Antimicrobial Actions of Hexachlorophene: Cytological Manifestations

Hexachlorophene is a soap-compatible bisphenol that has been widely used as an antiseptic, yet its mechanism of action is undefined. The relative threshold concentration for bactericidal effect on a susceptible test organism, Bacillus megaterium, was established to be about 10 mug/mg of cell dry weight. At this or at high (>/=100 mug/mg) concentration, adsorptive uptake by cells displayed saturation kinetics. At about 30 mug/mg, the time course of adsorption occurred in three distinct stages. The triphasic pattern was interpreted to represent successive penetration of and adsorption by the cell wall, the protoplast membrane, and the cytoplasm. This interpretation was substantiated by determinations of hexachlorophene adsorption by isolated cell components. Electron microscopy disclosed cytopathology, evidenced as gaps or discontinuities, in the protoplast membrane (but not in the cell wall or cytoplasm) at > 30 mug of hexachlorophene per mg of cell dry weight. Similarly, treatment with > 30 mug/mg allowed a fluorescigenic dye (tolyl-peri acid) to penetrate into the protoplast. However, no detectable cytological manifestations were discerned at the minimum lethal concentration of 10 mug/mg. Apparently, hexachlorophene is physically disruptive at intermediate or high relative concentrations but acts in a more subtle fashion at the minimal lethal concentration.     

Protoplast formation and regeneration of dehydrodivanillin-degrading strains of Fusobacterium varium and Enterococcus faecium

Two strains of rumen anaerobes isolated from dehydrodivanillin-degrading cultures were identified as Fusobacterium varium and Enterococcus faecium. These organisms degraded dehydrodivanillin synergistically to 5-carboxymethylvanillin and vanillic acid. Specific conditions for protoplast formation and cell wall regeneration for both bacteria were determined, under strictly anaerobic conditions, to be as follows. The cell wall of each bacterium in yeast extract medium was loosened by adding penicillin G during early log-phase growth. The cell wall of F. varium was lysed by lysozyme (1 mg/ml) in glycerol (0.2 M)-phosphate buffer (0.05 M; pH 7.0). The addition of NaCl (0.08 M) with lysozyme was necessary for lysis of E. faecium in this solution. Almost all cells were converted to protoplasts after 2 h of incubation at 37 degrees C. Regeneration of both protoplasts was 20 to 30% on an agar-containing yeast extract medium.     

Protoplast formation and regeneration of dehydrodivanillin-degrading strains of Fusobacterium varium and Enterococcus faecium.

Two strains of rumen anaerobes isolated from dehydrodivanillin-degrading cultures were identified as Fusobacterium varium and Enterococcus faecium. These organisms degraded dehydrodivanillin synergistically to 5-carboxymethylvanillin and vanillic acid. Specific conditions for protoplast formation and cell wall regeneration for both bacteria were determined, under strictly anaerobic conditions, to be as follows. The cell wall of each bacterium in yeast extract medium was loosened by adding penicillin G during early log-phase growth. The cell wall of F. varium was lysed by lysozyme (1 mg/ml) in glycerol (0.2 M)-phosphate buffer (0.05 M; pH 7.0). The addition of NaCl (0.08 M) with lysozyme was necessary for lysis of E. faecium in this solution. Almost all cells were converted to protoplasts after 2 h of incubation at 37 degrees C. Regeneration of both protoplasts was 20 to 30% on an agar-containing yeast extract medium.     

Hyperosmotic stress induces formation of tubulin macrotubules in root-tip cells of Triticum turgidum: their probable involvement in protoplast volume control

Treatment of root-tip cells of Triticum turgidum with 1 M mannitol solution for 30 min induces microtubule (Mt) disintegration in the plasmolyzed protoplasts. Interphase plasmolyzed cells possess many cortical, perinuclear and endoplasmic macrotubules, 35 nm in mean diameter, forming prominent arrays. In dividing cells macrotubules assemble into aberrant mitotic and cytokinetic apparatuses resulting in the disturbance of cell division. Putative tubulin paracrystals were occasionally observed in plasmolyzed cells. The quantity of polymeric tubulin in plasmolyzed cells exceeds that in control cells. Root-tip cells exposed for 2-8 h to plasmolyticum recover partially, although the volume of the plasmolyzed protoplast does not change detectably. Among other events, the macrotubules are replaced by Mts, chromatin assumes its typical appearance and the cells undergo typical cell divisions. Additionally, polysaccharidic material is found in the periplasmic space. Oryzalin and colchicine treatment induced macrotubule disintegration and a significant reduction of protoplast volume in every plasmolyzed cell type examined, whereas cytochalasin B had only minor effects restricted to differentiated cells. These results suggest that Mt destruction by hyperosmotic stress, and their replacement by tubulin macrotubules and putative tubulin paracrystals is a common feature among angiosperms and that macrotubules are involved in the mechanism of protoplast volume regulation.     

