Hygromycin resistance as an efficient selectable marker for wheat stable transformation

Summary A highly efficient method for stable wheat transformation using hygromycin resistance as a selectable marker is described. Young embryogenic calli growing from immature wheat embryos were transformed using a gunpowder-driven microparticle accelerator. Transgenic wheat plants were determined by PCR amplification of transgene fragments and confirmed by Southern hybridization, activity of the transgene expression and by analysis of the progeny. The hpt gene was as good as or a better selectable marker than the bar gene with an average efficiency (number of transgenic plants relative to the number of bombarded calli) of 5.5% compared with 2.6% for the bar gene.     

An efficient wheat transformation procedure: transformed calli with long-term morphogenic potential for plant regeneration

 A method for producing large numbers of transgenic wheat plants has been developed. With this approach, an average of 9.7% of immature embryo explants were transformed and generated multiple self-fertile, independently transformed plants. No untransformed plants, or escapes, were regenerated. This transformation procedure uses morphogenic calli derived from scutellum tissue of immature embryos of Triticum aestivum cv. Bobwhite co-bombarded with separate plasmids carrying a selectable marker gene (bar) and a gene of interest, respectively. Transformed wheat calli with a vigorous growth phenotype were obtained by extended culture on media containing 5.0 mg/l bialaphos. These calli retained morphogenic potential and were competent for plant regeneration for as long as 11 months. The bar gene and the gene of interest were co-expressed in T0 progeny plants. This wheat transformation protocol may facilitate quantitative production of multiple transgenic plants and significantly reduce the cost and labor otherwise required for screening out untransformed escapes. Received: 15 June 1998 / Revision received: 6 April 1999 / Accepted: 26 April 1999     

Transgenic maize plants by tissue electroporation.

In this paper, we describe the transformation of regenerable maize tissues by electroporation. In many maize lines, immature zygotic embryos can give rise to embryogenic callus cultures from which plants can be regenerated. Immature zygotic embryos or embryogenic type I calli were wounded either enzymatically or mechanically and subsequently electroporated with a chimeric gene encoding neomycin phosphotransferase (neo). Transformed embryogenic calli were selected from electroporated tissues on kanamycin-containing media and fertile transgenic maize plants were regenerated. The neo gene was transmitted to the progeny of kanamycin-resistant transformants in a Mendelian fashion. This showed that all transformants were nonchimeric, suggesting that transformation and regeneration are a single-cell event. The maize transformation procedure presented here does not require the establishment of genotype-dependent embryogenic type II callus or cell suspension cultures and facilitates the engineering of new traits into agronomically relevant maize inbred lines.     

Optimisation of transformation conditions and production of transgenic sorghum (Sorghum bicolor) via microparticle bombardment

Conditions for microparticle bombardment were optimised for four explant types of sorghum Sorghum bicolor (L.) Moench based on transient expression of the uidA reporter gene. The tested physical parameters included acceleration pressure, target distance, gap width and macroprojectile travel distance. The sorghum explants studied were immature and mature embryos, shoot tips and embryogenic calli. In addition, the activity of four heterologous promoters was determined both by GUS histochemical staining and enzymatic activity assay in immature embryos and shoot tips. The strength of these promoters could be placed in the following order: ubi1> act1D> adh1>CaMV 35S. The optimised bombardment conditions were applied for selecting phosphinothricin- or geneticin-resistant in vitro cultures in order to generate transgenic plants. Production of transgenic plants via phosphinothricin-selection was not successful due to the release of phenolic substances from the herbicide-resistant cultures during the regeneration process. After selection on geneticin, however, fertile transgenic sorghum plants were regenerated from immature embryos as well as from shoot tips. Stable integration and Mendelian inheritance of the neo selectable marker gene was demonstrated in all transgenic plants.     

