An electron microscopic study of antagonism between cephalexin and erythromycin in Staphylococcus aureus.

This study concerns investigations at the cellular level of antagonism between cephalexin (CEX) and erythromycin (EM) with the aid of electron microscopes and a liquid scintillation counter. Exposure of Staphylococcus aureus 209-P to CEX and EM in combination was found to result in a marked antagonism between the two antibiotics in their effects on the growth of the organism. Observations under a scanning electron microscope revealed lysed cells in the presence of CEX alone but almost no lysis in the presence of a combination of CEX and EM. Observations under a transmission electron microscope, on the other hand, disclosed that nearly all of the cells exposed to 20 mug/ml of CEX were transformed into protoplasts with their morphological changes being most marked after 4 hr of exposure. When 1 mug/ml of EM was allowed to act alone, this exposure resulted in thickening of the cell walls. The combined use of CEX and EM, however, resulted in neither thickening of the cell walls as in the presence of EM alone nor in the formation of protoplasts as in the presence of CEX alone but merely produced the swelling of separating walls. Cellular uptake of 14C-L-lysine and N-acetylglucosamine-1-14C into the cell wall fraction and the protein fraction was affected by CEX and EM, respectively, when used alone or in combination.     

Cell Wall Synthesis in Staphylococcus aureus in the Presence of Protein Synthesis Inhibitory Agents

Electron-microscopic and biochemical studies on morphological changes in Staphylococcus aureus following exposure to protein synthesis inhibitory agents such as lincomycin (LCM), clindamycin (CLM), erythromycin (EM), and spiramycin (SP) are presented in this paper. It was demonstrated that bacterial cell walls became extremely thickened usually with the formation of multilayers, when exposed to each of the above-mentioned antibiotics. Furthermore, electron density of the cytoplasm was higher in those cells exposed to drugs than in intact control cells. Incorporations of ¹⁴C-labeled l-lysine into the cell-wall fraction and the protein fraction were measured for biochemical elucidation of these phenomena. Labeled lysine was selectively incorporated into the cell-wall fraction when the test organism was exposed to the respective antibiotics. Uptake at 15 min after exposure was about twice as large as that of intact control cells. SP and CLM inhibited protein synthesis while they stimulated cell-wall synthesis. The evidences for thickening of, and formation of multilayers in the bacterial cell walls following exposure to drugs were closely related to the stimulating action of these antibiotics on the cell-wall synthesizing system. Morphology of resistant clinical isolates following such antibiotic exposure was also investigated using two staphylococcal strains, one resistant to EM alone and the other completely cross-resistant to all the macrolides.     

The effect of triadimenol on the cytology and growth of sensitive and resistant strains of Ustilago avenue

Two triazole resistant mutants of Ustilago avenae and a wild type strain were treated with different concentrations of the fungicide triadimenol in liquid cultures. Growth rates were measured and the morphology of the sporidia examined by light and electron microscopy. After treatment with 1 – 10 μg ml^-1 for 4 days wild type sporidia increased in growth rate, changed from budding to filamentous growth and had considerably thicker cell walls. Their cytoplasm also showed strong degeneration and damage to the cell organelles. The resistant strains were not influenced under these conditions but under longer exposure (14 days) to higher fungicide concentrations (50 to 200 μg ml^-1) similar changes to growth rates, morphology and cell wall thickness also occurred. However, cell disruption only occurred at 200 to 250 μg triadimenol ml^-1 and there were differences in cell wall thickening. One resistant strain (r13) never showed thickening, while in the other (r8), the wall consisted of two distinct layers. The implications of these results are discussed in relation to possible resistance mechanisms.     

THE LABELING OF CULTURED CELLS OF ACER WITH [14C]PROLINE AND ITS SIGNIFICANCE

The distribution of the radioactivity from [¹⁴C]proline that is bound in cultured cells of Acer has been determined by electron microscope autoradiography. In this way proline may be related to the cell wall as a morphological entity rather than as a fraction in a biochemical separation of a heterogeneous crop of cells. The cells in culture may vary greatly. Some are active growing, turgid cells, with thin protoplasts tightly pressed against their walls; in others the protoplasts may spontaneously withdraw from the wall; in still others the protoplasts disorganize, and walls thicken and become sculptured as the cells differentiate and even senesce. Different culturing practices may affect the status of the cells, and this, in turn, affects the distribution of radioactivity from proline in the cells. Cells which are actively growing, turgid, and nucleated have the highest grain density in their protoplasts and nuclei; as the protoplasts of such cells withdraw from their walls, they retain the bulk of the radioactivity. On the other hand, in cells which have thickened walls and sparse protoplast contents, the radioactivity is accumulated in their walls. A high content of proline and hydroxyproline-rich protein is, therefore, not a necessary or invariable feature of the cell walls of cultured Acer cells but depends on the state of development of these cells.     

