In vitro plant regeneration via organogenesis of cowpea [Vigna unguiculata (L.) Walp.]

Shoot regeneration via organogenesis was achieved from axenic cowpea [Vigna unguiculata subsp. unguiculata L. (Walp.) Verde.] hypocotyls and cotyledons of advanced breeding lines and varieties. Cotyledons and embryos were excised from green immature pods. The apical parts of the embryos were removed and the hypocotyls were transferred to regeneration media. Cotyledons and hypocotyls were tested on media with gradients of several hormonal and putrescine combinations. Cowpea cotyledons and hypocotyls exhibited a pattern of shoot formation that occurred in three distinct phases. Multiple shoots developed within 45 days from the wounded region of the primary hypocotyl and cotyledons in different media containing a high cytokinin concentration. The induced plant explants were then grown for 20 days in low-intensity light (10 μmol m^–2 s^–1) on the same medium and numerous shoot buds emerged de novo from the upper part of the hypocotyl and the wounded part of the cotyledons. These buds had no apparent vascular connection with the parent tissues. The plant regeneration capability of this procedure was tested with several cowpea genotypes, five of which (83D-442, 86D-1010, 93K-624, Vita 3 and Ife Brown) responded positively with shoot development and were able to form roots and whole plants. Some somaclonal variation was observed. Received: 14 June 1996 / Revision received: 14 December 1996 / Accepted: 25 January 1997     

Genotype effects on proliferative embryogenesis and plant regeneration of soybean

Summary Proliferative somatic embryogenesis is a regeneration system suitable for mass propagation and genetic transformation of soybean [Glycine max (L.) Merr.]. The objective of this study was to examine genotypic effects on induction and maintenance of proliferative embryogenic cultures, and on yield, germination, and conversion of mature somatic embryos. Somatic embryos were induced from eight genotypes by explanting 100 immature cotyledons per genotype on induction medium. Differences in frequency of induction were observed among genotypes. However, this step was not limiting for plant regeneration because induction frequency in the least responding genotype was sufficient to initiate and maintain proliferative embryogenic cultures. Six genotypes selected for further study were used to initiate embryogenic cultures in liquid medium. Cultures were evaluated for propagation of globular-stage tissue in liquid medium, yield of cotyledon-stage somatic embryos on differentiation medium, and plant recovery of cotyledon-stage embryos. Genotypes also differed for weight and volume increase of embryogenic tissue in liquid cultures, for yield of cotyledon-stage embryos on differentiation medium, and for plant recovery from cotyledon-stage embryos. Rigorous selection for a proliferative culture phenotype consisting of nodular, compact, green spheres increased embryo yield over that of unselected cultures, but did not affect the relative ranking of genotypes. In summary, the genotypes used in this study differed at each stage of plant regeneration from proliferative embryogenic cultures, but genotypic effects were partially overcome by protocol modifications.     

Maturation,germination, and conversion of norway spruce (Picea abies L.) somatic embryos to plants

Summary Quantitative data are presented on the efficiency of three stages of plant regeneration from somatic embryos of Norway spruce (Picea abies L.): 1) Maturation, the development of immature embryos to the cotyledonary stage; 2) Germination, primary root growth; and 3) Conversion, plantlet survival and continued growth in nonaxenic conditions. Maturation frequency was calculated relative to the number of immature somatic embryos induced to develop on the basal medium of von Arnold and Eriksson (1981). The average number of immature somatic embryos was 700 per gram of embryogenic callus, on medium supplemented with ABA and IBA (1 μM each). Maturation was the least efficient stage of regeneration; an average of 3% of the embryos induced to develop reached the cotyledonary stage. Mean germination frequencies were improved on treatments which avoided immersion of the radicle in medium solidified with agar. Whereas, 27% of the somatic embryos germinated when radicles were immersed in agar medium, 45% germinated when placed on the surface of the medium, and 56% germinated when cotyledons were immersed in agar medium and the culture vessel inverted. Twenty-nine percent of the somatic embryos germinatedin vitro were converted to plants. Under greenhouse conditions these plants set dormant buds, subsequently survived overwintering (to −5°C), and renewed vegetative growth synchronously with seedlings grown under the same conditions. Our results verified long-term (2 year) growth and development potential of conifer somatic embryo plants.     

