Interactions of Cowpea Mosaic Virus with Cowpea Protoplasts1)

The capability of cowpea mosaic virus to attach to and infect protoplasts of immune, hypersensitive, and susceptible cowpea (Vigna unguiculata) lines was examined by inoculating protoplasts with either purified virus or radioiodinated purified virus ¹²⁵I-CPMV. Systems were used in which plants were immune and protoplasts susceptible, plants were immune and protoplasts resistant, and plants and protoplasts were susceptible to CPMV. No differences were observed in the attachment of ¹²⁵I-CPMV to resistant and susceptible protoplasts. Polycations, proteins, or virus particles were added to the inoculation medium to neutralize potential nonspecific interactions between cells and virus particles. The various additives induced quantitative differences in binding of virus particles to protoplasts.     

Structural and ultrastructural analysis of Solanum lycopersicoides protoplasts during diploid plant regeneration

Light, fluorescence and electron microscopy were used to analyse the structural properties of protoplasts obtained from established suspension culture of Solanum lycopersicoides Dun, composed of meristematic cell aggregates. Four types of protoplasts were distinguished immediately after isolation: (1) mononuclear; (2) polynuclear, (3) anuclear and (4) homogeneous protoplasts. Only mononuclear protoplasts were capable of complete cell wall regeneration and mitotic division. Other types of protoplasts were eliminated during culture. Three phases were distinguished in the developing protoplast culture: (1) the elimination phase during which protoplasts damaged during isolation underwent complete degradation; (2) a phase of intense division during which both mitotic cell division and amitotic nuclear division took place; and (3) a stabilization phase leading to the formation of suspension culture. The cell suspension culture obtained from protoplasts was capable of regenerating diploid plants.     

Production of asymmetric hybrids between Arabidopsis thaliana and Brassica napus utilizing an efficient protoplast culture system

Application of the protoplast culture method developed for Brassica protoplasts to protoplasts of Arabidopsis thaliana has increased the opportunities for interspecific hybridizations involving Arabidopsis. A more-efficient and much-simpler method was established compared to the earlier-reported protocol developed for A. thaliana protoplasts in which alginate beads were utilized. Mesophyll protoplasts of A. thaliana (ecotypes 'Landsberg erecta' and 'Wassilewskija') were cultured in the modified 8p liquid medium, which had been developed for Brassica protoplasts. For comparison, protoplasts were cultured in sodium alginate beads supplied with B5 medium according to the protocol for A. thaliana. The protoplasts divided with high frequencies in the 8p medium, and calli proliferated more rapidly than in the sodium alginate beads. High frequencies of shoot differentiation and regeneration were observed in calli of both ecotypes, from about 30% in the ecotype 'Wassilewskija' to about 60% for 'Landsberg erecta'. The more-rapidly the calli developed, the higher the regeneration frequencies were. Asymmetric hybrids between A. thaliana and Brassica napus were obtained by treating the protoplasts of A. thaliana with iodoacetamide (IOA) and B. napus protoplasts with UV-irradiation before fusion with polyethylene glycol (PEG). By using the culture procedure developed for Brassica protoplasts, calli developed and plants were regenerated. Although most of the plants regenerated after cell fusion were A. thaliana-like and were judged to be escapes from IOA treatment, more than ten plants showed hybrid features of both morphological and molecular characters. Among the hybrids that have flowered so far, both male-fertile and male-sterile plants have been obtained. Back-crossings to A. thaliana are now in progress as is morphological and molecular characterization of the plants.     

激光诱导金盏菊原生质体融合方法初探

本文简述运用激光微束诱导金盏菊(Calendula Officinali L.)叶肉细胞原生质体融合的方法和初步结果,并就激光诱导植物原生质体融合的条件进行初步讨论。     

Isolation,culture, and regeneration of plants from potato protoplasts

A technique is described for the routine isolation of protoplasts from storage parenchyma cells of potato tubers grown in vitro. The protoplasts typically contained many starch grains. On culture, most of the starch grains were metabolised during the first 7 days, after which the cells began to divide. Following further culture, protoplast-derived colonies and calli were obtained, from which shoots and intact plants were regenerated. Cytological study of regenerated plants showed that the majority were octaploid or aneuploid at the octaploid level. This aspect is compared with plants regenerated from mesophyll protoplasts of potato. The use of tuber protoplasts for studies on tissue-specific transient gene expression of chimeric gene constructs, following their introduction into the protoplasts by electroporation, is discussed, together with the uses of tuber protoplasts in fundamental physiological and biochemical studies.     