Modulation of photosynthesis and respiration in guard and mesophyll cell protoplasts by oxygen concentration

Stomatal movement is an energetic oxygen-requiring process. In the present study, the effect of oxygen concentration on mitochondrial respiratory activity and red-light-dependent photosynthetic oxygen evolution by Vicia faba and Brassica napus guard cell protoplasts was examined. Comparative measurements were made with mesophyll cell protoplasts isolated from the same species. At air saturated levels of dissolved oxygen in the protoplast suspension media, respiration rates by mesophyll protoplasts ranged from 6 to 10μmoles O₂ mg^?1 chl h^?1, while guard cell protoplasts respired at rates of 200–300 μmoles O₂ mg chl^?1 h^?1, depending on the species. Lowering the oxygen concentration below 50–60 mmol m^?3 resulted in a decrease in guard cell respiration rates, while rates by mesophyll cell protoplasts were reduced only at much lower concentrations of dissolved oxygen. Rates of photosynthesis in mesophyll cell protoplasts isolated from both species showed only a minor reduction in activity at low oxygen concentrations. In contrast, photosynthesis by guard cell protoplasts isolated from V. faba and B. napus decreased concomitantly with respiration. Oligomycin, an inhibitor of oxidative phos-phorylation, reduced photosynthesis in mesophyll cell protoplasts by 27–46% and in guard cell protoplasts by 51–58%. The reduction in both guard cell photosynthesis and respiration following exposure to low oxygen concentrations suggest close metabolic coupling between the two activities, possibly mediated by the availability of substrate for respiration associated with photosynthetic electron transport activity and subsequent export of redox equivalents.     

Comparison of cell wall regeneration on maize protoplasts isolated from leaf tissue and suspension cultured cells

Summary The cell wall regeneration on protoplasts derived from maize mesophyll cells was compared with wall regeneration on protoplasts derived from suspension cultured cells using light microscopy, transmission electron microscopy, and mass spectrometry. The time course of cell wall regeneration has shown that the mesophyll protoplasts regenerated walls much slower than the protoplasts derived from cultured cells. Moreover, cell wall materials on the mesophyll protoplasts were often unevenly distributed. Electron microscopy has further demonstrated that the mesophyll protoplasts have less organized and compact walls than the protoplasts from cultured cells. Chemical analysis revealed that the mesophyll protoplasts had a lower ratio ofβ-(1–3)-glucan toβ-(1–4)-glucan than protoplasts from cultured cells. The significance of these results for the viability and development of protoplasts in culture is discussed. National Research Council of Canada paper no. 32458.     

Protoplast isolation and regeneration from <Emphasis Type="Italic">Gracilaria changii</Emphasis> (Gracilariales,Rhodophyta)

The tropical agarophyte Gracilaria changii has been much researched and documented by the Algae Research Laboratory, University of Malaya, especially with regards to its potential as a seaweed bioreactor for valuable compounds. Protoplast regeneration of this seaweed was developed following the optimization of protoplast isolation protocol. Effect of the concentration and combination of isolating enzymes, incubation period, temperature, enzyme solution pH, tissue source on the protoplast yields were used to optimize the isolation protocol. The enzyme mixture with 4% w/v cellulase Onozuka R-10, 2% w/v macerozyme R-10 and 1 unit mL^-1 agarase was found to produce the highest yield of protoplast at 28°C and 3 h incubation period. Thallus tips gave higher yields of protoplasts than middle segments. Freshly isolated G. changii protoplasts were cultured in MES medium. Regeneration of protoplast cell walls after 24 h was confirmed by calcofluor white M2R staining under UV fluorescence microscopy. The protoplasts with regenerated cell walls then underwent a series of cell division to produce callus-like cell masses in MES medium. Following this, juvenile plants of G. changii were obtained.     

