反馈抑制不敏感邻氨基苯甲酸合成酶基因作为筛选标记基因用于大豆遗传转化研究

目前广泛采用的抗菌素或抗除草剂基因作为植物转化筛选标记基因可能带来转基因逃逸,因此寻找能够用于植物转化的来源于植物本身的筛选基因是解决这一问题的方法之一。通过从烟草中克隆的邻氨基苯甲酸合成酶基因(ASA2)作为筛选标记基因,并采用氨基酸的类似物5—甲基色氨酸为筛选剂,进行了农杆菌介导的大豆成熟胚尖转化研究。Southern杂交结果表明ASA2基因成功整合到大豆基因组,Northern杂交也显示该基因在转化大豆叶片中表达。HPLC检测转化大豆叶片游离色氨酸的含量比野生型要高59％～123％。PCR检测转化子1代结果显示转化基因通过孟德尔规律稳定遗传。这些结果表明反馈抑制不敏感ASA2基因可以作为筛选标记基因用于大豆遗传转化。同时也证实来源于一种植物(烟草)编码的邻氨基苯甲酸α—亚基能够与另一种植物(大豆)编码该酶的β—亚基结合形成具有完整活性的邻氨基苯甲酸合成酶。对ASA2基因作为一种新的植物转化筛选标记基因的优缺点进行了讨论。     

The application of the mutated acetolactate synthase gene from rice as the selectable marker gene in the production of transgenic soybeans

We investigated selective culturing conditions for the production of transgenic soybeans. In this culturing system, we used the acetolactate synthase (ALS)-inhibiting herbicide-resistance gene derived from rice (Os-mALS gene) as a selectable marker gene instead of that derived from bacteria, which interfered with the cultivation and practical usage of transgenic crops. T₁ soybeans grown from one regenerated plant after selection of the ALS-targeting pyrimidinyl carboxy (PC) herbicide bispyribac-sodium (BS) exhibited herbicide resistance, and the introduction and expression of the Os-mALS gene were confirmed by genetic analysis. The selective culturing system promoted by BS herbicide, in which the Os-mALS gene was used as a selectable marker, was proved to be applicable to the production of transgenic soybeans, despite the appearance of escaped soybean plants that did not contain the Os-mALS transgene.     

High-efficiency transformation by biolistics of soybean, common bean and cotton transgenic plants

This protocol describes a method for high-frequency recovery of transgenic soybean, bean and cotton plants, by combining resistance to the herbicide imazapyr as a selectable marker, multiple shoot induction from embryonic axes of mature seeds and biolistics techniques. This protocol involves the following stages: plasmid design, preparation of soybean, common bean and cotton apical meristems for bombardment, microparticle-coated DNA bombardment of apical meristems and in vitro culture and selection of transgenic plants. The average frequencies (the total number of fertile transgenic plants divided by the total number of bombarded embryonic axes) of producing germline transgenic soybean and bean and cotton plants using this protocol are 9, 2.7 and 0.55%, respectively. This protocol is suitable for studies of gene function as well as the production of transgenic cultivars carrying different traits for breeding programs. This protocol can be completed in 7-10 months.     

HDAC6 inhibitors reverse axonal loss in a mouse model of mutant HSPB1-induced Charcot-Marie-Tooth disease

Charcot-Marie-Tooth disease (CMT) is the most common inherited disorder of the peripheral nervous system. Mutations in the 27-kDa small heat-shock protein gene (HSPB1) cause axonal CMT or distal hereditary motor neuropathy (distal HMN). We developed and characterized transgenic mice expressing two different HSPB1 mutations (S135F and P182L) in neurons only. These mice showed all features of CMT or distal HMN dependent on the mutation. Expression of mutant HSPB1 decreased acetylated α-tubulin abundance and induced severe axonal transport deficits. An increase of α-tubulin acetylation induced by pharmacological inhibition of histone deacetylase 6 (HDAC6) corrected the axonal transport defects caused by HSPB1 mutations and rescued the CMT phenotype of symptomatic mutant HSPB1 mice. Our findings demonstrate the pathogenic role of α-tubulin deacetylation in mutant HSPB1-induced neuropathies and offer perspectives for using HDAC6 inhibitors as a therapeutic strategy for hereditary axonopathies.     

