An ultrastructural study of the interaction of liposomes with plant protoplasts

A one-step procedure using a mixture of glutaraldehyde and osmium tetroxide was devised to fix in situ large unilamellar liposomes of phosphatidylserine for transmission electron microscopy (TEM), since the conventional fixation method was found to be inadequate in this respect. The new fixation procedure enabled us to visualize the sequence of events in the interaction of liposomes with protoplasts from Vinca rosea suspension cultures in the presence of polyethylene glycol. Liposomes were thus found adhering to the surface of protoplasts, in association with invaginating plasmalemma, and within intracellular vesicles. These observations showed that liposomes enter plant protoplasts via endocytosis. Ultrastructural profiles indicating fusion of liposomes with protoplasts were not observed.     

Liposome-Mediated transfer of bacterial RNA into carrot protoplasts

The uptake of liposome-encapsulated E. coli [³H]RNA by carrot (Daucus carota L.) protoplasts was examined. [³H]RNA extracted from protoplasts that had been incubated with [³H]RNA-containing, large, unilamellar lipid vesicles (liposomes) obtained by ether infusion, and examined by sucrose gradient centrifugation and formamide-polyacrylamide gel electrophoresis, appeared substantially degraded, with a total elimination of 23S RNA and a partial loss of 16S RNA. In contrast, no breakdown of the [³H]RNA was apparent in the liposomes after sequestration, even in the presence of externally added ribonuclease, or in the unfused liposomes remaining after incubation of protoplasts with liposomes. Thus, the degradation of the [³H]RNA extracted from the protoplasts must have occurred within the protoplasts and represents evidence for liposome-mediated RNA uptake. Naked RNA added to the protoplast culture was found to be totally degraded after incubation with the protoplasts. The uptake of liposome-sequestered RNA by protoplasts was demonstrated to be a function both of the lipid composition of the liposomal membrane and of the temperature of incubation of the liposomeprotoplast mixture. Furthermore, the mode of this uptake (fusion versus endocytosis) could be manipulated by adjusting the cholesterol content of the liposomal membrane. The implications of the ability to insert RNA into protoplasts without degradation by extracellular nucleases are discussed.     

Liposome-mediated delivery of DNA to carrot protoplasts

The encapsulation of DNA within liposomes and subsequent fusion of the liposomes with carrot (Daucus carota L.) protoplasts were examined to determine optimum conditions for effective liposome-mediated delivery of DNA to protoplasts. Escherichia coli [³H]DNA could be encapsulated with 50% efficiency using encapsulation volumes as low as 0.5 ml. Incorporation of liposome-encapsulated [³H]DNA by carrot protoplasts increased linearly for 2.5 h, and increasing the ratio of protoplasts to liposomes increased the total amount of radioactive label incorporated within the protoplasts. Liposome-mediated incorporation of [³H]DNA by protoplasts increased over a range of polyethylene glycol concentrations up to 20%, but Ca²⁺ did not increase liposome-mediated incorporation when present in the liposome-protoplast incubation mixture. Optimum incorporation was observed when the pH of the liposome-protoplast incubation medium was decreased to 4.8. Encapsulation experiments using DNA of the plasmid pBR322 indicated that an average of 200–1,000 intact copies of pBR322 were sequestered within each nucleus after liposome delivery.     

Genetic transfers inBrevibacterium sp.

A positive genetic transfer by protoplast fusion was obtained in auxotrophic mutants Brevibacterium sp. M27 his and Brevibacterium sp. M27 arg. Transformation and protoplast fusion with liposomes (as genetic transfers in intact cells and their protoplasts by both the chromosomal and plasmid DNA) did not lead to transfer of the markers followed.     

The interaction of Bacillus protoplasts with sonicated phosphatidylcholine liposomes

When protoplasts from Bacillus subtilis are incubated with sonicated liposomes made from egg-yolk phosphatidylcholine, this phospholipid is incorporated into the protoplast membranes. Biochemical, fluorescence and ultrastructural data suggest that incorporation occurs through membrane fusion.     

