Molecular Characteristics of Transgenic Wheat and the Effect on Transgene Expression

A population of R0 transgenic wheat plants, generated by particle bombardment, was analyzed to define molecular, genetic and phenotypic properties resulting from transformation with a cointegrate vector, or cotransformation with two separate plasmids. By evaluating the progeny of 70 independently-derived transgenic plants, we also identified rare events such as chimerism and transgene elimination, which provide valuable information concerning the development of transgenic cereal plants following bombardment experiments. The frequency of chimerism in our transgenic wheat plants was very low. Furthermore, while transgene elimination did occur, this was also a very rare event. We determined the copy numbers of integrated transgenes and the levels of transgene expression. Comparisons to transgenic rice plants generated in the same manner demonstrated some similarities, but also important differences in transgene behavior. Whereas in rice there is no evidence for any direct relationship between transgene copy number and transgene expression or stability, multicopy populations in wheat demonstrated a bias towards higher levels of expression for the two genes and the maize ubiquitin promoter evaluated in the present study.     

Estimating the copy number of transgenes in transformed rice by real-time quantitative PCR

In transgenic plants, transgene copy number can greatly influence the expression level and genetic stability of the target gene, making estimation of transgene copy number an important area of genetically modified (GM) crop research. Transgene copy numbers are currently estimated by Southern analysis, which is laborious and time-consuming, requires relatively large amounts of plant materials and may involve hazardous radioisotopes. We report here the development of a sensitive, high-throughput real-time (RT)-PCR technique for estimating transgene copy number in GM rice. This system uses TaqMan quantitative RT-PCR and comparison to a novel rice endogenous reference gene coding for sucrose phosphate synthase (SPS) to determine the copy numbers of the exogenous beta-glucuronidase (GUS) and hygromycin phosphotransferase (HPT) genes in transgenic rice. The copy numbers of the GUS and HPT in primary rice transformants (T0) were calculated by comparing quantitative PCR results of the GUS and HPT genes with those of the internal standard, SPS. With optimized PCR conditions, we achieved significantly accurate estimates of one, two, three and four transgene copies in the T0 transformants. Furthermore, our copy number estimations of both the GUS reporter gene and the HPT selective marker gene showed that rearrangements of the T-DNA occurred more frequently than is generally believed in transgenic rice.     

Direct DNA transfer using electric discharge particle acceleration (ACCELL™ technology)

Direct DNA transfer methods based on particle bombardment have revolutionized plant genetic engineering. Major agronomic crops previously considered recalcitrant to gene transfer have been engineered using variations of this technology. In many cases variety-independent and efficient transformation methods have been developed enabling application of molecular biology techniques to crop improvement. The focus of this article is the development and performance of electric discharge particle bombardment (ACCELL™) technology. Unique advantages of this methodology compared to alternative propulsion technologies are discussed in terms of the range of species and genotypes that have been engineered, and the high transformation frequencies for major agronomic crops that enabled the technology to move from the R&D phase to commercialization. Creation of transgenic soybeans, cotton, and rice will be used as examples to illustrate the development of variety-independent and efficient gene transfer methods for most of the major agronomic crops. To our knowledge, no other gene transfer method based on particle bombardment has resulted in variety-independent and practical generation of large numbers of independently-derived crop plants. ACCELL™ technology is currently being utilized for the routine transfer of valuable genes into elite germplasm of soybean, cotton, bean, rice, corn, peanut and woody species.     

Transgene behaviour across two generations in a large random population of transgenic rice plants produced by particle bombardment

The relationship between transgene copy number, rearrangement levels, inheritance patterns, expression levels, transgene stability and plant fertility was analysed in a random population of 95 independently transformed rice plant lines. This analysis has been conducted for both the selectable marker gene ( aphIV) and the unselected reporter gene ( gusA), in the presence or absence of flanking Matrix Attachment Regions (MARs) in order to develop a better understanding of transgene behaviour in a population of transgenic rice plants created by particle bombardment. In the first generation (T(0)), all the independently transformed plant lines contained and expressed the aphIV gene conferring resistance to hygromycin, but only 87% of the lines were co-transformed with the unselected gusA marker gene. Both transgenes seemed to be expressed independently. Most lines exhibited complex transgene rearrangements as well as an intact transgene expression unit for both aphIV and gusA transgenes. Transgene copy number was proportional to the quantity of DNA used during bombardment. In T(0) plants, high gusA copy number significantly decreased GUS expression levels but there was no correlation between expression level and transgene copy number across the entire population of lines. Four main factors impaired transgene expression in primary transgenic plants (T(0)) and their progeny (T(1)): (1) absence of transgene expression in T(0) plants (41% of lines), (2) sterility of T(0) plants (28% of lines), (3) non-transmission of intact transgenes to some or all progenies (at least 14% of lines), and (4) silencing of transgene expression in progeny plants (10% of lines). Transgene stability was significantly related to differences in transgene structure and expression levels. The presence of Rb7 MARs flanking the gusA expression unit had no effect on plant fertility or non-transmission of transgenes, but provided copy number-dependent expression of the transgene and improved expression levels and stability over two generations. Overall, only 7% of the plant lines without MARs and 17% of the lines with MARs initially generated, exhibited stable transgene expression over two generations.     

