Embryogenic response of Mexican alfalfa (Medicago sativa) varieties

The in vitro embryogenic response of nine varieties of alfalfa (Medicago sativa L.) grown in México (five Mexican varieties: Puebla 76, Inia 76, Bajío 76, Sintético I and Sintético II and four foreign or introduced varieties: Moapa 69, San Joaquín II, Hairy Peruvian and Valenciana) were tested. We screened 25 genotypes from each variety in four tissue culture protocols. All the varieties, except San Joaquín II, gave a positive response in one or more of the protocols tested. The response in each variety was low; this was also observed in a wider screening performed with the varieties Moapa 69, Hairy Peruvian, Sintético I and Sintético II. Two plants from Moapa 69 were regenerated and appeared normal.     

Embryogenic response of multiple soybean [Glycine max (L.) merr.] cultivars across three locations

Summary Nine soybean [Glycine max (L.) Merr.] cultivars representing midwestern, mid-south, and southern US growing regions were evaluated at each of three locations (Athens, GA; Lexington, KY; and Wooster, OH) using uniform embryogenic induction and proliferation protocols in order to evaluate the portability of soybean somatic embryogenic protocols to different locations. The experimental design minimized variation between locations by having all cultivars present at all locations on all days. A quantitative weighted score for primary embryo induction was developed on average embryo number per explant and was used to describe non-embryogenic, poorly embryogenic, moderately embryogenic, and highly embryogenic responses. Ranking of cultivars remained similar across all locations, indicating a uniform transportability of the protocol, at least as far as embryo induction is concerned. Continued proliferation of embryogenic cultures was also measured using a repetitive growth measure but few meaningful conclusions could be made due to the high level of variability including inconsistent growth of cultures between each subculture. Overall, several cultivars were identified as being uniformly embryogenic or non-embryogenic at the primary induction phase at all locations, and we predict that those embryogenic cultivars could be used by any laboratory for high-efficiency induction of embryogenesis. The best of these cultivars, ‘Jack’, was uniformly responsive across all locations and should be selected as the genotype most likely to yield positive results when attempting to culture and genetically engineer soybeans via embryogenic protocols.     

防风组织培养中畸形胚状体的发生和控制

采用组织培养和石蜡切片法,分析多种因素对防风畸形胚状体发生和发育过程的影响及控制。结果表明,诱导正常体细胞胚高频发生的培养基组合是：启动胚性愈伤组织的培养基是MS 0．5mg／L 2．4-D,蔗糖浓度3％;分化培养基是MS 1mg／L 6-BA 0．2mg／L NAA 0．5mg／L ABA,蔗糖浓度4％～5％;成熟培养基是MS培养基,蔗糖浓度3％。结论：一定浓度的生长素是诱导防风胚性愈伤组织的关键因素,细胞分裂素在体细胞胚的分化和发育过程中起协同作用;蔗糖浓度、ABA、接种方法以及适宜的培养条件和培养容器等均可有效降低畸形胚状体的发生率。     

Improvement of the tissue culture response of seed-derived callus cultures of Poa pratensis L.: Effect of gelling agent and abscisic acid

The effects of gelling agent and abscisic acid on the morphogenetic response of seed-derived callus cultures of Poa pratensis L. were investigated. On medium solidified with Gelrite, the regeneration frequency of the calluses was twice as high as compared to agar-solidified medium. The average number of green shoots per regenerating callus was not influenced by the type of gelling agent used. When abscisic acid was added to the differentiation medium only, or to both the differentiation medium and the regeneration medium, the percentage of calluses with somatic embryos or embryo-like structures increased (up to 29.6%) as compared to the control (16.4%). The plant formation frequency, however, was not affected by abscisic acid.     

