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.     

Genetic variability of somatic embryogenesis in tissue cultures of sugar beet breeding lines

Genetic variability of callus initiation and plant regeneration has been investigated among three sugar beet genotypes. It was found that TDZ has a genotype-independent effect on callus initiation and is responsible for more than a two-fold increase in the friable callus induction rate and more than a three-fold increase in the shoot regeneration rate from this callus. Along with the genotype-independent organogenesis, regeneration from callus occasionally went through the process of somatic embryogenesis in a highly genotype-specific manner. Despite fast and uncontrollable conversion of embryos to normal plants, it was possible to select and maintain repetitive embryogenic culture without loosing regeneration and root formation capabilities. Extensive experimenting with medium composition and culture conditions resulted in an optimal medium for maintenance of repetitive embryos. Comparing with BAP, low concentrations of TDZ provide higher level of adventitious shoot formation and do not induce vitrification of tissues.     

Efficient procedures for callus induction and adventitious shoot organogenesis in sugar beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) breeding lines

Summary Improved in vitro tissue culture systems are needed to facilitate the application of transgene technology to the improvement of sugar beet germplasms. Several commercially important sugar beet breeding lines (SDM, 3, 5, 8, 9, 10, 11, HB 526, and CMS 22003) and commercial varieties (Roberta and Gala) were tested for their regeneration capacity through adventitious shoot organogenesis from cotyledons, hypocotyls, root/hypocotyl/shoot transition zone tissues, and leaf lamina and petiole via an intervening callus phase. Callus induction and adventitious shoot regeneration was dependent on genotype and combinations of plant growth regulators. With cotyledon or hypocotyl explants, SDM 3 and 10 showed a better response on adventitious shoot regeneration in medium containing benzyladenine (BA) and 2,3,5-triiodobenzoic acid or 1-naphthaleneacetic acid (NAA) than SDM 11, 5, and 9. Shoot regeneration was obtained from hypocytyl-root or hypocotyl-shoot transition zone tissue in SDM 9, 10, and HB 526 grown on PGo medium supplemented with BA to induce callus, and the regeneration frequency was 25%. Adventitious shoots were also regenerated from leaf explants of SDM 3 and 9 cultured on medium containing NAA for callus induction and BA and NAA to induce shoot regeneration, and in SDM 10 and CSM 22003 cultured on medium containing BA for callus induction and to induce shoot regeneration.     

In Vitro Shoot Regeneration from Callus, Leaf Axils and Petioles of Sugar Beet (Beta vulgaris L.)

Procedures are described for producing axillary shoots fromseedling apices and adventitious shoots from petioles and leaf-derivedcallus of sugar beet cultivars. The rate of adventitious shootregeneration from petioles was influenced by temperature, BAPconcentration of the medium, and the time in culture of theseedling apices from which the petioles were excised. Petiolesectioning confirmed that adventitious shoots originated inthe sub-epidermal parenchyma. Two distinct types of callus wereproduced from leaf explants, but only white friable callus wascapable of shoot development. This callus developed from browntissue and was composed of thin-walled cells with dense cytoplasmand prominent nuclei. Green compact callus with thick-walledlignified cells developed from green tissue, but did not produceshoots. Successful seed sterilization and shoot regenerationfrom petiole explants and callus was cultivar-dependent. Adventitiousshoots were rooted and successfully transplanted to pottingcompost under glasshouse conditions. Key words: Adventitious shoots, axillary shoots, callus, sugar beet (Beta vulgaris L.)     

