Cellular localization of lipoteichoic acid in Streptococcus faecalis.

The release of lipoteichoic acid and mesosomal vesicles to the supernatant buffer during the formation of spherical, osmotically fragile bodies was studied using Streptococcus faecalis ATCC 9790. Autolytic N-acetylmuramidase action was permitted to take place in exponential-phase cells incubated in a buffer which provides an exceptional degree of osmotic stabilization. Both lipoteichoic acid and mesosomal vesicles were relatively rapidly released to the supernatant buffer. Most of the cellular content of lipoteichoic acid (and mesosomal vesicles) was found in the supernatant buffer at incubation times when the cells still retained over 75% of their cell wall. [14-C]- or [3-H]glycerol was used as a label for both cellular lipoteichoic acids and lipid-glycerol. Glycerol in lipoteichoic acid was quantitated after phenol-water and chloroform-methanol treatments and identified by products of acid hydrolysis and its ability to be precipitated by (i) antibodies specific for the polyglycerol-phosphate backbone, (ii) antibodies to the streptococcal group D antigen, and (iii) concanavalin A. Evidence was obtained that lipoteichoic acid was not associated with isolated mesosomal vesicles. Centrifugation of supernates at 200,000 X g sedimented membranous (mesosomal) vesicles and nearly all of the lipid-glycerol present, whereas essentially all of the lipoteichoic acid remained in the supernatant. The sedimented mesosomal vesicles differed from protoplast membrane in their higher lipid-phosphorus to protein ratio and in the absence of detectable levels of two enzymatic activities found in protoplast membranes, adenosine triphosphatase and polynucleotide phosphorylase. Both types of membranes were found to contain DD-carboxypeptidase and LD-transpeptidase activities at nearly the same specific activities. No evidence was obtained for the association of autolytic N-acetylmuramidase activity with either type of membrane preparation.     

Electron microscopic demonstration and isolation of ribosomes in mesosomes from Staphylococcus aureus

Mesosomes of Staphylococcus aureus 209P were observed to be extruded as tubules upon protoplast formation by electron microscopy and isolated under hypertonic conditions to maintain their structural integrity by differential centrifugation followed by sucrose density gradient centrifugation. Isolated mesosomes were composed of long, branched tubules of irregular sizes and they were shortened during purification. Thin sections of isolated mesosomes showed that the mesosomal tubule was surrounded by a triple-layered membrane and contained ribosome-like particles in diameter of about 15 to 20 nm. These particles were isolated from purified mesosomal preparation by disrupting the mesosomal tubule with deoxycholate and Triton X-100 under hypotonic conditions followed by a linear sucrose density gradient centrifugation. Negatively stained preparations of the isolated particles revealed the same appearance as those of the ribosomes isolated from the cytoplasm. The mesosomal particles sedimented at 70S in sucrose gradients in the presence of 10 mM Mg2+, but they were dissociated into two subparticles, 50S and 30S subunits, upon lowering the Mg2+ concentration to 1 mM. These findings indicate that the mesosomal tubule is packed with ribosomes.     

The Separation and Isolation of Plasma Membranes and Mesosomal Vesicles from Staphylococcus Aureus

We have separated and Isolated the plasma membranes and mesosomal vesicles of Staphylococcus aureus ATCC 6538P. Cells were grown aerobically in Difco synthetic AOAC broth, washed and resuspended in hypertonic buffer (3.45 M NaC1) containing 0.02 M MgSO₄. Cell wall was removed by treatment with lytic enzyme from S. aureus, strain LS. The protoplasts were collected by centrifugation at 10,000 × g for 1 hour, resuspended in hypotonic buffer containing 0.02 M MgSO₄ and lysed. The resultant plasma membranes were washed and centrifuged on a 60tr>75Z sucrose density gradient at 55,000 × g for 15 hours. Gradient patterns showed two bands of membranes. Crude mesosomes were obtained from the 10,000 × g supernatant fractions by centrifugation at 100,000 × g for 2 hours. The reddish-brown gelatinous pellet, which consisted of mesosomal vesicles and a few ribosomes, was washed and centrifuged on a 60 to 85% sucrose density gradient at 100,000 × g for 15 hours. Gradient patterns produced two bands of mesosomal vesicles. The homogeneity of the plasma membranes and mesosomal vesicles was determined by electron microscopy and chemical analyses.     