ENTRY OF BASIC MACROMOLECULES INTO BARLEY ROOTS

The entry of labelled calf-thymus histone, lysozyme, and poly-L-lysine into barley root tips was studied at concentrations which strongly inhibit root elongation. The macromolecules were suitably labelled and at these concentrations it was found, by autoradiography and fluorescence microscopy, that histone and lysozyme readily entered the roots and appeared to bind mainly to cell walls of the epidermis and cortex and to penetrate the cytoplasm occasionally. Except in cap cells, nuclei were rarely penetrated. Poly-L-lysine readily permeated cell walls and invaded cytoplasm and nuclei throughout the root tip. Some cells were damaged by contact with basic macromolecules, as evidenced by a change in appearance of protoplasts under phase contrast and by the inability of these same protoplasts to exclude labelled β-lactoglobulin. Such damage was restricted to cells in contact with the outer solution. Interior to the epidermis, development of many cells was inhibited without visible signs of damage. Evidence supports the conclusion that in the presence of polybasic polymers the integrity of cell membranes is altered, thereby allowing leakage of some cell constituents essential for normal development.     

A plasmolytic cycle: The fate of cytoskeletal elements

Summary In most plant cells, transfer to hypertonic solutions causes osmotic loss of water from the vacuole and detachment of the living protoplast from the cell wall (plasmolysis). This process is reversible and after removal of the plasmolytic solution, protoplasts can re-expand to their original size (deplasmolysis). We have investigated this phenomenon with special reference to cytoskeletal elements in onion inner epidermal cells. The main processes of plasmolysis seem to be membrane dependent because destabilization of cytoskeletal elements had only minor effects on plasmolysis speed and form. In most cells, the array of cortical microtubules is similar to that found in nonplasmolyzed states except that longitudinal patterns seen in some control cells were never observed in plasmolyzed protoplasts of onion inner epidermis. As soon as deplasmolysis starts, cortical microtubules become disrupted and only slowly regenerate to form an oblique array, similar to most nontreated cells. Actin microfilaments responded rapidly to the plasmolysis-induced deformation of the protoplast and adapted to its new form without marked changes in organization and structure. Both actin microfilaments and microtubules can be present in Hechtian strands, which, in plasmolyzed cells, connect the cell wall to the protoplast. Anticytoskeletal drugs did not affect the formation of Hechtian strands.Abbreviations DIC differential interference contrast - DiOC₆(3) 3,3-dihexyloxacarbocyanine iodide Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

The relationship between cell injury and osmotic volume reduction: III. Freezing injury and frost resistance in winter wheat

In order to distinguish between several possible mechanisms of frost hardening in winter wheat (Triticum aestivum L.) cells from two hardy and two tender cultivars were plasmolyzed in CaCl₂ solution at room temperature and cell volumes estimated by microscopic examination. Analyses of Boyle-van't Hoff plots of these data reveal that all cells from cultivars progressively increase their intracellular solute concentration up to 20 days hardening. This increase, which we had predicted from published calorimetric data to be the sole mechanism of hardening explained less than half of the increase in hardening seen in the most hardy cultivar, Kharkov. Hardening also increased the osmotically inactive volume.At CaCl₂ concentrations greater than 5%, plasmolyzed protoplasts departed further from the Boyle-van't Hoff prediction, remaining larger than expected until some higher concentration of CaCl₂, where protoplast volume again sharply decreased. In all cultivars except hardened Kharkov, the concentration of CaCl₂ producing this abrupt volume decrease had a freezing point corresponding to the killing temperature. If this concentration was exceeded during plasmolysis, then the protoplasts burst during deplasmolysis at some volume less than their original volume.We interpret these data to mean that, in addition to the often described hardening mechanism of increased cell solute and water binding, winter wheat shows a third mechanism, a mechanical resistance to protoplast shrinkage which produces volumes larger than those predicted during osmotic stress. The resisting element appears to be the plasma membrane itself. Shrinkage brings the membrane under compressive stress, developing tangential pressure within it. Cell injury occurs when the cell membrane area has been reduced to the point at which irreversible loss of membrane material is inevitable. Cell death occurs during deplasmolysis when the protoplast bursts because its membrane contains insufficient material to subtend the area of the cell wall.Of the cultivars tested, hardened Kharkov was unique in avoiding injury. Hardened Kharkov was injured only after the volume inflection had been greatly exceeded. Refractile droplets of lipid appeared in the cytoplasm of hardened Kharkov protoplasts during plasmolysis but disappeared during deplasmolysis suggesting that hardy Kharkov was able reversibly to store membrane lipids in cytoplasmic vesicles and return them to the membrane on deplasmolysis.     

