Protoplasts fromPodospora anserina: Isolation,purification, and transformation

Protoplasts fromPodospora anserina mycelium were produced using the commercially available enzyme Novozym 234. Different parameters involved in protoplast isolation were analyzed in order to establish optimal conditions, and protoplast production was notably increased. For the purification of protoplasts, several techniques based on both centrifugation and filtration were assayed, with filtration yielding the best results. Regeneration of protoplasts was studied on different media and osmostic stabilizers, and about 80% regeneration was obtained. The good physiological condition of the protoplasts produced with this method is demonstrated by the lack of cell wall and high regeneration rate and transformation frequencies.     

A method for isolation of protoplasts from dermatophytes

A method has been developed to isolate protoplasts from dermatophytes using Novozym 234. A simple technique of flotation in MgSO4 has been adapted to separate protoplasts from incubation mixture. Electron microscopic studies confirmed the absence of cell wall material on these protoplasts. The recovery of DNA from protoplasts was higher than from mycelia.     

Optimal conditions for the release of protoplasts ofNeurospora using Novozym 234

The optimal conditions for the release of protoplasts from 18-h-hyphae ofNeurospora crassa using Novozym 234 were 120-minute incubations at 25°C and 10 mg/ml Novozym. Protoplasts were released from all parts of hyphae and were found not to contain surface-bound cell wall material. About 10% of Novozym-derived protoplasts were viable.     

Formation and regeneration of protoplasts of Sclerotium glucanicum

Summary Protoplast yields from Sclerotium glucanicum using Novozym 234 as the lytic enzyme were affected by the osmotic stabilizers selected, the incubation conditions used for wall degradation, and culture age. Scanning electron microscopic observations revealed that protoplast release from all hyphal regions gradually followed random wall attack, and nuclear staining showed that some protoplasts contained as many as eight nuclei. Their regeneration involved germ tube production on solid media, but formation of chains of buds and possibly cytoplasmic cleavage in liquid medium. Regenerated protoplasts gave similar exopolysaccharide yields to those of the parent culture.     

Production and regeneration of protoplasts from Cryptococcus

Protoplasts were quickly and efficiently produced from both varieties of Cryptococcus neoformans and from C. laurentii by use of the multi-enzyme product Novozym 234. Conditions for regeneration of protoplasts are described. DNA yield from the Novozym-produced protoplasts was superior to that from snail gut enzyme-derived protoplasts.     

Lipase production by free and immobilized protoplasts of Sporotrichum (Chrysosporium) thermophile Apinis

Summary Production of lipase by free and alginate-entrapped protoplasts was studied in batch culture. Cell-wall-degrading enzymes Novozym 234 and cellulase CP improved lipase secretion of normal mycelium by 25%–100%. The protoplast-regenerated mycelium exhibited several-fold higher lipase activity in batch replacements in TRIS buffer over normal spore-derived mycelium. The specific lipase activity of immobilized protoplasts was about four times higher than normal mycelial beads. Protoplasts beads were stable and retained high enzyme activity even after three buffer replacements lasting 120 h; TRIS buffer was better than acetate or normal glucose medium. A minimum of 8 h regeneration period was necessary for lipase synthesis. Triolein, olive oil, tributyrin and oleic acid butylester were able to induce lipase in immobilized protoplasts. Tween 80 enhanced lipase activity of the immobilized protoplasts. Partially degraded immobilized mycelium was nearly as effective as normal immobilized protoplasts for lipase secretion. Both free and immobilized protoplasts could be reused for up to 200 h with some loss in enzyme activity.     

Production and regeneration of protoplasts from the mycorrhizal fungus Suillus granulatus

Experiments were performed with the mycorrhizal fungus Suillus granulatus to define the parameters for production and regeneration of protoplasts. Protoplasts were released at frequencies between 1 and 3×10⁷/ml from mycelium 3 to 7 days old. The best osmotic stabilizer for protoplast release was MgSO₄ (0.7 m). To optimize protoplast release and regeneration an enzyme (Novozym 234) concentration 1.7 mg/ml was chosen, with a digestion time of 1 to 2 h. Regenerated colonies formed mycorrhizae within 60 days after inoculation in Pinus caribaea var. hondurensis seedlings.     

