Characteristics of penicillinase release by washed cells of Bacillus licheniformis

Saline-washed cells of Bacillus licheniformis strain 749/C (constitutive for penicillinase) were able to release exopenicillinase in the presence of concentrations of chloramphenicol that prevented protein synthesis completely. The release reaction was strongly pH-dependent, occurring at a faster rate at alkaline pH in anionic or cationic buffers than at neutral pH. A strongly pH-dependent release reaction was noted in growing cells also. The reaction in washed cells can be stopped completely by changing the pH to 6.0. Within 30 min at pH 9.0, about 55% of the cell-bound penicillinase was released; thereafter, release continued at a greatly reduced rate. Suspensions of washed cells retained their capacity to release penicillinase at pH 9.0 for 90 min. Penicillinase released at pH 9.0 from either cells or protoplasts was not readsorbed over a 60-min period after changing the pH to 6.0. The release reaction was strongly temperature-dependent. We examined the effect of a large number of metabolic inhibitors and other compounds on the pH-dependent release phenomenon. Quinacrine hydrochloride, chloroquine diphosphate, and chlorpromazine hydrochloride reduced secretion substantially at 10(-4)m. Deoxycholate and Triton X-100 were active at 10(-3)m, but tungstate, arsenate, and molybdate had small effects at 10(-1)m. The rate of exopenicillinase release at pH 9.0 from fully stabilized protoplasts was one-half that of intact cells. Protoplasts lysed in hypotonic media or detergents showed even greater reduction in releasing activity. Penicillinase released from washed cells at pH 7.5 or 9.0 appeared to be derived from the periplasmic tubule and vesicle fraction that was released by protoplast formation.     

Further evidence for a partially folded intermediate in penicillinase secretion by Bacillus licheniformis.

Protoplasis of Bacillus licheniformis 749/C (a mutant constitutive for penicillinase production) continued to synthesize and release penicillinase in hypertonic growth medium in the presence of trypsin and chymotrypsin at 25 mug each per ml. When the protoplasts were stripped of about half of their membrane-bound penicillinase by pretreatment at pH 9.5 or with a higher level of trypsin, penicillinase activity no longer increased in the presence of the proteases. This effect was immediately eliminated after addition of soybean trypsin inhibitor. These proteases do not significantly inhibit general protein synthesis. Stripped protoplasts of strain 749/C and of uninduced strain 749 (unable to synthesize penicillinase) were incubated with 50 mug of chymotrypsin per ml, and the supernatent fluids were examined immunochemically for peptides derived from the penicillinase chain. Such fargments were found only with the protoplasts capable of synthesizing penicillinase (strain 749/C). The direct detection of the products of protease degradation of a susceptible form of penicillinase provides strong evidence that, in stripped protoplasts of B. licheniformis 749/C, penicillinase synthesis continues in the presence of trypsin or chymotrypsin and that, in these modified membranes, the protease is able to act on an early form of the enzyme that has not yet attained the protease-resistant conformation characteristic of the membrane-bound and exopenicillinases. This finding is discussed in terms of the current models of penicillinase secretion.     

Vesicle penicillinase of Bacillus licheniformis: existence of periplasmic-releasing factor(s).

In earlier studies of the membrane-bound penicillinase of Bacillus licheniformis 749/C, the enzyme present in the vesicles that were released during protoplast formation and the enzyme retained in the plasma membrane of protoplasts appeared to differ (i) in their behavior on gel permeation chromatography in the presence or absence of deoxycholate and (ii) in their tendency to convert to the hydrophilic exoenzyme (Sargent and Lampen, 1970). We have now shown that these vesicle preparations contain a soluble, heat-sensitive enzyme(s) that is released along with the vesicles during protoplast formation. The enzyme will convert the vesicle penicillinase to a form that resembles exopenicillinase, and this conversion can be inhibited by deoxycholate under certain circumstances. Sedimentation of such vesicle preparations at 100,000 X g produces vesicles which contain penicillinase that behaves as the plasma membrane enzyme obtained from protoplasts. Exopenicillinases released by growing cells at pH 6.5 and by washed cells or protoplasts at pH 9.0 have the same NH2-terminal residues (lysine and some glutamic acid); in addition, the various release systems show a parallel sensitivity to inhibition by deoxycholate, quinacrine, chloroquine, and o-phenanthroline. The formation of exopenicillinase (by cleavage of the membrane-bound enzyme) may well be dependent on the action of the releasing enzyme.     