Hemolysis by hexachlorophene

Human erythrocytes were hemolyzed by doses of hexachlorophene (HCP) comparable to those which caused lysis of bacterial protoplasts. The hemolytic doses were about 5 orders of magnitude higher than the reported blood levels in regular hexachlorophene users. Thus, hemolytic phenomena seem unlikely sources of hexachlorophene toxicity.     

Properties of protoplasts from the thermophile Bacillus coagulans and their significance for genetic studies

Regeneration of protoplasts of Bacillus coagulans was optimized by using low lysozyme concentrations and glycerol as the osmotic support. Protoplasts formed from cells grown at higher temperatures were thermostable and capable of regeneration at 55°C. Transfer of plasmids pAB224 and pUB110, using either whole cells or protoplast transformation was not achieved, despite using a variety of conditions. However, plasmid transfer was achieved by fusion with B. subtilis protoplasts containing plasmid pAB224.     

Flow cytometric analysis of protein content in Taxus protoplasts and single cells as compared to aggregated suspension cultures

Plant suspension cultures are highly aggregated, preventing the direct application of flow cytometry for the study of population dynamics. The utility of single cells to accurately represent aggregated suspension cultures was tested through the analysis of total protein content. Specifically, protein content of two Taxus cuspidata suspension culture lines was studied using the Bradford assay for aggregated suspension cultures, and flow cytometry with fluorescein isothiocyanate staining for protoplasts and single cells. Taxus protein levels were measured at 75–160 mg per gram dry weight via the Bradford assay. Aggregated suspension cultures, protoplasts, and single cells predicted the same trend of protein content over the culture period (21 days). Normalized protein content of isolated single cells was statistically equivalent to aggregated suspensions for both cell lines. However, normalized protein content of isolated protoplasts showed significant differences from aggregated suspensions for one of the two cell lines. Elicitation with methyl jasmonate (MJ) is commonly utilized to increase paclitaxel accumulation in suspension cultures, and therefore the effect of MJ elicitation on protein content in aggregated suspensions, isolated single cells and protoplasts was assessed. Aggregated suspension cultures, protoplasts, and single cells did not show any change in total protein content following elicitation with MJ at 200 M on day 7. This study illustrates the usefulness of flow cytometry for obtaining culture population information and the value of using intact single cells for the study of plant metabolism.     

Subcellular fractionation of the Gram negative rumen bacterium, Butyrivibrio S2, by protoplast formation, and localisation of lipolytic enzymes in the plasma membrane

Treatment of the anaerobic, Gram negative general fatty acid auxotroph Butyrivibrio S2 with lysozyme in low molarity buffers resulted in the formation of protoplasts, some of which retained the original rod-shaped morphology of the organism. The protoplasts were stabilised by the presence of Mg²⁺ ions. Most of the phospholipase A and C and galactolipase activity of the cells was retained by the protoplasts. Electron microscopy and chemical markers were used to monitor the separation of plasma membrane and cell wall fragments by density gradient centrifugation after osmotic lysis of protoplasts. Phospholipase and galactolipase activities were demonstrated in a subcellular fraction which contained only fragments of plasma membrane.     

Fine Structure of Listeria monocytogenes in Relation to Protoplast Formation

Among the eight strains of Listeria monocytogenes tested for lysozyme sensitivity, two were resistant to lysozyme but became sensitive after lipase pretreatment. Among the other six, one was very sensitive to lipase and another one was extremely susceptible to lysozyme. Stable protoplasts were formed from the lysozyme-resistant strain (42) by lipase and lysozyme treatment, which completely digested the cell wall. The cell wall (uranyl acetate-lead stained) was of a thick triple-layered profile, with the intermediate layer of low density. Lipase treatment for a short time (60 min) did not cause any alteration in structure, but prolonged treatment (180 min) caused extensive digestion of the plasma membrane and the cell wall, liberating cytoplasmic material. When the cells were treated with either lipase or lysozyme, a small number of protoplasts were extruded through the partly digested or weakened transverse cell wall, leaving an almost intact cell wall ghost. There were small vesicular structures in the interspace between cell wall and plasma membrane. Mesosomes of varied organization were prominent in electron micrographs, both in sections and in negatively stained preparations. These were largely everted during protoplasting in the form of tubules and as small peripheral buds; a few small vesicles also remained as intrusive structures, some of which were very unusual because they appeared to be enclosed by the inner layer of plasma membrane alone. Lysis of the protoplasts by dilution of the sucrose, while maintaining a constant ionic environment, liberated many small vesicular structures and fibrillar nuclear material.     