Parameters influencing the liposome-mediated insertion of fluorescein diacetate into plant protoplasts

Maximum uptake of liposome-encapsulated fluorescein diacetate by Daucus carota protoplasts was observed when 6 × 10⁶ protoplasts per milliliter were incubated with 2.4 × 10⁷ liposomes per milliliter for 1 hour. In the case of Nicotiana glutinosa protoplasts, optimum ratio of protoplasts to liposomes was 1:10, where 2.3 × 10⁵ protoplasts per milliliter were provided. Neutral and positive liposomes were found to be efficient vehicles to transfer their contents into plant protoplasts. When protoplasts treated with liposomes were cultured in a synthetic medium for 1 week, 20% resumed cell divisions.     

Improved Cytoplasmic Delivery to Plant Protoplasts via pH-Sensitive Liposomes

We demonstrated that the liposomes composed of dioleolylphosphatidylethanolamine/cholesterol/oleic acid (4:4:2) dramatically release their contents at a pH of less than or equal to 6.0 and are capable of delivering their contents into the cytoplasm of higher plant protoplasts. This is shown by using a soluble fluorescent dye, calcein, as a liposome-entrapped marker. We found that calcein fluorescence was evenly distributed in the cytoplasm of wild carrot protoplasts after the incubation of protoplasts with liposomes in the presence of polyethylene glycol 6000. At 0.45 micro mole phospholipid per 6 × 10⁵ protoplast, for example, the percentage of protoplasts which took up liposomes was 89% which was much higher than that achieved by conventional pH-insensitive liposomes. In this study, liposomes were prepared by a detergent dialysis method which avoided sonication and organic solvents. Thus macromolecules such as proteins and nucleic acids could be entrapped in the liposomes and delivered to the cytoplasm of the protoplasts.     

Low pH-induced fusion of liposomes with membrane vesicles derived from Bacillus subtilis

We have investigated the pH-dependent interaction between large unilamellar phospholipid vesicles (liposomes) and membrane vesicles derived from Bacillus subtilis, utilizing a fluorescent assay based on resonance energy transfer (RET) (Struck, D. K., Hoekstra, D., and Pagano, R. E. (1981) Biochemistry 20, 4093-4099). Efficient interaction occurs only with negatively charged liposomes, containing cardiolipin or phosphatidylserine, as revealed by the dilution of the RET probes from the liposomal bilayer into the bacterial membrane. The initial rate of fluorophore dilution increases steeply with decreasing pH. The interaction involves a process of membrane fusion, as indicated by the proportional transfer of cholesteryl-[1-14C]oleate, 14C-labeled egg PC, and the RET probes from the liposomes to the bacterial vesicles, the formation of interaction products with an intermediate buoyant density, and the appearance of colloidal gold, initially encapsulated in the liposomes, in the internal volume of fused structures as revealed by thin-section electron microscopy. Treatment of B. subtilis vesicles with trypsin strongly inhibits the fusion reaction, indicating the protein dependence of the process. Vesicles derived from Streptococcus cremoris or from the inner membrane of Escherichia coli also show low pH-dependent fusion with liposomes. The fusion process described in this paper may well be of considerable importance to studies on the mechanisms of membrane fusion and to studies on the structure and function of bacterial membranes. In addition, the fusion reaction could be utilized to deliver foreign substances into bacterial protoplasts.     

Infection of evacuolated turnip protoplasts with liposome-packaged cauliflower mosaic virus

The infectivity of reverse phase evaporation (REV) liposome-encapsidated cauliflower mosaic virus (CaMV) to turnip protoplasts was tested. The uptake of neutral or negative liposomes was stimulated by polyethylene glycol (PEG), while high levels of uptake of positive liposomes were obtained both in the absence and presence of PEG. The delivery of the vesicle contents to the protoplasts paralleled the uptake of liposomes. CaMV delivered to turnip protoplasts was degraded during the early period of culture. No increase in the amount of CaMV DNA could be detected on longer periods of culture. In contrast, when protoplasts were evacuolated prior to addition of REV liposomes, an increase in the amount of CaMV DNA was noted after some initial degradation of the input DNA.     

