Application of nurse culture for plant regeneration from protoplasts of Lilium japonicum thunb

Summary The regeneration of lily protoplasts isolated from suspension cells of Lilium japonicum was achieved by using the nurse culture method. The protoplasts divided only under the nurse culture application. The divided protoplasts grew into colonies and developed into visible calluses on a medium containing picloram. After the calluses were transferred to a hormone-free medium, plantlets formed from them. The highest frequency of plant regeneration was obtained on a medium containing 1 μM gibberellin 4 (GA₄). The cleaved amplified polymorphie sequences (CAPS) method was used to confirm that the regenerants were not plants that had escaped from nurse cells. We were able to transplant the plantlets to soil in pots without acclimatization, and they showed normal growth.     

Direct and indirect somatic embryogenesis in Freesia refracta]

Somatic embryogenesis can be induced in tissue cultures of Freesia refracta either directly from the epidermal cells of explant, or indirectly via intervening callus. In direct pathway, somatic embryos were in contact with maternal tissue in a suspensor-like structure. In indirect pathway, the explants first proliferacted to give rise to calluses before embryoids were induced. The two sorts of calluses were defined to embryogenic callus and non-embryogenic callus according to producing of somatic embryos. An indirect somatic embryo is developed from a pre-embryogenically determined cell. This kind of somatic embryo has no suspensor structure instead of a complex with maternal tissue. Somatic embryos have their own vascular tissues, and can develop new plantlets independently.     

香雪兰的直接与间接体细胞胚胎发生

香雪兰的体细胞胚胎发生可通过两种途径进行,即直接发生与间接发生。在直接发生方式中,体细胞胚直接来源于尚未完全分化的外植体表皮细胞;体细胞胚与母体组织以一种类似胚柄的结构相联系。间接发生方式中,体细胞胚的形成要经过一个愈伤组织阶段。以是否能形成体细胞胚分类,可将愈伤组织分为胚性和非胚性愈伤组织。以间接方式形成的体细胞胚是由胚性愈伤组织中的一种决定细胞发育来的。这种体细胞胚不具有类似胚柄的结构,而与母体组织共同形成一个复合体。体细胞胚具有自己独立的维管束系统,在脱离母体组织后能够独立发育成株。     

Genesis of microspore-derived triploid petunias

Summary A total of 61 microspore-derived plants of Petunia parodii were grown to maturity revealing a predominent population of triploids, 80.3%. Cytological investigations, together with the evidence from microfluorimetry, suggest that the origin of these triploids was due to the fusion of interphase nuclei in two different pathways. In the majority of embryogenic microspores, a vegetative nucleus of 1C DNA content fused with an endo-reduplicated 2C DNA generative nucleus at the binucleate stage and produced true triploid embryoids and plantlets (A pathway). Where this fusion failed, both the vegetative and the generative nuclei divided separately and in the multinucleate microspore two or more daughter nuclei fused to form a mixoploid embryoid. Such mixoploid embryoids produced a mixed population of plants with various ploidy levels as well as ploidy polymorphism within an individual. Since the triploids are morphologically superior with a faster growth rate than their diploids and related tetraploids, a predominent population of triploid plants was obtained from such mixoploid embryoids (B pathway). By low temperature treatment of the anther-donor buds, the embryogenic response of microspores was enhanced up to 5-fold.     

Nontranslation of foreign genetic information for fraction 1 protein under circumstances favorable for direct transfer ofNicotiana gossei isolated chloroplasts intoN. Tabacum protoplasts