High frequency somatic embryogenesis and plant regeneration in tissue cultures of Codonopsis lanceolata

Culture conditions for high frequency somatic embryogenesis and plant regeneration from cotyledonary explants of Codonopsis lanceolata are described. The maximum induction frequency of somatic embryos from cotyledonary explants was 80% on Murashige and Skoog (MS) medium containing 6% sucrose with 1 mg/l 2,4-dichlorophenoxyacetic acid and 10% coconut water. Upon transfer onto MS basal medium containing 3% sucrose, most somatic embryos developed into plantlets.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - GA₃ gibberellin a₃ - MS Murashige and Skoog     

Further evidence of a cybridization requirement for plant regeneration from citrus leaf protoplasts following somatic fusion

Summary Somatic hybridization experiments in Citrus that involve the fusion of protoplasts of one parent isolated from either nucellus-derived embryogenic callus or suspension cultures with leaf-derived protoplasts of a second parent, often result in the regeneration of diploid plants that phenotypically resemble the leaf parent. In this study, plants of this type regenerated following somatic fusions of the following three parental combinations were analyzed to determine their genetic origin (nuclear and organelle): (embryogenic parent listed first, leaf parent second) (1) calamondin (C. microcarpa Bunge) + Keen sour orange (C. aurantium L.), (2) Cleopatra mandarin (C. reticulata Blanco) + sour orange, and (3) Valencia sweet orange (C. sinensis (L.) Osbeck) + Femminello lemon (C. limon (L.) Burm. f.). Isozyme analyses of PGI, PGM, GOT, and IDH zymograms of putative cybrid plants, along with RFLP analyses using a nuclear genome-specific probe showed that these plants contained the nucleus of the leaf parent. RFLP analyses using mtDNA-specific probes showed that these plants contained the mitochondrial genome of the embryogenic callus donor, thereby confirming cybridization. RFLP analyses using cpDNA-specific probes revealed that the cybrid plants contained the chloroplast genome of either one or the other parent. These results support previous reports indicating that acquisition of the mitochondria of embryogenic protoplasts by leaf protoplasts is a prerequisite for recovering plants with the leaf parent phenotype via somatic embryogenesis following somatic fusion.Abbreviations cp chloroplast - GOT glutamateoxaloacetate transaminase - IDH isocitrate dehydrogenase - mt mitochondria - PEG polyethylene glycol - PGI phosphoglucose isomerase - PGM phosphoglucomutase - RFLP restriction fragment length polymorphism Florida Agricultural Experiment Station Journal Series No. R-04631.     

Mechanisms of somatic embryogenesis in cell cultures: Physiology,biochemistry, and molecular biology

Summary One of the most characteristic cell functions in plants is totipotency. Somatic embryogenesis can be regarded as a model system for the investigation of mechanisms of totipotency, because a high frequency and synchronous embryogenic system from single somatic cells has been established in carrot suspension cultures. Four phases are recognized in this process, and several molecular markers, viz. polypeptides, mRNAs, antigens against monoclonal antibodies, can be detected during the expression of totipotency, but they disappear during its loss. Four organ-specific genes have been isolated from hypocotyls and roots by differential screening. They were expressed preferentially after the globular-heart stages of embryogenesis, and were strongly suppressed by auxin. A CEM 1 gene was isolated by differential screening of embryogenic cell clusters. This gene was expressed strongly and transiently during the proglobular and globular stages. The sequence of CEM 1 was found to encode a polypeptide showing high homology to the elongation factor isolated from eucaryotic cells. Thus good progress is being made in understanding the basic mechanisms of somatic embryogenesis. Presented in the Session-in-Depth Developmental Biology of Embryogenesis at the 1991 World Congress on Cell and Tissue Culture, Anaheim, California, June 16–20, 1991.     