Targeting of large liposomes with lectins increases their binding to plant protoplasts

Soybean agglutinin, peanut agglutinin, and concanavalin A were covalently bound by condensation reaction to gangliosides and ceramides incorporated within the bilayer of multilamellar and unilamellar liposomes. These modified liposomes had a much higher affinity for carrot and tobacco protoplasts except when concanavalin A was used.

In addition, soybean agglutinin and concanavalin A were attached by ligand-specific binding to liposomes containing cholesterol molecules derivatized with each lectin-specific sugar. This procedure allowed efficient crosslinking of liposomes to protoplasts. The same effect was achieved with soybean agglutinin and peanut agglutinin when derivatized cholesterol was replaced by gangliosides. The implications of these findings for the liposome-mediated nucleic acid transfer into protoplasts are discussed.

     

Liposome-mediated gene delivery into plant cells

Liposomes may offer several advantages as vectors for gene delivery into plant cells: (1) enhanced delivery of encapsulated DNA by membrane fusion, (2) protection of nucleic acids from nuclease activity, (3) targeting to specific cells, (4) delivery into a variety of cell types besides protoplasts by entry through plasmodesmata, (5) delivery of intact small organelles. Realization of these advantages calls for the construction of efficient liposomes, for appropriate fusion conditions and for an understanding of the nature of liposome-cell interactions. Various characteristics and techniques of the liposome-cell system are described (mode of delivery, liposome types and composition, and means of promoting delivery of liposome contents). Data of liposome-mediated delivery of various macromolecules into plant cells, with special reference to protoplasts, calli and pollen are reviewed. This includes data obtained by the use of fluorescent probes, radioactive-labelled DNA, viral nucleic acids and expression of plasmid-DNA. Structure and characteristics of plant surfaces and plasmodesmata are discussed with respect to DNA entry. It is suggested that liposome-mediated gene delivery into plant cells, and not only protoplasts, will be advantageous in certain specific tissues and situations.     

The lack of a phospholipid-exchange-protein activity in soluble fractions of Spinacia oleracea leaves.

When 14C-labelled liposomes prepared from Spinacia oleracea leaf lipids or 14C-labelled microsomal fraction ('microsomes') prepared from Spinacia oleracea leaf protoplasts were incubated with unlabelled intact chloroplasts, there was a considerable transfer of label to the chloroplasts. This transfer occurred in the absence of added protein, but was stimulated by soluble protein fractions from Spinacia oleracea leaves. The stimulation was heat-stable and decreased after dialysis of the protein fractions. Salt solutions, containing no protein, stimulated lipid transfer proportionally to their conductivity. In all cases, the lipid transfer was not protein-dependent, but rather resulted from the fusion of 14C- and 3H-labelled liposomes or microsomes with chloroplasts. It is proposed that this photosynthetic tissue contains no detectable lipid-exchange activity between liposomes, microsomes and chloroplasts and that lipid transfer between these organelles is achieved by non-protein-dependent means.     