PREPARATION AND CHARACTERIZATION OF PROTOPLASTS OBTAINED FROM THE PRASINOPHYTE SCHERFFELIA DUBIA (CHLOROPHYTA)1

The prasinophyte genera Scherffelia and Tetraselmis are the only genera that form a cell wall by an extracellular fusion of scales called a theca. We established a protocol for the production of protoplasts from Scherffelia dubia Pascher emend. Melkonian et Preisig using 3 mM Ellman's reagent (5,5′‐dithio‐bis‐2‐nitrobenozoic acid [DTNB]). Protoplasts analyzed by EM lacked flagella and thecae but were otherwise similar to control cells. In response to treatment with DTNB, many protoplasts synthesized new thecal scales in the Golgi apparatus, indicating that cells attempted to regenerate new cell walls. However, complete regeneration of the thecae only occurred once DTNB was washed out from the medium. At higher DTNB concentrations (5 mM), two protoplasts were found within the parental cell wall and scales accumulated between the plasma membrane of the protoplasts and the original theca but failed to form a new theca.     

Protoplasts of Gelidium robustum (Rhodophyta)

Viable protoplasts were isolated from apices of the agarophyte Gelidium robustum (Gardn.) Hollenb. & Abb. using a combination of commercial cell-wall degrading enzymes and extracellular wall-degrading enzymes isolated from a marine bacterium. The protoplasts were approximately 8–15 µm in diameter, liberated mainly from the surface cell layers and from cells at the distal ends of medullary filaments. The bacterial enzyme alone was not sufficient to liberate significant numbers of protoplasts. Maximum yield was 9 × 10⁵ protoplasts/g tissue (wet wt.). Optimum osmolality occurred between 1750–1950 mOs kg^–1; yield and viability were severely diminished at osmolalities less than 1350 mOs kg^–1. Viability, as determined by flurorescein diacetate staining and Evans Blue exclusion 1 hr after removal from the enzyme solution, was approximately 80–95%. Roughly 80% of the cells did not show Calcofluor fluorescence, while 40% stained positively for the presence of sulfated polysaccharides. Cell wall regeneration was observed with inconsistent reproducibility, and no cell division was observed when the protoplasts were placed in culture medium.Dedicated to the memory of Professor Michael Neushul.     

Protoplast induction in Chlorella pyrenoidosa

Chlorella pyrenoidosa (UTEX 1230) cells in late log phase of growth were induced to form viable protoplasts by enzymatic digestion only when incubated in 2-deoxy-d-glucose (2DG) for 24 h. The combination of hemicellulase (4% w/v), Cellulysin (4% w/v), and glucuronidase (5% v/v) with 0.8 M mannitol and 8 mM CaCl₂ in modified Bristol's solution, was most effective for obtaining viable protoplasts as determined by light and electron microscopy, and vital staining with primuline (0.01% w/v). Resistance of cell walls to extensive extraction (acetolysis), and infrared analysis indicated that sporopollenin is a component of the cell wall. Transmission electron miscroscopy of acetolysed cell walls also allowed visualization of the laminate nature of the wall. This is the first report of successful induction of protoplasts from algae which contain sporopollenin in their cell walls.     

Scanning electron microscopy of cells and protoplasts ofSaccharomyces rouxii

Cells ofSaccharomyces rouxii from a normal broth culture were subjected to a high osmotic pressure (2 M KCl), fixed in 3% glutaraldehyde fortified with 2 M KCl, and then processed routinely for examination in a scanning electron microscope. Micrographs revealed birth and bud scars typical for the genus and an apparently undamaged surface topography. Protoplasts were prepared from the same material by digestion of cell walls with snail gut enzymes in the presence of 2 M KCl. Naked protoplasts were obtained and these exhibited surface invaginations. In addition, spheroidal protrusions were noted and these structures were equated with the periplasmic bodies previously described by transmission electron microscopy. The propensity for periplasmic body formation inSaccharomyces rouxii is contrasted with otherSaccharomyces species and the circumstantial evidence that relates periplasmic bodies to cryptic β-fructofuranosidase inS. rouxii is briefly discussed.     

Production of protoplasts from Fusarium scirpi by lytic enzymes from Streptomyces tsusimaensis

Summary The ability of serveral strains of Streptomyces to degrade cell walls from Fusarium scirpi was tested by plating them on agar containing a cell wall preparation derived from the fungus. In this assay, S. tsusimaensis was most effective in producing a clear zone of lysis during growth on the opaque medium. This Streptomyce strain was subsequently grown in liquid culture containing cell walls as the sole carbon source and the exoenzymes were isolated from the culture broth. The enzyme preparation produces a clear zone of lysis when filled into wells in the cell wall agar and was used to prepare protoplasts from F. scirpi. The protoplast yield was 1x10⁹ protoplasts/ml of enzyme solution from 35 mg dry weight of Fusarium mycelium. Protoplasts could be regenerated at a frequency of up to 80%.     