Penicillinase-releasing protease of Bacillus licheniformis: purification and general properties.

The membrane penicillinase of Bacillus licheniformis 749/C is a phospholipoprotein which differs from the exoenzyme in that it has an additional sequence of 24 amino acid residues and a phosphatidylserine at the NH2 terminus. In exponential-phase cultures, the conversion of membrane penicillinase to exoenzyme occurs at neutral and alkaline pH. An enzyme that will cleave the membrane penicillinase to yield the exoenzyme is present (in small amounts) in exponential-phase cells and is released during their conversion to protoplasts. The enzyme is found in the filtrate of a stationary-phase culture of the uninduced penicillinase-inducible strain 749 and has been purified to apparent homogeneity from this source. The protease has an approximate molecular weight of 21,500 and requires Ca2+ ions for stabilization. It has a pH optimum of 7.0 to 9.5 for hydrolysis of casein and for the cleavage of membrane penicillinase. Both activities are inhibited by diisopropylfluorophosphate; hence, the enzyme is a serine protease. This enzyme may be entirely responsible for the formation of exopenicillinase by this organism, since the other neutral and alkaline proteases of strain 749 have little, if any, activity in releasing exopenicillinase. The enzyme has been termed penicillinase-releasing protease.     

Periplasmic Structure of Frozen-Etched and Negatively Stained Cells of Bacillus licheniformis as Correlated with Penicillinase Formation

Bacillus licheniformis strain 749/C (constitutive for penicillinase formation) and uninduced cells of strain 749 (penicillinase-inducible) were examined after freezeetching. In the early stationary phase, strain 749/C organisms had clusters of vesicles (30 to 40 nm in diameter) on the outer surface of the plasma membrane. These are randomly distributed on the membrane, including the region of septum formation. The vesicles are not intimately associated with the plasma membrane, and their inner and outer surfaces are devoid of particles. Periplasmic vesicles were not detected by freeze-etching in strain 749 (uninduced) or in young cells of 749/C; however, the membrane of mid-logarithmic phase 749/C cells had a corrugated appearance. Negatively stained 749/C cells (logarithmic phase) also showed many vesicular and tubular bodies in the periplasm as well as septal and cytoplasmic mesosomes of typical morphology. The periplasmic structures appear to be formed either by evagination of plasma membrane or by migration of vesicular bodies from the membranous pockets of the cytoplasm. Stationary phase cells of 749/C still have many periplasmic vesicular bodies; however, the mesosomes are greatly reduced both in number and size. In sharp contrast, strain 749 organisms have very few structures similar to the periplasmic bodies of strain 749/C. These findings support our previous view that penicillinase-producing cells of 749/C have periplasmic membranous structures that are rare in the uninduced strain 749, though there is some lack of correspondence between freeze-etching, negative staining, and thin section data. These structures may be important for the retention or storage of penicillinase in the cell.     

Morphological Phenomena Associated with Penicillinase Induction and Secretion in Bacillus licheniformis

Cells of uninduced Bacillus licheniformis (strain 749) in mid-logarithmic phase have no extensive intracytoplasmic membrane. After induction with cephalosporin C, characteristic organelles that contain tubules and vesicles with single-layered membranes and no visible internal substructure can be seen in thin sections in the periplasm. A magnoconstitutive penicillinase producer (749/C) contains similar structures. It is suggested that they represent a penicillinase secretory apparatus. In the first 15 min after induction, negatively stained preparations of induced 749 show large intracellular vesicles without individual contact with the cell surface. Negatively stained 749/C and fully induced 749 contain invaginations comparable to the structures seen in thin sections. When protoplasts of induced 749 and of 749/C are prepared, vesicles and tubules similar to those seen in thin sections of whole cells are liberated from the cell. Growing protoplasts of induced 749 show massive convolutions of the peripheral membrane, multiple layers of membrane, and characteristic long, slender tubules extending from the protoplast surface. These phenomena are not observed in uninduced 749 except for the production of a relatively small number of tubules. In 749/C, there were fewer convolutions than in induced 749, although tubule production was similar. Multiple layers of membrane were not observed in 749/C. The relation of the penicillinase secretory structures to mesosomes and to secretory structures of other organisms is discussed.     

