Microprotoplast isolation, enrichment and fusion for partial genome transfer in plants

Somatic hybridization using protoplasts with whole genomes has often resulted in complex hybrids with many unwanted chromosomes or genes. Several researchers have attempted to reduce the number of undesired chromosomes through irradiation of the donor protoplasts, but so far without much success. Alternatively, micropro-toplasts containing one or a few chromosomes can be used for partial genome transfer, as has been demonstrated in human and other mammalian cell systems using microcells. Recently, we have optimized the 'microprotoplast system' for several donor cell lines (potato, Nicotiana , sugar beet) carrying various genetic markers, such as kanamycin resistance, β-glucuronidase, nitrate reductase deficiency, hormone autotrophy, opines, etc. Protocols were developed to obtain higher yields of micro-protoplasts as well as to enrich sub-diploid microprotoplasts containing one or a few chromosomes. These microprotoplasts were fused with whole mesophyll protoplasts of recipient lines using polyethylene glycol. Various requirements for lines used as donor and recipient partners in microprotoplast-protoplast fusions are described. The results are discussed in the context of partial genome transfer.     

Intergeneric transfer of a partial genome and direct production of monosomic addition plants by microprotoplast fusion

Results are reported on the transfer of single, specific chromosomes carrying kanamycin resistance (Kan^R) and -glucuronidase (GUS) traits from a transformed donor line of potato (Solanum tuberosum) to a recipient line of the tomato species Lycopersicon peruvianum through microprotoplast fusion. Polyethylene glycol-induced mass fusion between donor potato microprotoplasts containing one or a few chromosomes and normal recipient diploid L. peruvianum protoplasts gave several Kan^R calli. A high frequency of plants regenerated from Kan^R calli expressed both Kan^R and GUS, and contained one or two copies of npt-II and a single copy of gus. Genomic in situ hybridization showed that several microprotoplast hybrid plants had one single potato donor chromosome carrying npt-II and gus genes and the complete chromosome complement of the recipient L. peruvianum (monosomic additions). Several monosomic-addition hybrid plants could be regenerated within the short time of 3 months and they were phenotypically normal, resembling the recipient line. These results suggest that the transfer of single chromosomes is tolerated better than is the transfer of the whole donor genome. The unique advantages of microprotoplast fusion are discussed: these include the direct production of monosomic addition lines for the transfer and introgression of economically important traits in sexually-incongruent species, the construction of chromosome-specific DNA libaries, high-resolution physical mapping and the identification of alien chromosome domains related to gene expression.     

Liposomes as a carrier of genetic information

Incorporation of genetic material into the bilayer lipid vesicles (liposomes) and the subsequent transfer of liposomal content into cells or protoplasts appear to be a promising technique for transfer of genetic information. The following three methods are most frequently used to incorporate DNA into liposomes lipid microinjection into aqueous phase, multistep treatment of the lipid suspension by ultrasonication, Ca2+ ions and EDTA, reverse phase evaporation. Viral particles, chromosomes, nuclei, viral nucleic acids, plasmids and chromosomal DNA can be successfully transferred into animal and plant protoplasts by the described technique. Successful transformation of a number of microorganisms (Neurospora, E. coli, B. subtilis, Streptomyces, Mycoplasma) with the liposome incorporated DNA has also been reported. Transformation frequency can be considerably increased by optimizing the conditions of liposome formation or of liposome-protoplasts interaction.     

Uptake of isolated plant chromosomes by plant protoplasts

For mass isolation of plant metaphase chromosomes, cultured cells of wheat (Triticum monococcum) and parsley (Petroselinum hortense) were synchronized by hydroxyurea and colchicine treatment. This synchronization procedure resulted in high mitotic synchrony, especially in suspension cultures of parsley in which 80% of the cells were found to be at the metaphase stage. Mitotic protoplasts isolated from these synchronized cell cultures served as a source for isolation of chromosomes. The described isolation and purification method yielded relatively pure chromosome suspension. The uptake of the isolated plant chromosomes into recipient wheat, parsley, and maize protoplasts was induced by polyethylene-glycol treatment. Cytological studies provided evidences for uptake of plant chromosomes into plant protoplasts.Abbreviations PEG polyethylene glycol - HU hydroxyruea - C colchicine - HUC hydroxyurea and colchicine - CIM chromosome isolation medium - TCM Tris chromosome medium     