Plantlet regeneration from cotyledon,cotyledon petiole,and hypocotyl explants via somatic embryogenesis pathway in roquette (Eruca sativa Mill)

Abstract

A high-efficiency plant regeneration protocol based on somatic embryo formation for Huining Roquette, an interesting ecotype of Eruca sativa Mill, was established for future transgenic applications. On Murashige and Skoog (MS) medium containing 2,4-dichlorophenoxyacetic acid (2,4-D), alone or in combination with 6-benzylaminopurine (BA) or kinetin (KT), the cotyledon explants, cotyledon petioles, and hypocotyls all produced embryogenic callus (ECs) or somatic embryos (SEs) to different extents. After transferring onto hormone-free MS medium, the ECs or SEs from the different explants and media, all of them developed shoots with a frequency of 6–48%, and then produced roots with a frequency of 2–29%. As regards the probability of shoot differentiation, cotyledon explants appeared similar to hypocotyls, but superior to cotyledon petioles; 2,4-D + KT worked more effectively than 2,4-D alone and 2,4-D + BA for callus induction and shoot differentiation. The optimal hormone combinations for plant regeneration of cotyledon, cotyledon petiole, and hypocotyl explants were 1.0 mg/l 2,4-D + 0.1 mg/l KT, 0.8 mg/l 2,4-D + 0.3 mg/l BA, and 1.0 mg/l 2,4-D + 0.3 mg/l KT, respectively. MS medium with 60–80 g/l sucrose was the most effective for improving SE maturation and germination.     

Thidiazuron-induced organogenesis and somatic embryogenesis in sugar beet (Beta vulgaris L.)

Summary Improved in vitro tissue culture systems are needed to facilitate the application of recombinant DNA technology to the improvement of sugar beet germplasm. The effects of N ⁶-benzyladenine (BA) and thidiazuron (TDZ) pretreatment on adventitious shoot and somatic embryogenesis regeneration were evaluated in a range of sugar beet breeding lines and commercial varieties. Petiole explants showed higher frequencies of direct adventitious shoot formation and produced more shoots per explant than leaf lamina explants. TDZ was more effective than BA for the promotion of shoot formation. The optimal TDZ concentrations were 2.3–4.6 μM for the induction of adventitious shoot regeneration. Direct somatic embryogenesis from intact seedlings could be induced by either BA or TDZ. TDZ-induced somatic embryogenesis occurred on the lower surface of cotyledons at concentrations of 0.5–2μM and was less genotype-dependent than with Ba. A high frequency of callus induction could be obtained from seedlings and leaf explants, but only a few of the calluses derived from leaf explants could regenerate to plants via indirect somatic embryogenesis. These results demonstrated that TDZ could prove to be a more effective cytokinin for in vitro culture of sugar beet than BA. Rapid and efficient regeneration of plants using TDZ may provide a route for the production of transgenic sugar beet following Agrobacterium-mediated transformation.     

川芎高频再生体系的建立

为建立川芎(Ligusticum chuanxiong Hort.)高频再生体系,优化了诱导和分化培养基及培养条件。以叶柄为外植体,以MS为基本培养基,KT 2.0 mg/L+IAA 0.5 mg/L的激素组合对不定芽分化最有利。在此基础上,针对外植体来源、培养条件和愈伤组织继代时间3个因素进行优化。结果表明:采用川芎无菌苗叶柄作为外植体,黑暗条件下诱导出愈伤组织,再在光照下继代培养15 d后转入分化培养基中对不定芽诱导最为有利,分化率为44.4%。分化后得到的不定芽在含NAA 0.5 mg/L和IBA 0.5 mg/L的 1/2MS培养基上生根率达90%,移栽存活率为95%。     

Rhizobium radiobacter conjugation and callus-independent shoot regeneration used to introduce the cercosporin export gene cfp from Cercospora into sugar beet (Beta vulgaris L.)

Leaf spot disease caused by Cercospora is responsible for crop and profitability losses in sugar beet crops in the US and worldwide. The cfp gene that encodes a protein that exports phytotoxic cercosporins from Cercospora was conjugally transferred to sugar beet using Rhizobium radiobacter (Agrobacterium tumefaciens), to improve Cercospora-induced leafspot resistance. Conditions for shoot regeneration were optimized to increase regeneration/transformation efficiencies. Low-light and room-temperature conditions were favorable to sugar beet regeneration without callus when cytokinin had been added to the tissue culture medium. Using this procedure adventitious shoots from leaf pieces were obtained in a simple, one-step regeneration procedure. T7, a cfp-transgenic clone verified by PCR with gene-specific primers, is being propagated for leaf spot disease resistance evaluation.     