Mechanism of penicillinase inhibition by alkyl sulfates in the presence of synthetic polyeletrolytes]

Competing inhibition of Bacillus licheniformis 749/C penicillinase by alkylsulfates CnH2n+ 1OSO3N1 where n was 8--16 was studied. The values of the inhibition constants Ki of individual homologues were estimated. It was shown that stability of complex "enzyme-inhibitor" increased with lengthening of the hydrocarbon radical which was probably due to increased hydrophobic interaction of the alkyl radical with the lipophilic areas of the penicillinase active center. Inhibition in the presence of sopolymers of vinylpirrolidone with N-alkylvinylamine was studied with the aim of modeling the process of penicillinase inhibitions by alkylsulfates in the presence of the blood serum. It was shown that polyelectrolytes posessing hydrophobic substituents had an ability of reducing the activity of inhibited penicillinase, cooperative transfer of alkylsulfate molecules from the enzyme to polyelectrolyte being observed. The maximum effect was registered in the polyelectrolytes with substituents C12H25 and C16H33 which was confirmed in the experiments with the penicillinase-producing strains of staphylococci.     

Localization of Cell-bound Penicillinase in Bacillus licheniformis

When protoplasts are prepared from Bacillus licheniformis (strain 749/C, constitutive for penicillinase), approximately 60% of the cell-bound penicillinase is released. The remainder is retained by the protoplast and cannot be removed by washing. This release is specific, in that less than 7% of the cellular reduced nicotinamide adenine dinucleotide (NADH) dehydrogenase and alpha-glucosidase is liberated by the treatment. The freed penicillinase is excluded from G-200 Sephadex, and it is partially sedimented with a force of 65,000 x g for 20 hr. It is probably attached to characteristic tubular and vesicular structures with single-layered membranes that are comparable to structures previously described in intact penicillinase-forming cells. The specific activity of the organelle is more than six times that of twice washed peripheral membrane; furthermore, about 8% of the protein of the structure is penicillinase. At substrate concentrations (benzylpenicillin) of about one-fifth the K(m) value, whole cells show a slight permeability restriction, although this does not occur in isolated particles and protoplasts.     

Synthesis and secretion of hemolysin by Escherichia coli.

Hemolytic Escherichia coli cells were found to synthesize and secrete significant amounts of hemolysin into a mineral salt-glucose medium containing hemoglobin. The release of de novo-synthesized hemolysin was stopped in the presence of energy metabolism inhibitors such as 2,4-dinitrophenol, sodium azide, or potassium cyanide, resulting in an accumulation of intracellular hemolysin. A similar effect was observed in the presence of procaine, a neuroactive drug which inhibits the processing of exoproteins. Small amounts of hemolysin were secreted into the medium within approximately 10 min of inhibition of protein synthesis by chloramphenicol. This represented the final release of preformed periplasmic hemolysin en route to secretion through the outer membrane and was not caused by adsorption of external hemolysin to the cell surface. This secretion was not energy dependent but was inhibited above pH 8 and at low temperatures (10 to 20 degrees C). We concluded that two transport processes are involved in hemolysin secretion. De novo-synthesized hemolysin is extruded by an energy-dependent process through the cytoplasmic membrane and probably requires processing. In the periplasmic space a small internal pool of preformed hemolysin is accumulated temporarily before being transported through the outer membrane. Release of hemolysin through the outer membrane does not require energy or de novo protein synthesis.     

