Electrotransformation of the stable L-form of Proteus mirabilis

Abstract To improve the transformability of stable protoplast type L-forms of Proteus mirabilis for recombinant plasmid DNA, conditions for efficient electrotransformation were explored. Exposing cells from the exponential phase of growth at a density of 6−8 × 10⁹/ml in electrotransformation buffer having a conductivity of 1.4 mS/cm to a field strength of 6.5 kV/cm for a mean pulse duration time of 1.2 ms reproducibly yielded transformation efficiencies in the order of 5 × 10⁴ transformants per μg of DNA. Compared to the polyethylene glycol method for transformation, electrotransformation appeared to be the method of choice for introduction of plasmid DNA into L-form cells.     

Membranes of the protoplast L-form of Proteus mirabilis

Isolated membranes of the cell wall-less stable protoplast L-form of Proteus mirabilis were characterized by density gradient centrifugation and by assay for their major chemical constituents, proteins, phospholipids and lipopolysaccharide, and for some specific marker enzymes of the cytoplasmic membrane. In most of the analyzed properties the L-form protoplast membrane resembled the bacterial cytoplasmic membrane, with some notable modifications. considerable amounts of lipopolysaccharide, normally an exclusive constituent of the outer membrane, were found. Furthermore, the L-form membranes contained the functions of the reduced nicotinamide adenine dinucleotide oxidase system, of d-lactate dehydrogenase (EC 1.1.1.28) and of succinate dehydrogenase (EC 1.3.99.1) at specific activities comparable to, or in some cases considerably higher than, those present in cytoplasmic membranes of the bacterial form. Of two peptidoglycan DD-carboxypetidase/transpeptidases (EC 3.4.17.8 and EC 2.3.2.10), which are normally present in the cytoplasmic membrane of the bacterial form of P. mirabilis, the membrane of the protoplast L-form contained only one. Electron microscopy of thin sectioned L-form protoplasts showed extensive heterogeneity of membraneous structures. In addition to the single membraneous integument, internal membrane-bounded vesicles and multiple stacks of membranes were present, as the result of unbalanced growth and membrane synthesis in the L-form state.     

Interaction between penicillin and the DD-carboxypeptidase of the unstable L-form of Proteus mirabilis strain 19.

Binding of penicillin to the DD-carboxypeptidase of the unstable spheroplast L-form of Proteus mirabilis results in the rapid formation of a modified enzyme-inhibitor complex which in turn undergoes rapid decay into reactivated enzyme and an antibiotically inactive penicillin degradation product. Major antibiotic metabolites recovered from such interactions were benzylpenicilloic acid and phenoxymethylpenicilloic acid from benzylpenicillin and phenoxymethylpenicillin, respectively, suggesting a second enzymic function of the DD-carboxypeptidase as a penicillinase of low efficiency. Statistical analyses made with the help of a linear regression program show that the enzyme interacts with the substrate UDP-N-acetylmuramoyl-L-alanyl-D-gamma-glutamyl-(L)-meso-2,6-diaminopimelyl-(L)-D-alanyl-D-alanine and either benzympenicillin or carbenicillin in a non-competitive manner.     

D-alanyl-D-alanine carboxypeptidase in the bacterial form and L-form of Proteus mirabilis.

Membranes of the bacterial form and the stable and unstable L-forms of Proteus mirabilis contain LD and DD-carboxypeptidase. The DD-carboxypeptidase is inhibited non-competitively by penicillin G. The enzyme of the bacterial form is highly penicillin-sensitive (Ki - 4 X 10(-9) M penicillin G). Inhibition is only partly reversible by treatment with penicillinase or by dialysis against buffer. In contrast, the DD-carboxypeptidase of the unstable L-form, grown in the presence of penicillin, is 175-fold less penicillin-sensitive (Ki = 7 X 10(7) M penicillin G). Inhibition is completely reversed by penicillinase or dialysis. After inhibition by penicillin and subsequent reactivation the penicillin sensitivity of the bacterial DD-carboxtpeptidase is similar to the sensitivity of the enzyme of the unstable L-form. The hypothesis is proposed that P. mirabilis contains two DD-carboxypeptidases of different penicillin sensitivity and with different mechanisms of penicillin binding. Peptidoglycan synthesis in the cell walls of the unstable L-form is probably carried out with the help of only one DD-carboxypeptidase, viz. the completely reactivatable enzyme with the lower penicillin sensitivity.     