The Effect of Aerobic Methylotrophic Bacteria on the in vitro Morphogenesis of Soft Wheat (Triticum aestivum)

The effects of four aerobic methylotrophic bacteria on the morphogenesis of soft wheat (Triticum aestivum) were studied in vitro using immature embryos as explants. The inoculation of the embryos with methylotrophic bacteria led to their stable colonization with the bacteria. The colonization of the explants with the strains of Methylobacterium sp. D10 and Methylophilus glucoseoxidans stimulated the formation of morphogenic calli and shoots and also promoted development of the regenerated plants. These regenerated plants manifested bright green leaves and a well-developed root system. The colonization of immature wheat embryos with methylotrophic bacteria can be employed as a tool for raising the efficiency of genetic transformation of various wheat cultivars.     

Agrobacterium-mediated large-scale transformation of wheat (Triticum aestivum L.) using glyphosate selection

An Agrobacterium-mediated transformation system with glyphosate selection has been developed for the large-scale production of transgenic plants. The system uses 4-day precultured immature embryos as explants. A total of 30 vectors containing the 5-enol-pyruvylshikimate-3-phosphate synthase gene from Agrobacterium strain CP4 (aroA:CP4), which confers resistance to glyphosate, were introduced into wheat using this system. The aroA:CP4 gene served two roles in this study-selectable marker and gene of interest. More than 3,000 transgenic events were produced with an average transformation efficiency of 4.4%. The entire process from isolation of immature embryos to production of transgenic plantlets was 50-80 days. Transgenic events were evaluated over several generations based on genetic, agronomic and molecular criteria. Forty-six percent of the transgenic events fit a 3:1 segregation ratio. Molecular analysis confirmed that four of six lead transgenic events selected from Agrobacterium transformation contained a single insert and a single copy of the transgene. Stable expression of theAROA:CP4 gene was confirmed by ELISA through nine generations. A comparison of Agrobacterium-mediated transformation to a particle bombardment system demonstrated that the Agrobacterium system is reproducible, has a higher transformation efficiency with glyphosate selection and produces higher quality transgenic events in wheat. One of the lead events from this study, no. 33391, has been identified as a Roundup Ready wheat commercial candidate.     

The development of herbicide-resistant maize: stable Agrobacterium-mediated transformation of maize using explants of type II embryogenic calli

One of the limitations to conducting maize Agrobacterium-mediated transformation using explants of immature zygotic embryos routinely is the availability of the explants. To produce immature embryos routinely and continuously requires a well-equipped greenhouse and laborious artificial pollination. To overcome this limitation, an Agrobacterium-mediated transformation system using explants of type II embryogenic calli was developed. Once the type II embryogenic calli are produced, they can be subcultured and/or proliferated conveniently. The objectives of this study were to demonstrate a stable Agrobacterium-mediated transformation of maize using explants of type II embryonic calli and to evaluate the efficiency of the protocol in order to develop herbicide-resistant maize. The type II embryogenic calli were inoculated with Agrobacterium tumefaciens strain C58C1 carrying binary vector pTF102, and then were subsequently cultured on the following media: co-cultivation medium for 1 day, delay medium for 7 days, selection medium for 4 × 14 days, regeneration medium, and finally on germination medium. The T-DNA of the vector carried two cassettes (Ubi promoter-EPSPs ORF-nos and 35S promoter–bar ORF-nos). The EPSPs conferred resistance to glyphosate and bar conferred resistance to phosphinothricin. The confirmation of stable transformation and the efficiency of transformation was based on the resistance to phosphinothricin indicated by the growth of putative transgenic calli on selection medium amended with 4 mg l^?1 phosphinothricin, northern blot analysis of bar gene, and leaf painting assay for detection of bar gene-based herbicide resistance. Northern blot analysis and leaf painting assay confirmed the expression of bar transgenes in the R₁ generation. The average transformation efficiency was 0.60%. Based on northern blot analysis and leaf painting assay, line 31 was selected as an elite line of maize resistant to herbicide.     