Genome reorganization in Nicotiana asymmetric somatic hybrids analysed by in situ hybridization

In situ hybridization was used to examine genome reorganization in asymmetric somatic hybrids between Nicotiana plumbaginifolia and Nicotiana sylvestris obtained by fusion of gamma-irradiated protoplasts from one of the parents (donor) with non-irradiated protoplasts from the other (recipient). Probing with biotinylated total genomic DNA from either the donor or the recipient species unequivocally identified genetic material from both parents in 31 regenerant plants, each originating from a different nuclear hybrid colony. This method, termed genomic in situ hybridization (GISH), allowed intergenomic translocations containing chromosome segments from both species to be recognized in four regenerants. A probe homologous to the consensus sequence of the Arabidopsis thaliana telomeric repeat (5'-TTTAGGG-3')n, identified telomeres on all chromosomes, including 'mini-chromosomes' originating from the irradiated donor genome. Genomic in situ hybridization to plant chromosomes provides a rapid and reliable means of screening for recombinant genotypes in asymmetric somatic hybrids. Used in combination with other DNA probes, it also contributes to a greater understanding of the events responsible for genomic recovery and restabilization following genetic manipulation in vitro.     

Isolation of microprotoplasts from a partially synchronized suspension culture of Citrus unshiu

The effect of hydroxyurea (HU) and amiprophos-methyl (APM) on the synchronization of suspension cultures of Satsuma mandarin (Citrus unshiu) and micronucleation of the suspension cells sequentially treated with both, HU and APM, were investigated. When suspension cultures in early-log phase were treated with 4 or 10mM HU for 24h, the number of cells in the S-phase and the mitotic index (MI) increased significantly. Exposure of the early-log phase suspension culture to 32microM APM led to a marked increase in the MI 12 and 24h after treatment, while higher as well as lower concentrations (16, 24 and 48microM) had no effect. Suspension cultures subjected to sequential treatment, e.g. pretreatment with 10mM HU for 24h followed by treatment with 32microM APM for 24h, also showed a considerably increased MI. Furthermore, 61.5% of the protoplasts isolated from the sequentially treated suspension cells were micronucleated, whereas only 3.6% of the control protoplasts, isolated from untreated cells, showed micronucleation. Ultra-centrifugation of the micronucleated protoplasts generated microprotoplasts of different sizes, most of them below 5microM in diameter, with 1 or few chromosomes. The potential application of microprotoplasts in citrus genetic improvement is discussed.     

Characterization and molecular analysis of transgenic plants obtained by microprotoplast fusion in sunflower

Asymmetric somatic hybrid (ASH) plants were obtained by PEG-mediated mass fusion of microprotoplasts from perennial Helianthus species and hypocotyl protoplasts of Helianthus annuus. The formation of micronuclei in perennial sunflower cell cultures was induced, at early log phase, by addition of the herbicides amiprophos-methyl or oryzalin. Sub-diploid microprotoplasts were isolated by high-speed centrifugation and the smallest enriched by sequential filtration through nylon sieves of decreasing pore size. Fusion products were cultured and the regenerated plants phenotypically, genetically and cytologically characterized. DNA analysis using RAPD markers revealed that 28 out of 53 regenerated plants were asymmetric hybrids. Subsequent nuclear-DNA flow cytometric analysis showed that these plants had a higher DNA content than the receptor H. annuus, suggesting that they represented addition lines. Cytological investigation of the metaphase cells of 16 hybrids revealed an addition of 2–8 extra chromosomes in these plants. The phenotype of most ASH plants resembled H. annuus. These results indicate that micronuclear induction and asymmetric somatic hybridization represent a potent tool for partial genome transfer aimed at the specific transfer of economically important traits in breeding programs. Received: 21 December 1999 / Accepted: 25 March 2000<@head-com-p1a.lf>Communicated by K. Glimelius     

Isolation and characterization of microprotoplasts from APM-treated suspension cells ofNicotiana plumbaginifolia