The isolation and regenaration of protoblast from Lipomyces starkeyi: an oleaginous yeast

The isolation and regenration of prostoplasts from Lipomyces starkeyi have been optimised. Snail enzyme (12 mg·ml⁻¹) proved to be the most effective lytic enzyme although treatment with Novozym 234, Cellulase CP and β-glucanase also resulted in protoplast formation. Magnesium sulphate (0.55 M) was shown to be the best fro protoplast isolation. Exponential phase cells were most susceptible to the lytic enzyme, stationary phase cells appeared to be resistant. 2-Mercaptoethanol or dithiothreitol did not enahance the isolation of protoplasts in this yeast. The optimum pH for protoplast isolation was 5.8. Ultrastructural observations were made on cells during lytic digestion and revealed that the cell wall and capsule are stripped away from the protoplast.Protoplast synthesised new cell wall material when cultured on osmotically stabilised medium, regeneration was not oberved in liquid medium. Optimum regeneration occured when protoplasts were embedded in a thin layer of minimal medium osmotically stabilised with mannitol (0.6M) and solidified with 1.5–2.0% agar. A basal layer of medium was also stabilised with mannitol (0.6 M) but contained 3% agar. The lytic enzyme used for protoplast isolation did not appear to effect the regeneration of protoplasts.     

Production of carotenoids by protoplasts of the fungus Acremonium diospyri

Protoplast yields from the fungus Acremonium diospyri, prepared using Novozym 234, were affected by culture age, osmotic stabilizer and its concentration, and incubation time. Protoplasts were released by extension through pores in small hyphal fragments produced by enzyme action on the mycelium, and regeneration was similar to that reported for other fungi. Stabilized protoplasts were shown to synthesize carotenoids on exposure to light, but their carotenoid composition differed from that of mycelium incubated under the same conditions.     

Assembly of the protoplasm of Codium fragile (Bryopsidales, Chlorophyta) into new protoplasts

The cell organelles of the coenocytic alga Codium fragile (Sun) Hariot aggregated rapidly and protoplasts were formed when its protoplasm was extruded out in seawater. Continuous observation showed that there were long and gelatinous threads connecting the cell organelles. The threads contracted, and thus the cell organelles aggregated into protoplasmic masses. The enzyme digestion experiments and Coomassie Brilliant Blue and Anthrone stainings showed that the long and gelatinous threads involved in the formation of the protoplasts might Include protein and saccharides as structure components. Nile Red staining Indicated that the protoplast primary envelope was non-lipid at first, and then lipid materials Integrated Into its surface gradually. The fluorescent brightener staining Indicated that the cell wall did not regenerate in the newly formed protoplasts and they all disintegrated within 72 h after formation. Transmission electron microscopy of the cell wall of wild C. fragile showed electron-dense material embedded in the whole cell wall at regular intervals. The experiments indicated that C. fragile would be a suitable model alga for studying the formation of protoplasts.     

Protoplasts formation inFusarium species

Formation of protoplasts from four species ofFusarium genus is described. Protoplasts were isolated from mycelium by enzymatic digestion of the cell wall in the presence of an osmotic stabilizer. The results obtained differed between the studied species. Best yields of protoplasts were obtained fromF. moniliforme (90 % cells as protoplasts).     