Application of bioreactor design principles to plant micropropagation

Principles of oxygen consumption, oxygen transport, suspension, and mixing are discussed in the context of propagating aggregates of plant tissue in liquid suspension bioreactors. Although micropropagated plants have a relatively low biological oxygen demand (BOD), the relatively large tissue size and localization of BOD in meristematic regions will typically result in oxygen mass transfer limitations in liquid culture. In contrast to the typical focus of bioreactor design on gas–liquid mass transfer, it is shown that media-solid mass transfer limitations limit oxygen available for aerobic plant tissue respiration. Approaches to improve oxygen availability through gas supplementation and bioreactor pressurization are discussed. The influence of media components on oxygen availability are also quantified for plant culture media. Experimental studies of polystyrene beads in suspension in a 30-l air-lift and stirred bioreactors are used to illustrate design principles for circulation and mixing. Potential limitations to the use of liquid suspension culture due to plant physiological requirements are acknowledged.     

In vitro plant regeneration of Aster scaber via somatic embryogenesis

We established an in vitro plant regeneration system via somatic embryogenesis of Aster scaber, an important source of various biologically active phytochemicals. We examined the callus induction and embryogenic capacities of three explants, including leaves, petioles, and roots, on 25 different media containing different combinations of α-naphthalene acetic acid (NAA) and 6-benzyladenine (BA). The optimum concentrations of NAA and BA for the production of embryogenic calli were 5.0 μM and 0.05 μM, respectively. Media containing higher concentrations of auxin and cytokinin (such as 25 μM NAA and 25 μM BA) were suitable for shoot regeneration, especially for leaf-derived calli, which are the most readily available calli and are highly competent. For root induction from regenerated shoots, supplemental auxin and/or cytokinin did not improve rooting, but instead caused unwanted callus induction or retarded growth of regenerated plants. Therefore, plant growth regulator-free medium was preferable for root induction. Normal plants were successfully obtained from calli under the optimized conditions described above. This is the first report of the complete process of in vitro plant regeneration of A. scaber via somatic embryogenesis.     

Secondary product formation in plant tissue cultures

The formation of secondary products in plant tissue culturesis reviewed. The conditions for the enhanced production of secondaryproducts, which include alkaloids, terpenoids, steroids andphenolics, can be regulated in a number of ways. For example,manipulation of secondary product formation is possible by varyingthe nutrient composition of the growth medium, light, temperatureand pH, and by the use of elicitors, permeabilisation and two-stagesystems. Molecular engineering and the use of biomass and large-scaleculture are described along with future prospects for the commercialproduction of secondary products from cell suspension cultures.     

Bioreactor-based advances in plant tissue and cell culture: challenges and prospects

Bioreactors are engineered systems capable of supporting a biologically active situation for conducting aerobic or anaerobic biochemical processes. Stability, operational ease, improved nutrient uptake capacity, time- and cost-effectiveness, and large quantities of biomass production, make bioreactors suitable alternatives to conventional plant tissue and cell culture (PTCC) methods. Bioreactors are employed in a wide range of plant research, and have evolved over time. Such technological progress, has led to remarkable achievements in the field of PTCC. Since the classification of bioreactors has been extensively reviewed in numerous reviews, the current article avoids repeating the same material. Alternatively, it aims to highlight the principal advances in the bioreactor hardware s used in PTCC rather than classical categorization. Furthermore, our review summarizes the most significant steps as well as current state-of-the-art of PTCC carried out in various types of bioreactor.     

Somatic embryogenesis and plant regeneration in olive (Olea europaea L.)

Leaf discs from olive (Olea europaea L.) grown in vitro and immature zygotic embryos collected at 50, 75, 90 and 105 days after full bloom were tested for their somatic embryogenic capacity. The embryos were grown in half-strength MS medium and half-strength OM medium with BAP combinated with either 2,4-D or NAA. Incubation was either in an initial dark period followed by 16h daylight or in 16h daylight throughout. Somatic embryogenesis, approx. 40%, mostly directly from the embryos, was observed only in 75-day-old embryos in medium containing low cytokinin and auxin concentrations. Differentiation was inhibited by 2,4-D whereas NAA did not. In leaf discs and younger and older zygotic embryos, only callus and root formation was observed. Somatic embryos were germinated and then potted-up to soil.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - BAP 6-benzylaminopurine - NAA naphtaleneacetic acid     