Summary Subprotoplasts with a DNA content of less than the G1 level (microprotoplasts) were isolated from micronucleated cells of transformedNicotiana plumbaginifolia (Doba line resistant to kanamycin) and characterized cytologically as well as by flow cytometry and Feulgen microdensitometry. Micronuclei were induced upon treatment of the suspension cells with the anti-microtubule drug amiprophos-methyl (APM). Protoplasts were fractionated on a continuous iso-osmotic gradient of Percoll; this resulted in several visible bands. Flow cytometric analysis of fluorescein and nuclear DNA contents after staining with fluorescein and DAPI respectively showed that the main band contained mostly evacuolated, intact (sub)protoplasts. Microprotoplasts contained one or a few micronuclei surrounded by a thin rim of cytoplasm and an intact plasma membrane. A maximum of 40% of the microprotoplasts in the fraction just below the main band had a DNA content less than the G1 level, in other fractions this maximum was 20%. Some of these contained an amount equivalent to that of one or a few chromosomes. The application of microprotoplasts for chromosome-mediated gene transfer in plants is indicated.     

Micronucleation by mitosis inhibitors in developing microspores of Spathiphyllum wallisii Regel

Key message

We developed an efficient protocol for chromosome scattering in Spathiphyllum microspores. The effects of plant material, developmental age, genotype and antimicrotubular toxin type, exposure and concentration were evaluated.

Abstract

Asymmetric hybridization through microprotoplast-mediated chromosome transfer (MMCT) is a known method for overcoming sexual breeding barriers between distantly related plant species. To obtain microprotoplasts, it is necessary to induce mass micronucleation either in somatic or gametic cells. We have tested the efficiency for micronuclei induction of five mitosis inhibitors, amiprophos-methyl (APM), butamiphos (BUT), chlorpropham (CIPC), oryzalin (ORY) and propyzamide (PRO), on developing microspores of diploid Spathiphyllum wallisii Regel. Besides the used toxins, also the effect of their concentrations and incubation period as well as plant genotypes and material was tested. We observed micronuclei (MNi) in pollen mother cells, dyads and tetrads as well as other abnormalities such as ball metaphases and chromosome bridges. The flower position on the spadix and the type of starting material (dissected anthers vs. complete spadices) did not significantly influence micronucleation frequencies. The highest micronucleation index of 86 % was obtained in microspores treated with 10 μM ORY during 72 h. All six genotypes tested formed micronuclei after this particular treatment, although the efficiency varied between cultivars. Next to ORY, CIPC was also a very efficient MNi inducer. The average number of MNi found in micronucleated cells varied between 1.67–6.44 for CIPC and 0.83–5.50 for ORY. The maximal number of MNi observed was 12 for CIPC and 9 for ORY. Our results demonstrate that CIPC and ORY can be applied for mass micronucleation on developing microspores of S. wallisii as a first step of MMCT in aroid interspecific or intergeneric breeding.     

Detection of alien chromatin introgression from Thinopyrum into wheat using S genomic DNA as a probe--a landmark approach for Thinopyrum genome research

The introduction of alien genetic variation from the genus Thinopyrum through chromosome engineering into wheat is a valuable and proven technique for wheat improvement. A number of economically important traits have been transferred into wheat as single genes, chromosome arms or entire chromosomes. Successful transfers can be greatly assisted by the precise identification of alien chromatin in the recipient progenies. Chromosome identification and characterization are useful for genetic manipulation and transfer in wheat breeding following chromosome engineering. Genomic in situ hybridization (GISH) using an S genomic DNA probe from the diploid species Pseudoroegneria has proven to be a powerful diagnostic cytogenetic tool for monitoring the transfer of many promising agronomic traits from Thinopyrum. This specific S genomic probe not only allows the direct determination of the chromosome composition in wheat-Thinopyrum hybrids, but also can separate the Th. intermedium chromosomes into the J, J(S) and S genomes. The J(S) genome, which consists of a modified J genome chromosome distinguished by S genomic sequences of Pseudoroegneria near the centromere and telomere, carries many disease and mite resistance genes. Utilization of this S genomic probe leads to a better understanding of genomic affinities between Thinopyrum and wheat, and provides a molecular cytogenetic marker for monitoring the transfer of alien Thinopyrum agronomic traits into wheat recipient lines.     

