Inhibitory protein controls the reversion of protoplasts and L forms of Bacillus subtilis to the walled state.

When the cell wall of Bacillus subtilis is removed by lysozyme and the resultant protoplasts are plated on hypertonic soft agar medium, each protoplast forms an L colony. L bodies from such L colonies again plate as L-colony-forming units (CFU). However, if protoplasts or L bodies are "conditioned" by 1 h of incubation in 0.4% casein hydrolysate medium and then incubated in 25% gelatin medium for 1 h, 60 to 100% of the formerly naked cells give rist to bacillary colonies. The present experiments largely explain the mechanism responsible for the "heritable" persistence of the wall-less state in B. subtilis. It is shown that protoplasts produce a reversion inhibitory factor (RIF) which blocks reversion when the cell concentration exceeds 5 x 105 CFU/ml. This inhibitor is nondialyzable and sensitive to trypsin, heat, and detergent. Efficient reversion at 2 x 107 CFU/ml is obtained if the protoplasts are treated with trypsin after conditioning and chloramphenicol is incorporated into the gelatin reversion medium. In the presence of 500 mug of trypsin per ml, the requirement for gelatin is sharply reduced, and reversion occurs rapidly in liquid medium containing only 10% gelatin. Trypsin also stimulates reversion in L colonies growing on soft agar. Latent RIF is activated by beta-mercaptoethanol. This reagent blocks reversion of protoplast suspensions at densities of 5 x 105 CFU/ml. Comparison of the autolytic behavior of B. subtilis and of the RIF revealed that several or the properties of the two activities coincide: both are inhibited by high concentrations of gelatin, both are activated by beta-mercaptoethanol, and both have high affinity for cell wall. Going on the assumption that RIF is autolysin, models for protoplast reversion is suggested by the finding that mutants with altered teichoic acid show altered reversion behavior.     

Experimental inhibition of cell wall formation and of reversion inNadsonia elongata andSchizosaccharomyces pombe protoplasts

Summary The growth, cell wall regeneration, and the reversion of the protoplasts ofNadsonia elongata andSchizosaccbaromyces pombe cultivated in nutrient media containing snail enzyme was studied by light and electron microscopy. The protoplasts grew in the presence of snail enzyme and an incomplete cell wall composed of fibrils was formed on their surface. Thus, the presence of snail enzyme inhibited the completion of cell wall structure and, consequently, the reversion of the protoplasts to normal cells. The transfer of these protoplasts to medium free from snail enzyme led first to the completion of the cell wall and then to the reversion of the protoplasts to normal cells. The reported experiments confirmed that the regeneration of the complete cell wall preceded the protoplast reversion.     

Gelatin-induced Reversion of Protoplasts of Bacillus subtilis to the Bacillary Form: Electron-microscopic and Physical Study

Protoplasts of Bacillus subtilis plated on SD medium form L colonies in quantitative yield and propagate in the L form indefinitely. L bodies or protoplasts placed in 25% gelatin medium form bacillary colonies. Details of the reversion of naked bodies to the walled form are reported. In 25% gelatin medium, reversion begins earlier (about 50% reversion in 4 hr) than the multiplication of bacilli. Thus, virtually all the observed bacillary forms are themselves revertants and not the offspring of a few growing clones. The optimal temperature for reversion is 26 C in 25% gelatin. When cells reverting at 26 C are warmed to 40 C for 3 min, reversion is delayed markedly, whereas viability is unaffected. For electron microscopy, a dense protoplast inoculum was placed on a gelatin surface, incubated, and then fixed in situ. There was no multiplication, but crowding delayed reversion markedly. Successive events of reversion are as follows. The loose nucleoid of the protoplasts condenses in response to the gelatin medium and condenses further and further as reversion proceeds. A thin coat of wall develops around the bodies of various sizes and shapes and then increases uniformly in thickness until a wall of normal aspect is formed. Rod-shaped cells grow out from these bodies-sometimes in several directions at once. A few mesosomes begin to appear only after a thin coat of wall has been formed. These are dense, atypical structures compartmented by membranes. They are located at the cell periphery and do not seem to be in contact with the nucleoids. Quantitative estimates showed that only 20 to 25% of revertant cells or cells grown on gelatin contain even a single mesosome. The others have no mesosome at all. Mesosomes thus do not appear to play a significant role in reversion, and normal mesosome functions must presumably be performed elsewhere in the cell in gelatin-grown bacilli. The role of cell wall, its synthesis, and its chemical nature in successive steps in reversion are discussed.     

