The importance of the explant on regeneration in thin cell layer technology

Summary The basic factor underlying the success of the tissue culture, large-scale micropropagation and genetic transformation of any plant species is regeneration. This has been achieved over the years through the use of various-sized explants ranging from protoplasts (small scale) to entire organs (large scale). Inherent problems underlie the use of either extreme, leading to both nonspecific morphogenic reactions in the latter, or to undesired necrosis in the former. This review investigates the importance of different aspects of a thin cell layer (TCL) explant, from its source to its size. TCLs, as a results of their size and origin, in combination with other controllable factors such as media and environmental conditions, have shown this system to be superior to the use of conventional explants. Numerous species that were previously unsuccessfully tissue-cultured have, with the use of TCL technology, resulted in their successful micropropagation and regeneration. These successes, based on the inherent qualities of the TCL explant—specific for a given species—are also examined.     

Somatic embryogenesis in peach palm using the thin cell layer technique: induction, morpho-histological aspects and AFLP analysis of somaclonal variation

BACKGROUND AND AIMS: The thin cell layer (TCL) technique is based on the use of very small explants and has allowed enhanced in vitro morphogenesis in several plant species. The present study evaluated the TCL technique as a procedure for somatic embryo production and plantlet regeneration of peach palm. METHODS: TCL explants from different positions in the shoot apex and leaf sheath of peach palm were cultivated in MS culture medium supplemented with 0-600 microM Picloram in the presence of activated charcoal. The production of primary calli and embryogenic calli was evaluated in these different conditions. Histological and amplified fragment length polymorphism (AFLP) analyses were conducted to study in vitro morphogenetic responses and genetic stability, respectively, of the regenerated plantlets. KEY RESULTS: Abundant primary callus induction was observed from TCLs of the shoot meristem in culture media supplemented with 150-600 microM Picloram (83-97%, respectively). The production of embryogenic calli depends on Picloram concentration and explant position. The best response observed was 43% embryogenic callus production from shoot meristem TCL on 300 microM Picloram. In maturation conditions, 34+/-4 somatic embryos per embryogenic callus were obtained, and 45.0+/-3.4% of these fully developed somatic embryos were converted, resulting in plantlets ready for acclimatization, of which 80% survived. Histological studies revealed that the first cellular division events occurred in cells adjacent to vascular tissue, resulting in primary calli, whose growth was ensured by a meristematic zone. A multicellular origin of the resulting somatic embryos arising from the meristematic zone is suggested. During maturation, histological analyses revealed bipolarization of the somatic embryos, as well as the development of new somatic embryos. AFLP analyses revealed that 92% of the regenerated plantlets were true to type. The use of TCL explants considerably improves the number of calli and somatic embryos produced in comparison with previously described protocols for in vitro regeneration of peach palm. CONCLUSIONS: The present study suggests that the TCL somatic embryogenesis protocol developed is feasible, although it still requires further optimization for in vitro multiplication of peach palm, especially the use of similar explants obtained from adult palm trees.     

Plant Thin Cell Layers: A 40-Year Celebration

The concept of a thin cell layer (TCL) was initially presented by Tran Thanh Van in two key papers exactly 40 years ago. At that time, Nicotiana tabacum was the model plant used to establish three main pathways for de novo organogenesis by developing a flower, vegetative bud, and root “programme” from pedicel tissue. Over the last 40 years, a wealth of research in plant tissue culture based on TCLs has emerged, fortifying the importance of this very simple technique, and highlighting its fundamental importance as a key tool in plant cell and tissue differentiation as well as organ development. This review not only highlights the achievements made using TCLs in the plant kingdom over these 40 years, it also reports on the success of this technique in ornamentals, fruit and forestry species, vegetables, and medicinal plants. There is overwhelming evidence of the importance of this technique for plant biotechnology, and it provides one solution for the mass clonal propagation of plants, use in bioreactors, genetic transformation, or micropropagation.     

In vitro culture of Aloe barbadensis Mill.: Morphogenetic ability and nuclear DNA content

In vitro culture of Aloe barbadensis is very difficult for both callus Induction and plant regeneration. By contrast, micropropagation from shoot meristems is easily achieved. A DNA microdensitometric study was performed on different organs of A. barbadensis and during in vitro culture of different explants. It was shown that morphogenetic ability is correlated to nuclear DNA content in the explant and/or in the callus. In particular, plant regeneration (or micropropagation) is obtained only from calli (or from explants) in which the amount of DNA per nucleus falls strictly within the diploid limits (2C and 4C) of the species.     