Microviscosity of plasmalemmas in rose petals as affected by age and environmental factors

The microviscosity of the plasmalemma of protoplasts isolated from rose (Rosa hyb. cv. Golden Wave) petals was measured by fluorescence depolarization. The plasmalemma's microviscosity was found to increase in petals which were allowed to age on cut flowers or after isolation as well as in isolated protoplasts aged in an aqueous medium. Increasing the temperature of the cut flowers or the isolated protoplasts enhanced the increase of the microviscosity of the protoplast plasmalemma. The mole ratio of free sterol to phospholipid was greater in protoplasts isolated from old flowers or in protoplasts aged after isolation than in protoplasts isolated from younger flowers. Microviscosity was greatest when protoplasts were aged at pH 4.4 and in the presence of Ca²⁺. Artificial alterations of the sterol to phospholipid ratio in the protoplasts, induced by treatment with liposomes, caused similar changes in their measured microviscosity.

These findings strongly suggest that the increase in the petal plasmalemma microviscosity with age is associated with an increase in the sterol to phospholipid ratio which results, at least partially, from the activity of endogenous phospholipases.

     

Culture of soybean mesophyll protoplasts in alginate beads

Mesophyll protoplasts were isolated from leaves of 10 day old aseptically grown soybean seedlings, or from surface disinfested leaves of 3 week old plants grown in environmental chambers. The protoplasts were encapsulated in 2mm diameter Ca alginate beads. Immobilized protoplasts were induced to divide by culturing in shaker flasks containing an actively growing soybean cell suspension. The feeder cell suspension supported the division of protoplasts independent of the protoplast density in the Ca alginate beads. At day 18 after encapsulation, the alginate matrix was dissolved, releasing viable callus colonies. The feeder cell suspension obviated plating of protoplasts at high density which is usually required for subsequent cell division and colony development. Since the protoplasts were embedded at low density, the cell colonies were derived from single cells.     

Surface Charge Density of Hetero-Fused Plant Protoplasts: an Electrophoretic Study

Electrophoretic mobilities of hetero-fused plant protoplasts,which were obtained by electrofusion of barley mesophyll cellprotoplasts and Rauwolfia serpentina cultured cell protoplasts,and those of the unfused parent protoplasts were measured invarious media of different pH values. At pH 5.2, the zeta potentialof the fused protoplasts was intermediate between those of thebarley and R. serpentina protoplasts and the average surfacecharge density of the fused protoplasts was closer to that ofR. serpentina than to that of barley. The distribution of thesurface charge density of fused protoplast obtained at pH 5.2is discussed in terms of the surface charge densities and thesizes of parent protoplasts. These results revealed that thesurface charge density of fused protoplasts was determined bythe surface charge densities and the ratio of the surface areasof the respective parent protoplasts. (Received December 28, 1989; Accepted August 10, 1990)     

Procedure for the isolation of mutants of Bacillus subtilis with defective cytoplasmic membranes

A procedure has been devised to isolate mutants of Bacillus subtilis with structurally defective membranes. The procedure used to screen for the mutants involved comparison of the stability of protoplasts of the mutant with those of the wild type in a medium of sufficient osmotic strength to stabilize wild-type protoplasts. Mutagenized cells were grown as clones on agar plates, and then replicated onto plates containing 0.5 m lactose, which is sufficient to stabilize wild-type protoplasts. The colonies on the lactose-containing plates were then treated with lysozyme to convert the cells to protoplasts. Colonies of wild-type protoplasts remained opaque; however, colonies of mutant protoplasts lysed and became clear. Twenty-nine osmotically fragile mutants were isolated in this manner; the membranes of several mutants were found to contain alterations in the composition of their proteins or lipids.     