Karyokinesis in growing and reverting protoplasts ofSchizosaccharomyces pombe

Division of nuclei without cytokinesis proceeds in growing protoplasts ofSchizosaccharomyces pombe. Prior to regeneration of the complete cell wall and reversion the protoplasts contain 1–7 nuclei, protoplasts with 1–2 nuclei are most frequent. When regeneration of the wall is postponed by adding snail enzymes to the growth medium, protoplasts with a higher number of nuclei (2–4) occur. Multinuclear protoplasts can revert to cells. During the first cytokinesis the protoplast with the regenerated cell wall is divided into two cells by a septum, distribution of nuclei between the two cells being probably incidental. More than only a single nucleus can pass to the revertants even during the second cytokinesis. Septation of protoplasts occurs also during a partial blockage of the wall formation by the snail enzyme preparation, however, reversion to cells can never be observed here (it occurs only after transfer of protoplasts to the medium without the enzyme preparation). The growing and reverting protoplasts represent a very good model system for studying relations among individual processes of the cell cycle, primarily growth of the cell, nuclear cycle and cytokinesis. Yeast protoplasts are often utilized as models for studying morphogenic processes, relations among regeneration of the cell wall, including division of the nucleus (karyokinesis) and cytokinesis.     

Protoplast fusion — a tool for genetic manipulation and breeding in industrial microorganisms

Protoplasts can be isolated from microbial cells by enzymatic digestion of the cell wall, in the presence of an osmotic stabilizer. Such protoplasts can be induced to fuse in the presence of agents such as the poly (ethylene glycols). When suitably selected auxotrophic strains are used, the fusion products can be recovered by selection on the basis of nutritional complementation. Cultivation of the protoplasts on a hypertonic growth medium induces regeneration of new cell wall material and their subsequent reversion to the normal cell form of the organism. The protoplast fusion technique has been applied sucessfully to both bacterial and fungal systems leading to the recovery of recombinant progeny. In the fungi, the recovery of non-parental segregants from inter-species crosses has also been demonstrated. In assessing the value of the fusion technique, caution may be necessary at this stage in its application to genetic mapping in bacteria. The behaviour of protoplasts, especially with respect to reversion, could be an additional factor that operates during selection, distorting recombination frequencies. However, the fusion technique, in providing a mechanism by which genetic recombination can be readily achieved, should be of great potential in empirical breeding and strain improvement. These aspects are reviewed.     

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.     

Gelatin-induced Reversion of Protoplasts of Bacillus subtilis to the Bacillary Form: Biosynthesis of Macromolecules and Wall During Successive Steps

Protoplasts of Bacillus subtilis plated on SDG medium formed L colonies in quantative yield and propagated in the L-form indefinitely. Protoplasts or L bodies placed in 25% gelatin medium formed bacillary colonies. Details of the reversion of these naked bodies to the walled form are reported here. Protoplasts prepared in minimal medium reverted fairly synchronously 3 to 4 hr after inoculation into gelatin, but protoplasts preincubated in casein hydrolysate (CH)-enriched minimal medium were primed to revert within 1 hr in the gelatin. Preincubation for 1.5 hr in 0.44% CH was required for good priming. Cells must be subjected to this preincubation (step 1) in the naked state; it is effective for L bodies as well as protoplasts. Priming was blocked by chloramphenicol, puromycin, and actinomycin D but was not affected by penicillin, lysozyme, or inhibition of deoxyribonucleic acid (DNA) synthesis. It is concluded that protein and ribonucleic acid (RNA) synthesis are required during step 1, that DNA synthesis is not required, and that wall mucopeptide is not made. The reversion of well-primed protoplasts in the gelatin (step 2) proceeded undisturbed in thymine-starved cells with chromosomes arrested at the terminus. It was scarcely slowed by chloramphenicol in the gelatin but was delayed about 3 hr by both puromycin and actinomycin D. Escape from inhibition occurred while the inhibitors were still actively blocking growth. Penicillin and cycloserine inhibited and lysozyme reversed reversion. Momentary melting of the gelatin delayed reversion. It is concluded that mucopeptide synthesis occurs in step 2, that concomitant RNA, DNA, or protein synthesis is not essential, but that physical immobilization of excreted cell products at the protoplast surface is necessary early in step 2. Newly reverted cells were misshapen and osmotically sensitive. Processes which confer osmotic stability after reversion (step 3) did not occur in the presence of chloramphenicol or actinomycin D.     

