Stability and comparative transport capacity of cells, mureinoplasts, and true protoplasts of a gram-negative bacterium

The outer layers of the cell envelope of a pseudomonad of marine origin were removed by washing the cells in 0.5 m NaCl followed by suspension in 0.5 m sucrose. The term mureinoplast has been suggested for the rod-shaped forms which resulted from this treatment. As previously established, these forms lacked the outer cell wall layers but still retained a rigid peptidoglycan structure. Mureinoplasts remained stable if suspended in a balanced salt solution containing 0.3 m NaCl, 0.05 m MgSO(4), and 0.01 m KCl but, unlike whole cells, lost ultraviolet (UV)-absorbing material if suspended in 0.5 m NaCl or 0.05 m MgCl(2). Sucrose added to the balanced salt solution also enhanced the loss of UV-absorbing material. Addition of lysozyme to suspensions of mureinoplasts in the balanced salt solution produced spherical forms which, by electron microscopy and the analysis of residual cell wall material, appeared to be true protoplasts. Only undamaged mureinoplasts, as judged by their capacity to fully retain alpha-aminoisobutyric acid, were capable of being converted to protoplasts. Protoplasts and undamaged mureinoplasts retained 100% transport capacity when compared to an equal number of whole cells. The Na(+) requirement for transport of alpha-aminoisobutyric acid and the sparing action of Li(+) on this Na(+) requirement were the same for both protoplasts and whole cells. These observations indicate that, in this gram-negative bacterium, the cell wall does not participate in the transport process though it does stabilize the cytoplasmic membrane against changes in porosity produced by unbalanced salt solutions. The results also indicate that the requirements for Na(+) for transport and for the retention of intracellular solutes are manifested at the level of the cytoplasmic membrane.     

Capacity of the outer membrane of a gram-negative marine bacterium in the presence of cations to prevent lysis by Triton X-100.

Cells of marine pseudomonad B-16 (ATCC 19855) washed with a solution containing 0.3 M NaCl, 50 mM MgCl2, and 10 mM KCl (complete salts) could be protected from lysis in a hypotonic environment if the suspending medium contained either 20 mM Mg2+, 40 mM Na+, or 300 mM K+. When the outer double-track layer (the outer membrane) of the cell envelope was removed to yield mureinoplasts, the Mg2+, Na+ or K+, requirements to prevent lysis were raised to 80, 210, and 400 mM, respectively. In the presence of 0.1% Triton X-100, 220, 320, and 360 mM Mg2+, Na+ or K+, respectively, prevented lysis of the normal cells. Mureinoplasts and protoplasts, however, lysed instantly in the presence of the detergent at all concentrations of Mg2+, Na+, or K+ tested up to 1.2 M. Thus, the structure of the outer membrane appears to be maintained by appropriate concentrations of Mg2+ or Na+ in a form preventing the penetration of Triton X-100 and thereby protecting the cytoplasmic membrane from dissolution by the detergent. K+ was effective in this capacity with cells washed with complete salts solution but not with cells washed with a solution of NaCl, suggesting that bound Mg2+ was required in the cell wall membrane for K+ to be effective in preventing lysis by the detergent. At high concentrations (1 M) K+ and Mg2+, but not Na+, appeared to destabilize the structure of the outer membrane in the presence of Triton X-100.     

Biochemical Localization of Alkaline Phosphatase in the Cell Wall of a Marine Pseudomonad

The various layers of the cell envelope of marine pseudomonad B-16 (ATCC 19855) have been separated from the cells and assayed directly for alkaline phosphatase activity under conditions established previously to be optimum for maintenance of the activity of the enzyme. Under conditions known to lead to the release of the contents of the periplasmic space from the cells, over 90% of the alkaline phosphatase was released into the medium. Neither the loosely bound outer layer nor the outer double-track layer (cell wall membrane) showed significant activity. A small amount of the alkaline phosphatase activity of the cells remained associated with the mureinoplasts when the outer layers of the cell wall were removed. Upon treatment of the mureinoplasts with lysozyme, some alkaline phosphatase was released into the medium and some remained with the protoplasts formed. Cells washed and suspended in 0.5 M NaCl were lysed by treatment with 2% toluene, and 95% of the alkaline phosphatase in the cells was released into the medium. Cells washed and suspended in complete salts solution (0.3 M NaCl, 0.05 M MgSO(4), and 0.01 M KCl) or 0.05 M MgSO(4) appeared intact after treatment with toluene but lost 50 and 10%, respectively, of their alkaline phosphatase. The results suggest that the presence of Mg(2+) in the cell wall is necessary to prevent disruption of the cells by toluene and may also be required to prevent the release of alkaline phosphatase by toluene when disruption of the cells by toluene does not take place.     