Comparative analysis of transgenic rice plants obtained by Agrobacterium-mediated transformation and particle bombardment

We compared rice transgenic plants obtained by Agrobacterium-mediated and particle bombardment transformation by carrying out molecular analyses of the T₀, T₁ and T₂ transgenic plants. Oryza sativa japonica rice (c.v. Taipei 309) was transformed with a construct (pWNHG) that carried genes coding for neomycin phosphotransferase (nptII), hygromycin phosphotransferase (Hyg^r), and -glucuronidase (GUS). Thirteen and fourteen transgenic lines produced via either method were selected and subjected to molecular analysis. Based on our data, we could draw the following conclusions. Average gene copy numbers of the three transgenes were 1.8 and 2.7 for transgenic plants obtained by Agrobacterium and by particle bombardment, respectively. The percentage of transgenic plants containing intact copies of foreign genes, especially non-selection genes, was higher for Agrobacterium-mediated transformation. GUS gene expression level in transgenic plants obtained from Agrobacterium-mediated transformation was more stable overall the transgenic plant lines obtained by particle bombardment. Most of the transgenic plants obtained from the two transformation systems gave a Mendelian segregation pattern of foreign genes in T₁ and T₂ generations. Co-segregation was observed for lines obtained from particle bombardment, however, that was not always the case for T₁ lines obtained from Agrobacterium-mediated transformation. Fertility of transgenic plants obtained from Agrobacterium-mediated transformation was better. In summary, the Agrobacterium-mediated transformation is a good system to obtain transgenic plants with lower copy number, intact foreign gene and stable gene expression, while particle bombardment is a high efficiency system to produce large number of transgenic plants with a wide range of gene expression.     

Particle bombardment and the genetic enhancement of crops: myths and realities

DNA transfer by particle bombardment makes use of physical processes to achieve the transformation of crop plants. There is no dependence on bacteria, so the limitations inherent in organisms such as Agrobacterium tumefaciens do not apply. The absence of biological constraints, at least until DNA has entered the plant cell, means that particle bombardment is a versatile and effective transformation method, not limited by cell type, species or genotype. There are no intrinsic vector requirements so transgenes of any size and arrangement can be introduced, and multiple gene cotransformation is straightforward. The perceived disadvantages of particle bombardment compared to Agrobacterium-mediated transformation, i.e. the tendency to generate large transgene arrays containing rearranged and broken transgene copies, are not borne out by the recent detailed structural analysis of transgene loci produced by each of the methods. There is also little evidence for major differences in the levels of transgene instability and silencing when these transformation methods are compared in agriculturally important cereals and legumes, and other non-model systems. Indeed, a major advantage of particle bombardment is that the delivered DNA can be manipulated to influence the quality and structure of the resultant transgene loci. This has been demonstrated in recently reported strategies that favor the recovery of transgenic plants containing intact, single-copy integration events, and demonstrating high-level transgene expression. At the current time, particle bombardment is the most efficient way to achieve plastid transformation in plants and is the only method so far used to achieve mitochondrial transformation. In this review, we discuss recent data highlighting the positive impact of particle bombardment on the genetic transformation of plants, focusing on the fate of exogenous DNA, its organization and its expression in the plant cell. We also discuss some of the most important applications of this technology including the deployment of transgenic plants under field conditions.     