荧光脂质体导入黄瓜悬浮细胞原生质体的研究

用“脱水再加水法”制成包裹荧光黄的脂质体,通过PEG诱导融合或保温共培养法,成功地将脂质体导入了黄瓜悬浮细胞原生质体。PEG处理组摄入脂质体的细胞可达80—90%,其中50—60%的细胞荧光较强,均匀一致。脂质体/原生质体保温共培养半小时,荧光细胞达95%以上,荧光较弱,在细胞中呈点状分布,3—4天后脂质体逐渐破裂,点状荧光变为均匀一致的荧光。导入荧光黄脂质体的原生质体经持续分裂形成愈伤组织和胚状体,进一步分化出芽和根。     

A Comparison of Methods for Plasmid Delivery into Plant Protoplasts

Three methods of plasmid delivery to mesophyll protoplasts ofNicotiana tabacum cv. Xanthi have been evaluated. Specifically;a) chemically stimulated uptake of isolated plasmid, b) deliveryof plasmid encapsulated in liposomes, and c) fusion of plasmid-containingspheroplasts, were combined with divalent cation (Ca²⁺ and Mg²⁺)or polyalcohol [polyethylene glycol (PEG) and polyvinyl alcohol(PVA)] treatments. The quantity and quality of plasmid associatedwith intact protoplasts, was assessed by DNA-DNA blot hybridisationanalysis, following stringent washing to separate intact protoplastsfrom non-viable protoplasts and debris. Treatments which increasedassociation of plasmid with protoplasts decreased protoplastviability. Optimum association of plasmid with protoplasts,in the context of acceptable loss of viability, was achievedwhen protoplasts were interacted with either naked plasmid orliposomeencapsulated DNA in the presence of 15% w/v PEG 6000,or with Escherichia coli spheroplasts containing chloramphenicol-amplifiedplasmid in the presence of 25% w/v PEG 6000. Divalent cationsdid not stimulate significant plasmid delivery without unacceptableloss of protoplast viability. Strategies to further increasethe efficiency of plasmid delivery are discussed. (Received June 21, 1984; Accepted August 20, 1984)     

Cwp2p, the plasma membrane receptor for Pichia membranifaciens killer toxin

PMKT is a channel-forming killer toxin secreted by Pichia membranifaciens. To identify novel genes that mediate cellular resistance to PMKT we screened a collection of 288 deletion mutants. We found 29 open reading frames (ORFs) that, when deleted, confer resistance to PMKT. In addition, the deletion of 15 ORFs was observed to increase protoplast resistance, in agreement with the initial assumption that a plasma membrane receptor for PMKT exists. Whole cells and protoplasts of a cwp2Delta mutant were found to be completely resistant to PMKT and were unable to bind PMKT, indicating that Cwp2p interacts with it. A protein with a molecular mass of 11.7 kDa was purified from PMKT-affinity columns. This protein was sequenced and identified as Cwp2p. Glycosylphosphatidylinositol (GPI) anchoring-defective mutants were much less sensitive to PMKT, as were wild-type protoplasts pretreated with phosphatidylinositol-specific phospholipase C to remove GPI-anchored proteins, indicating that the GPI-anchored precursor of Cwp2p is also necessary for PMKT activity. Carboxyfluorescein-entrapped liposomes containing a purified GFP-Cwp2p fusion protein in their membranes were much more sensitive to PMKT than protein-free liposomes. Cwp2p and its GPI-anchored precursor are proposed for the first time to be involved as PMKT secondary receptors.     

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。     

Delivery of tobacco mosaic virus RNA into plant protoplasts mediated by reverse-phase evaporation vesicles (Liposomes)

Summary Protoplasts were isolated from tobacco suspension cultures using a new cellulase preparation. Tobacco mosaic virus (TMV) RNA was encapsulated in reverse-phase evaporation vesicle (REV) liposomes of phosphatidylserine and cholesterol, and was successfully introduced into tobacco protoplasts by treatment of the REV/protoplast mixture with polyvinyl alcohol or polyethylene glycol followed by washing with high pH-high Ca buffer. Delivery of TMV-RNA was monitored by determining the number of infected protoplasts using the immunofluorescence technique. Production of TMV particles in the infected protoplasts was also confirmed by electron microscopy. Because of the high encapsulation efficiency of REV liposomes the amount of TMV-RNA necessary to cause infection in the majority of protoplasts could be reduced to 1/10 to 1/5 that required in the previous study (Fukunaga et al. 1981). The usefulness of the REV-mediated delivery of nucleic acids for genetic manipulation of plant protoplasts is discussed.     