Swarmer cell differentiation in Proteus mirabilis

Under the appropriate environmental conditions, the gram-negative bacterium Proteus mirabilis undergoes a remarkable differentiation to form a distinct cell type called a swarmer cell. The swarmer cell is characterized by a 20- to 40-fold increase in both cell length and the number of flagella per cell. Environmental conditions required for swarmer cell differentiation include: surface contact, inhibition of flagellar rotation, a sufficient cell density and cell-to-cell signalling. The differentiated swarmer cell is then able to carry out a highly ordered population migration termed swarming. Genetic analysis of the swarming process has revealed that a large variety of distinct loci are required for this differentiation including: genes involved in regulation, lipopolysaccharide and peptidoglycan synthesis, cell division, ATP production, putrescine biosynthesis, proteolysis and cell shape determination. The process of swarming is important medically because the expression of virulence genes and the ability to invade cells are coupled to the differentiated swarmer cell. In this review, the genetic and environmental requirements for swarmer cell differentiation will be outlined. In addition, the role of the differentiated swarmer cell in virulence and its possible role in biofilm formation will be discussed.     

Swarmer cell differentiation of Proteus mirabilis in fluid media

After 3-4 h in a rich fluid medium such as brain--heart infusion broth, motile nonseptate filaments developed from normal short rods and formed about 80% of the cell mass of Proteus mirabilis PM23. This developmental pattern was not observed in any of the other nine representatives of the species. These filaments were considered to be equivalent to swarmer cells formed on agar media because these cells ceased tumbling (i.e., chemotaxis was repressed), they developed large numbers of flagella (i.e., flagella synthesis and insertion was derepressed), and the distribution of nuclei in the filaments indicated that there was normal segregation. The population of cells grown in a minimal medium supplemented with amino acids and nicotinic acid consisted only of short cells with tumbling motility, despite the production of long cells and swarming on the same medium solidified with ordinary agar (refined agar was not effective). These short cells differentiated in 1-1.5 h in brain--heart infusion broth at 37 degrees C after an initial division. The requirements for initiation of differentiation were good basal nutrition, suitable cations (probably Ca2+ and Na+, or K+), and unknown heat-stable organic factors (molecular weight less than 10 000) present in crude agar and yeast extract. Other components of media promoted swarmer differentiation if it was initiated and these included organic acids (lactate), amino acids (proline or serine), phosphate, and an appropriate ionic environment. Comparison of the observed sequence of length classes in brain--heart infusion broth culture with computer generated growth models suggested that, at the outset of growth, 50% of the products of each short cell division ceased septation but grew in length for about five doubling periods and then divided cells from each end at a faster rate (3-5 times per hour) for return to the short cell pool.     

Tertiary structure of Staphylococcus aureus cell wall murein

The recently described scaffold model of murein architecture depicts the gram-negative bacterial cell wall as a gel-like matrix composed of cross-linked glycan strands oriented perpendicularly to the plasma membrane while peptide bridges adopt a parallel orientation (B. A. Dmitriev, F. V. Toukach, K. J. Schaper, O. Holst, E. T. Rietschel, and S. Ehlers, J. Bacteriol. 185:3458-3468, 2003). Based on the scaffold model, we now present computer simulation studies on the peptidoglycan arrangement of the gram-positive organism Staphylococcus aureus, which show that the orientation of peptide bridges is critical for the highly cross-linked murein architecture of this microorganism. According to the proposed refined model, staphylococcal murein is composed of glycan and oligopeptide chains, both running in a plane that is perpendicular to the plasma membrane, with oligopeptide chains adopting a zigzag conformation and zippering adjacent glycan strands along their lengths. In contrast to previous models of murein in gram-positive bacteria, this model reflects the high degree of cross-linking that is the hallmark of the staphylococcal cell wall and is compatible with distinguishing features of S. aureus cytokinesis such as the triple consecutive alteration of the division plane orientation and the strictly centripetal mode of septum closure.     