K plus-dependent deplasmolysis of a marine pseudomonad plasmolyzed in a hypotonic solution

When cells of a marine pseudomonad were washed with a solution consisting of 0.3 m NaCl, 0.05 m MgSO(4), and 0.01 m KCl (complete salts), they maintained their normal morphology. When washed with a solution of 0.05 m MgSO(4), they became plasmolyzed as indicated by both phase and electron microscopy. Suspensions of cells washed with 0.05 m MgSO(4) showed an increase in optical density (OD) when 0.3 m NaCl was added, and this was followed by a decrease in OD upon the further addition of 0.01 m KCl. Salts of other monovalent cations were not effective in replacing K(+) in producing the OD decrease. Phase-contrast microscopy revealed that the increase in OD was accompanied by a decrease in cell size, and the decrease in OD, by an increase in the cell size. Both phase and electron microscopy showed that the K(+)-dependent decrease in OD was accompanied by deplasmolysis of the cells. Na(+) was required in the suspending medium in addition to K(+) to obtain deplasmolysis. The intracellular K(+) concentration in cells which had been washed with complete salts and which had retained their normal morphology was found to be 0.290 m. In cells plasmolyzed by washing with 0.05 m MgSO(4), the intracellular K(+) concentration was 0.004 m. Deplasmolyzed cells contained 0.330 m K(+). The membrane profile of plasmolyzed cells was retained when protoplasts were formed. The protoplasts became spherical if incubated in a solution permitting the deplasmolysis of the parent cells. The evidence obtained indicates that plasmolysis and deplasmolysis under the conditions described was due to the loss and gain, respectively, of K(+) by the cells. The effect of Na(+) could be ascribed to its capacity to control the porosity of the cytoplasmic membrane of this organism.     

Facilitated protoplasting in certain auxotrophic mutants of Corynebacterium glutamicum

Summary Auxotrophic mutants of Corynebacterium glutamicum strain ATCC 13 059 showed considerable variation in their ability to form protoplasts when treated with lysozyme and ethylene-diaminetetraacetic acid (EDTA) following growth in nutrient medium containing up to 2% glycine. The proportion of protoplasts formed by the parent strain was normally 10 to 15% whereas certain amino-acid auxotrophs formed protoplasts at much higher frequencies (>95%). There was no obvious correlation between the presence of specific auxotrophic markers or the number of rounds of mutagenesis and protoplasting ability. Strains which were most readily protoplasted were morphologically distinct from other auxotrophs and the parent strain but were similar to the parent strain in their sensitivity to lysozyme. However, isoleucine auxotrophs were more sensitive to penicillin G. All strains produced osmotically sensitive cells (lysed by dilution in water) after growth in glycine-containing media and lysozyme-EDTA treatment. These damaged cells could be distinguished from true protoplasts by their ability to recover on osmotically non-protective media if diluted in high osmotic pressure buffers. Protoplasts were regenerated on an osmotically protective medium (ET) in 48 to 72 h, at frequencies averaging 50–60%.     

Optimal Cultural and Physiological Conditions for Handling Streptomyces rimosus Protoplasts

A general procedure for manipulating protoplasts of three Streptomyces rimosus strains was developed. More than 50% regeneration efficiency was obtained by optimizing the osmotic stabilizer concentrations and modifying the plating procedure. Preparation and regeneration of protoplasts were studied by both phase-contrast and electron microscopy. After cell wall degradation with lysozyme, protoplasts about 1,000 to 1,500 nm in diameter appeared. The reversion process exhibited normal and aberrant regeneration of protoplasts to hyphae and to spherical cells, respectively. Spherical cells contained no alpha, epsilon-ll-diaminopimelic acid and were colorless or red after Gram staining. They showed consistent stability during at least five subsequent subcultivations. However, the omission of glycine from the precultivation medium reduced the unusual process of regeneration almost completely. After normal protoplast regeneration, the production of oxytetracycline by single isolates was not affected.     