Evacuolation and enucleation of mesophyll protoplasts in self-generating percoll gradients

Mesophyll protoplasts from Brassica oleracea, B. napus, Nicotiana tobaccum and Solanum tuberosum were isolated and subjected to uttracentrifugation at 65000g for 30 min in percoll solutions containing various strengths of salt and osmotic stabilizing agents. After centrifugation, the self-generated percoll gradients were evaluated for their effectiveness in protoplast evacuolation and enucleation. The vacuoles, cell debris, evacuolated protoplasts and enucleated protoplasts were separated. Factors that affected evacuolation and enucleation in the percoll gradients were described. Mesophyll protoplasts produced by epidermis peeling and short enzyme incubation periods were more easily evacuolated and enucleated than those produced by leaf-slicing and long incubation periods. Lower centrifugal force at 25000g for 80 min was also successful in evacuolating and enucleating the mesophyll protoplasts. A green band that contained nearly pure evacuolated protoplasts, of which 45% were enucleated protoplasts, was obtained from the self-generated percoll gradient. Rhodamine 123 staining of mitochondria indicated that the evacuolated protoplasts were metabolically active and were capable of regenerating the vacuole and cell wall. Cell divisions were also observed when the evacuolated protoplasts were cultured.     

Changing desiccation tolerance of pea embryo protoplasts during germination

Protoplasts were isolated from pea (Pisum sativum L. cv. Alaska) embryonic axes during and after germination to determine whether the loss of desiccation tolerance in the embryos also occurs in the protoplasts. At all times studied, protoplast survival decreased as water content decreased; however, the sensitivity to dehydration was less when the protoplasts were isolated from embryos that were still desiccation-tolerant (12 h and 18 h of imbibition) than when protoplasts were derived from axes that were sensitive (24 h and 36 h of imbibition). The water content at which 50% of the population was killed (WC50) increased throughout germination and early seedling growth for both the intact tissue and the protoplasts derived from them. Prior to radicle emergence, protoplasts were less desiccation-tolerant than the intact axes; however, protoplasts isolated from radicles shortly after emergence had lower WC50s than the intact radicles. A comparison of protoplast survival after isolation and dehydration in either 500 mM sucrose/raffinose or 700 mM sucrose revealed no difference in tolerance except at 24 h of imbibition, when protoplasts treated in the more concentrated solution had improved tolerance of dehydration. Although intact epicotyls are generally more desiccation-tolerant than radicles, protoplasts isolated separately from epicotyls and radicles did not differ in tolerance. Collectively, these data suggest that protoplasts gradually lose desiccation tolerance during germination, as do the orthodox embryos from which they were derived. However, even prior to radicle emergence, protoplasts display a sensitivity to progressive dehydration that is similar to that shown by recalcitrant and ageing embryos.     

Functional sieve element protoplasts

Sieve element (SE) protoplasts were liberated by exposing excised phloem strands of Vicia faba to cell wall-degrading enzyme mixtures. Two types of SE protoplasts were found: simple protoplasts with forisome inclusions and composite twin protoplasts-two protoplasts intermitted by a sieve plate-of which one protoplast often includes a forisome. Forisomes are giant protein inclusions of SEs in Fabaceae. Membrane integrity of SE protoplasts was tested by application of CFDA, which was sequestered in the form of carboxyfluorescein. Further evidence for membrane intactness was provided by swelling of SE protoplasts and forisome dispersion in reaction to abrupt lowering of medium osmolarity. The absence of cell wall remnants as demonstrated by negative Calcofluor White staining allowed patch-clamp studies. At negative membrane voltages, the current-voltage relations of the SE protoplasts were dominated by a weak inward-rectifying potassium channel that was active at physiological membrane voltages of the SE plasma membrane. This channel had electrical properties that are reminiscent of those of the AKT2/3 channel family, localized in phloem cells of Arabidopsis (Arabidopsis thaliana). All in all, SE protoplasts promise to be a powerful tool in studying the membrane biology of SEs with inherent implications for the understanding of long-distance transport and signaling.     

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.     