向日葵的幼胚培养

实验所用的基本培基中以B_5培养基对向日葵幼胚培养为最适。激素萘乙酸主要促进幼胚的胚性生长。吲哚乙酸(IAA)与激动素(KT)的配合使用,对幼胚的分化起明显的调节作用。天然提取物则明显地促进幼胚生长、其中荸荠汁的培养基可使向日葵球形胚进行正常发育。 用两种改良的B_5培养基做胚胎培养系统,使向日葵种间杂交胚生长发育。先将杂交后的心形胚培养在胚胎生长培养基上,进行充分的胚性生长。然后把胚转移到萌发培养基,使其萌发形成幼苗,最后移入土壤直至开花。     

Maturation of soybean somatic embryos and the transition to plantlet growth

The maturation of soybean (Glycine max L. Merr.) somatic embryos was characterized. Maturation was assayed by evaluating the ability of somatic embryos to make the transition to a plantlet through a germination-like process. Somatic embryos were organized from cotyledons of immature soybean embryos. Maturation of somatic embryos occurred on a Murashige-Skoog basal medium supplemented with activated charcoal and 0.28 molar sucrose. After 8 weeks on this medium, somatic embryos exhibited vigorous, high frequency development to plantlets. The “germination” frequency (conversion) of somatic embryos, and plantlet recovery frequency varied concurrently with maturation period. Conversion and plant recovery required no exogenous growth regulators. Desiccation of immature somatic embryos under controlled humidity regimes resulted in increased frequency of conversion of immature somatic embryos. Morphological abnormalities appeared in the somatic embryos, but few were detrimental to conversion velocity. There was little effect of genotype on conversion velocity or frequency.     

A protocol for efficient transformation and regeneration of Carica papaya L.

Summary A reproducible and effective biolistic method for transforming papaya (Carica papaya L.) was developed with a transformation-regeneration system that targeted a thin layer of embryogenic tissue. The key factors in this protocol included: 1) spreading of young somatic embryo tissue that arose directly from excised immature zygotic embryos, followed by another spreading of the actively growing embryogenic tissue 3 d before biolistic transformation; 2) removal of kanamycin selection from all subsequent steps after kanamycin-resistant clusters were first isolated from induction media containing kanamycin; 3) transfer of embryos with finger-like extensions to maturation medium; and 4) transferring explants from germination to the root development medium only after the explants had elongating root initials, had at least two green true leaves, and were about 0.5 to 1.0 cm tall. A total of 83 transgenic papaya lines expressing the nontranslatable coat protein gene of papaya ringspot virus (PRSV) were obtained from somatic embryo clusters that originated from 63 immature zygotic embryos. The transformation efficiency was very high: 100% of the bombarded plates produced transgenic plants. This also represents an average of 55 transgenic lines per gram fresh weight, or 1.3 transgenic lines per embryo cluster that was spread. We validated this procedure in our laboratory by visiting researchers who did four independent projects to transform seven papaya cultivars with coat protein gene constructs of PRSV strains from four different countries. The method is described in detail and should be useful for the routine transformation and regeneration of papaya. Based in part on a presentation at the 1997 SIVB Congress on In Vitro Biology held in Washington, DC, June 14–18, 1997.     

Induction of somatic embryogenesis in Pinus roxburghii Sarg.