The influence of sucrose, 2,4-D,and kinetin on the growth,fine structure,and lignin content of cultured sycamore cells

Summary When suspensions of sycamore cells are cultured in a synthetic medium containing 1.0 mg/l 2,4-D and 0.25 mg/l kinetin, maximum cell yield is obtained with an initial concentration of 6 per cent sucrose. There is a progressive increase in dry weight per cell, decline in extractive-free weight as a percentage of cell dry weight and increase in lignin content per cell as the initial sucrose concentration is increased from 1 per cent to 15 per cent. The percentage of lignin in the extractive-free cell residue is further enhanced by increasing the level of 2,4-D to 10 mg/l or by growing the cells in an auxin-free medium containing 10 mg/l kinetin.When the cell suspensions are treated with phloroglucinol/HCl it is found that only a proportion of the cells contain lignin, that this lignin occurs in the protoplasts and in plates between the cells, and that lignin is present in the culture medium.Electron micrographs confirmed the absence of any secondary wall such as is characteristic of tracheary elements. Cells cultured in the presence of 6 per cent sucrose or higher levels showed numerous amyloplasts and frequently the presence of electron opaque material. This occurs in the irregular but not frequent wall thickenings, as droplets in the vacuoles and as amorphous sheets between the cells. Pictures showing such electron opaque droplets clustered on the inner face of the tonoplasts suggest that this material is formed in the cytoplasm and released into the vacuoles. In addition these cells are characterised by the presence of fine electron opaque granular material in their vacuoles and external to their protoplasts. Cultures richest in lignin showed the highest content of electron opaque globules in, and amorphous sheets between, the cells and it is suggested that these correspond to lignin or a lignin-hemicellulose complex. In the presence of 15 per cent sucrose many cells showing breakdown of organised structure were observed; they were characterised by the persistence of mitochondria and particularly of the amyloplasts and by their high content of the electron opaque material equated with lignin. This material was also present in the dead cells.     

O-acetyl-salicylic acid promotes colony formation from protoplasts of an elite maize inbred

The salicylic acid derivative acetylsalicylic acid (ASA) was found to promote colony formation from protoplasts isolated from embryogenic suspension cultures of an elite maize inbred line. The drug was most effective at concentrations of 30–100 mg/l, and increases of more than 20-fold in the number of colonies recovered from protoplasts were obtained. The rate of growth of protoplast-derived cell colonies was not affected.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - DMSO dimethylsulfoxide - KM Kao and Michayluk medium (1975) - MES 2[N-morpholino]ethanesulfonic acid - ASA acetylsalicylic acid     

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.     

Development and Characterization of a Nonmorphogenetic Cell Line of Wheat (Triticum aestivum)

This study was conducted to compare characteristics of a wheat (Triticum aestivum L.) cell line to those of the maize (Zea mays L.) black Mexican sweet (BMS) cell line and to compare protoplasts isolated from suspension cells of these cell lines. The wheat cell line was established from immature-embryo derived callus of the experimental line ‘ND7532’ and was conditioned for growth in suspension culture. For both cell lines, measurements of packed cell volume (PCV), fresh weight (FW), and dry weight (DW) were taken at 3 day intervals from suspension cultures. Measurements of FW of calluses cultured from suspension cells of both cell lines were taken at 6 day intervals. The morphogenetic potential of the wheat ND7532 cell line was tested in both callus and suspension cultures using media promoting regeneration and/or organogenesis. Growth rates of ND7532 cells in suspension culture were comparable to those of BMS cells. However, relative growth rates of calluses recovered from ND7532 suspension cells were slower than those of calluses recovered from BMS suspension cells. The ND7532 cell line has very limited morphogenetic potential and has been maintained as rapidly growing callus tissue for 11 years. Yields of protoplasts from suspension cells of the two cell lines were comparable, though ND7532 protoplasts were typically smaller. The wheat cell line has is now designated ND7532-NM (nonmorphogenetic) and is available for cellular and molecular biology research.     

Optimum conditions for efficient transformation ofStreptomyces venezuelae protoplasts

Summary Optimum conditions for protoplast regeneration and transformation ofStreptomyces venezuelae ETH 14630 have been established. Protoplasts from mycelium grown to the stationary phase and treated with lysozyme in P medium under mild conditions gave the best regeneration frequency. Transformation of protoplasts with naked DNA was very efficient using either polyethylene glycol of mol. wt. 4000 or 6000, at concentrations of 28.5% or 36% (w/v) respectively. About 10⁵ transformants/g DNA could be isolated using protoplasts derived from cells cultivated to the early exponential growth phase in LB medium containing 0.2%-0.6% glycine and subsequently treated at 30°–32°C with 20 mg lysozyme/ml in P medium for 30 min. Selection of the transformants occurred on MRYE plates containing less than 10⁵ regenerating protoplasts per plate. Higher protoplast densities considerably decreased the regeneration frequency of the transformants.