Microparticle bombardment as a tool in plant science and agricultural biotechnology

Microparticle bombardment technology has evolved as a method for delivering exogenous nucleic acids into plant cells and is a commonly employed technique in plant science. Desired genetic material is precipitated onto micron-sized metal particles and placed within one of a variety of devices designed to accelerate these "microcarriers" to velocities required to penetrate the plant cell wall. In this manner, transgenes can be delivered into the cell's genome or plastome. Since the late 1980s microparticle bombardment has become a powerful tool for the study of gene expression and production of stably transformed tissues and whole transgenic plants for experimental purposes and agricultural applications. This paper reviews development and application of the technology, including the protocols and mechanical systems employed as delivery systems, and the types of plant cells and culture systems employed to generate effective "targets" for receiving the incoming genetic material. Current understanding of how the exogenous DNA becomes integrated into the plant's native genetic background are assessed as are methods for improving the efficiency of this process. Pros and cons of particle bombardment technologies compared to alternative direct gene transfer methods and Agrobacterium based transformation systems are discussed.     

Plasmolysis of precultured immature embryos improves Agrobacterium mediated gene transfer to rice (Oryza sativa L.)

Efficiency of Agrobacterium mediated gene transfer was improved in rice by microprojectile pretreatment. Fertile transgenic plants were easily recovered using this protocol. Since an osmotic treatment is part of the bombardment protocol, we studied the effect of plasmolysis alone (i.e. without any microprojectiles) on transient expression of the gus gene transferred by Agrobacterium to precultured rice embryos. We report here for the first time that plasmolysis alone as a single pretreatment, yielded an even higher number of cells expressing the marker gene than the combination of microprojectile bombardment and osmotic treatment. This indicates that the effect of the osmoticum on gene transfer is independent from bombardment.     

High-efficiency,microprojectile-mediated cotransformation of sugarcane,using visible or selectable markers

Transient expression of the maize anthocyanin regulatory elements,R andC1, was used to optimise parameters for microprojectile-mediated delivery of DNA into sugarcane embryogenic callus. Osmotic treatment of target tissues and particle acceleration in a high-pressure helium pulse increased the frequency of transient expression to 5–8×10³ cells per bombardment, with minimal tissue damage. An average of 0.34% of transiently expressing cells developed into stably transformed, anthocyanin-pigmented proembryoids which subsequently regenerated into plantlets. However, constitutive expression ofR andC1 proved deleterious, and no anthocyanin-pigmented plant survived beyond 3 cm in height. We also compared selective subculture of callus portions showing luciferase activity with antibiotic selection on medium containing G418 or phosphinothricin, upon bombardment of callus with constructs driving strong expression ofluc, aphA orbar genes. Selective subculture based on luciferase activity enabled recovery of 1.4±0.5 independent transgenic plants per bombardment, compared to 19.8±3.7 independent transgenic plants per bombardment from an optimised G418 selection regimen, and no transformed plants from phosphinothricin selection. Whenluc andaphA on separate plasmids were coprecipitated onto microprojectiles before bombardment, 67–79% of callus lines selected for G418 resistance also showed luciferase activity detectable under a low-light camera. Southern analysis confirmed a very high cotransformation frequency, with variable copy numbers of introduced genes. The high efficiencies of gene transfer, selection and cotransformation in the optimised system, coupled with the simple initiation and regeneration of embryogenic callus, provide an effective tool for practical genetic transformation of sugarcane.     

Agrobacterium -mediated Transformation of Rice with Help of Bombardment

Oryza sativa L. ssp. japonica cv. Zhonghua 8, which is recalcitrant to infection of Agrobacterium tumefaciens (Smith et Townsend) Conn strain EHA105 with ordinary binary vector pCambia 1301, was transformed through Agrobacterium mediated transformation with help of bombardment. The transformation efficiency can be raised greatly. Single copy of gene insertion in the genome of transgenic rice plants was proved by Southern analysis and the expression of GUS gene was observed. GUS gene and hygromycin-resistant gene show 3∶1 segregation in progenies of the transgenic rice plants.     