Embryogenic calli were initiated from embryonic explants of Pinus roxburghii using female gametophytes containing immature pre-cotyledonary embryos. Zygotic embryos were collected at different developmental stages and cultured on various media. Initiation of embryogenic calli was achieved in pre-cotyledonary zygotic embryos of a 0.1-mm to 1.2-mm embryonal head on Douglus fir cotyledon revised medium (DCR) medium supplemented with 2,4-D or NAA and BA. Embryogenic callus development was initiated from the suspensor region of immature embryos. The method of immature embryo culture was significant as rapid embryogenic callus development occurred in megagametophytes where the suspensor was stretched onto the medium from the cut micropylar end. Sixty embryogenic lines were established from 2500 explants cultured during one season. A pro-embryo with six to eight meristematic cells and suspensor of six to ten long, vacuolated cells dominated the early phase of the callus development. Cleavage polyembryony occurred in proliferating callus, constituting a method of multiplication of these somatic embryos. Somatic embryos developed to stage-I and stage-II embryos on DCR medium supplemented with 5 μM 2,4-D or 10 μM NAA. Received: 30 June 1999 / Revision received: 15 November 1999 / Accepted: 3 December 1999     

2,4-Dichlorophenoxyacetic acid and kinetin in anther culture of cultivated and wild oats and their interspecific crosses: plant regeneration from A. sativa L.

The effect of 2,4-dichlorophenoxyacetic acid (2,4-D) and kinetin was studied in anther culture of oat Avena sativa L., wild oat A. sterilis L. and progeny of crosses between them. A high 2,4-D concentration (5–6 mg l^–1) increased embryo production in genotypes of both species and promoted plant regeneration in anther cultures of A. sterilis and A. sativa×A. sterilis progeny, while kinetin caused severe browning. However, a low concentration of kinetin was essential for initiation of regenerable embryos from anther culture of A. sativa cv. Kolbu: one green and one albino plant were produced. In addition, medium containing W₁₄ salts gave higher regenerant recovery compared with medium containing Murashge and Skoog salts, when cross progeny were tested. Received: 6 March 1998 / Revised: 30 April 1998 / Accepted: 16 November 1998     

Efficient plant regeneration from protoplasts of Arachis paraguariensis Chod. et Hassl. using a nurse culture method

Factors influencing in vitro growth rates of soybean embryos were investigated using embryos isolated in the cotyledon stage. The influence of these factors on final plant recovery from the embryos cultured was tested. Sucrose and glucose could serve as carbon sources with final plant yields being higher with sucrose than with glucose. A culture medium containing only KNO₃ (25 mM) as the nitrogen source supported embryo growth. Adding glutamine (10 mM) to the medium containing KNO₃ increased final plant recovery to 25%. Of several vitamin supplements tested a combination of pyridoxine-HCl, nicotinic acid and pantothenic acid (0.5; 1.0; 0.5 mg l^-1) provided the best growth and plant yield. Of the plant growth regulators tested IAA, BAP and GA₃ stimulated embryo growth and plant development when added to the medium at a low concentration (0.1 M). The optimal temperature for in vitro growth of cotyledon stage embryos was 27°C. Temperatures above 30°C caused growth retardation and reduced plant yield. A protocol for culturing soybean cotyledon stage embryos under conditions ensuring high plant recovery is proposed.Abbreviations IBA indole-3-butyric acid - GA₃ gibberellic acid - IAA indole-3-acetic acid - NAA -naphthaleneacetic acid - BAP 6-benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid     

Improved and synchronized maturation of Norway spruce (<Emphasis Type="Italic">Picea abies</Emphasis> (L.) H.Karst.) somatic embryos in temporary immersion bioreactors

Somatic embryogenesis offers many benefits for clonal propagation in large-scale plant production of conifers. A key rate-limiting step is the conversion from early-stage somatic embryos in pro-embryogenic masses (PEMs) to the maturation stage. Immature embryos in PEMs are present at different developmental stages, where some are unable to respond to the maturation treatment, thus limiting yields of mature embryos. Synchronization of early somatic embryo development in PEMs could greatly improve subsequent yields of mature embryos. A temporary immersion bioreactor designed for Norway spruce (Picea abies (L.) H.Karst.) was used in this study. Through a specific system for dispersion, connected tissue of PEMs, composed of immature embryos grown in liquid medium in the temporary immersion bioreactors or on solid medium as a control, was dispersed and redistributed in a more uniform spatial arrangement. It was demonstrated that development of mature embryos could be significantly stimulated by dispersion, compared to controls, in both medium types. Synchronization of maturation was evaluated by a statistical approach. The present study shows that the yield of mature embryos from dispersed PEMs was three to five times higher than that from non-dispersed controls in three of four cell lines of Norway spruce tested, both in bioreactors and on solid medium.     