Immunofluorescence of the microtubular skeleton in growing and drug-treated yeast protoplasts

The microtubular system in growing protoplasts of Saccharomyces uvarum was visualized by immunofluorescence using the monoclonal antitubulin antibody TU 01. We confirmed the coexistence of regular spindle configuration and extensive cytoplasmic networks in growing protoplasts and also observed a distinct distortion of cytoplasmic microtubules in association with wall removal. After a short period for recovery of protoplasts in nutrient medium a restitution of cytoplasmic microtubules and their resumed contact with the protoplast surface was observed. Treatment of growing protoplasts with nocodazole resulted in the disappearance of spindle and cytoplasmic microtubules in the relevant fraction of the protoplast population. In carbendazime (MBC)-arrested protoplasts spindle microtubules were absent but cytoplasmic microtubules associated with spindle pole bodies were clearly visible. Microtubule reassembly on spindle pole bodies occurred within 30 min after washing out nocodazole as well as carbendazime. The approach using protoplasts suggests a simple way in which the differential effect of antimicrotubule agents can be experimentally tested and the microtubule organizing activity of yeast protoplasts visualized at the population level.     

The isolation and purification of surface specific proteins of somatic and reproductive protoplasts of lily and rapeseed

The plasma membrane surface proteins of intact somatic (leaf) and reproductive (pollen, generative cell or sperm cell) protoplasts of lily ( Lilium longiflorum ) and rapeseed ( Brassica napus cv. Midas) were compared after probing with N-hydroxysuccinimido- (NHS) or sulfo-NHS-biotin. The plasma membranes of intact protoplasts are impermeable to these biotin probes, which bind covalently to the free amino groups of surface proteins. Enzyme-labelled streptavidin was used to detect membrane proteins after separation by SDS-PAGE and western blotting. In lily, six proteins specific to the surface membrane of leaf protoplasts were identified varying from 25–64 kDa, three proteins to pollen protoplasts in the range 35–64 kDa and two proteins to generative cell protoplasts, 63 and 67 kDa. In rapeseed leaf protoplasts, seven proteins in the range 22–69 kDa were detected, while in the sperm enriched fraction five proteins were present in the same kDa range. The proteins identified as membrane specific for generative cell protoplasts of lily have been isolated and were used as antigens for monoclonal antibody production. Preliminary results indicate the successful production of antibodies to surface antigens. These antibodies will be used to localise surface specific epitopes which are likely to be involved in cell-cell recognition at fertilization.     

Differential responses of Brassica napus and Petunia hybrida to leaf protoplast isolation stress

Changes in the response to abiotic stress during the isolation of leaf protoplasts were compared between a recalcitrant species of Brassica napus and regenerating species of Petunia hybrida . Initially, levels of soluble free putrescine (put), spermidine (spd) and spermine (spm) in leaves and protoplasts were determined. The sum of these three polyamines increased in petunia and B. napus leaf protoplasts by 1.6-fold and 1.1-fold, respectively. The soluble free fraction of spd and spm decreased in B. napus but not in petunia protoplasts. During the isolation of leaf protoplasts from B. napus , the ratio of soluble free put to the total PAs almost doubled, but that of spd and spm declined significantly. Petunia leaf protoplasts treated with cyclohexylamine (CHA), an inhibitor of spermidine synthase, accumulated ammonia and soluble putrescine, but lost the soluble spermidine. The soluble polyamine levels of CHA-treated petunia leaf protoplasts corresponded with those in B. napus . Leaves were subjected to abiotic stress during the isolation of protoplasts, namely wounding and osmotic stress which changed soluble free polyamine levels in B. napus and petunia, respectively. Both B. napus and petunia leaf protoplasts showed an increase in ammonia, but total free amino acid content and activation of proteases were only enhanced in B. napus leaf protoplasts. These results suggest that in B. napus wounding initiated senescence of leaf protoplasts during their isolation, leading to a constant production of ethylene early in the culture.     