Thin cell layer culture system in Lilium: Regeneration and transformation perspectives

Summary Lilies are one of the most valuable bulbous ornamental cut flower crops and are commercially propagated by conventional scaling, which results in varied bulb quality. This article demonstrates the effectiveness of using specific organ sources in conjunction with the thin cell layer (TCL) system to establish successful organogenic and somatic embryogenic pathways in Lilium longiflorum. TCLs derived from different explant sources, such as receptacle, leaf, young stem, stem node, bulblets, pseudo-bulblets, shoot and somatic embryos, respectively, can be manipulated to form different organs. Furthermore, the choice of plant growth regulator and medium additives such as activated charcoal and sucrose strongly affect the success of the process. This article further highlights that transient transgene expression derived from either particle bombardment or Agro-infection is both strong and repeatable, as a result of the direct exposure of competent cells to the gene introduction method, resulting in a reduction of escapes. The ability to manipulate and control organogenesis through a TCL system, coupled with repeatable, efficient transformation opens up the possibility of micropropagating members of this genus with new and available characteristics, producing superior plants of high quality.     

Direct somatic embryogenesis of Agave fourcroydes Lem. through thin cell layer culture

Here, we describe a new protocol for the induction of direct somatic embryogenesis of Agave fourcroydes through thin cell layer (TCL) culture technology. The protocol was optimized for the main factors known to affect the process, including the type of explant (stem or leaf tissue), type and concentration of exogenous growth regulators (α-naphthalene acetic acid [NAA], 2,4-diclorophenoxyacetic acid [2,4-D], 4-amino-3,5,6-trichloro-2-pyridinecarboxylic acid [picloram], and 3,6-dichloro-2-methoxybenzoic acid [dicamba]), and the influence of plant genotype. Thin tissue segments cut transversally (tTCLs) from stems of in vitro-cultured plants gave the best embryogenic response when cultured with 2.26 μM dicamba (92.22 embryos/explant) or 2.07 μM picloram (81.72 embryos/explant). It was interesting to observe that the embryogenic capacity of these tissues was affected by the presence of 6-benzylaminopurine (BA) in the culture medium in which the explant donor plantlets were maintained. Thirteen clonal lines (each derived from a different parental plant), compared for their embryogenic competence under the same culture conditions, produced very different embryogenic responses that varied from very high (117 embryos/explant) to null. The histological analysis revealed that the amount of meristematic tissue present in the tTCLs varied according to the region of the stem (apical, middle, or basal) from which they originated. The cells of the vascular procambium became competent and developed into cell lines that formed embryos, either by a unicellular or a multicellular pathway. Mature embryos germinated in half-strength Murashige and Skoog medium without growth regulators and 85% of regenerated plants was successfully acclimatized in a greenhouse.     

Changes in symplastic permeability during adventitious shoot regeneration in tobacco thin cell layers

Thin cell layer (TCL) explants of tobacco (Nicotiana tabacum L.) were cultured in either a regeneration medium that resulted in formation of adventitious vegetative shoots or a non-regeneration (control) medium that maintained the TCLs but did not promote shoot formation. Microinjections were conducted on epidermal cells at 1- or 2-day intervals during the culture period (14 days) and also on meristematic regions as they appeared in regenerating TCLs. A fluorescein isothiocyanate-labelled peptide (F(Glu)₃ MW 799) was used to assess the permeability of the symplast during adventitious shoot regeneration. A period of increased symplastic movement of F(Glu)₃ was detected during day 2 of culture and was significantly greater in regenerating TCLs than in non-regenerating TCLs. This corresponded to the period of the first cell divisions and represents the re-initiation of a meristematic type of symplastic linkage between epidermal cells. A smaller increase in cell-to-cell movement within non-regenerating TCLs indicated a possible stress response as a factor in these changes. Movement of F(Glu)₃ throughout the epidermal symplast of regenerating TCLs returned to pre-culture levels by the time of shoot primordia formation. F(Glu)₃ movement was further down-regulated in non-regenerating TCLs, with a high degree of cell isolation observed. Within newly formed shoots, symplastic movement of F(Glu)₃ cycled between high and low levels.     