Proteus mirabilis mutants defective in swarmer cell differentiation and multicellular behavior

Proteus mirabilis is a dimorphic bacterium which exists in liquid cultures as a 1.5- to 2.0-microns motile swimmer cell possessing 6 to 10 peritrichous flagella. When swimmer cells are placed on a surface, they differentiate by a combination of events that ultimately produce a swarmer cell. Unlike the swimmer cell, the polyploid swarmer cell is 60 to 80 microns long and possesses hundreds to thousands of surface-induced flagella. These features, combined with multicellular behavior, allow the swarmer cells to move over a surface in a process called swarming. Transposon Tn5 was used to produce P. mirabilis mutants defective in wild-type swarming motility. Two general classes of mutants were found to be defective in swarming. The first class was composed of null mutants that were completely devoid of swarming motility. The majority of nonswarming mutations were the result of defects in the synthesis of flagella or in the ability to rotate the flagella. The remaining nonswarming mutants produced flagella but were defective in surface-induced elongation. Strains in the second general class of mutants, which made up more than 65% of all defects in swarming were motile but were defective in the control and coordination of multicellular swarming. Analysis of consolidation zones produced by such crippled mutants suggested that this pleiotropic phenotype was caused by a defect in the regulation of multicellular behavior. A possible mechanism controlling the cyclic process of differentiation and dediferentiation involved in the swarming behavior of P. mirabilis is discussed.     

Bacteriophage Typing of Proteus mirabilis, Proteus vulgaris, and Proteus morganii

A bacteriphage typing scheme for differentiating Proteus isolated from clinical specimens was developed. Twenty-one distinct patterns of lysis were seen when 15 bacteriophages isolated on 8 Proteus mirabilis, 1 P. vulgaris, and 1 P. morganii were used to type 162 of 189 (85.7%) P. mirabilis and P. vulgaris isolates. Seven phages isolated on 3 P. morganii were used to type 13 of 19 (68.4%) P. morganii isolates. Overall, 84.1% of the 208 isolates were lysed by at least 1 phage at routine test dilution (RTD) or 1,000 x RTD. Fifty isolates, retyped several weeks after the initial testing, showed no changes in lytic patterns. The phages retained their titers after storage at 4 C for several months. A computer analysis of the data showed that there was no relationship between the source of the isolate and bacteriophage type. This bacteriophage typing system may provide epidemiological information on strains involved in human infections.     

Characterization of the cell wall murein of Thiobacillus versutus

Amino acid analysis of pure murein isolated from cells of Thiobacillus versutus grown in complex medium revealed the typical constituents of most mureins from gram-negative cells, i.e. muramic acid, glucosamine, glutamic acid, alanine and diaminopimelic acid in molecular ratio of 0.58: 0.79: 1.0: 1.76:1.07, respectively. The presence of glycine and leucine was also demonstrated (0.20 and 0.08 compared to glutamic acid). Glycine was also present in the murein of cells grown in chemically defined synthetic medium. The crosslinkage of T. versutus murein was approximately 36% --much higher than for most other gram-negative species. High pressure liquid chromatography analysis of muropeptide composition following muramidase digestion of T. versutus murein revealed essentially the same pattern as for Escherichia coli under similar conditions of digestion and separation with, however, some differences in the minor peaks.     