Relationship of a Wall-Associated Enzyme with Specific Layers of the Cell Wall of a Gram-Negative Bacterium

In untreated cells of the marine pseudomonad studied here, alkaline phosphatase was found to be located in the periplasmic space, at the cell surface, and in the medium into which it had been shed during growth. Washing in 0.5 M NaCl, which removed the loosely bound outer layer, caused a shift of periplasmic enzyme to the outer aspect of the double-track layer and released some of the cell surface-associated enzyme. When the double-track layer of the cell wall was partially deranged, large amounts of this cell wall-associated enzyme were released, and, when the double-track was removed from the cells to produce mureinoplasts, alkaline phosphatase was released into the menstruum. There was no significant association of the enzyme with the peptidoglycan layer of the cell wall, which is the outermost structure of the mureinoplast, and no association of the enzyme with the cytoplasmic membrane of these modified cells. This study has shown that alkaline phosphatase is specifically associated with the outer layers of the cell walls of cells of this organism and is retained within the cell wall by virtue of this association.     

Factors affecting the lytic susceptibility of some marine and terrestrial bacteria

Eighteen gram-negative marine bacteria and two terrestrial species, Escherichia coli and Pseudomonas aeruginosa, were examined for their sensitivity to lysis in distilled water after exposure to a salt solution containing a sea water concentration of Mg2+ (0.05 M) or to 0.5 M NaCl. A spectrum of lytic susceptibility was observed among the marine bacteria ranging from those organisms which lysed in distilled water after exposure to the Mg2+-containing solution, through organisms which could be sensitized to lysis by washing with the NaCl solution, to organisms which failed to lyse in distilled water even after having been washed with a solution of 0.5 M NaCl. Pseudomonas aeruginosa and E. coli fell within this spectrum, the former being capable of being induced to lyse in distilled water by washing with 0.5 M NaCl, while the latter failed to lyse in distilled water after this treatment. It was thus concluded that no overall distinction could be made between marine and terrestrial bacteria on the basis of the sensitivity of the two groups of organisms to lysis in freshwater. Quite large decreases in optical density and increases in the release of ultraviolet-absorbing material took place when cells preexposed to the Mg2+-containing solution or to 0.5 M NaCl were subsequently suspended in distilled water even though in some cases no loss of cell numbers could be detected. In most cases two to three times as much K+ as Na+ and 1/10 to 1/100 as much Mg2+ was required to prevent these changes. For three of the marine bacteria and P. aeruginosa grown in a terrestrial type medium little difference in the requirements for Na+ and K+ to prevent the optical density changes was noted. For P. aeruginosa grown in a marine type medium, cells required more K+ than Na+ to prevent these changes.     

Separation and localization of cell wall layers of a gram-negative bacterium

The cell envelope of a marine pseudomonad as seen in thin section by electron microscopy has the double-membrane structure typical of other gram-negative bacteria. Cells washed with a solution containing Na(+), K(+), and Mg(++) at their concentrations in the growth medium, when suspended briefly in 0.5 m sucrose, lost 13% of their hexosamine in a form nonsedimentable by centrifugation at 73,000 x g. Since the resulting cells in thin section appeared unchanged, it was concluded that the material released was derived from a nonstaining, loosely bound outer layer. This same layer could be removed from the cells by washing with 0.5 m NaCl. A second nonsedimentable fraction was released after successive suspension of the cells in 0.5 m sucrose. Since this material was released only when the outer double-track structure had broken, it was concluded that it arose from a layer immediately underlying the latter layer. The three layers differed in their content of hexosamine and protein. None of the layers released contained muramic or diaminopimelic acid. The cell form remaining was rod shaped and appeared in thin section to be bounded only by its cytoplasmic membrane. This form contained all the muramic and diaminopimelic acid in the cell. Treatment with lysozyme released the muramic and diaminopimelic acid and converted the rod form to a protoplast, indicating that in the rod form (mureinoplast) a thin layer of peptidoglycan is located on the outside surface of the cytoplasmic membrane. Thus, five separate layers have been detected in the cell envelope of this marine pseudomonad.     