Protoplast formation and regeneration in <Emphasis Type="Italic">Lactobacillus delbrueckii</Emphasis>

Method for production and regeneration of Lactobacillus delbrueckii protoplasts are described. The protoplasts were obtained by treatment with a mixture of lysozyme and mutanolysin in protoplast buffer at pH 6.5 with different osmotic stabilizers. The protoplasts were regenerated on deMan, Rogosa and Sharpe (MRS) with various osmotic stabilizers. Maximum protoplast formation was obtained in protoplast buffer with sucrose as an osmotic stabilizer using a combination of lysozyme (1 mg/ml) and mutanolysin (10 μg/ml). Maximum protoplast regeneration was obtained on MRS medium with sucrose (0.5 M) as an osmotic stabilizer. The regeneration medium was also applicable to other species of lactobacilli as well. This is, to our knowledge, the first report on protoplast formation and efficient regeneration in case of L. delbrueckii.     

Sugar effects on membrane damage during desiccation of pea embryo protoplasts

Desiccation tolerance of protoplasts isolated from germinating pea (Pisum sativum L. cv. 'Alaska') embryonic axes depends, in part, on the osmotic strength and composition of the suspending medium. To determine the reason for this dependence and whether treatment with different solutions results in different types of damage, protoplast recovery and survival were assessed after dehydration to a range of water contents. Protoplasts were derived from germinating axes that had intermediate desiccation tolerance. Protoplasts were isolated and resuspended in buffers containing sucrose/raffinose (85:15, w/w) or sorbitol, which were isotonic or hypertonic to the cells of the embryonic axis, then were flash-dried to a range of water contents. Protoplasts were rehydrated and stained with fluorescein diacetate (FDA) to assess survival and to estimate two types of membrane injury: lysis and the loss of semipermeability. In all treatments, protoplast survival dropped sharply during the initial phase of dehydration due to lysis. Protoplast survival was greater in hypertonic sucrose/raffinose buffer than in isotonic sucrose/raffinose buffer, or in the latter made hypertonic by the addition of sorbitol. When sorbitol was substituted for sucrose/raffinose in either the isolation or desiccation buffer, or both, protoplast survival at intermediate and low hydrations decreased due to a loss of membrane semipermeability. The results indicate that additional sucrose/raffinose is beneficial for the desiccation tolerance of protoplasts, the benefit is not due to a simple osmotic effect, and the benefit is greatest at water contents less than 0.5 g g(-1) DW, where the presence of the sugars appears to protect membrane semipermeability.     

Methanogenesis and ATP synthesis in a protoplast system of Methanobacterium thermoautotrophicum.

When Methanobacterium thermoautotrophicum cells were incubated in 50 mM potassium phosphate buffer (pH 7.0) containing 1 M sucrose and autolysate from Methanobacterium wolfei, they were transformed into protoplasts. The protoplasts, which possessed no cell wall, lysed in buffer without sucrose. Unlike whole cells, the protoplasts did not show convoluted internal membrane structures. The protoplasts produced methane from H2-CO2 (approximately 1 mumol min-1 mg of protein-1) at about 50% the rate obtained for whole cells, and methanogenesis was coupled with ATP synthesis. Addition of the protonophore 3,5-di-tert-butyl-4-hydroxybenzylidenemalononitrile (SF-6847) to protoplast suspensions resulted in a dissipation of the membrane potential (delta psi), and this was accompanied by a parallel decrease in the rates of ATP synthesis and methanogenesis. In this respect protoplasts differed from whole cells in which ATP synthesis and methanogenesis were virtually unaffected by the addition of the protonophore. It is concluded that the insensitivity of whole cells to protonophores could be due to internal membrane structures. Membrane preparations produced from lysis of protoplasts or by sonication of whole cells gave comparatively low rates of methanogenesis (methylcoenzyme M methylreductase activity, less than or equal to 100 nmol of CH4 min-1 mg of protein-1), and no coupling with ATP synthesis could be demonstrated.     