Production of superoxide dismutases from Proteus mirabilis and Proteus vulgaris

Proteus mirabilis and Proteus vulgaris expressed a combination of superoxide dismutase (Sod) activities, which was assigned to FeSod1, FeSod2 and MnSod for P. mirabilis, and FeSod, MnSod and CuZnSod for P. vulgaris. Production of the Sod proteins was dependent on the availability of iron, whether cells were grown under anaerobiosis or aerobiosis and growth phase. Nalidixic acid and chloramphenicol inhibited cell growth and the iron- and dioxygen-dependent production of Sod. These results support the involvement of metal ions and redox status in the production of Proteus Sods.     

Murein biosynthesis in synchronized cells of Proteus mirabilis. Quantitative analysis of O-acetylated murein subunits and of chain terminators incorporated into the sacculus during the cell cycle

Cells of Proteus mirabilis, synchronized by sucrose density gradient centrifugation, were grown in complex medium containing radioactive N-acetylglucosamine. At various times, labelled murein sacculi were isolated and digested with endo-N,O-acetylmuramidase from Chalaropsis. The murein fragments thus obtained were separated into disaccharide peptides as the monomeric subunits and into peptide-cross-linked subunits by gel filtration. The subunits were further differentiated into O-acetylated and non-O-acetylated species, and into subunits containing anhydro-N-acetylmuramic acid which were glycan chain terminators in the native sacculi. Quantification of the subunit species gave the following results. At specific times during the cell cycle, murein subunits were lost from the polymer and a transient decrease in cross-linkage was observed. The overall degree of cross-linkage in mature murein, i.e. the ratio of peptide-cross-linked subunits versus uncross-linked subunits, was 1.15 as determined by regression analysis. Anhydro-N-acetylmuramic-acid-containing murein subunits representing glycan chain terminators were found either peptide-cross-linked or uncross-linked as monomers. Since these two subunit species were recovered in a defined ratio of 1.6, mature murein consisted of at least two different types of glycan chains. On average, each chain contained 15.4 murein subunits. About 60% of the murein subunits in mature murein were O-acetylated and showed a higher degree of cross-linkage than the non-O-acetylated portion. Finally, following the composition of the sacculus during the cell cycle revealed a complex precursor-product relationship between non-O-acetylated and O-acetylated subunits during murein maturation. The data allowed us to deduce several features of the assembly process of murein sacculi.     

Genetic analysis of Proteus mirabilis mutants defective in swarmer cell elongation.

Swarmer cell differentiation is a complex process involving the activity of many gene products. In this report, we characterized the genetic locus of Tn5 insertion in each of 12 mutants defective in swarmer cell elongation. The mutations fell into four categories affecting either flagellar biosynthesis or energetics, lipopolysaccharide and cell wall biosynthesis, cellular division, or proteolysis of peptides.     

Regulation of reductase formation in Proteus mirabilis

Summary The levels of several redox enzymes in a chlorate-resistant mutant of Proteus mirabilis, which is partially affected in the formation of formate hydrogenlyase, thiosulfate reductase and tetrathionate reductase, were compared with those of the wild type. The composition of the electron transport system of both strains was almost the same in cells grown aerobically, but very different in cells grown anaerobically. In the mutant, the cytochrome content increased twofold, whereas the level of the anaerobic enzymes is strongly diminished. The anaerobic formation of electron transport components in the mutant was, in contrast to that of the wild type, not influenced significantly by azide. During anaerobic growth with nitrate low levels of a functional nitrate reductase system were formed in the mutant. Under these conditions the formation of formate dehydrogenase, formate hydrogenlyase, formate oxidase, thiosulfate reductase, tetrathionate reductase, cytochrome b_563,5 and partly that of cytochrome a₂, was repressed. The repressive effect of nitrate, however, was completely abolished by azide. Therefore, it seems likely that a functional nitrate reductase system, rather than nitrate, controls the formation of the enzymes repressible by nitrate.