Protease activity in cells ofBacillus megaterium during derepression

A proteolytic activity hydrolyzing denatured proteins of Bacillus megaterium labelled with 35S or 14C amino acids was detected in cells of the asporogenic strain of Bacillus megaterium. The substrate is hydrolyzed by the enzyme or enzymes at optimum pH around 7, their activity being almost completely inhibited by EDTA and o-phenanthroline. PMSF, the inhibitor of serine proteases, is slightly inhibitory. Gel filtration on a Sephadex column separated the protease activity to two or three fractions. The protease activity in cells with the repressed synthesis of protease corresponds to 5-20 mug of substrate degraded per hour by 1 mg of protein at 37 degrees C. It increases five to ten-fold during the derepression. When the intracellular protease activity increases the extracellular enzyme begins to be excreted into the medium. The intracellular protease activity rapidly decreases after the addition of chloramphenicol or of a mixture of amino acids to the derepressed culture. Half or even more of the protease activity is released from the cells during their conversion to protoplasts by means of lysozyme. This "periplasmic" activity remains mostly in the supernatant also after mesosomes have been centrifuged down from the periplasm. A portion of the activity bound in protoplasts sediments together with membrane fraction after their lysis.     

Osmotic regulation of invertase formation and secretion by protoplasts of Saccharomyces

Osmotic regulation of invertase formation and secretion by protoplasts of Saccharomyces was examined using sorbitol, KCl, NaCl, or magnesium sulfate as the osmotic support. The synthesis and secretion of the enzyme is remarkably sensitive to the osmolarity of the supporting medium irrespective of the particular support employed. Invertase formation was inhibited at high osmolarity and was maximal at 0.65 to 0.75 osmolal, even though some leakage of the intracellular enzyme alpha-glucosidase and of ultraviolet (UV)-absorbing materials occurred under these conditions. The reduction of invertase formation and secretion due to high osmolarity was eliminated promptly when protoplasts were transferred into a medium of lower osmolarity. The rate of fructose uptake and of threonine incorporation into protein was decreased by high osmolarity; also reduction of invertase formation could be partially reversed by increasing the level of sugar supplied as energy source. Thus changes in the permeability of the plasma membrane (and presumably also in its structure) are important factors in the response of protoplasts to high osmolarity, though certainly not the complete explanation. Protoplasts suspended in 0.8 m sorbitol, with 10mm fructose as the energy source, increased their invertase level 5- to 10-fold during a 2-hr incubation without substantial release of alpha-glucosidase or UV-absorbing materials. Both the large and small forms of invertase were present in the protoplasts, but only the large form was released into the medium when enzyme was being actively synthesized. Formation and secretion of newly formed invertase and the release of enzyme initially present were inhibited by cycloheximide.     

Characteristics of Secretion of Penicillinase, Alkaline Phosphatase, and Nuclease by Bacillus Species

The distribution of alkaline phosphatase and nuclease activity between cells and medium was examined in one strain of Bacillus licheniformis and four strains of B. subtilis. Over 95% of both activities was found in the medium of the B. licheniformis culture, but in the B. subtilis cultures the amount of enzyme activity found in the medium varied with the strain and the enzyme considered. B. licheniformis 749 and its penicillinase magnoconstitutive mutant 749/C were grown in continuous culture with phosphorous as the growth-limiting factor, and the kinetics of penicillinase formation and secretion were examined. Nutrient arrest halted secretion (usually after a lag of about 30 min) in both the inducible and constitutive strains. Chloramphenicol did not eliminate secretion, but under certain circumstances reduced its rate. In the inducible strain treated with a low level of inducer, the rate of secretion was more affected by the rate of synthesis than by the level of cell-bound enzyme. During induction, the onset of accretion of cell-bound penicillinase and secretion of the exoenzyme were nearly simultaneous. It seems unlikely that a long-lived, membrane- or cell-bound intermediate is mandatory in the secretion of the three enzymes by Bacillus species. In the case of penicillinase secretion, there are at least two different phases. When penicillinase synthesis is proceeding rapidly, the rate of secretion is five to six times greater at equivalent concentrations of membrane-bound penicillinase than it is when penicillinase synthesis is reduced. The data require that any membrane-bound intermediate in the formation of exoenzyme be much shorter-lived in cells with a high rate of synthesis than in cells with a low rate. Either there are two separate routes for the secretion of penicillinase or the characteristics of the process vary substantially between the early stages and the declining phase of induction.     