Cellular Location of Degradative Enzymes in Staphylococcus aureus

Staphylococus aureus, ATCC 6538P, was fractionated into protoplast membranes, mesosomal vesicles, periplasm, and cytoplasm. These fractions and the culture fluid were then assayed for various degradative enzyme activities. They were not restricted to a single fraction nor dispersed homogeneously, but were distributed predominantly (on the basis of specific activity) as follows: nuclease in the culture fluid; alkaline phosphatase, 5'-nucleotidase, and acid phosphatase in the periplasm; adenosine triphosphatase in the protoplast membrane; and protease (low levels) in mesosomal vesicles. No significant esterase nor cell wall hydrolytic activity was found in any fraction. S. aureus 80/81 was studied for penicillinase activity after induction with benzyl penicillin; this enzyme was localized in the mesosomal vesicles. Electron microscopy did not reveal any ultrastructural changes associated with secretion of the extracellular fraction. Overall, these studies demonstrate that degradative enzymes are located in several surface compartments and that, therefore, the mesosome does not function as a prototype lysosome in S. aureus.     

Optimization of formation and regeneration of protoplasts from biocontrol agents ofTrichoderma species

The optimal conditions necessary for a large yield and a high frequency of regeneration of protoplasts isolated from the biocontrol agentsTrichoderma koningii andT. harzianum were investigated. Protoplast yields were 1.2×10⁸/ml fromT. koningii and 6×10⁷/ml fromT. harzianum when 20-h mycelial culture was treated with a lytic enzyme solution containing Novozym 234 (15 mg/ml), sucrose (0.6 M) and citrate phosphate buffer (0.02 M), pH 5.6 at 31°C. When the protoplasts were grown in the regeneration medium containing yeast extract (1.5%), 1 I of Mandel's salts, pH 5.6, and glucose (0.8 M), a high frequency of regeneration of the protoplast was obseved: 66% forT. koningii and 45% forT. harzianum. Two patterns of regeneration were observed. First, the hyphae arose directly from the regenerated protoplast mother cell. Second, a chain of bud cells developed from the protoplast and subsequently generating hyphae generally protruded from the terminal bud cells.     

Vectorial and nonvectorial transphosphorylation catalyzed by enzymes II of the bacterial phosphotransferase system

The plasmolytic response of Bacillus licheniformis 749/C cells to the increasing osmolarity of the surrounding medium was quantitated with stereological techniques. Plasmolysis was defined as the area (in square micrometers) of the inside surface of the bacterial wall not in association with bacterial membrane per unit volume (in cubic micrometers) of bacteria. This plasmolyzed surface area was zero when the cells were suspended in a concentration of sucrose solution lower than 0.5 M, but increased linearly when the sucrose molarity rose above 0.5 M, reaching a plateau value of 3.61 micrometers2/micrometers3 in 2 M sucrose. In contrast, when the bacterial cells were treated with lysozyme plasmolysis increased abruptly from 0.06 micrometers2/micrometers3 in 0.75 M sucrose to 4.09 micrometers2/micrometers3 in 1 M sucrose. When the time of exposure was prolonged, the degree of plasmolysis increased gradually for the duration of the experiment (30 min) after exposure to 1 M sucrose without lysozyme, whereas with lysozyme plasmolysis reached a maximum (4.09 micrograms2/micrometers3) in 2 to 5 min. The examination of ultrastructure showed that the protoplast bodies of lysozyme-treated cells in 1 M sucrose and untreated cells in 2 M sucrose are maximally retracted from the intact wall of the bacteria; hardly any retraction of protoplasts could be seen for untreated cells in 1 M sucrose. The data suggest that the B. licheniformis cells are isoosmotic to 800 to 1,100 mosM solutions, but are able to withstand much greater osmotic pressure with no signs of plasmolysis because the cell wall and the plasma membrane are held in close association, perhaps by a covalent bond. It is likely that lysozyme weakens this bond by degradation of the peptidoglycan layer. Cellular autolysis also weakens this wall-membrane association.     