Effect of exogenous ABA on embryo maturation and quantification of endogenous levels of ABA and IAA in <Emphasis Type="Italic">Quercus suber</Emphasis> somatic embryos

Knowledge of the relationship between indole-3-acetic acid (IAA) and abscisic acid (ABA) is relevant to control the development and the maturation of cork oak (Quercus suber L.) somatic embryos. The addition of 1 M ABA to the culture medium significantly promoted somatic embryo maturation and increased both fresh and dry matter without affecting the relative water content. This effect was parallel to the pattern of variation observed in the endogenous ABA level, which increased from the immature to the mature stage. Endogenous ABA content during the occurrence of secondary embryogenesis was similar to that of the immature stage, showing that embryos with lower ABA levels produced secondary embryos. In contrast, IAA showed the highest concentration during early embryo development and decreased afterwards. Only in somatic embryos subjected to 1-week desiccation followed by stratification at 4 °C for 2 weeks, was a moderate increment of endogenous IAA content observed. IAA and ABA showed opposite levels during the development and maturation of cork oak somatic embryos and characterised specific stages of the embryonic development.     

Somatic embryogenesis and plant regeneration of tropical maize genotypes

In Latin America and sub-Saharan Africa, tropical maize (Zea mays L.) is a major crop for human consumption. To cope with the increasing population and changing environment, there is a need for improving tropical maize germplasm. As part of a biotechnological approach, efficient in vitro regeneration of two tropical maize inbred lines (CML216 and CML244) was established. A number of parameters were optimized, such as age of the immature embryos, plant media and growth regulator concentration. After 6 weeks of culture, somatic embryos that had already reached the coleoptilar stage produced shoots after light induction and developed into fertile plants after acclimation in the soil. The callus induction frequencies and somatic embryo-derived plantlet formation were higher when cultured with the Linsmaier and Skoog medium than those with the Chu’s N6 basal medium. Regeneration of tropical maize shoots depended on the 2,4-dichlorophenoxyacetic acid (2,4-D) concentration at the callus initiation stage from immature embryos. The recalcitrance of the tropical maize inbred line TL26 to in vitro regeneration was overcome in a single-cross hybrid with the CML216 and CML244 genotypes. Remarkably, tropical maize somatic embryos were formed at the abaxial side of the scutellum facing the medium, probably from the axis of the immature embryos, as shown by histological sections. Upon co-cultivation, agrobacteria transiently expressed their intronless β-glucuronidase-encoding gene at the embryogenic tissue, but not with an intron-containing gene, suggesting that virulence genes are induced in Agrobacterium, but that subsequent steps in the T-DNA transfer are inhibited.     

Clonal propagation in vitro from immature embryos and flower buds of Lycopersicon peruvianum and L. esculentum

Direct propagation of Lycopersicon esculentum Mill. and L. peruvianum (L.) Mill. has been achieved from both reproductive and embryonic stages of the life cycle. Multiple adventitious shoots were induced from immature flower buds on Murashige and Skong (MS) basal medium supplemented with 2 mg 1⁻¹ 6-benzylaminopurine (BAP). Multiple shoots and somatic embryos were induced from immature zygotic embryos on HLH basal medium supplemented with 1 g 1⁻¹ yeast extract and 2 mg 1⁻¹ BAP. The nature of the response was related to the developmental stage of the parent embryo at explanting. The process of multiple shoot induction from embryos shows features in common with direct somatic embryogenesis from sexual embryos of Lycopersicon and other genera.     