Mechanism of dissolution of envelopes of the extreme halophile Halobacterium cutirubrum

Onishi, H. (National Research Council, Ottawa, Ontario, Canada), and D. J. Kushner. Mechanism of dissolution of envelopes of the extreme halophile Halobacterium cutirubrum. J. Bacteriol. 91:646-652. 1966.-Envelopes of Halobacterium cutirubrum dissolved rapidly in media of low ionic strength. Heating partially inhibited breakdown, probably because of nonspecific protein coagulation rather than inactivation of a lytic enzyme(s). Dissolution of envelopes in water did not involve splitting of peptide bonds or protein-lipid bonds, or any extensive breakdown of carbohydrate polymers. Dissolution was increased by alcohols and urea, even at high salt concentrations, but was not affected by metabolic inhibitors. Thus, no evidence was found for a dilution-activated lytic enzyme that contributes to envelope breakdown. Cells of H. cutirubrum were stable in 2 m NaCl, but lysis occurred in 2 m KCl or NH(4)Cl. This lysis did not involve an extensive breakdown of the envelope. No evidence for different sites of Na(+), K(+), and NH(4) (+) action was obtained from the pattern of release of envelope constituents in different concentrations of these salts. Ultracentrifugation studies showed that adding salts to envelopes that had been dissolved in water led to a nonspecific reaggregation of envelope material. No difference was seen between the effects of KCl and NaCl, except at 3 to 4 m concentrations where KCl caused more aggregation. The preferential effect of Na(+) on intact cells is probably due to its ability specifically to prevent leakage rather than to an overall effect on envelope integrity.     

Isolation, Characterization, and Ultrastructure of the Peptidoglycan Layer of a Marine Pseudomonad

The peptidoglycan layer of a marine pseudomonad was observed by electron microscopy in thin sections of plasmolyzed intact cells and mureinoplasts but not in untreated intact cells. Only fragments of this layer could be isolated by sodium lauryl sulfate (SLS) treatment of mureinoplast envelopes. Sacculus-like peptidoglycan structures were obtained from growing cells by immediate heat inactivation of cellular autolytic enzymes and subsequent SLS, trypsin, and nuclease treatments. Recently, similar peptidoglycan sacculus-like structures have been obtained by adding SLS to the growing culture and treating the isolated particulate material with nucleases. Thin-sectioned and negatively stained preparations of whole cell peptidoglycan showed compressed profiles of cell-shaped sacculi. Peptidoglycan prepared by SLS treatment of mureinoplast envelopes had a similar composition to that prepared from whole cells. The major amino sugars and amino acids in the peptidoglycan component were glucosamine, muramic acid, alanine, glutamic acid and diaminopimelic acid in the molar ratios 1.18:1.24:1.77:1.00:0.79. Forty-five per cent of the epsilon-amino groups of diaminopimelic acid were cross-linked. The peptidoglycan was estimated to account for about 1% of the cell dry weight.     