Protoplast Fusion of Lactobacillus casei

Lactobacillus casei ATCC 7469 was successfully converted to protoplasts by treatment with endo-7V-acetyl muramidase in sucrose phosphate buffer. For full hydrolysis of cell walls, a high concentration of sucrose and a cold shock were necessary. Mg²⁺ ions enhanced the stability of protoplasting cells. The cell wall regeneration of protoplasts was more effective on gelatin-induced regeneration medium than with the soft overlay method. The optimal concentration of gelatin was 2.5%. The frequency of regeneration was found to be about 6% for the protoplast prepared by enzyme treatment for 20 min. The mutants having streptomycin resistance and rifampicin resistance, as selection markers for the detection of fusion, were isolated by UV irradiation and NTG treatment. These mutants were stable for at least several transfers. Protoplast fusion was carried out using PEG (50% solution of polyethyleneglycol, M.W. 6,000). The frequency of protoplast fusion was found to be about 10^-5.     

Respiratory Activities Associated with Mesosomal Vesicles and Protoplast Membranes of Staphylococcus aureus

Analysis of oxidase and dehydrogenase activities, cytochrome content of mesosomal vesicles, and protoplast membranes showed that the respiratory chain in Staphylococcus aureus is associated predominantly with the protoplast membranes.     

High frequency plant regeneration from protoplasts in cotton <Emphasis Type="Italic">via</Emphasis> somatic embryogenesis

A highly reproducible system for efficient plant regeneration from protoplast via somatic embryogenesis was developed in cotton (Gossypium hirsutum L.) cultivar ZDM-3. Embryogenic callus, somatic embryos and suspension culture cells were used as explants. Callus-forming frequency (82.86 %) was obtained in protoplast cultures from suspension culture cells in KM₈P medium with 0.45 μM 2,4-dichlorophenoxyacetic acid (2,4-D), 0.93 μM kinetin (KIN), 1.5 % glucose and 1.5 % maltose. Protocolonies formed in two months with plating efficiency of 14 %. However, the callus-forming efficiencies from other two explants were low. The calli from protoplast culture were transferred to somatic embryo induction medium and 12.7 % of normal plantlets were obtained on medium contained 3 % maltose or 1 % of each sucrose + maltose + glucose, 2.46 μM indole-3-butyric acid (IBA) and 0.93 μM KIN. Over 100 plantlets were obtained from protoplasts derived from three explants. The regenerated plants were transferred to the soil and the highest survival rate (95 %) was observed in transplanting via a new method.     

Characterization of mesosomes of Micrococcus luteus: isolation and properties of mesosomal ribosomes, and localization of penicillin-binding proteins in mesosomal membranes

Mesosomes were isolated and purified from Micrococcus luteus under hypertonic conditions throughout preparation processes. The purified mesosomal preparation was composed of closed tubules and vesicles. Electron-dense ribosome-like particles were observed within the isolated mesosomal vesicles by electron microscopy. The ribosome-like particles were isolated from the purified mesosomes by a procedure involving solubilization of the membranes with detergents followed by centrifugation on a linear density gradient of sucrose. The isolated particles have a sedimentation coefficient of 70S in the presence of 10 mM Mg2+, when Mg2+ concentration was lowered to 0.1 mM, the particles were dissociated into two sub-particles of 30S and 50S. The 70S particles had the same appearance as cytoplasmic 70S ribosome particles upon observations of negatively stained preparations. These findings indicate that mesosomal tubules contain ribosomes. The isolated mesosomal ribosomes had the ability for protein synthesis when polyuridylic acid-directed polyphenylalanine synthesis was assayed. The sensitivity of mesosomal ribosomes to inhibitors, chloramphenicol and streptomycin, for protein synthesis was significantly lower than that of both cytoplasmic and cytoplasmic membrane-bound ribosomes. In addition, three penicillin-binding proteins were detected in the mesosomal membranes. One of these was localized predominantly in the mesosomal membranes and the other two were distributed almost equally in both mesosomal and cytoplasmic membranes.     