Factors influencing the regeneration capacity of oilseed rape and cauliflower in transformation experiments

The efficiency ofAgrobacterium-based transformation technique in oilseed rape and cauliflower was influenced by cultivar specificity, donor plant age and explant type. Marked differences in demands for plant hormone contents in the regeneration medium were recorded already among different types of nontransformed explants. The highest regeneration capacity was recorded with stem and leaf segments isolated from one-month-old aseptically grown plants. The regeneration was markedly species-dependent. Regeneration of transformed plants from stem segments and thin layers isolated from field-grown oilseed rape plants (at the most 2% of regenerating explants) and from oilseed rape hypocotyls (0.8% of regenerating explants) and cauliflower (1.2% of explant regenerated transformed shoots) was achieved after disarmedAgrobacterium treatment. Hypersensitive reaction of explants could be prevented by using prolongedin vitro precultivation and delayed application of the selective agent.     

Sugar beet (Beta vulgaris L.) morphogenesis in vitro: Effects of phytohormone type and concentration in the culture medium, type of explants, and plant genotype on shoot regeneration frequency

In vitro regeneration techniques have been optimized for seven strains and cultivars of sugar beet (Beta vulgaris L.) bred in Russia. The frequency of shoot regeneration from somatic cells and tissues of sugar beet varies from 10 to 97% depending on the explant type, culture-medium composition, and genotype. The in vitro regeneration potential has been estimated in plants with different genotypes. The effect of medium composition (phytohormones and carbohydrates) on the frequency of the formation of a morphogenic callus competent for plant regeneration has been determined. The effect of the types and concentrations of various cytokines (zeatin, kinetin, and 6-benzylaminopurine) on direct shoot regeneration from cotyledon nodes has been estimated. The culture-medium composition has been optimized for direct shoot regeneration from petioles. The effects of different concentrations of abscisic acid on the frequency of shoot regeneration from a morphogenic callus has been studied. Micropropagation has been used to obtain petiole explants and reproduce the shoots obtained by direct regeneration from cotyledonnodes, petioles, and calluses. Improved shoot-regeneration methods can be used for both agrobacterial and bioballistic genetic transformation of the sugar beet genotypes studied.     

Developmental and hormonal regulation of direct shoot organogenesis and somatic embryogenesis in sugarcane (Saccharum spp. interspecific hybrids) leaf culture

Rapid and efficient in vitro regeneration methods that minimise somaclonal variation are critical for the genetic transformation and mass propagation of commercial varieties. Using a transverse thin cell layer culture system, we have identified some of the developmental and physiological constraints that limit high-frequency regeneration in sugarcane leaf tissue. Tissue polarity and consequently the orientation of the explant in culture, size and developmental phase of explant, and auxin concentration play a significant role in determining the organogenic potential of leaf tissue in culture. Both adventitious shoot production and somatic embryogenesis occurred on the proximal cut surface of the explant, and a regeneration gradient, decreasing gradually from the basal to the distal end, exists in the leaf roll. Importantly, auxin, when added to the culture medium, reduced this spatial developmental constraint, as well as the effect of genotype on plant regeneration. Transverse sections (1-2 mm thick) obtained from young leaf spindle rolls and orienting explants with its distal end facing the medium (directly in contact with medium) are critical for maximum regeneration. Shoot regeneration was observed as early as 3 weeks on MS medium supplemented with alpha-naphthalenencetic acid (NAA) and 6-benzyladenine, while somatic embryogenesis or both adventitious shoot organogenesis and somatic embryogenesis occurred on medium with NAA and chlorophenoxyacetic acid. Twenty shoots or more could be generated from a single transverse section explant. These shoots regenerated roots and successfully established after transplanted to pots. Large numbers of plantlets can be regenerated directly and rapidly using this system. SmartSett, the registered name for this process and the plants produced, will have significant practical applications for the mass propagation of new cultivars and in genetic modification programs. The SmartSett system has already been used commercially to produce substantial numbers of plants of orange rust-resistant and new cultivars in Australia.     