Summary The nuclei and cytoplasm ofN. gossei andN. tabacum are compatible to the extent that reciprocal, interspecific F₁ hybrids can be produced by conventional breeding techniques. Conditions were established in which manyN. gossei isolated chloroplasts could be seen by phase and fluorescence microscopy to adhere to 40% of the population of protoplasts obtained from white tissue of variegatedN. tabacum plants and to remain attached after washing the protoplasts. Chloroplasts also could be seen to enter the interior of the protoplasts. After treating albino protoplasts withN. gossei chloroplasts, the protoplasts were subjected to further conditions whereby 65 calluses containing shoots developed. TwentyN. tabacum protoplasts not treated with foreign chloroplasts also produced calluses with shoots to serve as a control. All calluses developed chlorophyll irrespective of whether or not the albino protoplasts had been treated with isolatedN. gossei chloroplasts. The Fraction 1 protein ofN. tabacum has a different electrophoretic mobility from the protein ofN. gossei or anN. gossei xN. tabacum F₁ hybrid. The Fraction 1 protein large subunit is coded by chloroplast DNA, whereas the small subunit is coded by nuclear DNA. Fraction 1 protein was isolated from the variegated shoots of the 65 calluses obtained after treating albino protoplasts with foreign chloroplasts. Immunoelectrophoresis demonstrated the protein from each callus to have a mobility identical toN. tabacum protein. Therefore, under circumstances highly favorable for the direct transfer ofN. gossei isolated chloroplasts (and possibly nuclei also) intoN. tabacum protoplasts, no evidence was obtained to suggest that genetic information contained in the isolated foreign organelles was being translated into the polypeptides of either the large or small subunits of Fraction 1 protein contained in newly differentiated leaves derived from the protoplasts. Supported by Research Grant PCM-75-07368 from the National Science Foundation.     

Phenotypic Variation and Changes of Chromosome Number in Plantlets Regenerated from Potato Protoplasts

Morphological variation and change of chromosome number in the plantlets of potato (Solanum tuberosum L. cv. Xiao Yie Zi × Duo Zi Bai) regenerated from mesophyll protoplasts have been studied. The normal plantlets from protoplasts were similar to parent plants. Their chromosome numbers were 2n = 48±or 2n= 72 of euploid. The plantlets with distinctive phenotypic variation were likely to be aneuploid with increased chromosome numbers.     

Callus formation from stem protoplasts of corn (Zea mays L.)

Summary The first successful culture, with sustained divisions, of protoplasts from intact plants of Zea mays is described. The method involves the use of a hanging microdrop array technique which permits the testing of very large numbers of different culture media and hormone variations. Several different phytohormone combinations were found to allow sustained divisions in protoplasts isolated from stem tissue of corn plants, suggesting the importance of the source of the protoplasts rather than specific medium conditions. In some cases more than 5% of the protoplasts divided, giving macroscopic calluses within 35 days.     

DEVELOPMENTAL STUDIES IN PORPHYRA (RHODOPHYCEAE). III. EFFECT OF CULTURE CONDITIONS ON WALL REGENERATION AND DIFFERENTIATION OF PROTOPLASTS1

Protoplasts isolated from thalli of four Porphyra species regenerated successfully into differentiated plantlets. The efficiency of protoplast isolation and the developmental patterns of the regenerating protoplasts depended on the type of tissues from which they were isolated. However, culture conditions greatly influenced the patterns of development at the cellular and organismal levels. Sorbitol, nitrogen, and agar concentration in the medium controlled rates of cell division, thickening of cell walls, development of rhizoids, and formation of calluses or differentiated blades. Agitation disturbed the attachment of the protoplasts to a substrate. Cells in agitated cultures produced suspensions of single cells and non-polarized small calluses. Calluses which developed from protoplasts survived in storage for over two years. The stored calluses, and cells and protoplasts that were isolated from them, were subcultured successfully. We forsee extensive use of Porphyra cell suspensions for strain selection and vegetative propagation of cultivars. This technology, which makes vegetative cloning of selected Porphyra plants possible, may eliminate the need for cultivation and storage of the conchocelis phase. Protoplasts are also being used as tools for studies in genetic engineering of these commercial species.     

Transformation of pollen embryo-derived explants by <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> in <Emphasis Type="Italic">Hyoscyamus niger</Emphasis>

Leaf, root, stem, petiole, hypocotyl, and zygotic embryo explants, as well as pollen embryoids, and redifferentiated tissues from pollen embryoid-derived plantlets of Hyoscyamus niger L. (black henbane) were inoculated with Agrobacterium tumefaciens, harboring binary vectors (pGS Gluc1) and then cultured on media containing kanamycin. Transient -glucuronidase activity and kanamycin resistant callus formation were influenced by explant origin. Transgenic calluses were obtained at a frequency of up to 30% from all the explants tested. However, transgenic shoots were obtained only from the hypocotyl of plantlets derived from pollen embryoids. Transformation was confirmed by the ability of leaf segments to produce kanamycin resistant calluses, -glucuronidase histochemical and flurometric assays, polymerase chain reaction and Southern blot analysis. The results show that pollen embryoid-derived explants may be an alternative source for both efficient transformation and regeneration of transgenic plants in recalcitrant species.     