Structure of the cell envelope of Halobacterium halobium

The structure of the isolated cell envelope of Halobacterium halobium is studied by X-ray diffraction, electron microscopy, and biochemical analysis. The envelope consists of the cell membrane and two layers of protein outside. The outer layer of protein shows a regular arrangement of the protein or glycoprotein particles and is therefore identified as the cell wall. Just outside the cell membrane is a 20 A-thick layer of protein. It is a third structure in the envelope, the function of which may be distinct from that of the cell membrane and the cell wall. This inner layer of protein is separated from the outer protein layer by a 65 A-wide space which has an electron density very close to that of the suspending medium, and which can be etched after freeze-fracture. The space is tentatively identified as the periplasmic space. At NaCl concentrations below 2.0 M, both protein layers of the envelope disintegrate. Gel filtration and analytical ultracentrifugation of the soluble components from the two protein layers reveal two major bands of protein with apparent mol wt of approximately 16,000 and 21,000. At the same time, the cell membrane stays essentially intact as long as the Mg++ concentration is kept at treater than or equal to 20 mM. The cell membrane breaks into small fragments when treated with 0.1 M NaCl and EDTA, or with distilled water, and some soluble proteins, including flavins and cytochromes, are released. The cell membrane apparently has an asymmetric core of the lipid bilayer.     

Studies on the deoxyribonucleic acid-bearing portion of the cell envelope of Escherichia coli.

The envelope components of nuclear bodies which were obtained from Escherichia coli W7 by a mild lysis method were investigated. By using 2,6-diaminopimelic acid (DAP) as precursor which is incorporated only into peptidoglycan in this strain it was found that the particles contained about 14% of the murein layer of the cell. The percentage of phosphatidylethanolamine was enriched at the cost of the other phospholipids in the nuclear bodies compared to whole cells. If lipids were labelled with 3H-palmitic acid the cytoplasmic and the outer membrane could be found after isopycnic centrifugation; however, when the cells were incubated with chloramphenicol, only the outer membrane was seen. The peptidoglycan and the proteins could be assigned only to the outer membrane. The DNA is also bound to the outer membrane. From these results it was concluded that (1) in all lysis methods the cytoplasmic membrane is more easily dissolved than the outer layers of the envelope, and (2) that there is a firm binding between DNA and the outer membrane in vivo.     

Structural changes during lysis of a psychorophilic marine bacterium

The marine psychrophile, a red, gram-negative motile rod with a single polar flagellum, is stable when suspended in 0.1 m Mg(2+) plus 0.5 m NaCl at 0 C and neutral pH but lyses if the salt composition of the medium is changed, the temperature raised above 20 C, or the pH lowered. Lysis is accompanied by a fall in turbidity, a release of ultraviolet-absorbing substances, and a loss of deoxyribonucleic acid and ribonucleic acid. Ultrastructural changes accompanying lysis were studied. Thin sections of cells fixed while intact showed a triple-layered cell wall and cytoplasmic membrane, each 6.0 to 7.5 nm thick. Mesosomes were also observed. Either Na(+) or Mg(2+) could maintain wall integrity, whereas Mg(2+) was needed for membrane integrity. In distilled water, lysis was very extensive, and much material was released as wall fragments and as vesicles which probably came from the wall and cytoplasmic membrane. Lysis at 37 C resulted in degradation of the wall and liberation of wall fragments. The cell membrane was rarely observed as a triple-layered structure in such temperature-lysed cells. After lysis at pH 5.0, the cell wall was distorted, and only a suggestion of the cell membrane remained. Replicas showed that this organism had a matted surface which was distorted under different conditions of lysis.     

Superficial cell-wall layers on Spirillum "Ordal" and their in vitro reassembly.

The cell envelope of Sporillum sp. strain "Ordal" (possibly a variety of S. anulus) demonstrated multiple superficial wall layers which were diverse in their macromolecular arrays. Negative staining and freeze-etching techniques revealed an outer hexagonally packed layer and an inner tetragonally packed layer. However, both thin sections and freeze-etched cleavages of the wall showed that each of these regular structures rested upon a backing layer, and that there was a delicate amorphous layer overlying the outer hexagonal array. Rotary integration, optical deffraction, and reconstruction of image were used to clarify measurements of each array and to verify the validity of a diagrammatic model of the outer hexagonal system. The integrity of these layers required suitable cations (Ca2+ appeared essential) and pH (pH less than or equal to 4.6 dissociated most superficial layers). These observations aided in the development of a low-pH cationic-substitution technique, in which Na+ replaced essential Ca2+, for extraction of the layers from the cell surface. Dialysis to remove Na+ and restoration of Ca2+ initiated in vitro reassembly of the superficial layer components until regularly structured assembly products were formed.     