桃褐腐病菌(Monilia fructigena)原生质体制备及再生条件

以桃褐腐病菌(Monilia fructigena)为供试菌株,研究了酶系组成、液体培养基、菌龄、酶解温度、酶解时间对原生质体制备的影响,以及等渗液、固体再生培养基、酶解时间对原生质体再生的影响。结果表明:Fries(1/2)液体培养基培养24h,在10mg/mL崩溃酶+5mg/mL纤维素酶+20mg/mL蜗牛酶+10mg/mL溶菌酶的混合酶液中28°C酶解4h为桃褐腐病菌原生质体制备的最佳条件。采用液体再生涂布平板法,以含Ca2+的STC为等渗液的液体培养基和含蔗糖及Ca2+的Fries(1/2)固体培养基为桃褐腐病菌原生质体再生的最佳条件。经过观察与测定,再生菌株保持了原有的培养性状和致病性,接种桃果实后发病率为100%。     

Inhibition of the cell wall regeneration and reversion in protoplasts ofRhizopus nigricans

During cultivation in a nutrient medium with snail gastric juice the protoplasts ofRhizopus nigricans produce an incomplete cell wall and grow. A true growth, associated with nuclear division, is involved. Morphology of growth of the formations is determined by the structure of the incomplete cell wall. When the incomplete wall is formed by a thin fibrillar net the growing formation assumes the physically optimal shape—i.e. a sphere; when the net is dense polar growth predominates. The degree of construction of the new wall depends on the activity of snail gastric juice enzymes which decreases during the cultivation. When fresh snail enzymes were added at certain intervals, only a fine fibrillar net was formed on the surface of growing protoplasts. The formations grew for up to 8 d under these conditions, reached several hundred μm in size and the number of nuclei increased up to 80-fold. When the blocking of the wall synthesis was interrupted, a complete cell wall regenerated on the surface of these giant formations and a reversion to hyphae was observed. The incomplete cell wall functions as a passive morphogenetic factor: It can influence the morphology of the growing protoplasts but it cannot induce reversion to hyphase and secure the permanent existence of these structures.     

High Frequency Divisions in Leaf Base Protoplasts of Wheat (Triticum aestivum L.)

Protoplasts were isolated from the basal meristematic region of leaves from 6-day-old seedlings of wheat (Triticum aestivum). Protoplasts divided when cultured on MS medium (as agarose beads) in presence of nurse tissue. Donor seedlings when grown on BAP-supplemented MS medium were found to be considerably superior for protoplast isolation and culture than when grown on MS basal medium, in terms of protoplast viability, cell wall formation and cell division frequency. In addition, reduction of ammonium content of the culture medium, together with a dark Incubation, led to a high protoplast division frequency of about 70%. Microcolonies of 10-to 12-celled stages were obtained in Triticum aestivum, varieties HD 2329, HD 2285, Kalyan Sona, Arjun and CPAN 1676.     

Lily (<Emphasis Type="Italic">Lilium longiflorum</Emphasis> L.) pollen protoplast adhesion is increased in the presence of the peptide SCA

The style of lily produces a specialized extracellular matrix (ECM) in the transmitting tract epidermis that functions to guide pollen tubes to the ovary. This adhesive ECM contains low esterified pectins and a peptide, SCA (stigma/stylar cysteine-rich adhesin). Together they form a matrix to which pollen tubes adhere as they grow through the style. Pollen tubes also adhere to each other but only when grown in vivo, not in vitro. Pollen does not produce detectable SCA, but when SCA is added to an in vitro growth medium, it binds to pollen tubes that have esterified and low-esterified pectins in their walls. Since adhesion of the pollen tube to the stylar matrix requires tip growth, we hypothesized that the pectin wall at the pollen tube tip interacted with the SCA protein to initiate adhesion with the stylar pectin [Lord (2000) Trends Plant Sci 5:368–373]. Here, we use a pollen protoplast system to examine the effect of SCA on protoplast adhesion when it is added to the growth medium in the absence of the stylar pectin. We found that SCA induces a 2-fold increase in protoplast adhesion when it is added at the start of protoplast culture. This effect is less when SCA is added to the medium after the cell wall on the protoplast has begun to regenerate. We show that among the first components deposited in the new wall are arabinogalactan proteins (AGPs) and highly esterified pectins. We see no labeling for low esterified pectins even after 3 days of culture. In the pollen protoplast culture, adhesion occurs in the absence of the low esterified pectin. The newly formed wall on the protoplast mirrors that of the pollen tube tip in lily, which is rich in AGPs and highly esterified pectins. Thus, the protoplast system may be useful for isolating the pollen partner for SCA in this adhesion event.     