Chemical and electron microscopic studies of factors associated with the release of penicillinase from Staphylococcus aureus

The effect of various factors such as sodium chloride, sodium citrate, pH, buffers, and enzymatic and physical disruption of cells on the release of penicillinase by Staphylococcus aureus ATCC 14458 was investigated. Penicillinase was measured at selected time intervals from supernates of cultures grown in Antibiotic Medium 3 broth containing various concentrations of salts or buffers or from supernates of cultures treated with lysostaphin and subsequently disrupted by French press treatment.Incubation of cells with media containing either sodium chloride (5, 10, and 15%), sodium citrate (5 and 10%), or organic buffers (Tris-HC1, 2.5, 5.0, and 7.5%; BES, 10 and 20%) resulted in a significant stimulation of the release of penicillinase when compared to control cells. It was also observed that pH 7.0–7.5 was optimal for penicillinase activity and release. From studies of enzymatic and mechanical disruption of cells, it was observed that an increase in ionic strength of the suspending medium to certain optimal levels appeared to stimulate the conversion of penicillinase to an extracellular form.Electron microscopic studies revealed that a large number of mesosomal vesicles seemed to be present in cells incubated for 4 hours in media containing various concentrations of sodium chloride. It is proposed that either appearance of vesicles or convolution of cell membrane, which may be caused by further synthesis of new membrane, is involved in stimulation of the synthesis and release of membrane-bound penicillinase.     

Localization of the Ethylene-synthesizing System in Apple Tissue

Apple (Malus sp.) slices gradually lost the ability to synthesize ethylene when incubated with a mixture of enzymes that digest cell walls. The released protoplasts did not produce ethylene. The release of protoplasts was faster from climacteric fruit slices than from preclimacteric tissue. In protoplast suspension culture, as new cell wall was deposited (as judged by the intensity of fluorescence of regenerating protoplasts stained with Calcofluor White and the incorporation of labeled myo-inositol into their ethanol-insoluble residue), ethylene synthesis was gradually regained. Restored ethylene synthesis reached a maximum after 80 hours in protoplasts from preclimacteric fruit and in 120 hours in those from climacteric tissue. Addition of methionine (1 mm) to the culture medium was essential for appreciable synthesis of ethylene; and this synthesis was inhibited by the aminoethoxy analogue of rhizobitoxine and by propyl gallate, inhibitors of ethylene synthesis in higher plants. We suggest that the ethylene-synthesizing enzyme system is highly structured in the apple cell and is localized in a cell wall-cell membrane complex.     

Simple assay and extraction of periplasmic penicillinase in Escherichia coli

Benzylpenicillin was clearly separated from benzylpenicilloic acid by ascending chromatography on a diethylaminoethyl cellulose paper using 0.1 M ammonium acetate as a solvent. Using this chromatographic system, penicillinase was assayed by measuring the formation of [14C]benzylpenicilloic acid from [14C]benzylpenicillin. This assay remedies the lack of specificity of the commonly used iodometric assays. Periplasmic penicillinase was released from Escherichia coli by suspension in a mixture of 1% phenethyl alcohol and 5 mM ethylenediaminetetraacetate (pH 7.0). This simple extraction method not only facilitates the assay of penicillinase in an E. coli culture, but will also be useful for large-scale purification of periplasmic penicillinase.     

Extracellular Enzyme Secretion by Pseudomonas lemoignei

The ability of succinate to repress the secretion of Pseudomonas lemoignei poly-beta-hydroxybutyrate depolymerase was a function of pH. Repression only occurred when the pH of the medium was 7.0 or less. At a higher pH, lack of sensitivity to succinate concentration may have been due to a limited ability to transport succinate. Actively secreting cultures (at pH 7.4) continued to secrete enzyme for approximately 30 min after the pH was rapidly decreased to pH 6.8, even though sufficient succinate was present to repress enzyme synthesis. Similarly, after the addition of rifampin to secreting cultures, there was a 30-min delay before secretion was inhibited. Evidence is presented which suggests that continued secretion may be the result of depolymerase messenger ribonucleic acid accumulation within the cells. Studies with chloramphenicol indicated that de novo protein synthesis is necessary for the secretion of poly-beta-hydroxybutyrate depolymerase and that exoenzyme is not released from a preformed pool. Studies with various inhibitors of protein synthesis indicated that synthesis of exoenzyme is 5 to 10 times more susceptible to inhibition than is the synthesis of cell-associated proteins.     