Degradation of fungal cell walls taking into consideration the polysaccharide composition

Differences in polysaccharide composition of various fungal cell walls were indicated by their susceptibility to enzymatic digestion. This information was used to optimize the enzymatic extraction of intracellular enzymes or the preparation of fungal protoplasts in high yield. Bacterial glucanase and chitinase specially purified were used for this study. Mycelium of Aspergillus niger grown on uric acid was treated with mixtures of glucanase and chitinase. Cell wall breakdown products were analysed and the ratio of chitin to glucan was estimated to be 1:1.4. A. niger protoplast formation was optimized using this information. When the mixture of chitinase to glucanase was 1:1.4, similar to the fungal cell wall composition, a 95% yield of protoplasts was obtained after 30 min and their mean size was 7 μm. However, a ratio of 1.5 to 1 (chitinase to glucanase) was needed for the maximum extraction of uricase. Yield was 10.5 μ g⁻¹cells after 1.5 h incubation at 28°C. Glucanase alone resulted in a maximum yield of 1.9 μ g⁻¹while chitinase alone yielded 6.0 μ g⁻¹under the same conditions.     

Gene Transfer to Lentil Protoplasts by Lipofection and Electroporation

Abstract

Cationic liposomes made of dipalmitoylphosphatidylcholine and stearylamine (9:1) were prepared by reverse-phase evaporation and were able to interact spontaneously with plasmid DNA. The loaded vesicles delivered a β-glucuronidase (GUS)-carrying plasmid to lentil Lens culinaris) protoplasts, leading to transient expression of the GUS reporter gene. The transfection efficiency achieved by using stearylamine-containing liposomes (lipofection) was comparable to the one obtained by electroporating the protoplasts at 500 μF and different field strengths. Furthermore, the combination of electroporation and lipofection, though reducing cell survival, increased the activity of the reporter enzyme detected in the cell lysates, yielding transient expression levels higher than those recorded after lipofection or electroporation alone.     

Characterization of chitin and chitin synthase from the cellulosic cell wall fungusSaprolegnia monoi¨ca

The presence of chitin in hyphal cell walls and regenerating protoplast walls ofSaprolegnia monoi¨ca was demonstrated by biochemical and biophysical analyses. α-Chitin was characterized by X-ray diffraction, electron diffraction, and infrared spectroscopy. In hyphal cell walls, chitin appeared as small globular particles while cellulose, the other crystalline cell wall component, had a microfibrillar structure. Chitin synthesis was demonstrated in regenerating protoplasts by the incorporation of radioactiveN-acetylglucosamine into a KOH-insoluble product. Chitin synthase activity of cell-free extracts was particulate. This activity was stimulated by trypsin and inhibited by the competitive inhibitor polyoxin D (K_i 20 μM). The reaction product was insoluble in 1M KOH or 1M acetic acid and was hydrolyzed by chitinase into diacetylchitobiose. Fungal growth and cell wall chitin content were reduced when mycelia were grown in the presence of polyoxin D. However, hyphal morphology was not altered by the presence of the antibiotic indicating that chitin does not seem to play an important role in the morphogenesis ofSaprolegnia.     

Protoplast induction from sporophyte tissues of the heterosporous fern Azolla

We have developed a method for producing protoplasts from the heterosporous water fern Azolla using a combination of Cellulysin (4.0%) and Pectolyase (0.025%) in 0.6 M mannitol containing 6 mM CaCl₂ 2H₂O. These protoplasts regenerate new cell walls within 48 hours when cultured on modified Gamborg B-5 medium.     