Interspecific Hybridization of Trifolium repens with T. hybridum Using In Ovulo Embryo and Embryo Culture

In ovulo embryo culture followed by culture of excised immatureembryos produced interspecific hybrids between Trifolium repensL. (white clover) and autotetraploid T. hybridum L. (alsikeclover). Ovules containing hybrid embryos were excised 12–14 dafter pollination and cultured on Nitsch (1951) medium supplementedwith 15% young cucumber juice for 5–6 d. Embryos weresubsequently excised and transferred to hormone-free EG medium,a medium suitable for the culture of immature embryos. A total of 118 hybrid seedlings were obtained from 1978 reciprocalpollinations. All seedlings produced showed various chlorophylldeficiencies, either totally albino or albino with green sectors.Transmission electron microscope studies were carried out toinvestigate plastid development in embryos and seedlings. Someembryos produced only callus. Plants were regenerated from sevencalli. Two semi-albino plants survived transfer to soil, andone plant produced flowers. Backcrosses to T. repens producedone green plant. Hybridity is supported by analysis of morphological characters,karyotype and the gel electrophoretic separation of leaf isozymes. Pollen irradiated with 40 Gy of gamma rays was also used forpollinations. Results indicate that in certain cases ionizingradiation might be useful in overcoming hybrid inviability. Trifolium repens, Trifolium hybridum, clover, interspecific hybridization, in ovulo embryo culture, irradiation     

Interactions of ancymidol with sucrose and α-naphthaleneacetic acid in promoting asparagus (Asparagus officinalis L.) somatic embryogenesis

Interactions of varying ancymidol concentrations with those of α-naphthaleneacetic acid (NAA) or sucrose in embryo induction medium were related to the production and development of asparagus (Asparagus officinalis L.) somatic embryos, and to the ability of these embryos to germinate. A significant sucrose×ancymidol interaction was observed only for the production of bipolar embryos; 4% sucrose with 0.75 mg l^–1 ancymidol gave the best result, 78 g^–1 callus. The frequency of globular embryos decreased as sucrose or ancymidol concentrations increased. Sucrose concentration affected embryo germination; 3% and 4% sucrose were optimal with approximately 60% and 40% of bipolar and globular embryos germinating, respectively. Significant ancymidol×NAA interactions were observed for the production of bipolar and globular embryos and their germination. Varying ancymidol concentrations affected embryo production and germination in combination with 0.1 mg l^–1 NAA, but not with 1.0 mg l^–1 NAA. The treatment combination of 0.1 mg l^–1 NAA with 0.75 mg l^–1 ancymidol produced the most bipolar embryos, 64 g^–1 callus, and the greatest percentages of bipolar and globular embryos germinated, 63% and 42%, respectively. Received: 19 August 1996 / Revision received: 24 April 1997 / Accepted: 22 May 1997     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of sorghum (<Emphasis Type="Italic">Sorghum bicolor</Emphasis> (L.) Moench) using an improved in vitro regeneration system

An improved regeneration protocol suitable for transformation of sorghum was developed. The improvements focused on limiting the production of phenolic compounds and the use of suitable culture vessels for each developmental stage in plant regeneration from immature embryo derived calli. The addition of activated charcoal in the callus induction medium reduced the production of black pigments, however it also inhibited the callus formation on immature embryo explants. Cold pre-treatment of the immature seeds from which embryo explants were excised had a positive effect on both explant survival and callus formation. A one-day 4°C treatment of immature seeds significantly improved the callus formation from immature embryos and reduced the need for frequent subculture. Petri dishes with ventilation were suitable for the callus induction phase, but not for plant regeneration. Regeneration of plants could be improved by using disposal plastic boxes (250 ml volume) instead of Petri dishes. Agrobacterium-mediated transformation using the improved regeneration protocol and the hygromycin phosphotransferase gene as selectable marker resulted in the recovery of 15 transgenic plants from 300 initial immature embryos (5% efficiency). The transgenic nature of the obtained plants was demonstrated by Southern hybridisation and progeny analysis. The transgenes were inherited in a Mendelian fashion and were integrated at a single locus in the majority of the analysed lines.     