Plant mutant tubulin genes as marker selective genes for genetic engineering

The approaches for new marker genes usage in selection of transformed plant cells, which are based on using mutant tubulin genes from natural plant biotypes and, in perspective, from induced plant mutants have been considered. The results of investigations of plant (biotypes, mutants) resistance to herbicides with antimicrotubular mode of action on molecular and cellular levels have been summarized. The reports dealing with study the transferring and the expression of mutant tubulin genes conferring resistance to amiprophosmethyl (phosphorothioamidate herbicide) and to trifluralin (dinitroaniline herbicide) from corresponding N. plumbaginifolia mutants into related and remote plant species by somatic hybridisation methods have been analyzed. The results of experiments on monocotyledonous and dicotyledonous. plant transformation by mutant alpha-tubulin gene conferring resistance to dinitroanilines are described to test the possibility of its using as a marker gene with obtaining, at the same time, a dinitroaniline-resistant plants.     

植物基因组研究与利用的新型工具——异源单体附加系

在高等植物中, 以种间杂交和回交把有益基因从一个物种转移到另一个物种为目的育种项目中, 单个外源染色体常常被附加到含有受体细胞完整一套染色体中, 形成异源单体附加系。这种异源单体附加系是阐明基因组结构和转移基因的有效工具。它可以通过回交形成覆盖整个基因组的渗入系重叠群, 用于建立以受体物种基因组为载体的外源物种基因组文库。另外, 一套完整的异源单体附加系也可看作是一个拥有分散供体基因组成为单个染色体单位的文库, 便于精确高通量地将标记分配到单个供体染色体上, 从而可以比较供体染色体和各自的直向同源受体染色体之间的标记位置和同线性关系。同时, 也便于研究同源染色体的渗入机制和配对状态。文中介绍了异源单体附加系的培育和特性, 并着重阐明了它在遗传育种和基础研究中的应用。     

Development of DNA-mediated transformation systems for plants

The genetic engineering of plants by DNA-mediated gene transfer requires that efficient transformation systems be developed. Considerable progress has been made in manipulating the Ti plasmid of Agrobacterium tumefaciens as a vehicle for delivery of foreign genes into protoplasts of dicotyle-donous plants. Part of the Ti plasmid, the T-DNA, can be incorporated into the genome of the host cell; the T-DNA can carry a foreign DNA sequence which co-integrates with it; under normal conditions, the tumorigenic-causing portion of the T-DNA can be inactivated so that transformed protoplasts can be regenerated and T-DNA with an inserted foreign gene can be stably maintained during regeneration, meiosis and gamete formation. A foreign gene has yet to be expressed in regenerated plants although a T-DNA gene for opine synthesis can function in regenerates. Developing a more ubiquitous transformation system for monocotyledons is further from fruition. Based on transformation systems for simple eukaryotic organisms, it is reasonable to expect that a DNA vector which is capable of amplifying a novel plant gene and which contains both a drug resistance marker to facilitate the selection of transformed plant protoplasts and a species-specific autonomously replicating sequence to ensure the stable maintenance of the input gene in the recipient cell can be constructed.     

Intergeneric gene transfer mediated by plant protoplast fusion

Summary In attempts at somatic transfer of plant genomes of reduced size, X-irradiated leaf protoplasts of parsley (Petroselinum hortense, 2n=22) were fused with cell culture protoplasts of a nuclear albino mutant of carrot (Daucus carota, 2n=18). Introduction of genes from the irradiated parsley nuclei into the carrot genome was shown by the correction of the albino defect and by the appearance of parsley isoenzymes in selected green tissues and plants. The cytological studies provided information on significant deviation from the amphidiploid chromosome number. The high frequency of cells with 2n=19, 2n=38 and regeneration of plants with 2n=19 chromosomes can indicate that the elimination of parsley chromosomes is incomplete. A correlation was found between the lethality of selected tissues and differentiated or undifferentiated stages of the cells.     