DEVELOPMENTAL STUDIES IN PORPHYRA (RHODOPHYCEAE). III. EFFECT OF CULTURE CONDITIONS ON WALL REGENERATION AND DIFFERENTIATION OF PROTOPLASTS1

Protoplasts isolated from thalli of four Porphyra species regenerated successfully into differentiated plantlets. The efficiency of protoplast isolation and the developmental patterns of the regenerating protoplasts depended on the type of tissues from which they were isolated. However, culture conditions greatly influenced the patterns of development at the cellular and organismal levels. Sorbitol, nitrogen, and agar concentration in the medium controlled rates of cell division, thickening of cell walls, development of rhizoids, and formation of calluses or differentiated blades. Agitation disturbed the attachment of the protoplasts to a substrate. Cells in agitated cultures produced suspensions of single cells and non-polarized small calluses. Calluses which developed from protoplasts survived in storage for over two years. The stored calluses, and cells and protoplasts that were isolated from them, were subcultured successfully. We forsee extensive use of Porphyra cell suspensions for strain selection and vegetative propagation of cultivars. This technology, which makes vegetative cloning of selected Porphyra plants possible, may eliminate the need for cultivation and storage of the conchocelis phase. Protoplasts are also being used as tools for studies in genetic engineering of these commercial species.     

Transglutaminase-like activity participates in cell wall biogenesis in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Transglutaminases (TGases) catalyze the cross-linking between protein molecules by formation of an amide bond between γ-carboxyamide group of glutamine and the ε-amine group of lysine under deamination of glutamine. We have demonstrated the participation of transglutaminase-like activity in the isolated cell walls and in the process of cell wall regeneration in protoplasts of the yeast Saccharomyces cerevisiae. A radioactive TGase substrate [³H]putrescine was incorporated into the isolated cell walls and into the TCA-insoluble fraction in regenerating protoplasts. The incorporation was increased by adding exogenous artificial substrate of TGase N,N’-dimethylcasein and was inhibited by TGase inhibitor cystamine and/or EDTA. These results suggest the existence of a TGase-type reaction involved in the formation of covalent cross-links between glycoprotein molecules during cell wall construction in S. cerevisiae.     

Block-Surface Staining for Differentiation of Starch and Cell Walls in Wheat Endosperm

A staining technique for differentiating starch granules and cell walls was developed for computer-assisted studies of starch granule distribution in cells of wheat [Triticum aestivum L.] caryopses. Blocks of embedded caryopses were sectioned, exposing the endosperm tissue, and stained with iodine potassium iodide (IKI) and Calcofluor White. Excessive tissue hydration during staining was avoided by using stains prepared in 80% ethanol and using short staining times. The IKI quenched background fluorescence which facilitated the use of higher concentrations of Calcofluor White. Cell wall definition was improved with the IKI-Calcofluor staining combination compared to Calcofluor alone. The high contrast between darkly stained starch granules and fluorescent cell walls permitted computer assisted analysis of data from selected hard and soft wheat varieties. The ratio of starch granule area to cell area was similar for both wheat classes. The starch granule sizes ranged from 2.1 μm³ to 22,000 μm³ with approximately 90% of the granules measuring less than 752 μm³ (ca. 11 μm in diameter). Hard wheat samples had a greater number of small starch granules and a lower mean starch granule area compared to the soft wheat varieties tested. The starch size distribution curve was bimodal for both the hard and soft wheat varieties. Three-dimensional starch size distribution was measured for four cells near the central cheek region of a single caryopsis. The percentage of small granules was higher at the ends than at the mid-section of the cells.     

Expanding the Symbiodinium (Dinophyceae,Suessiales) Toolkit Through Protoplast Technology

Dinoflagellates within the genus Symbiodinium are photosymbionts of many tropical reef invertebrates, including corals, making them central to the health of coral reefs. Symbiodinium have therefore gained significant research attention, though studies have been constrained by technical limitations. In particular, the generation of viable cells with their cell walls removed (termed protoplasts) has enabled a wide range of experimental techniques for bacteria, fungi, plants, and algae such as ultrastructure studies, virus infection studies, patch clamping, genetic transformation, and protoplast fusion. However, previous studies have struggled to remove the cell walls from armored dinoflagellates, potentially due to the internal placement of their cell walls. Here, we produce the first Symbiodinium protoplasts from three genetically and physiologically distinct strains via incubation with cellulase and osmotic agents. Digestion of the cell walls was verified by a lack of Calcofluor White fluorescence signal and by cell swelling in hypotonic culture medium. Fused protoplasts were also observed, motivating future investigation into intra‐ and inter‐specific somatic hybridization of Symbiodinium. Following digestion and transfer to regeneration medium, protoplasts remained photosynthetically active, regrew cell walls, regained motility, and entered exponential growth. Generation of Symbiodinium protoplasts opens exciting, new avenues for researching these crucial symbiotic dinoflagellates, including genetic modification.