The isolation of protoplasts from the placental cells ofSolanum nigrum L.

Summary Living protoplasts were isolated from the interplacental regions ofSolanum nigrum berries by the removal of the walls from cells in tissue slices treated for 1–2 hours with 12% pectinase in 0.33 M to 0.38 M sucrose solution. Protoplasts thus isolated, then washed and transferred to microculture chambers for observation, invariably tended to be spherical. Comparative measurements of cell and protoplast volumes revealed that 10% of the isolated structures were subunits of protoplasts. From diameter changes in protoplasts studied in a hypotonic (0.20 M) sucrose solution, the maximum expansion of the plasma membrane was determined. Slightly hypertonic solutions (0.33 M to 0.38 M sucrose) promote stability of isolated protoplasts for several days. The importance to stability of osmotic concentration and ion balance in the medium is here established. Probably of equal importance is the optimal combination of several common constituents of culture media. Further studies on some aspects of specific medium requirements are in progress.This work was supported by a special grant from the Office of Advanced Studies and Research, University of South Carolina.     

Isolation and Characterization of Protoplasts from Saccharomyces rouxii

Cells of the osmotolerant yeast Saccharomyces rouxii were transformed to protoplasts in good yield (85%) by digesting cell walls with snail-gut enzyme in the presence of 10 mM dithioerythritol, 0.1 M sodium phosphate buffer (pH 6.8), and 2.0 M KCl. The requirement for 2.0 M KCl compares with that for S. bisporus var. mellis (another osmotolerant species) and contrasts with the 0.3 to 0.8 M KCl concentrations used in the preparation of most yeast protoplasts. Short digestions (60 min or less) produced mostly spheroplasts; longer incubations (90 min or more) yielded mostly protoplasts as judged by electron micrographs. These protoplasts could be transferred to 1.0 M KCl or 2.0 M sorbitol without lysing, but lysis was pronounced in 0.5 M KCl or 1.0 M mannitol and complete in 0.02 M KCl. Protoplasts were separated from isolated cell wall remnants and debris by centrifugation on a linear gradient of Ficoll 400 (35 to 17.5%, wt/vol) containing 2.0 M KCl. Both crude and fractionated protoplast preparations contained vesicles which were identified with the periplasmic bodies of whole cells. Some of the periplasmic bodies were connected to protoplasts by fine pedicels; others appeared free. Independent degeneracy of periplasmic bodies was occasionally observed. beta-Fructofuranosidase (EC 3.2.1.26) activity is cryptic (physically) in cells of S. rouxii in contrast to the expressed enzyme (periplasmic space) of other Saccharomyces species. This enzyme remains cryptic in protoplast preparations of S. rouxii but is expressed upon lysis. The same specific activities were found per unit cell or protoplast. The possible association of the cryptic enzyme with periplasmic bodies is discussed.     

Preservation of fine Structures in Yeast by Fixation in a Dimethyl Sulfoxide-Acrolein-Glutaraldehyde Solution

The primary fixative containing 2% acrolein, 2% glutaraldehyde in 50% aqueous dimethyl sulfoxide (DMSO) buffered at pH 7.4, was applied for 7 hr in the cold. After a short wash in 0.02 M s-collidine buffer, pH 7.4, containing 0.2 M sucrose and 0.001 M CaCl₂, the yeast cells were postfixed in 3% OsO₄ at pH 4.0 (veronal acetate buffer). This method preserves many cytoplasmic features such as lipid deposits and ribosomes which are usually destroyed by permanganate fixation. DMSO apparently acts as a permeating agent allowing maximum penetration of the cell wall by the fixative without disrupting cellular fine structure     

Morphological Changes during Conversion of Clostridium saccharoperbutylacetonicum to Protoplasts by Sucrose-Induced Autolysis

When exponentially growing cells of Clostridium saccharoperbutylacetonicum (ATCC 13564) were exposed to hypertonic concentrations of sucrose (0.3–0.5 M), rapid degradation of the cell wall occurred (sucrose-induced autolysis). The morphological changes from the original rod-shaped cells to protoplasts during the sucrose-induced autolysis were investigated by phase contrast and electron microscopy. When the cells were autolysed in the sucrose solution (0.35 M), each cell began to swell at the middle or at one pole and then formed a small bulb at the swollen part. The bulb consisted of the cytoplasm which was enveloped by the plasma membrane and extruded from the small gap produced by the degradation of the cell wall. The bulb gradually enlarged as lysis progressed, and finally became a protoplast which had no cell wall. The large pre-division cell frequently formed the bulb at the middle (septal site), while the small post-division cell formed the bulb at the pole.     