Effect of genotype on callus induction,shoot regeneration,and phenotypic stability of regenerated plants in the greenhouse of Primula ssp.

Genotypic differences between six genotypes of Primula vulgaris could be observed in callus induction rate, type of callus, root formation during the callus phase, and shoot regeneration rate. The shoot regeneration rate ranged from zero to 11.6 shoots per explant. There was no correlation between callus induction rate and shoot regeneration rate. Callus consistency and colour were an indicator of the organogenetic capacity of callus. An experiment with different periods of treatment with 4.0 mg l 2,4-dichlorophenoxyacetic acid and 2.0 mg l21 thidiazuron revealed that the shoot regeneration rate varied tremendously between genotypes. In two genotypes a period of 8 weeks on medium with plant growth regulators was sufficient to induce shoot regeneration. In three other genotypes a longer induction period was not able to overcome low regeneration capacity. However an increase in shoot regeneration rate was observed after 16iV32 weeks of induction. Phenotypic stability was also strongly dependent on genotype. In three genotypes the majority of regenerated plants looked normal and were diploid. Aberrations like abnormal growth habit, crinkly leaves, deviation of flower colour or lack of pollen formation occurred in only one genotype at a very low frequency (1.5 genotypes between 12.5 and 18.1 regenerants was tetraploid.     

Somatic embryogenesis in pearl millet (Pennisetum glaucum): Strategies to reduce genotype limitation and to maintain long-term totipotency

Three genotypes of Pearl millet were screened in vitro for induction of embryogenic callus, somatic embryogenesis and regeneration. Shoot apices excised from in vitro germinated seedlings or immature embryos isolated from green house established plants were used as primary explants. The frequency of embryogenic callus initiation was significantly higher in shoot apices in comparison with immature zygotic embryos. Moreover, differences between genotypes were minimal when using shoot apices. Friable embryogenic calli (type II) developed on the initial nodular calli after 1 to 3 months of culture. The frequency of type II callus is related to the composition of the maintenance medium and they were more often found in ageing cultures. The transfer of embryogenic calli onto auxin-free medium was sufficient for inducing somatic embryo development in short-term culture (3 months) while a progressive loss in regeneration potential was observed with increasing time of subcultures. Maturation of embryogenic calli on medium supplemented with activated charcoal, followed by germination of somatic embryos on medium supplemented with gibberellic acid, restored regeneration in long-term cultures. This revised version was published online in June 2006 with corrections to the Cover Date.     

<Emphasis Type="Italic">In vitro</Emphasis> organogenesis of chestnut (<Emphasis Type="Italic">Castanea sativa</Emphasis> Mill.) cotyleodon explants: responses to growth regulators and developmental aspects

Summary Adventious root and shoot formation was obtained from cotyledon fragments of chestnut (Castanea sativa Mill.) and these processes followed two phases. In a first stage after detachment of the embryonic axis, the cotyledon fragments in culture formed a cotyledon petiole, which elongated for about 6d. Thereafter, root primordia arose at the tip of the cotyledon petioles, followed by normal root development. In some cases, the cotyledon, petioles showed adventitious shoot regeneration from a nodular structure previously formed at the end of the petioles. The presence or absence of growth regulators did not significantly influence root regeneration, whereas cytokinins stimulated shoot formtion. The processes of root and shoot differentiation were studied also at the histological level. Observation with a light microscope showed that the developing root apical meristems were connected with a vascular bundle of the cotyledon petiole. Similarly, shoot bud meristem connections were observed with vascular tissue inside the nodular structure.     

Glutamine improves shoot morphogenesis in chickpea (Cicer arietinum L.)