Regeneration and molecular characterization of an intergeneric hybrid between Graphium putredinis and Trichoderma harzianum by protoplasmic fusion

The fungal strains Graphium putredinis and Trichoderma harzianum were selected as parents for fusant development. Protoplasts were isolated using the combination of lysing enzymes Novozym 234 and cellulase with 0.6 M KCl as osmotic stabilizer. The optimum conditions for release of viable protoplasts from the fungal mycelium viz. age of the mycelium, lytic enzymes, osmotic stabilizers, pH, incubation period and regeneration medium were determined. Intergeneric protoplast fusion was carried out using 50% polyethylene glycol with calcium chloride (CaCl₂) and glycine buffer and the conditions for effective protoplast fusion, viz. fusogen, osmotic stabilizer, pH, incubation period and regeneration medium were optimized. At optimum conditions, the regeneration frequency of the fused protoplasts on potato dextrose agar (PDA) medium and fusion frequency were calculated. The regeneration frequency on non-selective (PDA) and selective media (PDA amended with starch) was determined for the parental and fusant strains in which, fusant showed a higher rate of regeneration. Fusant formation was confirmed by morphological markers (colony morphology and spore size and shape) and genetical markers like, mycelial protein pattern, restriction digestion pattern and random amplified polymorphic DNA (RAPD) analysis. The efficiency of these parental strains and their intergeneric fusant in the production of hydrolytic enzymes – amylases (treatment plant for sago factory effluent), cellulases (bioethanol), xylanases (bleaching agents for waste paper pulp) and proteases (additives in commercial detergents) – have probable applications in various industrial processes.     

Preparation and Regeneration of Mycelial Protoplasts of Alternaria eichhomiae

Preparation and regeneration of mycelial protoplasts from Alternaria eichhorniae were examined. A commercially available muralytic enzyme, Novozym 234, was used for isolation of protoplasts. The mycelial age and the pH of the stabilized buffer affected the formation of protoplasts. The maximum production of protoplasts (3,9 × 10⁸/g fresh weight mycelia) was obtained from 24-h-old mycelia digested with Novozym 234 (20 mg/ml) in a stabilized buffer of pH 6.4 and incubated in the dark at 30°C on a rotary shaker (90 r.p.m.) for 6 h. Morphological characteristics of the protoplasts varied and depended on the age of the mycelia used in protoplast production. Moreover, mycelial age had a highly significant influence (P = 0.0001) on the frequency of protoplast regeneration.     

Optimization of protoplast formation,regeneration, and viability in Microsporum gypseum

Factors affecting high yields, regeneration frequencies, and viability of protoplasts from clonal cultures of Microsporum gypseum were investigated. Maximum yields of protoplasts were obtained after 6 hrs digestion of 2–4 days old mycelium with Novozyme 234 using CaCl₂ (0.4 M) as an osmotic stabilizer and glycine + HCl (pH 4.5) as the buffer system. Mercaptoethanol + dithiothreitol (0.01 M) proved to be the best pretreatment of mycelium prior to digestion with enzyme. A regeneration frequency of 94.4% was obtained using the top agar method with complete medium (pH 6.5) containing 0.5% agar and 0.4 M CaCl₂ as an osmoticum. Colonies from regenerated protoplasts on medium containing CaCl₂ were pigmented and completely powdery with high sporulation. Protoplast viability was studied in osmotic stabilizer supplemented with glucose or glutamine. After 24 hrs, glucose (2%) and glutamine (2%) enhanced protoplast viability by 22% and 23%, respectively. Protein synthesis, as measured by ³H-lysine uptake, matched the viability profile determined by fluorescence microscopy.     

Protoplasts of Pyricularia oryzae P2 : Preparation and Regeneration into Hyphal Form

Protoplasts of Pyricularia oryzae P₂, a rice blast mold, were prepared in high yield from the young mycelium of the fungus using lytic enzymes from Bacillus circulans WL 12. The majority of the protoplasts had one nucleus per cell. The protoplasts formed a cell wall and eventually reverted to normal mycelial form in liquid medium. The process of regeneration was studied under phase-contrast and electron microscopes. The protoplast built a very thick wall prior to the protrusion of a germ-tube like hypha. Golgi apparatus-like structures appeared in the early stage of regeneration and disappeared later. Electron-transparent amorphous structures accumulated during regeneration. Lomasomes were observed in the regenerated cell walls.     