MDMV CP基因的克隆及其转基因玉米的研究

用RT-PCR方法分离了玉米矮花叶病毒外壳蛋白基因(MDMV CP),并且利用基因枪法将该基因导入玉米优良自交系18-599红、18-599白幼胚诱导的愈伤组织中。转化的愈伤组织在Bialaphos浓度(PPT)为8mg／L、10mg/L、5mg／L的筛选压下经过3次抗性筛选后,分别再生出可育植株12株和6株。PCR和Southem检测结果说明CP基因已整合到玉米自交系基因组中。对T1代转基因植株进行病毒人工接种试验,结果表明对照植株全部表现为感染玉米矮花叶病的典型症状,而转基因植株后代呈现不同程度的抗性。     

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.     

小麦抗白粉病相关基因的转化

利用玉米花青素苷合成调节基因C1-Lc作为报告基因, 通过瞬间表达后愈伤组织表面红色斑点的统计分析, 优化了小麦幼胚愈伤组织的基因枪转化参数。小麦Beclin1类似基因TaTBL和硫代硫酸硫转移酶基因TaTST是2个在白粉菌诱导条件下具有增强表达特性的抗病相关基因。本实验进一步利用基因枪将ubi强启动子控制下的2个基因导入到小麦品种扬麦158的幼胚愈伤组织细胞中, 使用除草剂经两轮选择培养基上的筛选和再生获得抗性植株, 进一步通过抗性植株的PCR分析获得转TaTBL基因植株5株, 转TaTST基因植株6株。转基因植株离体叶片的人工接种实验表明, 外源基因的导入不同程度上增强了植株的白粉病抗性, 表现为延缓了白粉菌的发育。利用玉米花青素苷合成调节基因C1-Lc作为报告基因,通过瞬间表达后愈伤组织表面红色斑点的统计分析,优化了小麦幼胚愈伤组织的基因枪转化参数。小麦Beclin1类似基因TaTBL和硫代硫酸硫转移酶基因TaTST是两个在白粉菌诱导条件下具有增强表达特性的抗病相关基因。本实验进一步利用基因枪将ubi强启动子控制下的两个基因导入到小麦品种扬麦158的幼胚愈伤组织细胞中,使用除草剂经两轮选择培养基上的筛选和再生获得抗性植株,进一步通过抗性植株的PCR分析获得转TaTBL基因植株5株,转TaTST基因植株6株。转基因植株离体叶片的人工接种实验表明,外源基因的导入不同程度上增强了植株的白粉病抗性,表现为延缓了白粉菌的发育。     

Two critical factors are required for efficient transformation of multiple soybean cultivars: <Emphasis Type="Italic">Agrobacterium</Emphasis> strain and orientation of immature cotyledonary explant

An efficient transformation system was developed for multiple soybean [Glycine max (L.) Merrill.] cultivars using Agrobacterium-mediated gene transfer. A significantly high number of hygromycin-resistant somatic embryos (SEs) was obtained when immature zygotic cotyledons were inoculated with Agrobacterium tumefaciens strain KYRT1 and when the abaxial side of explants was oriented upwards (i.e., the adaxial side of explants was in contact with the medium). Most hygromycin-resistant SEs on selective medium were induced along the periphery of the abaxial side of cotyledonary explants. Extended periods of selection (up to 10 weeks post-cocultivation) increased the frequency of somatic embryogenesis, and more than 50% of selected SEs tested positive for beta-glucuronidase (GUS). Following maturation and regeneration of selected SEs, ten independent transgenic soybean plants of cv Jack were obtained, and the overall transformation frequency ranged from 1.1 to 1.7%. Six and two transgenic plantlets were obtained from cvs Dwight and Williams, respectively. In addition, transgenic suspension lines were established from cvs Jack, Williams, Dwight, Rend and Ina. Molecular analysis of embryogenic lines and/or transgenic plants, established from different cultivars, confirmed stable integration, expression, and/or inheritance of transgenes in both T0 and T1 plants.     