Griseofulvin

Griseofulvin (GF) is a mycotoxin produced by various species of Penicillium including P. griseofulvum Dierckx, P. janczewski (P. nigricans) and P. patulum. It is active against dermatophytic fungi of different species in the genera Microsporum, Trychophyton and Epidermophyton. Because of its capacity to concentrate in the keratinous layer of the epidermis and its relatively low toxicity in man, it has been extensively used in the therapy of dermatophytoses by oral administration. The biological activity of GF towards fungi is manifested as nuclear and mitotic abnormalities followed by distortions in the hyphal morphology. Mitotic segregation is also induced in fungi by GF treatment. In higher eukaryotes the cytostatic action of GF is essentially due to a mitotic arrest at late metaphase/early anaphase. The cytological effects observable both in vivo and in vitro on different plant and animal cell systems, include C-mitoses, multipolar mitoses and multinuclearity. Prolonged GF treatment in experimental animals provokes biochemical changes consisting mainly of disturbances of porphyrin metabolism, variation in the microsomal cytochrome levels and formation of Mallory bodies. In mice these alterations are followed by the development of multiple hepatomas. Evidence of tumor induction by GF has been obtained in mice and rats, but not in hamsters. GF may also act either as a promoting or a co-carcinogenic agent, depending on the circumstances of its administration. It has been found to increase the frequency of cell transformation induced by polyoma virus, but not to induce cell transformation per se. Induction of sperm abnormalities has been observed in GF-treated mice. The embryotoxic and teratogenic action of GF has been demonstrated in pregnant rats exposed during organogenesis. Genetic effects of GF have been investigated by the following tests: Salmonella/microsome mutagenicity assay, point mutations in mammalian and plant cells, DNA damage and repair, SCE, chromosome aberrations, micronuclei, dominant lethals, aneuploidy in lower and higher eukaryotes. A positive response has been obtained in the assays on numerical chromosome changes in all the systems analyzed; limited or inconclusive evidence has been obtained for SCE and structural chromosome changes. Doubled or highly polyploid sets can be detected in all types of cells during or immediately after GF treatment. A marked increase in chromosome number variation is observed at various times after withdrawal of the drug, with prevailing hyperdiploid and reduced sets in animal cells and plant cells respectively. Closely related to the effect on chromosome number is the ability of GF to increase the frequency of segregants for selected genetic markers in different cell systems either in the presence or in the absence of mutagenic treatment.The mode of action of GF on mitotic spindle microtubules (MTs) has been analyzed in comparison with other known antitubulins. Unlike colchicine and Vinca alkaloids GF causes a reduction or disruption of MTs, in relation to the dose, by inhibiting their combination with the microtubule-associated proteins (MAPs). Evidence in favor of this kind of interaction is provided by the results of studies on GF-resistant mutants in mammalian cells.In view of its unique properties as a microtubule-disorganizing agent, its capacity to induce chromosome malsegregation in a variety of organisms either in vivo or in vitro and its specific effects on liver metabolism, GF may be considered a valuable research antibiotic. Major reservations on its therapeutic use seem to be justified when considering the positive response to carcinogenicity and teratogenicity tests in animals and the chromosome effects observed both in vivo and in vitro.     

In vitro propagation and cryopreservation of Romanian endemic and rare Hypericum species

Efficient micropropagation and cryopreservation of Hypericum richeri ssp. transsilvanicum, an endemic species in Romania, and Hypericum umbellatum, a rare and endangered Daco-Balkan species, was achieved. The effects of type of explant and cytokinin on in vitro plant regeneration were investigated. Shoot organogenesis was achieved in all explants, but stem nodes regenerated best. Organogenesis from nodal segments was promoted by incubating these explants on Murashige and Skoog (MS) medium in the presence of cytokinins (6-benzyladenine, thidiazuron, kinetin or 6-??,??-dimethylallylaminopurine), each tested at four concentrations. The best morphogenic response for both Hypericum species (number of shoots per explant, shoot length, axillary branching of shoot, and frequency of shoot organogenesis) was observed when explants were incubated on MS medium containing 0.44 or 1.11???M 6-benzyladenine. Root induction was achieved only when regenerated shoots were transferred to fresh medium with or without auxin. Maximum rooting was recorded on MS medium supplemented with 2.45???M indole-3-butyric acid. Plantlets grown in vitro were successfully acclimatized in the greenhouse and showed normal development. Shoot tips and axillary buds excised from the in vitro regenerated plants were successfully cryopreserved in liquid nitrogen by the droplet-vitrification method. Following preculture in 0.25?M sucrose, dehydration and cryopreservation, the highest regeneration rates were obtained in both species by using axillary buds (68?% for H. richeri ssp. transsilvanicum and 71?% for H. umbellatum).     