Effects of Antibiotics on Induction, Viability, and Reversion Potential of L-Forms of Haemophilus influenzae

The physical interactions between Serratia marcescens and solutions of NaCl, CaCl(2), CaI(2), NaI, and Na(2)HPO(4) plus NaH(2)PO(4) were examined. Dilute (0.017 n) salt solutions did not cause cells to lose water, as evidenced by the unchanged weight of centrifugally packed cells. The cells preferentially adsorbed the cations and repelled the anions of most salts in these solutions. Concentrated (1.71 n) salt solutions markedly reduced the weight and water content of centrifugally packed cells, although these cells took up considerable amounts of salts. More than 90% of the water in the packed-cell pellets was available for the solution of NaCl at 4.2 to 4.4% concentration. The observation that salts apparently penetrated the cells freely and yet caused extensive dehydration was not readily compatible with conventional concepts of solute-induced plasmolysis. Alternative hypotheses to explain the data included the following. First, the cells lost weight and water to concentrated salt solutions through a nonosmotic competitive dehydration, causing a shrinkage of the protoplasmic gel. The shrinkage of the cell wall was limited because of the rigidity of its mucopeptide layer; therefore, a space appeared between the cell wall and the cell membrane. Second, cells may have equilibrated their water activity with that of their environment by two mechanisms: (i) the loss of water by plasmolysis or competitive dehydration, and (ii) alterations in cell permeability that admitted previously excluded solutes to the cell interior. Possibly, the correct explanation of the observations reported here involves elements of all three hypotheses, plasmolysis, competitive dehydration, and permeability alterations.     

The role of transmembrane cationic gradients in immune complex stimulation of human polymorphonuclear leukocytes

The role of monovalent cationic gradients in human polymorphonuclear leukocyte (PMNL) stimulation was investigated by monitoring immune complex-stimulated transmembrane depolarization and superoxide production, events which accompany--and have been used as indicators of --PMNL activation. Abolishing only the Na+ gradient by substitution of choline for extracellular Na+ did not affect the resting membrane potential but reduced the rate of stimulus-induced transmembrane depolarization to 50% of control. In contrast, collapsing both Na+ and K+ gradients by suspension in K+ buffer (high K-PRK) depolarized the cells and reduced the stimulus-induced rate of depolarization to 11% of control. Pretreatment of cells suspended in Na+ buffers with 5-(N,N-dimethyl)amiloride hydrochloride (DMA) or with valinomycin reduced by one-half the rate of immune complex induced membrane depolarization. Conversely, in the absence of either or of both Na+ or K+ gradients, or in the presence of valinomycin, immune complex elicited an enhanced rate of superoxide production. However, PMNL prepared via NH4Cl (NH4Cl-PMNL) instead of H2O (H2O-PMNL) lysis of residual red blood cells exhibited an absolute requirement for an intact Na+ gradient in cell stimulation. The present results thus demonstrate that: 1) both Na+ and K+ gradients participate equally in the membrane depolarization elicited by immune complex; 2) neither a Na+ or a K+ gradient is required for immune complex activation, or for activity of the respiratory burst; and 3) an artifactual requirement for an intact Na+ gradient occurs in neutrophils prepared by the NH4Cl lysis technique.     

Nutrition and metabolism of marine bacteria. XVI. Formation of protoplasts, spheroplasts, and related forms from a gram-negative marine bacterium

When cells of a marine pseudomonad were washed and suspended in 0.5 m sucrose, they retained their rod shape, but thin sections, when examined in an electron microscope, revealed that the outer layer of the cell wall had separated a considerable distance from the cytoplasmic membrane. Treatment of such cells with lysozyme alone produced no obvious change, but treatment with ethylenediaminetetraacetic acid (EDTA) alone caused the outer wall to disappear. A combination of EDTA and lysozyme resulted in the rapid formation of spheres essentially free from hexosamine and indistinguishable from protoplasts of gram-positive bacteria. When cells were washed with 0.5 m NaCl and then suspended in 0.5 m sucrose, they also retained their rod shape, but in this case the outer layer separated from the cells completely and could be recovered from the suspending medium. Such cells were converted to protoplasts by the action of lysozyme alone. Cells washed and finally suspended in 0.5 m NaCl, when treated with EDTA and lysozyme, slowly became spherical. Thin sections revealed typical spheroplasts of gram-negative bacteria in which the outer wall remained intact. Protoplasts took up alpha-aminoisobutyric acid by a Na(+)-dependent process.     