Induction of Endosperm Calluses and Regeneration of Endosperm Plantlets of Asparagus officinalis

The endosperm callus has been induced from the young endosperm of Asparagus officinalis L. on the MS supplemented with auxin. The induction frequency of callus amounts to 65.9%–83.1%. When the callus was transferred to the medium supplemented with lower concentration of NAA 0.1 ppm or containing BA 1 ppm and NAA 0.5 ppm, the differentiation of shoots, roots and a few embryoids began to occur. A few calluses and embryoids can develop into plantlets. The chromosome number in the cells from the same root tip and shoot apex of endosperm plantlet is very unstable. They can be euploids (n=10, 2n=20, 3n=30, 4n=40). or aneupl0ids (n=6, 7, 17, 25, 53).     

Fertile plant regeneration from barley (Hordeum vulgare L.) protoplasts isolated from primary calluses

Barley (Hordeum vulgare L.) protoplasts were isolated from the immature embryo-derived primary calluses. These protoplasts were cultured with nurse cells, and they then divided to form colonies. After transfer of the colonies to regeneration medium, either green or albino shoots were regenerated from these colonies. A high agarose concentration (2.4% w/v) in the protoplast culture medium promoted protoplast division. The plantlets that developed strong root systems were transferred to the soil. These plants flowered and have set seeds.     

CLONING HIGHER PLANTS FROM ASEPTICALLY CULTURED TISSUES AND CELLS

1. For a number of years considerable attention has been given both in the scientific and lay press to dramatic advances in the rapid clonal multiplication of plants by means of so-called ‘modern’ tissue culture techniques. Because the words clone, cloning and tissue culture mean different things to different people, there is considerable confusion even among biologists as to what has actually been achieved. 2. An historical approach has been used to put the accomplishments into perspective. 3. Organ culture, tissue culture, cell or suspension culture and protoplast culture all offer varying degrees of potential for clonal multiplication but the most substantial progress has been made with explanted stem tips or lateral buds which can be stimulated to produce numerous precocious axillary branches. These, in turn, can be separated or subdivided and induced to root and thus yield populations of genetically and phenotypically uniform plantlets. 4. Similarly, undifferentiated calluses can sometimes be induced to form shoots and/or roots adventitiously. This method of stimulating organ development on callus is based on the now classic work of Skoog and Miller done in the I950s with the Wisconsin 38 strain of a ‘Havana’ cultivar of tobacco. Because of the growing criticism that when callus cultures are maintained for more than a few subcultures genetic or chromosomal aberrations are induced and these nullify the ultimate goal - namely to get large numbers of genetically identical plants - callus procedures are generally being relinquished in favour of precocious axillary branching methods. 5. The number of plantlets obtainable through the procedures with precocious axillary shoots or callus culture are fewer, in theory, than the number of plantlets obtainable from a somatic embryo system starting with cells grown in suspension culture. But the fact is that cell culture techniques required to produce somatic embryos are also demanding and very much in their infancy as far as their applicability to clonal multiplication is concerned. 6. Even so, slowly but steadily, advances are being made in learning how to stimulate formation of somatic or adventive embryos from totipotent cells grown in suspension culture. In cases where it has proven feasible, not only may somatic embryos be generated in great quantities, but their discrete bipolar nature often obviates the need for time-consuming, laborious procedures to assure their success in a conventional soil or greenhouse setting. 7. While protoplast cultures are of very limited direct use for clonal propagation of higher plants, the procedures hold some hope as a vehicle whereby select useful genes can be introduced into plants. Parasexual hybridization, that is the production of hybrids by fusing totipotent protoplasts of different origin, offers no imminent prospects for the development of useful and novel plant types but may be applicable in the long term in very specific situations. 8. It is concluded that many problems exist in the producing and growing of totipotent or morphogenetically competent cell suspensions, but the potential benefits that could accrue when investigators learn to overcome these problems far outweigh any disadvantages that they may have. In short, cloning via cultured free cells should be seen in the context of potentialities rather than limitations.     

Recent advances in anther culture of Hevea brasiliensis (Muell.-Arg.)