Regeneration of Centella asiatica plants from non-embryogenic cell lines and evaluation of antibacterial and antifungal properties of regenerated calli and plants

Background

The threatened plant Centella asiatica L. is traditionallyused for a number of remedies. In vitro plant propagation and enhanced metabolite production of active metabolites through biotechnological approaches has gained attention in recent years.

Results

Present study reveals that 6-benzyladenine (BA) either alone or in combination with 1-naphthalene acetic acid (NAA) supplemented in Murashige and Skoog (MS) medium at different concentrations produced good quality callus from leaf explants of C. asiatica. The calli produced on different plant growth regulators at different concentrations were mostly embryogenic and green. Highest shoot regeneration efficiency; 10 shoots per callus explant, from non-embryogenic callus was observed on 4.42 μM BA with 5.37 μM NAA. Best rooting response was observed at 5.37 and 10.74 μM NAA with 20 average number of roots per explant. Calli and regenerated plants extracts inhibited bacterial growth with mean zone of inhibition 9-13 mm diameter when tested against six bacterial strains using agar well diffusion method. Agar tube dilution method for antifungal assay showed 3.2-76% growth inhibition of Mucor species, Aspergillus fumigatus and Fusarium moliniformes.

Conclusions

The present investigation reveals that non-embryogenic callus can be turned into embryos and plantlets if cultured on appropriate medium. Furthermore, callus from leaf explant of C. asiatica can be a good source for production of antimicrobial compounds through bioreactor.     

Rapid plant regeneration and analysis of genetic fidelity in micropropagated plants of Vitex trifolia: an important medicinal plant

An efficient in vitro regeneration protocol of a valuable medicinal plant, Vitex trifolia has been successfully established using nodal segments as explants. Three different cytokinins (BA, Kn, 2iP) and auxins (NAA, IAA, IBA) in different concentrations and combinations, evaluated as supplements to Murashige and Skoog’s medium showed to have a marked influence on the regeneration output. Among all the single cytokinin treatments MS medium supplemented with 5.0 μM BA produced the maximum number of shoots yielding 8.20 ± 0.37 shoots per explant with 4.8 ± 0.43 cm shoot length after 8 weeks of culture. Combined with low auxin concentrations, all the three cytokinins at their optimal concentrations synergistically enhanced the regeneration credentials. However, MS medium enriched with 5.0 μM BA and 0.5 μM NAA yielded the best possible regeneration in the species with a regeneration percentage of 97.33 ± 2.67 % and amounting to 16.80 ± 0.58 shoots per explant with 6.20 ± 0.25 cm mean shoot length at the end of 8 weeks in culture. Ex vitro rooting of in vitro derived microshoots was achieved by 20 min 500 μM IBA treatment followed by transfer to thermocol cups containing sterile soilrite. A 95 % plantlets survived acclimatization procedure to the field. Genetic conformity of the regenerated plants was established through RAPD. All the bands visualized on agarose gels were monomorphic with that of the donor plant indicating the clonal nature of the regenerants.     

Thin cell layer technology for induced response and control of rhizogenesis in chrysanthemum

Chrysanthemum (Dendranthema Xgrandiflora Ramat. Kitamura) stem transverse thin celllayers (tTCLs) were used to obtain defined morphogenic programs with selectedplant growth regulators. A rhizogenic pathway could be manipulated invitro by the application of a single auxin (2,4-D, NAA, IBA or IAA,in increasing order of rhizogenic response), or by the addition of coconutwater, with light or darkness playing a significant role. The addition of TIBAeliminated the rhizogenic capacity of all the auxins tested, but not that ofcoconut water, while the addition of activated charcoal was inhibitory. Theabsence of sucrose resulted in a limited rhizogenic response. Results clearlyindicate the importance of auxins, media additives and light in the activationof a rhizogenic program in chrysanthemum tTCLs. Due to their restricted size andmedium-dependant nature, the capacity to control rhizogenesis and/ororganogenesis in chrysanthemum (and indeed any plant species) by TCLs hasfar-reaching consequences and applications in the floricultural andpharmaceutical sectors. Since all factors (exogenously-applied hormones andother growth-stimulating or growth-inhibiting substances, light, temperature,humidity and other environmental cues) may be strictly controlled invitro, TCL technology allows for the establishment of protocols aimedat chrysanthemum flower improvement through genetic engineering, the success ofwhich lies in its first step i.e. programmable morphogenesis and regeneration.     