农杆菌介导的小麦遗传转化几个影响因素的研究

采用携带gus和（或）bar基因双元表达载体（p3301,pBTAaB)的3个根癌农杆菌（Agrobacterium tumefaciens)菌株（AGL-1,EHA105和LBA4404）对普通小麦（Triticum aestivumL.)冬性栽培品种农大170和农大146的幼胚及幼胚愈伤组织进行了遗传转化,结果表明,菌液浓度OD6001.0和侵染时间1h对外植体的生存和转化最为有利;侵染前对外植体进行高渗处理较明显地提高了抗性愈伤获得率;乙酰丁香酮（AS）对小麦转化的作用随菌株和外植体的不同而异;菌株/质粒组合,受体基因型及外植体的类型,年龄和生理状态对转化效率有很大的影响,条件优化后,得到大量具有PPT抗性的愈伤和一些抗性植株,抗性愈伤的GUS染色阳性率在50%-60%之间,所检测的抗性苗呈GUS阳性,对6株抗性苗的PCR和Southern检测初步证明,外源基因已经整合到其中3株的基因组中。     

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.     

Effects of kanamycin on tissue culture and somatic embryogenesis in cotton

The aminoglycoside antibiotic kanamycin was evaluated for its effects on callus initiation from hypocotyl and cotyledon explants, proliferation of non-embryogenic and embryogenic calli, initiation and development of somatic embryos in cotton (Gossypium hirsutum L.). On this basis, the potential use of kanamycin as a selective agent in genetic transformation with the neomycin phosphotransferase II gene as the selective marker gene was evaluated. Cotton cotyledon and hypocotyl explants, and embryogenic calluses were highly sensitive to kanamycin. Kanamycin at 10 mg/L or higher concentrations reduced callus formation, with complete inhibition at 60 mg/L. Kanamycin inhibited embryogenic callus growth and proliferation, as well as the initiation and development of cotton somatic embryos. The sensitivity of embryogenic callus and somatic embryos to kanamycin was different during the initiation and development stages. Kanamycin was considered as a suitable selective agent for transformed callus formation and growth of non-embryogenic callus. Forty to sixty mg/L was the optimal kanamycin concentration for the induction and proliferation of transformed callus. The concentration of kanamycin must be increased (from 50 to 200 mg/L) for the selection of transformation embryogenic callus and somatic embryos. A scheme for selection of transgenic cotton plants when kanamycin is used as the selection agent is discussed.     

<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.     

Agrobacterium-mediated transformation of rice using immature embryos or calli induced from mature seed

Here, we provide comprehensive, highly efficient protocols for Agrobacterium tumefaciens-mediated transformation of a wide range of rice genotypes. Methods that use either immature embryos (japonica and indica rice) or calli (japonica cultivars and the indica cultivar, Kasalath) as a starting material for inoculation with Agrobacterium are described. Immature embryos are pretreated with heat and centrifugal force, which significantly enhances the efficiency of gene transfer, and then infected with Agrobacterium. Callus is induced from mature seeds and infected. Transformed cells proliferated from these tissues are selected on the basis of hygromycin resistance, and transgenic plants are eventually regenerated. A single immature japonica or Kasalath embryo will produce between 10 and 18 independent transgenic plants; for other non-Kasalath indica varieties, the number of transgenic plants expected will be between 5 and 13. For japonica and Kasalath, transformants should be obtained from between 50 and 90% of calli. From inoculation with Agrobacterium to transplanting to soil will take 55 d for japonica and Kasalath, and 74 d for indica other than Kasalath using the immature embryo method, and 50 d for japonica and Kasalath using the callus method.     