Action of Penicillin G on Endosymbiote Lambda Particles of Paramecium aurelia

The kinetics of loss from the cytoplasm and changes in ultrastructure of symbiont lambda particles after treatment of axenically cultivated lambda-bearing Paramecium aurelia with penicillin G was investigated. Low concentrations (1 to 2 unit/ml) of the antibiotic caused many particles within the cell to become filamentous; high concentrations (2,000 unit/ml) caused lysis of the particles without noticeably affecting the protozoan. The ED(50) value (2 to 3 unit/ml) was within the range of values found to cause lysis of many gram-negative bacteria. Rapidly dividing lambda were more vulnerable to the action of the antibiotic than slowly dividing particles. Nondividing particles were not affected by exposure to the antibiotic. Ultrastructural changes observed in lambda during lysis by penicillin G were consistent with the view that penicillin interferes with the synthesis of a vital component of the cell envelope of the particle, possibly a peptidoglycan similar to that found in the cell walls of bacteria. The deoxyribonucleic acid of lambda was dispersed throughout the particle as electron dense fibers enclosed within electron transparent areas. The cell envelope appeared to consist of at least two morphologically distinguishable layers, an inner layer homologous to the plasma membrane of bacteria and an outer layer homologous to the bacterial cell wall. Lambda may be regarded as a randomly distributed population of bacteria growing and dividing synchronously within the collective cytoplasm of its protozoan host.     

Growth responses of blue-green algae to sodium chloride concentration

Summary General characteristics of blue-green algal halotolerance were studied by growth experiments and selected analyses. Variation in NaCl concentration was used to mimic salinity. Marine isolates were more halotolerant (8–10% NaCl) than non-marine isolates (2% NaCl). The Na⁺ requirement for growth was saturated at 1 mg NaCl/l for non-marine isolates and 100mg NaCl/l for marine isolates. Intracellular Na⁺ values were affected by washing; however, bound-K⁺ values for both marine and fresh-water blue-green algae were fairly constant, 1–3 g/mg cells. A specific Na⁺ function was implied by the retention after washing of ²²Na⁺ (0.1 g/mg cells) by Agmenellum quadruplicatum (PR-6), a marine coccoid blue-green alga.High concentrations of NaCl apparently inhibit growth more by ionic (Na⁺) stress than by osmotic stress. Changes in light, temperature, pH, or composition of the basal medium failed to alleviate this stress.In contrast to marine bacteria, cells of PR-6 grown in Medium ASP-2+90 g NaCl/l did not undergo lysis when suspended in distilled water. However, viability of cells grown in Medium ASP-2+90 g NaCl/l decreased rapidly compared to cells grown in Medium ASP-2+18 g NaCl/l.Cells of PR-6 grown in ASP-2+90 g NaCl/l were larger than normal, formed chains (3–16 cells), and appeared bleached. Analyses of such cells revealed an overall decrease in fatty acids, hydrocarbons, and pigment levels. Electron micrographs showed that NaCl stressed cells were little altered in morphology.The photosynthesis of PR-6 cells was immediately depressed when the cells were transferred from 18 g NaCl/l to 70 g NaCl/l medium. When held in the latter for several hours the rate recovered and approached the initial photosynthetic rate maintained before NaCl-shock. This phenomenon was never seen with non-marine isolates. The explanation may lie in the ability of the cell to adjust to sudden Na⁺ increase via an ion (Na⁺) pump, for example, adenosine triphosphatase (ATPase). Subsequent assays suggested more ATPase activity in a marine isolated than in a nonmarine isolate. The ATPase was not, however, ouabain sensitive.It is suggested that marine blue-green algal isolates are characteristically more halotolerant, perhaps by selection, than fresh-water forms. This difference may be due in part to inherent capacity of the cell to extrude Na⁺. Alternatively, in freshwater forms rhe Na⁺ functional sites may be more Na⁺ sensitive than in marine forms.     