The Appearance of Differentiating Vascular Cells after Fixation in Different Solutions

The cambium and differentiating xylem elements of Salix fragilisand Fagus sylvatica were most satisfactorily fixed in a 3 percent solution of glutaraldehyde in 0.05 M phosphate buffer and0.4 M sucrose at pH 7.2 with sodium, calcium, and potassiumchlorides added to a total combined molarity of about 0.1 M,so giving a total osmolality in excess of 1,000 milliosmols.As various factors such as the concentration of fixative, natureof buffer system, pH, addition of salts, addition of sucrose,osmolality, and temperature all affect fixation, it is importantto report the exact constituents and conditions of fixationin published work.     

EFFECTS OF FIXATIVES ON THE ULTRASTRUCTURE OF PHYSODES IN VEGETATIVE CELLS OF SCYTOSIPHON LOMENTARIA (SCYTOSIPHONACEAE,PHAEOPHYTA)1

The effects of different glutaraldehyde-osmium fixation schedules on the ultrastructure of the vegetative cells from the meristematic regions of Scytosiphon lomentaria (Lyngbye) Link fronds are described. The best overall preservation of cell structure was obtained with a 2 h fixation in 2.5–3.5% glutaraldehyde in 0.1 M cacodylate buffered seawater (pH 7.0), followed after washing by 1 h post fixation in 1% osmium tetroxide. The addition of 1% caffeine to the glutaraldehyde fixative resulted in better retention and spatial localization of the electron dense phenolic deposits within the cells. Particular attention was paid to the effects of the various fixation schedules on the electron-dense material within the cells and the images obtained were compared with previous accounts of brown algal cells. It is proposed that the term physode should be restricted to the discrete electron dense spherical bodies within the vacuoles and not applied to electron dense material in general. Although the organization of Scytosiphon cells was similar to that previously reported in the Scytosiphonaceae, the organization of the plasmodesmata into pit fields is at variance with previous accounts.     

Protective effect of sucrose and sodium chloride for Lactococcus lactis during sublethal and lethal high-pressure treatments

The bactericidal effect of hydrostatic pressure is reduced when bacteria are suspended in media with high osmolarity. To elucidate mechanisms responsible for the baroprotective effect of ionic and nonionic solutes, Lactococcus lactis was treated with pressures ranging from 200 to 600 MPa in a low-osmolarity buffer or with buffer containing 0.5 M sucrose or 4 M NaCl. Pressure-treated cells were characterized in order to determine viability, the transmembrane difference in pH (DeltapH), and multiple-drug-resistance (MDR) transport activity. Furthermore, pressure effects on the intracellular pH and the fluidity of the membrane were determined during pressure treatment. In the presence of external sucrose and NaCl, high intracellular levels of sucrose and lactose, respectively, were accumulated by L. lactis; 4 M NaCl and, to a lesser extent, 0.5 M sucrose provided protection against pressure-induced cell death. The transmembrane DeltapH was reversibly dissipated during pressure treatment in any buffer system. Sucrose but not NaCl prevented the irreversible inactivation of enzymes involved in pH homeostasis and MDR transport activity. In the presence 0.5 M sucrose or 4 M NaCl, the fluidity of the cytoplasmic membrane was maintained even at low temperatures and high pressure. These results indicate that disaccharides protect microorganisms against pressure-induced inactivation of vital cellular components. The protective effect of ionic solutes relies on the intracellular accumulation of compatible solutes as a response to the osmotic stress. Thus, ionic solutes provide only asymmetric protection, and baroprotection with ionic solutes requires higher concentrations of the osmolytes than of disaccharides.