Intergeneric nuclear gene transfer between somatically and sexually incompatible plants through asymmetric protoplast fusion

Summary A stable intergeneric transfer of nuclear genes from Physalis minima into the genome of Datura innoxia has been achieved through asymmetric protoplast fusion. No hybrid plants could be obtained from these species either by traditional methods of sexual breeding or by somatic hybridization via fusion of protoplasts containing complete nuclear genomes. The incompatibility barriers were bypassed by the fusion of highly X-irradiated (LD₁₀₀) wild-type Physalis with nuclear albino mutant Datura protoplasts. In this intergeneric reconstruction, 1.15% of the total heterokaryons restored the chlorophyll synthesis in their regenerants. Two representative transformed lines, TRL-A and TRL-D, were further characterized, showing 0.43–0.78 pg. additional nuclear DNA (4.45–8.07% nuclear DNA of P. minima). Since chromosomes of the species of Datura and Physalis were distinguishable, the mitotic complement of the transformed regenerants showed only 3 and 1 chromosomes of the donor in tetraploid (2n=48) and octoploid (2n=96) genomes of the recipient, respectively. The introduction and expression of limited genes of Physalis in Datura have also been confirmed by the allelic expression of various isoenzymes. Such stable gene transfer via asymmetric fusion of protoplasts has been discussed in relation to its application in the genetic manipulation of plants.     

An improved method for protoplast micro-injection suitable for transfer of entire plant chromosomes

A simple protoplast culture system, combining optimal plating efficiency and the prerequisites for microinjection (immobilization, localization, optics) is described. Microinjection of lucifer yellow into protoplasts and protoplast-derived cells from Nicotiana plumbaginifolia cell suspensions was carried out to demonstrate the vitality of the procedure, the possibility to penetrate cell walls, and the occurrence of aberrant cell divisions early during protoplast regeneration at high frequency.Using specific adaptations of the equipment, transfer of particles was carried out: metaphase chromosomes isolated from a partially synchronized kanamycin-resistant suspension culture of N. plumbaginifolia were microinjected into recipient wild-type N. plumbaginifolia protoplasts. So far only visual evidence was achieved; genetic and molecular verification for chromosome-mediated gene transfer is in progress.     

Factors influencing the utility of gametic microprotoplasts for partial genome transfer in potato

The potential of gametic microprotoplasts as a tool for partial genome transfer in potato (Solanum tuberosum L.) was investigated and a number of technical findings are reported. The phosphoric amide herbicide amiprophos-methyl was effective for microcell induction when applied at a concentration of 25 μm to excised anther material; however, neither whole buds nor isolated microspores responded to treatment. One selected clone responded well to spindle toxin treatment, and microcells were observed in 9% of tetrads, for which 4% (wt/vol) cellulase Onozuka R10 and 0.25% (wt/vol) driselase was found to be optimal for the release of protoplasts from the tetrads with conversion rates exceeding 40%. Technical problems identified at a number of crucial stages that may preclude the more widespread application of this technology are discussed. Received: 23 July 1996 / Revision received: 27 April 1997 / Accepted: 1 December 1998     

Multiple transformation of Saccharomyces cerevisiae by protoplast fusion

A technique for the multiple transformation of yeast by protoplast fusion is described. This involved the PEG-induced fusion of protoplasts from cells which had been treated with chromosome-fragmenting agents (in this case cupferron and hydroxylamine) with protoplasts of triply auxotrophic cells. The recovery of transformants was increased significantly if one of the amino acid requirements of the recipient strain was included in the selection medium. Transformants isolated on supplemented media remained auxotrophic for that requirement. Prototrophic, uninucleate transformants had a DNA content and cellular volume similar to that of the parental strains. Possible mechanisms of gene transfer are discussed. This technique offers the possibility of transferring desirable characteristics from one yeast strain to another without altering the ploidy level of the recipient strain.     

Preparation of megabase-size DNA from plant nuclei

A novel technique has been developed for the preparation of high molecular weight (HMW) DNA from plant nuclei. This technique involves physical homogenization of plant tissues, nuclei isolation, embedding of the nuclei in low-melting-point agarose microbeads or plugs, and DNA purification in situ . This technique is simple, rapid, and economical, and the majority of the DNA prepared is over 5.7 Mb in size. The genomic DNA content of the HMW DNA prepared by this technique is enriched by at least threefold and the chloroplast DNA content is reduced by over twofold relative to that prepared from plant protoplasts by existing methods. The DNA is readily digestible with different restriction enzymes and partial digestions of the DNA could be reproducibly performed. This method has been successfully used for the preparation of HMW DNA from a wide range of plant taxa, including grasses, legumes, vegetables, and trees. These results demonstrate that the DNA prepared by this technique is suitable for plant genome analysis by pulsed-field gel electrophoresis and for the construction of yeast and bacterial artificial chromosomes.