Cation interactions and biochemical composition of the cell envelope of a marine bacterium

Envelopes of a marine isolate, c-A1, and of a terrestrial isolate, 121, were compared for their susceptibility to disintegration in distilled water after exposure to 0.05 m MgCl(2) and to 0.1 and 1.0 m NaCl. After exposure to MgCl(2) alone, both types of envelopes remained intact in distilled water. Envelopes of marine isolate c-A1, but not of the terrestrial isolate, fragmented in distilled water after exposure to 1.0 m NaCl. Partial reaggregation of the c-A1 envelope fragments occurred on addition of MgCl(2). In cation-exchange experiments, bound Mg(++) in the envelopes of both organisms was displaced by Na(+). The envelopes of c-A1 were found to contain lipopolysaccharide, muramic acid, and a variety of phospholipids, of which the major component was phosphatidylethanolamine, accompanied by lesser amounts of phosphatidic acid, diphosphatidylglycerol, and phosphatidylserine. Analyses of envelope acid hydrolysates revealed a similar amino acid distribution in the marine and terrestrial isolates, but envelopes of c-A1 had less than half the total amino acid content of envelopes of 121 per envelope dry weight. Possible relationships between cations and biochemical components of the envelopes are considered in terms of differences in behavior of the two organisms in low ionic environments.     

Lysis of halophilic Vibrio alginolyticus and Vibrio costicolus induced by chaotropic anions.

High concentration (1.0 M) of KSCN, but not of NaSCN, induced lysis of slightly halophilic Vibrio alginolyticus and moderately halophilic Vibrio costicolus, and the decrease in absorbance of the cell suspension was complete after 30 min at 25 degrees C. Replacement of K+ with Na+ effectively prevented the lysis by SCN-.K+ salts of NO3-, Br- and I-, however, induced no significant lysis. In electron micrographs, a prolonged exposure of the cells of V. alginolyticus to 1.0 M KSCN displaced the nucleoplasm to maintain close contact with the cell membranes. After 40 min of interaction, 50% of the cellular protein, 96% of RNA and 94% of DNA were recovered in the lysed cells. In contrast to lysis in hypotonic conditions, the lysis induced by KSCN is due mainly to a partial release of protein from the cells. V. costicolus was more susceptible to SCN- than V. alginolyticus, whereas nonhalophilic Escherichia coli was resistant to 1.0 M KSCN. Thus, lysis by SCN- is characteristic of halophilic bacteria and cell membranes of more halophilic bacteria are more susceptible to chaotropic anions. The protective effect of Na+ observed here was considered to be manifested by specific interactions of Na+ with components of cell membranes, thereby rendering their structures resistant to the action of chaotropic anions.     

Salt-induced Contraction of Bacterial Cell Walls

Intact Bacillus megaterium cells were found to contract as much as 26% in terms of dextran-impermeable volume when transferred from water to unbuffered, non-plasmolyzing NaCl solutions. This shrinkage appeared to be primarily due to electrostatic wall contraction rather than to any osmotic response of the cells. A variety of salts (but not sucrose) added to water suspensions of isolated cell walls caused protons to be released from the walls with resultant lowering of suspension pH and contraction of the structures. In effect, B. megaterium walls behaved as flexible, amphoteric polyelectrolytes, and their compactness in aqueous suspensions was affected by changes in environmental ionic strength and pH. Isolated walls were most compact in low ionic strength media with a pH of about 4, a value close to the apparent isoelectric pH of wall peptidoglycan. Electrostatic attractions appeared to play a major role in determining the compactness of highly contracted walls, and the walls responded to increased environmental ionic strength by expanding. In contrast, electrostatic repulsions were dominant in highly expanded walls, and increased environmental ionic strength induced wall contraction. Walls of whole bacteria also shrank when the cells were plasmolyzed. This second type of contraction seemed to result from relief of wall tension during plasmolysis, and it could be induced with nonionic solutes. Thus, cell wall tone in B. megaterium appeared to be set both by mechanical tension and by electrostatic interactions among wall ions.