Conditions for induced fusion of fungal protoplasts in polyethylene glycol solutions.

Solutions containing polyethylene glycol MW 6000 (PEG) induced fusion of protoplasts of Penicillium chrysogenum. Balanced heterokaryons were formed by fusion of nutritionally complementing protoplasts. Heterokaryotic fusion products were obtained up to a frequency of 4% of the number of protoplasts, surviving the fusion treatment. Investigation of the conditions, necessary to achieve this high fusion frequency, showed that supplementing the PEG solution with Ca++ and adjustment to high pH gave the best results. Mechanisms of fusion of fungal protoplasts by PEG, calcium and alkaline pH are discussed in view of the obtained results.     

Conditions for induced fusion of fungal protoplasts in polyethylene glycol solutions

Solutions containing polyethylene glycol MW 6000 (PEG) induced fusion of protoplasts of Penicillium chrysogenum. Balanced heterokaryons were formed by fusion of nutritionally complementing protoplasts. Heterokaryotic fusion products were obtained up to a frequency of 4% of the number of protoplasts, surviving the fusion treatment. Investigation of the conditions, necessary to achieve this high fusion frequency, showed that supplementing the PEG solution with Ca⁺⁺ and adjustment to high pH gave the best results. Mechanisms of fusion of fungal protoplasts by PEG, calcium and alkaline pH are discussed in view of the obtained results.     

Fusion characteristics of plant protoplasts in electric fields

The electrical parameters important in the fusion of plant protoplasts aligned dielectrophoretically in high-frequency alternating electric fields have been established. Protoplasts were aligned in an alternating electric field between two relatively distant (1 mm) electrodes, by dielectrophoresis induced by field inhomogeneities caused by the protoplasts themselves. This arrangement allowed ease of manipulations, large throughput and low loss of protoplasts. In analytical experiments, sufficiently large samples could be used to study pulse duration-fusion response relations at different pulse voltages for protoplasts of different species, tissues and size (mesophyll protoplasts of Solanum brevidens, Triticum aestivum, Hordeum vulgare; suspension-culture protoplasts of Nicotiana sylvestris, N. rustica, Datura innoxia and S. brevidens; root-tip protoplasts of Vicia faba, hypocotyl protoplasts of Brassica napus). The percentage of aligned protoplasts that fused increased with increasing pulse parameters (pulse duration; voltage) above a threshold that was dependant on pulse voltage. The maximum fusion values obtained depended on a number of factors including protoplast origin, size and chain length. Leaf mesophyll protoplasts fused much more readily than suspension-culture protoplasts. For both types, there was a correlation of size with fusion yield: large protoplasts tended to fuse more readily than small protoplasts. In short chains (five protoplasts), fusion frequency was lower, but the proportion of one-to-one products was greater than in long chains (ten protoplasts). In formation by electrofusion of heterokaryons between mesophyll and suspension-culture protoplasts, the fusion-frequency response curves reflected those of homofusion of mesophyll protoplasts rather than suspension-culture protoplasts. There was no apparent limitation to the fusion of the smallest mesophyll protoplast with the largest suspension-culture protoplasts. Based on these observations, it is possible to direct fusion towards a higher frequency of one-to-one (mesophyll/suspension) products by incorporating low densities of mesophyll protoplasts in high densities of suspensionculture protoplasts and by using a short fusion pulse. The viability of fusion products, assessed by staining with fluorescein diacetate, was not impaired by standard fusion conditions. On a preparative scale, heterokaryons (S. brevidens mesophyll-N. sylvestris or D. innoxia suspension-culture) were produced by electrofusion and cultured in liquid or embedded in agar, and were capable of wall formation, division and growth. It is concluded that the electrode arrangement described is more suitable for carrying out directed fusions of plant protoplasts than that employing closer electrodes.