The use of glutamine has been shown to increase the frequency of organogenesis and regeneration in the in vitro culture of several plants. The effect of glutamine on hormone-induced multiple shoot formation in desi and kabuli genotypes of chickpea (C-235 and PUSA-1053) were evaluated. Embryo axes with or without attached cotyledons were cultured in thidiazuron (TDZ) or 6-benzylaminopurine (BAP)-containing medium, respectively, with various concentrations of glutamine. Glutamine improved and prolonged the multiple shoot regeneration ability of the embryo axis. Chickpea embryo axis with attached cotyledon and cultured in TDZ-containing medium showed improved and prolonged shoot regeneration with 5 mM glutamine, while embryo axis without cotyledon and cultured in BAP-containing medium showed prolonged regeneration ability in 10 mM glutamine. Glutamine, however, did not serve as a substitute for cotyledon. Desi genotype (C-235) showed better response for multiple shoot formation as compared to the kabuli genotype (PUSA-1053). Glutamine at a concentration of 5 mM also improved root formation in excised in vitro shoots.     

川芎高频再生体系的建立

为建立川芎(Ligusticum chuanxiong Hort.)高频再生体系,优化了诱导和分化培养基及培养条件.以叶柄为外植体,以MS为基本培养基,KT2.0 mg/L+ IAA0.5mg/L的激素组合对不定芽分化最有利.在此基础上,针对外植体来源、培养条件和愈伤组织继代时间3个因素进行优化.结果表明:采用川芎无菌苗叶柄作为外植体,黑暗条件下诱导出愈伤组织,再在光照下继代培养15d后转入分化培养基中对不定芽诱导最为有利,分化率为44.4％.分化后得到的不定芽在含NAA0.5 mg/L和IBA 0.5 mg/L的1/2MS培养基上生根率达90％,移栽存活率为95％.     

Genetic transformation of sugar beet: evolution of theoretical and experimental approaches

The review is dedicated to several aspects of sugar beet (Beta vulgaris L.) biotechnology: in vitro cultivation, callus induction, plant regeneration and genetic transformation. Media composition, methods of plant regeneration via somatic embryogenesis and protoplast culture are analysed. The use of Agrobacterium tumefaciens and gold particle bombardment is the base for modern genetic transformation methods.     

萝卜带柄子叶高频再生体系的建立

以11份萝卜（Raphanus sativus）基因型为材料进行子叶离体培养研究,筛选出具有较高再生率的基因型进行实验,考察基因型、外植体类型、激素配比和苗龄等因素对萝卜再生的影响。结果表明：萝卜离体再生的最佳外植体为全子叶-叶柄,最适苗龄为4天,最适培养基为MS＋6mg·L-16-BA＋0.05mg·L-1NAA,再生率高达86.95%,再生系数为1.80。该研究为进行萝卜遗传转化实验奠定了良好基础。     

Effect of genotype and medium composition on linseed (<Emphasis Type="Italic">Linum usitatissimum</Emphasis>) ovary culture

Breeding linseed (Linum usitatissimum L.) using haploid techniques allows breeders to develop new cultivars in a shorter time period. Many research groups successfully created new linseed genotypes through anther culture; however ovary culture has been the subject of only a few earlier studies. In the present study, the effect of genotype and growth regulators combination on callus induction and shoots regeneration in ovary culture of nine commercially important linseed cultivars was investigated. Ovaries were cultured on modified MS medium supplemented with three different combinations of plant growth regulators. Variable callogenic responses were expressed by all of the genotypes tested on different induction media. The results suggested that specific combination of growth regulators for callus induction must be designed for each genotype. Shoot regeneration from ovary derived callus is a critical phase of the whole gynogenetic process. Differences in adventitious shoot formation frequency among genotypes were demonstrated and four responsive genotypes have been selected. Ovary derived callus from cultivar ‘Mikael’ manifested the highest adventitious shoot formation frequency with a high number of shoots per explant. The optimum ratio of growth regulators for shoot regeneration was shown to depend on the genotype. Cultivars ‘Linola’, ‘Mikael’ and ‘Szaphir’ showed the highest shoot regeneration frequency when callus had originated on induction medium supplemented with 2 mg L⁻¹ BAP and 2 mg L⁻¹ NAA, while combination of 1 mg L⁻¹ BAP and 2 mg L⁻¹ IAA promoted shoot formation in ovary-derived callus of ‘Barbara’. The highest rate of shoots per explant has been obtained in second subculture.     