Summary The yield of pollen embryoids from cultured Hevea anthers was increased 4 fold by optimizing the proportion of ammonium nitrate to potassium nitrate in the dedifferentiation medium. For optimal differentiation of pollen embryoids, kinetin, 2,4-D and -naphtalene acetic acid are required. Anther culture for 50 days on the dedifferentiation medium is a prerequisite for the selective development of calli and embryoids from microspores.The determination of chromosome numbers in embryoids, plantlets and regenerated trees reveals that they originate from (poly)haploid pollen grains (n=2x=18). Aneuploid, triploid (3x=27) and tetraploid (4x=36) cells were encountered in increasing frequencies as the embryoids and plants developed. A few haploid cells with 9 chromosomes were consistently observed. Buds from shoots with mixoploid chromosome numbers can be grafted and the change in the chromosome constitution of the developing new shoots followed.     

Increased induction and chromosome doubling of androgenetic haploid rye

Summary Further progress of studies aimed at increasing production of androgenetic Secale cereale plants via the culture of anthers is described. Two culture media initially developed for rice and wheat anther culture have been shown to have pronounced influence on rye. It has been possible to increase the average percentages of responsive anthers (i.e. those producing embryoids or calluses) from 0.26% to 10% with a maximum in certain experiments of over 40 %. Of nearly 400 plants produced in 1976, 1/4 are green and can be grown further by transfer to potting compost; 3/4 are albino. Stable green haploid lines were present amongst the plants, and after vegetative propagation of the lines representative samples have been treated with colchicine resulting in diploid, triploid and tetraploid plants. The influence of the genetic background of the donor plants on the success rate of anther culture and on the percentage of albino formation is discussed.     

Improvement in efficiency of microspore culture to produce doubled haploid canola (<Emphasis Type="Italic">Brassica napus</Emphasis> L.) by flow cytometry

The efficiency of production of doubled haploid plants in canola (Brassica napus L.) breeding programmes is reduced when large numbers of haploid and infertile plants survive until flowering. We used flow cytometry to determine ploidy status and predict subsequent fertility of microspore-derived plantlets from three canola genotypes, with or without colchicine treatment of microspore suspensions. Young leaf tissue was sampled from microspore-derived plantlets within 1 week of transfer to soil, and processed immediately by flow cytometry. The process was repeated on the same plants 3–5 weeks later. Of the 519 plants transferred to soil, 57.2% were consistently haploid at both sample times, 33.5% were consistently diploid at both sample times, and the remainder (9.2%) were uncertain or inconsistent in ploidy status across sampling times. Of the 518 plants that survived to flowering, 32.4% were diploid at both times of sampling and fertile (set seed) and 46.3% were haploid at both sampling times and infertile. Another 10.8% were haploid at both sampling times and fertile, but had low pollen viability and seed set, and some were triploid or of uncertain ploidy level. Colchicine treatment of microspore suspensions significantly increased the proportion of diploid plants from 9.7 to 69.7%, with significant variation among genotypes. Evidence from simple sequence repeat marker loci indicated that diploid and fertile plants from the control treatment (no colchicine) were derived from spontaneously doubled haploid gametes, rather than unreduced gametes or somatic tissue. Flow cytometry at the first sample time was very efficient in detecting diploid plants of which 94.2% were subsequently fertile.     

Embryogenesis from cultured immature inflorescences and nodes ofLolium multiflorum

When cultured on agar-solidified media (based on Murashige and Skoog's formula), immature inflorescences and nodes ofLolium multiflorum underwent several different pathways of morphogenesis. The pathway expressed was dependent upon the type of explant, its age and the composition of the culture medium. Immature inflorescences generally produced either leaves and roots or embryoids whereas nodes produced axillary shoots or embryoids. Embryogenesis from both explant sources occurred from a firm, white, opaque, proliferating tissue. The embryoids could be cultured individually and induced to produce plantlets capable of transfer to soil. Generally the plantlets formed from newly isolated tissues were green, but chlorophyll-deficient plantlets arose infrequently (up to about 5%). However, this frequency increased as the embryoid-producing tissues were propagated by subculture. Dr Emrys Thomas died in May 1981.     

