At 42 degrees, C, mutation in either of these genes caused formation of spherical cells and mecillinam resistance. Both mutations was recessive, and complementation, as detected in +-/-+ meroheterodiploids having the wild-type phenotype, provided strong evidence that the two mutations are in different complementation groups. P1 transduction suggested that the most plausible gene order is leuS-mrdA-mrdB-lip. The rodA mutation reported previously seems to be similar to the mrdB murations, but the identities of the two have not yet been proven.

Positive selection of mutants with cell envelope defects of a Salmonells typhimurium strain hypersensitive to the products of genes hisF and hisH

Strain SB564 and its derivative DA78 are hypersensitive to the inhibitory action of the proteins coded for by genes hisF and hisH on cell division. Transduction of hisO1243, a regulatory mutation that elicits a very high level of expression of the histidine operon, into these strains resulted in the production of long filamentous cells carrying large "balloons" and in growth failure. Forty-one hisO1242 derivatives that escaped inhibition were isolated. These strains showed a large variety of alterations, many of which were related to the cell envelope. The more-frequent alterations included: changes in cell shape, increased sensitivity to one or more of several drugs (deoxycholate, cycloserine, penicillin, novobiocin, acridine orange), increased autolytic activity in alkaline buffer, anomalous fermentation of maltose on eosin--methylene blue plates, and temperature-conditional cell division. The alterations are produced, in some of the strains, by pleiotropic mutations in gene envB (Antón, Mol, Gen. Genet. 160:277--286, 1978) or envD (Antón and Orce, Mol. Gen. Genet. 144:97--105, 1976). Strains affected in divC, divD, and rodA loci have also been identified. Genetic analysis has shown that several strains carry more than one envelope mutation. It is assumed that envelope mutations are positively selected because they somehow alleviate the particularly severe inhibition of cell division caused, in strains SB564 and DA78, by the excessive synthesis of hisF and hisH gene products.

Morphology of an Escherichia coli mutant with a temperature-dependent round cell shape

Mutants of Escherichia coli capable of growing in the presence of 10 microgram of mecillinam per ml were selected after intensive mutagenesis. Of these mutants, 1.4% formed normal, rod-shaped cells at 30 degrees C but grew as spherical cells at 42 degrees C. The phenotype of one of these rod(Ts) mutants was 88% cotransducible with lip (14.3 min), and all lip+ rod(Ts) transductants of a lip recipient had the following characteristics: (i) growth was relatively sensitive to mecillinam at 30 degrees C but relatively resistant to mecillinam at 42 degrees C; (ii) penicillin-binding protein 2 was present in membranes of cells grown at 30 degrees C in reduced amounts and was undetectable in the membranes of cells grown at 42 degrees C. The mecillinam resistance, penicillin-binding protein 2 defect, and rod phenotypes all cotransduced with lip with high frequency. Thus the mutation [rodA(Ts)] is most likely in the gene for penicillin-binding protein 2 and causes the organism to grow as a sphere at 42 degrees C, although it grows with normal rodlike morphology at 30 degrees C. At 42 degrees C, cells of this strain were round with many wrinkles on their surfaces, as revealed by scanning electron microscopy. In these round cells, chromosomes were dispersed or distributed peripherally, in contrast to normal rod-shaped cells which had centrally located, more condensed chromosomes. The round cells divided asymmetrically on solid agar, and it seemed that the plane of each successive division was perpendicular to the preceding one. On temperature shift-down in liquid medium many cells with abnormal morphology appeared before normal rod-shaped cells developed. Few abnormal cells were seen when cells were placed on solid medium during temperature shift-down. These pleiotropic effects are presumably caused by one or more mutations in the rodA gene.

Cell envelope and shape of Escherichia coli: multiple mutants missing the outer membrane lipoprotein and other major outer membrane proteins

Starting with an Escherichia coli strain missing the outer membrane lipoprotein, multiple mutants were constructed than in addition to this defect miss the outer membrane proteins II, Ia and Ib, or Ia, Ib, and II. In contrast to all single mutants or strains missing the lipoprotein and polypeptides Ia and Ib, drastic influences on the integrity of the outer membrane and cell morphology were observed in mutants without lipoprotein and protein II. Such strains exhibited spherical morphology. They required increased concentrations of electrolytes for optimal growth, and Mg2+ or Ca2+ were the most efficient. These mutants were sensitive to hydrophobic antibiotics and detergents. Electron microscopy revealed abundant blebbing of the outer membrane, and it could clearly be seen that the murein layer was no longer associated with the outer membrane.