Effect of phyllotactic position and cultural treatments toward successful direct shoot organogenesis in dwarf ‘Pixie’ grapevine (Vitis vinifera L.)

In Vitis spp. where somatic embryogenesis-based regeneration predominates, an efficient, reproducible and robust method of direct shoot organogenesis from leaf explant material has been established in the dwarf wine grape ‘Pixie’ (Vitis vinifera). This regeneration system was achieved by testing the response of leaf material in two stages of development, and pre-conditioning the explant material in dark conditions and/or in liquid media prior to excising from the plant and placing it on solidified media. The pre-excision treatments included (1) a dark period of 24 h, with no regeneration medium; (2) soaking in regeneration medium followed by a dark period of 24 h; (3) a dark period of 24 h followed by soaking in liquid VRM (Vitis Regeneration Medium); (4) vacuum infiltration in liquid VRM followed by a dark period of 24 h; and (5) a control of no pre-conditioning treatment. Excised leaves from pre-treated intact plants in vitro significantly increased the frequency of shoot organogenesis. The most responsive explant material consisted of young semi-translucent apical leaves varying in size from 3 to 8 mm in length. The most successful combinations of factors contributing to shoot organogenesis involved the solely dark-exposed apical leaves or the soaking in VRM followed by a dark period. These results are expected to facilitate Vitis-related research in genetics, functional genomics, physiology, and other fields.     

Efficiency of direct and indirect shoot organogenesis in different genotypes of Rosa hybrida

To optimize indirect regeneration (IR) and direct regeneration (DR) in Rosa hybrida cv. Apollo different explant types and different concentrations of plant growth regulators were investigated. Among the different auxins studied and over all explant types, 10???M 2,4-dichlorophenoxyacetic acid (2,4-D) promoted the highest frequency of callus production for IR. The highest frequency of regeneration (60.8?%) was obtained when calli were transferred to Murashige and Skoog medium supplemented with 2.5???M thidiazuron (TDZ) and 2???M gibberellic acid. The highest frequency of regeneration (80.2?%) for DR was obtained from leaves cultured on the medium containing 10???M TDZ. The efficiency of IR and DR were compared in four different rose cultivars including ??Apollo??, ??Black Baccara??, ??Maroussia?? and ??Amanda??. The frequency of regeneration in all four cultivars was significantly higher in DR compared to IR. Also shoots regenerated by DR appeared earlier than the shoots regenerated by IR. The results of flow cytometry showed that the shoots derived from IR to DR were tetraploid like the original cultivars.     

Priming biotic factors for optimal protocorm-like body and callus induction in hybrid Cymbidium (Orchidaceae), and assessment of cytogenetic stability in regenerated plantlets

Protocorm-like bodies (PLBs) and callus were induced in epiphytic hybrid Cymbidium Twilight Moon ‘Day Light’, where induction capacity was strongly explant dependent. Following the use of various explant sources (PLB, leaf tip or base, root tip or base, cell and tissue ‘suspension’), highest PLB formation and callus induction occurred when we used whole PLBs, PLB segments or PLB transverse thin cell layers (tTCLs) or longitudinal TCLs (lTCLs). Plantlet growth and photosynthetic state from whole or bisected PLBs, as well as from tTCLs were not significantly different, after analysis of chlorophyll content. However plantlets generated from lTCLs showed lower values for growth and photosynthetic parameters. All resultant plants were shown to be cytogenetically identical using RAPD and mtDNA analysis despite cytological variation and endopolyploidy occuring between different plant parts. Acclimatization and survival rate was shown to be 100% in the generated plants.