Isolated Coxiella burnetii synthesizes DNA during acid activation in the absence of host cells

Two populations of Coxiella burnetii were isolated from fibroblast tissue cultures and examined for their ability to synthesize DNA when incubated in a defined medium. Both the populations released by mechanical lysis of heavily infected host cells, as well as those recovered from the tissue culture medium, incorporated H3 32PO4 into DNA. Incorporation occurred at pH 4.5 but not at pH 7.0, and proceeded for 12-15 h. When incorporation of [3H]thymidine was studied, only the organisms obtained by mechanical lysis of host cells were active. Those which had been released by natural means into the tissue culture medium, and then recovered for study, did not incorporate precursor thymidine but were extremely active in protein biosynthesis. In mechanically released organisms, thymidine incorporation was inhibited immediately by rifamycin (40 microM) and hydroxyurea (10 mM), but it was not affected by chloramphenicol (310 microM) until 4 h after addition of the drug. Incorporation of H3 32PO4 by both populations of organisms was also inhibited by rifamycin, chloramphenicol and hydroxyurea, but the time sequence of inhibition differed. Southern hybridization utilizing 32P-labelled DNA suggested that both populations synthesized authentic chromosomal DNA sequences, as well as QpH1 plasmid DNA, during acid activation of metabolism.     

Extracellular release of protease III (ptr) by Escherichia coli K12

Escherichia coli strains carrying the protease III structural gene (ptr) on a plasmid secreted the protein into the growth medium. Plasmid-encoded beta-lactamase and chloramphenicol acetyl transferase, which served as periplasmic and cytoplasmic markers during cell fractionation, were not released into the growth medium. There appeared to be some strain dependence on the proficiency of the secretion system. Protease III was not detectably processed upon export through the outer cell membrane.     

Membrane associated phospholipoproteins of Bacillus licheniformis 749

The membrane-bound penicillinase of Bacillus licheniformis 749/C is a phospholipoprotein that differs from the hydrophilic exoenzyme in that its polypeptide chain carries an additional 25 residues (mostly hydrophilic) with phosphatidylserine as the NH₂-terminus. To determine if other phospholipoproteins are present in the plasma membrane, the penicillinase-inducible strain 749 was grown without inducer in the presence of [2-³H] glycerol. Electrophoretic separation of the membrane proteins (after removel of free lipids) showed an association of ³H-activity with certain of the proteins which could not be broken by lipid solvents and strongly denaturing conditions. Pronase digestion of the membrane proteins (after solvent extraction) released phosphatidylserine, thus indicating the covalent linkage of protein and phospholipid. Treatment of the isolated membranes with trypsin solubilized the protein portion of some of the phospholipoproteins (as with penicillinase), but not the ³H-labelled fragment. Penicillinase should be considered as the first observed example of a group of phosphatidylserine-containing proteins present in the plasma membrane of B. licheniformis 749 and 749/C.     

Excretion of the penicillinase of an alkalophilic Bacillus sp. through the Escherichia coli outer membrane is caused by insertional activation of the kil gene in plasmid pMB9.

Most of the cloned penicillinase from alkalophilic Bacillus sp. strain 170 and alkaline phosphatase were released into the culture medium by Escherichia coli strains bearing plasmid pEAP1 or pEAP2 (T. Kudo, C. Kato, and K. Horikoshi, J. Bacteriol. 156:949-951, 1983). We analyzed the basis for excretion of periplasmic enzymes in the cells bearing these plasmids. Several experiments such as subcloning, insertion of a chloramphenicol acetyltransferase cartridge, and DNA sequencing were done. A dormant kil gene in plasmid pMB9 was expressed by a promoter of the inserted DNA fragment of alkalophilic Bacillus sp. strain 170, and as a result, the outer membrane of E. coli became permeable, allowing the proteins to be excreted without cell lysis.