Protoplast formation from submerged mycelium and from spore germinants of Streptomyces coelicolor

Stages in the formation of protoplasts from S. coelicolor strain A3(2) have been studied by transmission electron microscopy. Protoplasts liberated from submerged mycelial growth were variable in size and were released when digestion of the cell wall by lysozyme had completely or almost completely taken place. Protoplasts did not fully adopt the typical rounded shape until after release. A single region of cytoplasm gave rise to more than one protoplast unit. Protoplasts released from spore germinants escaped from the tip of the germ tube, which was the region of the cell wall most susceptible to digestion. Protoplasts derived from spore germinants were more consistent in size and rounded up more rapidly. If a cross-wall had formed in a germinant then it gave rise to separate protoplasts from each cellular compartment. Protoplasts of either type contained a single DNA region. These studies give an indication of the cellular organization of a streptomycete colony, which can be visualized as a multinucleated assemblage of cellular units in a common cytoplasm. The assembly of units separates into a number of protoplasts on digestion of the cell wall.     

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 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.     

Degradation of lignin and lignin related compounds by protoplasts isolated from Fomes annosus

Protoplasts from a lignolytic fungus Fomes annosus were prepared through enzymatic hydrolysis of mycelium utilizing Novozym, a wall lytic enzyme preparation. Isolated protoplasts and living mycelium were compared in their ability to degrade ¹⁴C-labelled lignin related phenols and dehydropolymers of labelled coniferyl alcohol (synthetic lignin). The amounts of ¹⁴CO₂ released from O¹⁴CH₃-groups, ¹⁴C-2-side chains and ¹⁴C-rings by protoplasts was in the same range as those for intact mycelium. The methoxyl groups of synthetic lignin were more rapidly metabolized by protoplasts than by mycelium. When calculated in dpm of released ¹⁴CO₂ per mg protein the decomposition of ¹⁴C-labelled synthetic lignin and lignin-related monomers in a hyphae-free system of protoplasts was considerable higher than that obtained by the intact mycelium. The presence of intact hyphae is thus not necessary for lignin degradation to occur.Non-common-abbreviations used DHP Dehydropolymer of coniferyl alcohol - LS lignosulfonates prepared from DHP     

Mycelial protoplast isolation and regeneration of Lentinus lepideus

Generation of fungal protoplast is essential for fusion and transformation systems. Protoplast fusion offers great potential for the improvement of industrially important microorganisms. To establish conditions for the protoplast isolation and regeneration of the mycelia of Lentinus lepideus, various enzymes and osmotic stabilizers were examined. To investigate suitable medium for the culture of L. lepideus, the mycelia were grown in ten different media at 28 degrees C for 10 days. Among them potato dextrose agar (PDA) medium was found to be the best for colony growth. When Novozym 234, cellulase and beta-glucuronidase were added to the mycelia in combination or alone, Novozym 234 alone at the concentration of 10 mg/ml was the most effective for the protoplast yield. Purified spherical protoplasts of the mycelia were osmotically hypersensitive and further incubation of the mycelia with the lytic enzyme resulted in the older parts of the hyphae swollen. When we applied various osmotic stabilizers at the fixed concentration of 0.6 M on the protoplasts, the yields of protoplasts were increased until 4-hr incubation. However application of sucrose or MgSO4 led to further protection of protoplasts after that time and reached a plateau on 5- and 7-hr incubations, respectively. The suitable incubation time and optimal pH with the lytic enzyme for the maximum release of protoplasts were 6 hrs of incubation and pH 5, respectively. When we examined various osmotic stabilizers for the regeneration of the protoplast, the complete medium containing 0.6 M sucrose induced highest hyphal growth with regeneration frequency of 3.28%.