绿色荧光蛋白基因作为报告基因在水稻基因转化中的应用研究

本研究中 ,构建了含有编码绿色荧光蛋白的改进型基因质粒pJPM5。用基因枪法分别把pJPM5和另一带有绿色荧光蛋白基因的质粒pSBG70 0转入水稻TNG6 7愈伤组织。用South ern杂交法证实了转基因的存在 ,而且表明多数转基因植株含有 1到 8个拷贝的转基因。取 2个月的转基因植株上的叶片用于分析绿色荧光蛋白基因表达。用SLM - 80 0 0荧光分析仪定量测定绿色荧光蛋白。多数转基因植株具有很高的绿色荧光蛋白信号。虽然水稻植株有少量自发荧光 ,但是绿色荧光蛋白基因表达出的绿色荧光蛋白信号比植株的自发荧光强得多 ,其测定不会受自发荧光的太大影响。在荧光显微镜下观察到了绿色荧光蛋白基因的表达。借助观察分析绿色荧光蛋白基因的瞬时表达 ,本研究还发现基因枪法转化中 ,如果两枪的气压为90 0psi& 135 0psi,比两枪的气压都为 90 0psi或者 135 0psi更好 ,因其能使质粒进入更多的细胞。研究结果表明 ,绿色荧光蛋白基因可以作为水稻 (甚至小麦、玉米 )转基因研究中的报告基因。研究还显示 ,MAR序列能明显增强绿色荧光蛋白基因的表达能力 (这一结果在另文讨论 ) .     

Generation of marker-free Bt transgenicindica rice and evaluation of its yellow stem borer resistance

We report on generation of marker-free (‘clean DNA’) transgenic rice (Oryza sativa), carrying minimal gene-expression-cassettes of the genes of interest, and evaluation of its resistance to yellow stem borerScirpophaga incertulas (Lepidoptera: Pyralidae). The transgenicindica rice harbours a translational fusion of 2 differentBacillus thuringiensis (Bt) genes, namelycry1B-1Aa, driven by the green-tissue-specific phosphoenol pyruvate carboxylase (PEPC) promoter. Mature seed-derived calli of an eliteindica rice cultivar Pusa Basmati-1 were co-bombarded with gene-expression-cassettes (clean DNA fragments) of the Bt gene and the markerhpt gene, to generate marker-free transgenic rice plants. The clean DNA fragments for bombardment were obtained by restriction digestion and gel extraction. Through biolistic transformation, 67 independent transformants were generated. Transformation frequency reached 3.3%, and 81% of the transgenic plants were co-transformants. Stable integration of the Bt gene was confirmed, and the insert copy number was determined by Southern analysis. Western analysis and ELISA revealed a high level of Bt protein expression in transgenic plants. Progeny analysis confirmed stable inheritance of the Bt gene according to the Mendelian (3∶1) ratio. Insect bioassays revealed complete protection of transgenic plants from yellow stem borer infestation. PCR analysis of T₂ progeny plants resulted in the recovery of up to 4% marker-free transgenic rice plants.     

Transformation of rice mediated by Agrobacterium tumefaciens

Agrobacterium tumefaciens has been routinely utilized in gene transfer to dicotyledonous plants, but monocotyledonous plants including important cereals were thought to be recalcitrant to this technology as they were outside the host range of crown gall. Various challenges to infect monocotyledons including rice with Agrobacterium had been made in many laboratories, but the results were not conclusive until recently. Efficient transformation protocols mediated by Agrobacterium were reported for rice in 1994 and 1996. A key point in the protocols was the fact that tissues consisting of actively dividing, embryonic cells, such as immature embryos and calli induced from scutella, were co-cultivated with Agrobacterium in the presence of acetosyringonc, which is a potent inducer of the virulence genes. It is now clear that Agrobacterium is capable of transferring DNA to monocotyledons if tissues containing competent cells are infected. The studies of transformation of rice suggested that numerous factors including genotype of plants, types and ages of tissues inoculated, kind of vectors, strains of Agrobacterium, selection marker genes and selective agents, and various conditions of tissue culture, are of critical importance. Advantages of the Agrobacterium-mediated transformation in rice, like on dicotyledons, include the transfer of pieces of DNA with defined ends with minimal rearrangements, the transfer of relatively large segments of DNA, the integration of small numbers of copies of genes into plant chromosomes, and high quality and fertility of transgenic plants. Delivery of foreign DNA to rice plants via A. tumefaciens is a routine technique in a growing number of laboratories. This technique will allow the genetic improvement of diverse varieties of rice, as well as studies of many aspects of the molecular biology of rice.     