植物体细胞胚发生过程中基因表达的研究进展

植物体细胞胚胎发生是一个复杂的发育过程,研究者们通过分析植物体细胞胚发生过程中的基因表达或胚性组织和非胚性组织中基因的差异表达,获得了在体细胞胚发生过程不同时期表达的基因,并分析了这些基因在胚胎发生途径中可能的作用。综述了在植物体细胞胚发生过程中细胞周期相关基因、胁迫和激素应答相关基因、信号转导相关基因、晚期胚胎丰富蛋白基因及与体细胞胚发生相关的胞外蛋白基因表达的研究进展。     

Volatile emissions of plant tissue cultures

Summary The low-molecular-weight volatiles released by a variety of plant tissue cultures were examined by gas chromatography. Callus cultures invariably produced carbon dioxide, ethylene, acetaldehyde and ethanol. In cultures with developed shoots, ethanol was absent and acetaldehyde was detected only rarely.     

Beneficial effects of activated charcoal on plant tissue and organ cultures

Summary Addition of activated charcoal to the medium for plant tissue cultures improves growth by adsorbing toxic metabolites. This research was supported in part by the National Science Council, Republic of China     

植物体细胞胚胎发生的调控网络

植物体细胞胚胎发生是一个极其复杂而有序的过程,受到多种内外因素的影响与调控。其中基因的表达与调控是影响体细胞胚胎发生最重要和最根本的因素。这些基因包括PLANT GROWTH ACTIVATOR系列基因、LEAFYCOTYLEDON家族基因、BABY BOOM基因、SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE基因和PICKLE基因等,它们相互作用构成了一个复杂的调控网络。以下结合作者对PLANT GROWTH ACTIVATOR 37等基因的研究,对这一调控网络进行了介绍,并探讨了未来体细胞胚胎发生的研究方向。     

Morphogenesis in Helianthus Tuberosus: Genotypic Influence and Increased Totipotency in Previously Regenerated Plants

Leaf tissues of 38 genotypes, derived from four accessions, of the hexaploid species Helianthus tuberosus (2n=6x=102) responded to growth regulators (BA, NAA) chiefly by forming callus, while aventitious organogenesis or somatic embryogenesis were induced occasionally. A remarkable regeneration frequency (about 30 %) was achieved only from leaves of genotype HTPI-15. Explants of many regenerated plants of HTPI-15 subjected to a second culture cycle in vitro displayed a high morphogenetic potential (regeneration frequency > 90 %). White globular structures were initiated on the adaxial surface of these leaves without a callus phase. Somatic embryogenesis was asynchronous and embryoids, of different developmental stage, were simultaneously detected on each explant. Although many embryos developed single or malformed cotyledons or germinated precocciously, without the differentiation of a complete root system, phenotypically normal plants were regenerated after rooting on regulator-free half-strength MS medium. This revised version was published online in July 2006 with corrections to the Cover Date.     

Miscanthus×giganteus plant regeneration: effect of callus types,ages and culture methods on regeneration competence