Repetitive somatic embryogenesis and plant recovery in white clover

Summary Breeding and selection was used to generate a population of white clover (Trifolium repens L.) from cultivar Osceola with a high embryogenic capacity. Somatic embryos were obtained from immature cotyledons of white clover placed onto EC6 basal medium containing 40 mg L^–1 of 2,4-D and 6% sucrose. The effects of 2,4-D at 20 and 40 mg L^–1 and of the carbohydrates, sucrose and maltose, were evaluated for their influence in the establishment of repetitive somatic embryogenesis. To determine the optimal protocol for plant recovery from somatic embryos, the effects of MS vs. EC6 basal salts, sucrose vs. maltose, B5 vitamins vs. yeast extract, and inclusion or exclusion of activated charcoal were evaluated. Repeated subculture of white clover somatic embryos on EC6 basal medium containing 6% sucrose with 2,4-D at 20 or 40 mg L^–1 effectively maintains repetitive embryogenesis. Medium containing MS salts with 6% maltose as the carbohydrate source was the most efficient for plant recovery.     

A liquid-medium-based protocol for rapid regeneration from embryogenic soybean cultures

Soybean [Glycine max (L.) Merrill] somatic embryos of the cultivar Jack underwent histodifferentiation in liquid Murashige and Skoog (MS) medium with 3% maltose, or according to the standard published procedure employing solidified MS media, permitting the recovery of an average of 8.1 and 3.9 embryos/mg of embryogenic tissue, respectively. Cotyledon-stage embryos that developed in liquid medium were ready for desiccation within 4 weeks, while the embryos from the standard procedure required a maturation step for an additional 4 weeks. Comparison of embryo development in MS medium with maltose or FN Lite-based medium without growth regulators and supplemented with maltose or an equimolar amount of sucrose revealed that sucrose promotes faster embryo histodifferentiation and maturation, and allows the recovery of up to 50% more mature, cotyledon-stage embryos within 3 weeks. The use of this liquid-medium-based protocol relative to the standard procedure led to a fourfold increase in the number of cotyledon-stage embryos recovered from other genotypes tested. In many cases, however, the percent germination was lower. Application of this new procedure also made it possible to harvest transgenic seed 9 months following biolistic bombardment, as compared to the 13 months required when the standard solid-medium-based protocol was used. Received: 1 December 1997 / Revision received: 27 April 1998 / Accepted: 20 May 1998     

High-yielding repetitive somatic embryogenesis and plant recovery in a selected tea clone, ‘TRI-2025’, by temporary immersion

 Methods for improving the efficiency of repetitive somatic embryogenesis and plant recovery from somatic embryos of clonal tea, TRI 2025 [Camellia sinensis (L.) O. Kuntze] were investigated by optimising the immersion frequencies of the explants using a modified temporary immersion system (TIS). The relative efficiencies of three conventional methods for multiplying embryos were compared with the temporary immersion method. The highest rate of multiplication of secondary embryos (24-fold) was achieved using the TIS. By controlling the immersion cycles, we achieved more consistent, synchronised multiplication and embryo development with a high level of plant recovery. A one-step computer-programmed immersion protocol based on a single, simple medium with no growth regulators was developed, enabling multiplication, maturation, germination and plant recovery within 17 weeks. Plantlets recovered through this method were hardy, with 2- to 5-cm-long shoots containing a minimum of 2–4 lush green leaves and a well-formed taproot. Callus formation, hyperhydricity and other developmental abnormalities were not observed at any stage in the process. Plantlets produced using this method were successfully acclimatised to glasshouse conditions. This protocol avoids culture transfers, and thus minimises the risk of contamination and reduces labour costs. This technique could have significant commercial implications in tea propagation as it has the potential for large-scale production with considerably reduced production costs. Received: 28 June 1999 / Accepted: 20 April 2000