Dynamics of morphological and anatomical changes in leaf tissues of an interspecific hybrid of oil palm during acquisition and development of somatic embryogenesis

Oil palm is an economically important plant species due to its high oil production per unit area. Large-scale clonal propagation of the species’s elite specimens is only possible through somatic embryogenesis, although methodology is partially still unknown and insufficiently understood. Current study characterizes in morphological and anatomical terms the acquisition and development stages of somatic embryogenesis of the oil palm’s immature leaves. The respective embryogenic stages were analyzed and characterized: immature leaves (initial explants); leaves with calli formation; leaves which failed to respond to calli formation; leaves with formation of root structures; primary calli; primary calli with differentiation of embryogenic calli; embryogenic calli; pro-embryogenic calli; calli with differentiated somatic embryos; somatic embryos at globular and torpedo stage; and mature fruit zygotic embryos. Cell masses emerged after approximately 60 days of cultivation through the proliferation of cells associated to initial explants´ vascular bundles. Consequently, the formation of two different types of calli was identified, namely, primary and embryogenic, respectively consisting partially and completely of meristematic cell clusters. After 420 days of cultivation, the propagules formed somatic embryos with no connection to source tissues, initially composed (globular stage) of a very characteristic ground meristem and protoderm. After 480 days of cultivation, as the cultures matured (torpedo stage), procambial strands, a structural characteristic also observed in mature zygotic embryos, were reported. The results provide an in-depth understanding of somatic embryogenesis of immature leaves of oil palm. Further, current analysis develops morphological markers at different stages of development obtained during the process.     

Genetic transformation of the actinorhizal tree Allocasuarina verticillata by Agrobacterium tumefaciens

We have developed an efficient transformation system for the tropical actinorhizal tree Allocasuarina verticillata using Agrobacterium tumefaciens mediated gene transfer. Mature zygotic embryos were inoculated with the disarmed strain C58C1 carrying, in the binary vector BIN19, the nptll gene, providing kanamycin resistance as a selectable marker, and the reporter gene β-glucuronidase containing an intron. The transformed embryos were cultivated on nutrient medium supplemented with 0.5 µM NAA, 2.5 µM BA, 100 mg l⁻¹ kanamycin and 250 mg l⁻¹ cefotaxime. After 2 months, a 21% transformation frequency was obtained. Within 6–9 months, transgenic plants were recovered from 70% of the transformed calli. The presence of the transgenes was demonstrated by PCR analysis and by the expression of the β-glucuronidase; integration of the T-DNA was confirmed by Southern hybridization. More than 100 transgenic plants from a total of 23 independent transformation events have been successfully established in soil. The possibility to obtain nitrogen-fixing nodules after inoculation of transgenic A. verticillata plants by the actinomycetal strain of Frankia Allo2 was established.     

几种玉米基因转移技术的研究及转基因植株的获得

用基因枪、超声波和子房注射法转化玉米,所用质粒pB48．415带有3’端截短的Bt毒蛋白基因和潮霉素磷酸转移酶(hpt)基因。用基因枪轰击玉米胚性愈伤组织和幼胚,超声波处理玉米胚性愈伤组织,用自制的微玻针注射授粉后l0～20h的玉米子房,均已成功地获得了转Bt基因的玉米檀株．点杂交和Southern吸印杂交的结果都证明在转基因玉米檀株中存在Bt毒蛋白基因。     

Plant regeneration through callus initiation from thin mature embryo fragments of wheat

A wheat regeneration system was developed using mature embryos. Embryos were removed from surface-sterilised mature caryopses (winter wheat Odeon cultivar and spring wheat Minaret cultivar) and ground to pieces through a sterile nylon mesh. The fragments were characterised by means of the image analysis technique. They were 500 M mean diameter and most of them were elongated. They were used as explants to initiate embryogenic calli on solid medium supplemented with 10 M 2,4-dichlorophenoxyacetic acid. The morphogenic pathway of the initiated calli was followed for a 40-day culture period. Active cellular division occurred within 24 hours of cultivation. Several hundred calli were produced from 100 fragmented embryos within 3 days. A 90% callus induction rate was achieved and proembryos appeared by the 8th day of culture. The highest embryogenic calli induction rate of 47% was obtained when 2,4-dichlorophenoxyacetic acid was suppressed after a 3–4 week induction period. Two regeneration methods were finally compared. A total of 513 plantlets were produced. The optimal protocol produced 25–30 plants per 100 embryos. This regeneration method may be suitable for transformation applications.