Morphology, RNase and transaminase of root protoplasts

RNase and transaminase activities were analysed for mechanicallyand enzymatically prepared protoplasts from Allium Cepa roots.The comparative analyses at three root regions show that theenzymes were less active in the protoplasts than in the cellsfrom which they had been obtained. The enzyme gradients (fromapex to base of the root: RNase increase and transaminase decrease)noted previously in the intact roots were found to be similarin the protoplasts, however to a lesser degree. On the otherhand, the relative activity of both tested enzymes was lowerin the enzymatically prepared protoplasts than in those obtainedby the mechanical technique. In connection with their physiologicalproperties, the respective effects of the mode of preparingthe protoplasts were discussed. (Received November 22, 1971; )     

Factors Influencing Protoplast Viability of Suspension-Cultured Rice Cells during Isolation Process

Callus cells of rice (Oryza sativa L.) that were actively dividing in suspension culture had lost the ability to divide during the isolation process of protoplasts. Factors influencing the protoplast viability were examined using highly purified preparations of cellulase C₁, xylanase, and pectin lyase, which were essential enzymes for the isolation of protoplasts from the rice cells. The treatment of the cells with xylanase and pectin lyase, both of which are macerating enzymes, caused cellular damage. Xylanase treatment was more detrimental to the cells. Osmotic stress, cell wall fragments solubilized by xylanase, and disassembly of cortical microtubules were not the primary factors which damaged the rice cells and protoplasts. The addition of AgNO₃, an inhibitor of ethylene action, to the protoplast isolation medium increased the number of colonies formed from the cultured protoplasts, although the yield of protoplasts was reduced by the addition. Superoxide radical (O₂-) was generated from the cells treated with xylanase or pectin lyase. The addition of superoxide dismutase and catalase to the protoplast isolation medium resulted in a marked improvement in protoplast viability especially when the non-additive control protoplasts formed colonies with a low frequency. The addition of glutathione peroxidase and phospholipase A₂, which have been known to reduce and detoxify lipid hydroperoxides in membranes, to the protoplast culture medium significantly increased the frequency of colony formation. These results suggested that some of the damage to rice protoplasts may be caused by oxygen toxicity.     

Analytical Studies on Regeneration of Protoplasts of Geotrichum candidum by Quantitative Thin-Layer-Agar Plating

A preparation of pure protoplasts of Geotrichum candidum became osmotically stable and colonies developed when the protoplasts were embedded in stabilizing thin-layer-agar and incubated with stabilizing basal medium. When growing protoplasts were exposed to distilled water and then reincubated with basal medium, the process of regeneration of protoplasts could be quantitatively demonstrated by counting colonies. The process was divided into three phases, lag, logarithmic, and stationary. Furthermore, the state of regeneration of protoplasts at each phase could be seen in detail by microscopic studies of protoplasts under similar growth conditions. In the lag phase, which lasted for 2 hr after inoculation, protoplasts were completely destroyed when placed in distilled water. During the logarithmic phase, from 2 to 5 hr after inoculation, protoplasts rapidly became osmotically stable and about 18% of them were growing. In the stationary phase, most protoplasts developed germ tubes within 2 hr. These results suggested that there are two main phases, although individual cells passed through three different conditions, osmotically labile, osmotically stable, and growing. No apparent structure of cell wall material could be detected by electron microscopy on the surface of the membrane of these osmotically stable cells.     

Ribulosebisphosphate carboxylase activity and photosynthetic o(2) evolution rate in vicia guard-cell protoplasts

Activities of ribulose-1,5-bisphosphate carboxylase and rates of photosynthetic O₂ evolution were measured in guard-cell and mesophyll protoplasts from Vicia faba. The ribulose-1,5-bisphosphate carboxylase activity of guard-cell protoplasts was 30% of that of mesophyll protoplasts; however, the O₂ evolution rate was 3 times higher in guard-cell protoplasts than in mesophyll protoplasts on a chlorophyll basis. When the dark-adapted, guard-cell protoplasts were illuminated by red light, O₂ was evolved with an induction period, which became shorter when the protoplasts were reilluminated. High activity of irreversible NADP-glyceraldehyde-3-phosphate dehyrogenase was found in guard-cell protoplasts. Several lines of evidence revealed that there was virtually no contamination by mesophyll cells in guard-cell preparations. These results indicate that guard cells fix CO₂ photosynthetically and imply that the cells utilize a considerable proportion of reducing equivalents from water for reactions other than CO₂ fixation.