Instability of actinomadurae protoplasts generated by lytic enzyme treatment

The effect of lytic enzyme treatment upon protoplast formation and reversion in three species of Actinomadura has been determined. Incubation in the presence of lytic enzyme L2 generates large protoplasts (4 μm diameter) which remain intact for only 2h. In comparison, protoplasts formed by the degradative effects of the enzymes lysozyme and L1 are smaller (2 μm diameter), and remain stable for up to 18h. This results in a greater efficiency of regeneration. Lytic enzyme L2 has been shown to contain impurities, including proteolytic activity, which may affect cell wall regeneration.     

Studies of cotyledon protoplast cultures from Brassica napus,B. campestris and B. oleracea. I: Cell wall regeneration and cell division

Protoplasts isolated from cotyledons of a number of cultivars of Brassica napus, B. campestris and B. oleracea were cultured in different media to study the characteristics of cell wall regeneration and cell division at early stages of culture. Time course analysis using Calcolfluor White staining indicated that cell wall regeneration began in some protoplasts 2–4 h following isolation in all cultivars. 30–70% of cultured cotyledon protoplasts exhibited cell wall regeneration at 24 h and about 60–90% at 72 h after the initiation of culture. Results also indicated that a low percentage (0.4–5.4%) of cultured cotyledon protoplasts entered their first cell division one day after initial culture in all twelve cultivars. The percentage of dividing cells increased linearly up to 40% from 1 to 7 day, indicating that cotyledon protoplasts of Brassica had a high capacity for cell division. Factors that influence the level of cell wall regeneration and cell division during cotyledon protoplast culture have been investigated in this study. Cotyledons from seedlings germinated in a dark/dim light regime provided a satisfactory tissue source for protoplast isolation and culture for all Brassica cultivars used. The percentages of protoplasts exhibiting cell wall regeneration and division were significantly influenced by cultivar and species examined, with protoplasts from all five cultivars of B. campestris showing much lower rates of cell wall regeneration than those of B. napus and B. oleracea over 24–120 h, and with the levels of cell division in B. napus cultivars being much higher than those in B. campestris and B. oleracea over 1–9 days. The capacity of cell wall regeneration and cell division in cotyledon protoplast culture of the Brassica species appears under strong genetic control. Cell wall regeneration in protoplast culture was not affected by the culture medium used. In contrast, the composition of the culture medium played an important role in determining the level of cell division, and the interaction between medium type and cultivars was very significant.Abbreviations BA benzylaminopurine - CPW Composition of Protoplast Washing-solution - CW Calcolfluor White - EDTA ethylenediamine-tetraacetic acid - KT Kinetin - Md MS modified Murashige and Skoog medium - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA -naphthaleneacetic acid - IAA indole-3-acetic acid - PAR photosynthetically active radiation - SDS sodium dodecyl sulfate     

Cytological study of early stages of regeneration of protoplasts of fungi and Streptomyces

Early stages of Penicillium chrysogenum 51 and Streptomyces lividans 66 protoplast regeneration on solid media were studied microscopically under conditions of microcompartments. It was shown that at the early regeneration stages there were both rapid reversion into the mycelial form and a retarded one. In P. chrysogenum retarded regeneration resulted in formation of hypha-like structures or protoplast breaking into fragments of various sizes. Some of the fragments restored the cell walls and mycelial organization whereas the others lysed. As a result of the breaking and compartmentalization of the viable areas one protoplasts formed several centers of P. chrysogenum colony reversion. Retarded regeneration of protoplasts in S. lividans 66 resulted in their growth and multiplication in the protoplast-like L-form. On media with penicillin, glycine and horse serum there were isolated colonies of S. lividans L-forms subject to passages or reversion depending on the medium composition.     

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.     

A Revised Medium for Growth of Pea Mesophyll Protoplasts

The nutrient requirements of mesophyll protoplasts from Pisum sativum L. cv. Timo have been investigated and a synthetic and completely defined medium has been designed. A high calcium concentration (12 mM) stimulated both protoplast survival and cell division. The content of iron and zinc was also critical. Additions of nicotinic acid, pyridoxine and thiamine were necessary. The protoplast growth was enhanced when some amino acids were included in the medium. An absolute requirement for auxin and cytokinin was shown. In the revised medium about 90% of the isolated protoplasts survived and formed a cell wall. The first divisions were observed after 5 days and after 1 week 10–20% of the cells had divided at least once.     