Adventitious shoot regeneration from immature embryos of sorghum

Eleven genotypes of sorghum were examined for their response in tissue culture, and the tissue culture system was optimized. The cultures were initiated from immature embryos taken approximately two weeks after flowering. The response of immature embryos varied with the genotype. `C. Kafir' and `PE932 025' showed the highest frequency of callus induction and regenerable callus formation under appropriate culture conditions. Regeneration occurred at high frequencies when cytokinins (kinetin or 6-benzyladenine) had been added in the callus induction medium, followed by regeneration medium devoid of growth regulators. The addition of proline and polyvinylpyrrolidone also enhanced shoot formation, but the addition of cytokinins to regeneration media did not improve shoot formation. On the revised culture medium, plants were regenerated from up to 100% of sorghum immature embryos.     

Clonal propagation byin vitro culture of Corchorus (jute)

Callus was produced on cotyledon, shoot tip, hypocotyl and root explants of twoCorchorus species on several media. Cytokinin was necessary for callus production on cotyledon explants. BothC.olitorius genotypes produced most callus on media with zeatin and either NAA or IAA, and theC.capsularis genotype produced most callus on media with IAA and either zeatin or BA. High frequencies of regenerated shoots were obtained from shoot tip explants of both species, from the apical meristem and from callus. Media with 2.0 mg 1⁻¹ BA were superior for both species, and media with zeatin were equally good forC.capsularis only. More regeneration was obtained for all genotypes after subculture of callus on media with 2.0 mg 1⁻¹ zeatin. Cotyledon callus produced less regeneration, also with differences between genotypes; explants of both genotypes ofC.olitorius produced regeneration on a medium with NAA and zeatin, and theC.capsularis genotype produced regeneration on a medium with IAA and BA. Limited regeneration from root explant callus was obtained forC.capsularis only on medium with BA and IAA. Regeneration was not obtained from hypocotyl callus. Further regeneration of shoots of both species was obtained from secondary callus after subculture, and from nodal segments of regenerated shoots and of seedling shoots cultured on basic MS medium without growth hormones. Roots were produced on about 80% of all shoots after transference to medium with 0.2 mg 1⁻¹ IBA, and rooted plantlets survived and flowered normally after transference to compost.     

Efficient somatic embryogenesis in sugar beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) breeding lines

Efficient regeneration via somatic embryogenesis (SE) would be a valuable system for the micropropagation and genetic transformation of sugar beet. This study evaluated the effects of basic culture media (MS and PGo), plant growth regulators, sugars and the starting plant material on somatic embryogenesis in nine sugar beet breeding lines. Somatic embryos were induced from seedlings of several genotypes via an intervening callus phase on PGo medium containing N⁶-benzylaminopurine (BAP). Calli were mainly induced from cotyledons. Maltose was more effective for the induction of somatic embryogenesis than was sucrose. There were significant differences between genotypes. HB 526 and SDM 3, which produced embryogenic calli at frequencies of 25–50%, performed better than SDM 2, 8, 9 and 11. The embryogenic calli and embryos produced by this method were multiplied by repeated subculture. Histological analysis of embryogenic callus cultures indicated that somatic embryos were derived from single- or a small number of cells. 2,4-dichlorophenoxyacetic acid (2,4-D) was ineffective for the induction of somatic embryogenesis from seedlings but induced direct somatic embryogenesis from immature zygotic embryos (IEs). Somatic embryos were mainly initiated from hypocotyls derived from the cultured IEs in line HB 526. Rapid and efficient regeneration of plants via somatic embryogenesis may provide a system for studying the molecular mechanism of SE and a route for the genetic transformation of sugar beet.