The perennial rhizomatous grass, Miscanthus×giganteus is an ideal biomass crop due to its rapid vegetative growth and high biomass yield potential. As a naturally occurring sterile hybrid, M. ×giganteus must be propagated vegetatively by mechanically divided rhizomes or from micropropagated plantlets. Plant regeneration through somatic embryogenesis is a viable approach to achieve large‐scale production of plantlets in tissue culture. Effect of the callus types, ages and culture methods on the regeneration competence was studied to improve regeneration efficiency and shorten the period of tissue culture in M. ×giganteus. Shoot‐forming calli having a yellow or white compact callus with light‐green shoot‐like structures showed the highest regeneration frequency. Percentage of shoot‐forming callus induction from immature inflorescence explants was 41% on callus induction medium containing 13.6 μM 2,4‐d and 0.44 μM benzyladenine (BA). The use of a regeneration medium containing 1.3 μM NAA and 22 μM BA was effective at shortening the incubation period required for plantlet regeneration, with 69% of total regenerated plantlets obtained within 1 month of incubation on regeneration medium. Embryogenic‐like callus morphotype could maintain regeneration competency for up to 1 year as suspension cultures. Field grown regenerated plants showed normal phenotypic development with DNA content and plant heights comparable to rhizome propagated plants. Winter survival rates of the regenerated plants planted in 2006 and 2007 at the University of Illinois South Farm, Urbana‐Champaign, Illinois, were 78% and 56%, respectively.     

Application of plant tissue cultures in phytoremediation research: Incentives and limitations

The aim of this review is to critically assess the benefits and limitations associated with the use of in vitro plant cell and organ cultures as research tools in phytoremediation studies. Plant tissue cultures such as callus, cell suspensions, and hairy roots are applied frequently in phytoremediation research as model plant systems. In vitro cultures offer a range of experimental advantages in studies aimed at examining the intrinsic metabolic capabilities of plant cells and their capacity for toxicity tolerance. The ability to identify the contributions of plant cells to pollutant uptake and detoxification without interference from microorganisms is of particular significance in the search for fundamental knowledge about plants. However, if the ultimate goal of plant tissue culture experiments is the development of practical phytoremediation technology, the limitations inherent in the use of in vitro cultures as a representative of whole plants in the field must be recognized. The bioavailability of contaminants and the processes of pollutant uptake and metabolite distribution are likely to be substantially different in the two systems; this can lead to qualitative as well as quantitative differences in metabolic profiles and tolerance characteristics. Yet, many studies have demonstrated that plant tissue cultures are an extremely valuable tool in phytoremediation research. The results derived from tissue cultures can be used to predict the responses of plants to environmental contaminants, and to improve the design and thus reduce the cost of subsequent conventional whole plant experiments. Biotechnol. Bioeng. 2009;103: 60–76.     

Exploring plant tissue culture in Withania somnifera (L.) Dunal: in vitro propagation and secondary metabolite production

Withania somnifera (L.) Dunal (family: Solanaceae), commonly known as “Indian Ginseng”, is a medicinally and industrially important plant of the Indian subcontinent and other warmer parts of the world. The plant has multi-use medicinal potential and has been listed among 36 important cultivated medicinal plants of India that are in high demand for trade due to its pharmaceutical uses. The medicinal importance of this plant is mainly due to the presence of different types of steroidal lactones- withanolides in the roots and leaves. Owing to low seed viability and poor germination, the conventional propagation of W. somnifera falls short to cater its commercial demands particularly for secondary metabolite production. Therefore, there is a great need to develop different biotechnological approaches through tissue and organ culture for seasonal independent production of plants in large scale which will provide sufficient raw materials of uniform quality for pharmaceutical purposes. During past years, a number of in vitro plant regeneration protocols via organogenesis and somatic embryogenesis and in vitro conservation through synthetic seed based encapsulation technology have been developed for W. somnifera. Several attempts have also been made to standardize the protocol of secondary metabolite production via tissue/organ cultures, cell suspension cultures, and Agrobacterium rhizogenes-mediated transformed hairy root cultures. Employment of plant tissue culture based techniques would provide means for rapid propagation and conservation of this plant species and also provide scope for enhanced production of different bioactive secondary metabolites. The present review provides a comprehensive report on research activities conducted in the area of tissue culture and secondary metabolite production in W. somnifera during the past years. It also discusses the unexplored areas which might be taken into consideration for future research so that the medicinal properties and the secondary metabolites produced by this plant can be exploited further for the benefit of human health in a sustainable way.