Regeneration of the cell wall of protoplasts of the fission yeastSchizosaccharomyces versatilis in liquid media and their reversion to cells

Regeneration of the cell wall and reversion of protoplasts with a completely regenerated cell wall to cells were studied by light and electron microscopy in protoplasts of the fission yeastsSchizosaccharomyces versatilis. On their surface the protoplasts regenerated a complete new wall even m liquid media The wall regeneration began with the formation of a thin irregular net of flat bundles of long microfibrils and the net was gradually filled with aggregates of short straight microfibrils and small piles of amorphous material. Osmotically resistant organisms with regenerated walls were detected after a 4–6 h cultivation Depending on the nutrient medium used 10–80 % of protoplasts with the regenerated wall were obtained that reverted subsequently to cells. The high percentage of the wall regeneration and reversion to cells was reached by combining cultivation in a poor medium with that in a rich medium Reversion to cells could only occur after the protoplasts had regenerated rigid cell walls These walled protoplasts underwent septation, and, by polar growth, produced cylindrical cells, further dividing by fission.     

A preliminary study of chromium distribution in chromium-rich brewer's yeast cell by NAA

The purpose of this study was to assess the chromium (Cr) distribution in chromium-rich brewer’s yeast cell. The chromium concentrations in the cell wall and protoplast fractions of the chromium-rich yeast were determined by neutron activation analysis (NAA). Moreover, the combined state of chromium and amino acid content in the Cr-rich brewer’s yeasts was analyzed and measured. The experimental results indicate that the introduction of water-soluble chromium (III) salt as a component of the culture medium for yeasts results in a substantial amount of chromium absorbed through the cell wall by the yeast, among which 80.9% are accumulated in the protoplast. It implies that, under optimal conditions, yeasts are capable of accumulating large amounts of chromium and incorporating chromium into organic compounds.     

ORGANIZATION AND BREAKDOWN OF THE PROTOPLAST DURING MATURATION OF PINE TRACHEIDS

The protoplast of maturing axial tracheids in the secondary xylem of shortleaf pine (Pinus echinata Mill.) was studied by transmission and scanning electron microscopy. The mature protoplast is differentiated into two interconnected components: (1) the commonly observed peripheral layer lining the secondary cell wall, and (2) an elaborate reticulum of cytoplasmic filaments and placoids within the central vacuole. The reticulum provides an extensive surface area of vacuolar membranes for rapid exchange of nutrients and metabolites with the vacuolar sap, which is envisaged to function as a vital medium during the period of secondary cell wall synthesis. The breakdown of the protoplast which terminates tracheid maturation is associated with poorly defined alterations of the vacuolar membranes. This is indicated by increased formation of cytoplasmic spherules and membraneous vesicles which may be portions of separated vacuolar membrane during early stages of degradation. Autolysis is supposed to occur when the cytoplasm is exposed to the vacuolar sap after rupture and separation of the vacuolar membranes. The Gomori acid phosphatase technique as combined with electron microscopy produced no evidence of autolysosomal segresomes in strands of intravacuolar reticulum of the cytoplasm.     

Plant regeneration from leaf protoplasts of <Emphasis Type="Italic">Solanum virginianum</Emphasis> L. (<Emphasis Type="Italic">Solanaceae</Emphasis>)

Leaves of Solanum virginianum plants were used for protoplast isolation. To support cell wall formation and cell division, protoplasts were cultured in thin alginate layers floated in liquid medium. When protoplasts were plated at a density of 1.0 × 10⁶/ml in Kao and Michyaluk (KMp8) medium supplemented with 0.5 mg/l zeatin, 1.0 mg/l 2,4-dichlorophenoxyacetic acid, and 1.0 mg/l α-naphthaleneacetic acid, 42.3% of the dividing cells developed microcalli in 3–4 weeks. Shoot formation via organogenesis of protoplast-derived calli was achieved for 28% of calli transferred to solidified KMp8 medium supplemented with 2.0 g/l zeatin and 0.1 mg/l 3-indol acetic acid in about 2 weeks. Further shoot development was observed in Murashige and Skoog (MS) medium without growth regulators and roots were induced after transfer to MS medium containing 1.0 mg/l 3-indol butyric acid. Regenerated plants have normal morphology.