采用玉米Ubi-1启动子获得低拷贝转基因玉米植株

通过基因枪粒子轰击和草丁膦（PPT）选择获得可育的玉米转基因植株,并分析了外源基因在转化体中的拷贝数与启动子之间的关系。用玉米Ubi-1启动子驱动外源基因,玉米转化体中外源基因的拷贝数较低;可能的原因为Ubi-1启动子通过与其内部同源序列发生重组而被定点整合进玉米基因组,共转化的两种质粒DNA在整合至玉米染色体DNA之前已重构成为一个整体。结果显示使用某一植物自身基因的启动子可以降低外源基因在该物种转基因个体中的拷贝数,进而避免基因沉默现象的发生。目前已得到第二代转基因玉米种子。     

Comparison of Biolistic and Agrobacterium -mediated Transformation Methods on Transgene Copy Number and Rearrangement Frequency in Rice

Transferring foreign DNA into plant cells by biolistic and Agrobacterium -mediated methods may result in random integration of different copy numbers of the transgene, and different proportions of intact vs. rearranged copies of the transgene. This may, in turn, affect transgene expression levels. To test the above hypothesis, we first introduced the same plasmid, pAc1PG-CAM, into rice (BX)Oryza sativa L.) calli separately by the biolistic method and by the Agrobacterium -mediated method. To show whether different plasmids may affect the results, we also introduced pTOK233 by the Agrobacterium -mediated method and pJPM44 by the biolistic method. Transgene expression of R0 plants was monitored by histochemical analysis of GUS activity. Transgene copy number was determined by Southern blot analysis after digesting genomic DNA with an enzyme that has a unique cutting site within the input plasmid. The total genomic DNA was also digested by a two-cut enzyme (the cuts are located at two sides of a given transgene expression cassette), followed by Southern blotting analysis, for determining the number of intact transgene expression cassettes. Our data showed that Agrobacterium -mediated transformation resulted in lower transgene copy number (average between 2.1 and 2.3) in transgenic rice plants, compared with those plants obtained by the biolistic method (average between 4.2 and 5.6). The frequency of DNA rearrangement in expression cassettes is lower in transgenic rice plants obtained by the Agrobacterium -mediated method than those obtained by the biolistic method. The average rearrangement frequency is 0.07 to 0.106 for the Agrobacterium -mediated method, and 0.57 to 0.66 for the biolistic method. Our results suggest that it is better to compare the number of intact expression cassettes instead of the total copy number of the transgene in demonstrating their influence on the level of transgene expression. This is the first report on the frequency of expression cassette rearrangement in transgenic plants transformed with the same plasmid by two different transformation methods.     

基因枪转化的bar基因表达盒在水稻中遗传行为复杂

基因枪介导基因表达盒(仅包括启动子、编码区和终止子)转化是基因枪转化植物的新趋势,它能消除质粒载体主干序列对转基因植物的不利影响。本文研究了基因枪转化的bar基因表达盒在转基因水稻T1～T3世代中的遗传行为。结果发现:作为筛选标记的bar基因表达盒在水稻基因组中多拷贝整合,遗传分离行为复杂,还出现了Basta抗感分离比在35:1～144:1之间的"假纯合体",但50%转基因株系中(5/10)bar基因可作为一个显性基因按孟德尔方式稳定遗传至自交T2代。虽然bar基因为多拷贝整合,30%的转基因株系(3/10)在自交低世代(T1)能获得纯合体。Southern杂交分析发现,多拷贝的bar基因表达盒倾向于连接成转基因串联子整合在水稻基因组内。我们发现在Basta抗性正常分离的株系后代中bar基因表达盒Southern杂交模式能稳定遗传,但异常分离的株系后代中bar基因表达盒的一些拷贝发生了丢失。我们推测,bar基因表达盒在水稻中遗传分离行为的复杂原因可能是bar基因表达盒多拷贝整合、基因丢失和基因表达互作。     

Transgenic rice plants expressing a Bacillus subtilis protoporphyrinogen oxidase gene are resistant to diphenyl ether herbicide oxyfluorfen

Protoporphyrinogen oxidase (Protox), the penultimate step enzyme of the branch point for the biosynthetic pathway of Chl and hemes, is the target site of action of diphenyl ether (DPE) herbicides. However, Bacillus subtilis Protox is known to be resistant to the herbicides. In order to develop the herbicide-resistant plants, the transgenic rice plants were generated via expression of B. subtilis Protox gene under ubiquitin promoter targeted to the cytoplasm or to the plastid using Agrobacterium-mediated gene transformation. The integration and expression of the transgene were investigated at T0 generation by DNA and RNA blots. Most transgenic rice plants revealed one copy transgene insertion into the rice genome, but some with 3 copies. The expression levels of B. subtilis Protox mRNA appeared to correlate with the copy number. Furthermore, the plastidal transgenic lines exhibited much higher expression of the Protox mRNA than the cytoplasmic transgenic lines. The transgenic plants expressing the B. subtilis Protox gene at T0 generation were found to be resistant to oxyfluorfen when judged by cellular damage with respect to cellular leakage, Chl loss, and lipid peroxidation. The transgenic rice plants targeted to the plastid exhibited higher resistance to the herbicide than the transgenic plants targeted to the cytoplasm. In addition, possible resistance mechanisms in the transgenic plants to DPE herbicides are discussed.     