Comparison of single cell culture derived Solanum tuberosum L. plants and a model for their application in breeding programs

Summary The techniques of microspore and protoplast regeneration starting from dihaploid Solanum tuberosum plants has been improved to such an extent that the production of more than 2000 microspore derived A₁ plant lines and of several hundred protoplast derived plantlets has become possible. Further, from the dihaploid Solanum species S. phureja the regeneration of microspores to plants, and from the species S. infundibuliforme, S. sparsipilum and S. tarijense the regeneration of protoplasts to calluses, has been achieved. The plants descending from the two single cell culture systems are compared with reference to phenotypic markers and economic qualities. Some principles characteristic for either microspore or protoplast derived plants are examined and their significance is discussed. The results are compiled into an extended analytical synthetic breeding scheme based on a stepwise reduction of the autotetraploid to the monohaploid level and a subsequent controlled combination to a new synthetic completely heterozygous tetraploid potato.     

Regeneration of diploid and tetraploid plants from callus-derived protoplasts of Agapanthus praecox ssp. orientalis (Leighton) Leighton

protoplasts was developed for the Liliaceous ornamental plant, Agapanthus praecox ssp. orientalis (Leighton) Leighton `Royal Purple Select' (2n=2x=32).Viable protoplasts were routinely isolated from leaf-derived embryogenic calluses with yields of 0.8 to 1.5x10 protoplasts per g FW of calluses. Protoplasts started to divide 5 to 7 days after isolation, and protoplast-derived colonies consisting of 50 to 100 cells were obtained after 1 month. A plating efficiency of 0.8% was obtained after 2 months of culture using a gellan gum-solidified medium containing 1 mg 1^-1 each of PIC and BA under continuous illumination. Protoplastderived calluses produced somatic embryos at a frequency of 46.7 % on PGR-free medium, whereas 68.3 % of the calluses regenerated adventitious shoots on a medium containing 1 mg 1^-1 BA. Somatic embryos and adventitious shoots developed into plantlets, which were successfully transplanted to pots. Flow cytometric analysis and chromosome observation revealed that both diploid and tetraploid plants were regenerated from protoplasts.     

Embryogenic Suspension Culture and Plant Regeneration from Suspension-Derived Proto-plasts of Cucumber (Cucumis sativus L.)

Fast growing embryogenic cell suspension culture was established when embryogenic callus derived from cotyledon protoplasts of cucumber was transferred into a liquid culture. So far the cell line has been subcultured for two years and retained the ability of embryogenesis and plant regeneration. Experimental data showed that the concentration of ABA or sucrose had a dramatic effect on embryogenesis and synchronization of embryoid development. Low level of sucrose concentration (1%) facilitated the precocious germination of the embryoids while 1 mg/l of ABA or 7–9% of sucrose was found to be effective for reducing callusing of the cultures and synchronisticly controlling the embryoids at globular or late globular stage. Embryogenic cells taken from 3–5 days after subculture were enzymatically digested. A large amount of viable protoplasts was isolated. Protoplasts were cultured in a DPDK1 medium either by means of drop or thin layer liquid culture or by means of sodium alginate encapsulation culture. Actively dividing cells formed cell colonies and globular embryoids which were transferred onto a solidified agar medium or directly into a liquid medium to form a shaken culture. The embryoids would proliferated continuously. Embryoids eventually developed into plantlets when they were transferred onto a 1/2 MSO medium devoid of phytohormones.     

Somatic hybridization in Citrus: navel orange (C. sinensis Osb.) and grapefruit (C. paradisi Macf.)

Summary Protoplasts of navel orange, isolated from embryogenic nucellar cell suspension culture, were fused with protoplasts of grapefruit isolated from leaf tissue. The fusion products were cultured in the hormone-free medium containing 0.6 M sucrose. Under the culture conditions, somatic embryogenesis of navel orange protoplasts was suppressed, while cell division of grapefruit mesophyll protoplasts was not induced. Six embryoids were obtained and three lines regenerated to complete plants through embryogenesis. Two of the regenerated lines exhibited intermediate morphological characteristics of the parents in the leaf shape. Chromosome counts showed that these regenerated plants had expected 36 chromosomes (2n=2x=18 for each parent). The rDNA analysis using biotin-labeled rRNA probes confirmed the presence of genomes from both parents in these plants. This somatic hybridization system would be useful for the practical Citrus breeding.