Genetic transformation of wheat: progress during the 1990s into the Millennium

Wheat transformation technology has progressed rapidly during the past decade. Initially, procedures developed for protoplast isolation and culture, electroporation- and polyethylene glycol (PEG)-induced DNA transfer enabled foreign genes to be introduced into wheat cells. The development of biolistic (microprojectile) bombardment procedures led to a more efficient approach for direct gene transfer. More recently, Agrobacterium-mediated gene delivery procedures, initially developed for the transformation of rice, have also been used to generate transgenic wheat plants. This review summarises the considerable progress in wheat transformation achieved during the last decade. An increase in food production is essential in order to sustain the increasing world population. This could be achieved by the development of higher yielding varieties with improved nutritional quality and tolerance to biotic and abiotic stresses. Although conventional breeding will continue to play a major role in increasing crop yield, laboratory-based techniques, such as genetic transformation to introduce novel genes into crop plants, will be essential in complementing existing breeding technologies. A decade ago, cereals were considered recalcitrant to transformation. Since then, a significant research effort has been focused on cereals because of their agronomic status, leading to improved genetic transformation procedures (Bommineni and Jauhar 1997). Initially, the genetic transformation of cereals relied on the introduction of DNA into protoplasts and the subsequent production of callus from which fertile plants were regenerated. More recently, major advances have been accomplished in the regeneration of fertile plants from a range of source tissues, providing an essential foundation for the generation of transgenic plants. This review summarises procedures, vectors and target tissues used for transformation, high-lights the limitations of current approaches and discusses future trends. The citation of references is limited, where possible, to the most relevant or recent reports.     

Efficient generation of transgenic barley: the way forward to modulate plant-microbe interactions

Stable genetic transformation represents the gold standard approach to the detailed elucidation of plant gene functions. This is particularly relevant in barley, an important experimental model widely employed in applied molecular, genetic and cell biological research, and biotechnology. Presented are details of the establishment of a protocol for Agrobacterium-mediated gene transfer to immature embryos, which enables the highly efficient generation of transgenic barley. Advancements were achieved through comparative experiments on the influence of various explant treatments and co-cultivation conditions. The analysis of representative numbers of transgenic lines revealed that the obtained T-DNA copy numbers are typically low, the generative transmission of the recombinant DNA is in accordance with the Mendelian rules and the vast majority of the primary transgenics produce progeny that expresses the respective transgene product. Moreover, the newly established protocol turned out to be useful to transform not only the highly amenable cultivar (cv.) 'Golden Promise' but also other spring and winter barley genotypes, albeit with substantially lower efficiency. As a major result of this study, a very useful tool is now available for future functional gene analyses as well as genetic engineering approaches. With the aim to modify the expression of barley genes putatively involved in plant-fungus interactions, numerous transgenic plants have been generated using diverse expression cassettes. These plants represent an example of how transformation technology may contribute to further our understanding of important biological processes.     

Co-transformation of gene expression cassettes via particle bombardment to generate safe transgenic plant without any unwanted DNA

The presence of resistant selectable marker genes and other added DNAs such as the vector backbone sequence in transgenic plant might be an unpredictable hazard to the ecosystem as well as to human health, which have affected the safe assessment of transgenic plants seriously. Using minimal gene expression cassette (containing the promoter, coding region, and terminator) without vector backbone sequence for particle bombardment is the new trend of plant genetic transformation. In the present paper, we co-transformed the selectable marker bar gene cassette and non-selected cecropinB gene cassette into rice (Oryza sativa L.) by particle bombardment, then eliminated the selectable marker bar gene in R₁ generation applying the hereditary segregation strategy and attained two safe transgenic plants only harboring cecropinB gene cassettes without any superfluous DNA. This is the fist report indicating that the combination of minimal gene cassettes transformation with the co-transformation and segregation strategy can generate selectable marker-free transgenic plants, which will promote the advancement in plant genetic engineering greatly.