Removal of heterologous sequences from Plasmodium falciparum mutants using FLPe-recombinase

Genetically-modified mutants are now indispensable Plasmodium gene-function reagents, which are also being pursued as genetically attenuated parasite vaccines. Currently, the generation of transgenic malaria-parasites requires the use of drug-resistance markers. Here we present the development of an FRT/FLP-recombinase system that enables the generation of transgenic parasites free of resistance genes. We demonstrate in the human malaria parasite, P. falciparum, the complete and efficient removal of the introduced resistance gene. We targeted two neighbouring genes, p52 and p36, using a construct that has a selectable marker cassette flanked by FRT-sequences. This permitted the subsequent removal of the selectable marker cassette by transient transfection of a plasmid that expressed a 37°C thermostable and enhanced FLP-recombinase. This method of removing heterologous DNA sequences from the genome opens up new possibilities in Plasmodium research to sequentially target multiple genes and for using genetically-modified parasites as live, attenuated malaria vaccines.     

Agrobacterium tumefaciens-mediated sorghum transformation using a mannose selection system

A dual-marker plasmid containing the selectable marker gene, manA, and the reporter gene, sgfp, was used to transform immature sorghum embryos by employing an Agrobacterium-mediated system. Both genes were under the control of the ubi1 promoter in a binary vector pPZP201. The Escherichia coli phosphomannose isomerase (PMI) gene, pmi, was used as the selectable marker gene and mannose was used as the selective agent. The sgfp gene encoding green fluorescence protein (GFP) was the reporter gene and served as a visual screening marker. A total of 167 transgenic plants were obtained from nine different embryogenic callus lines grown on a selection medium containing 1%-2% mannose. Embryoids and shoots regenerated via embryogenesis, that showed strong GFP fluorescence, were selected from two sorghum genotypes: C401, an inbred line, and Pioneer 8505, a commercial hybrid. The GFP accumulation in transgenic plants was observed with a dissecting stereomicroscope. The integration and expression of the manA gene was confirmed by Southern blot and Western blot analyses, and the feasibility of manA selection was demonstrated by the chlorophenol red (CPR) assay. Our results indicated that transgenes segregated in the Mendelian fashion in the T1 generation. The conversion of mannose to a metabolizable fructose carbon source is beneficial to plants. In addition, except in soybean and a few legumes, no endogenous PMI activity has been detected in plant species, indicating that PMI is useful in the transformation of sorghum. In addition, PMI has no sequence homology to known allergens. Optimization of this selection system for sorghum transformation provides an efficient way to produce transgenic plants without using antibiotic or herbicidal agents as selectable markers, and our results showed that the transformation efficiency reached 2.88% for Pioneer 8505 and 3.30% for C401, both values higher than in previously published reports.     

Cre/<Emphasis Type="Italic">lox</Emphasis>-mediated marker gene excision in transgenic maize (Zea mays L.) plants

After the initial transformation and tissue culture process is complete, selectable marker genes, which are used in virtually all transformation approaches, are not required for the expression of the gene of interest in the transgenic plants. There are several advantages to removing the selectable marker gene after it is no longer needed, such as enabling the reuse of selectable markers and simplifying transgene arrays. We have tested the Cre/lox system from bacteriophage P1 for its ability to precisely excise stably integrated marker genes from chromosomes in transgenic maize plants. Two strategies, crossing and autoexcision, have been tested and demonstrated. In the crossing strategy, plants expressing the Cre recombinase are crossed with plants bearing a transgene construct in which the selectable marker gene is flanked by directly repeated lox sites. Unlike previous reports in which incomplete somatic and germline excision were common, in our experiments complete somatic and germline marker gene excision occurred in the F₁ plants from most crosses with multiple independent Cre and lox lines. In the autoexcision strategy, the cre gene, under the control of a heat shock-inducible promoter, is excised along with the nptII marker gene. Our results show that a transient heat shock treatment of primary transgenic callus is sufficient for inducing cre and excising the cre and nptII genes. Genetic segregation and molecular analysis confirmed that marker gene removal is precise, complete and stable. The autoexcision strategy provides a way of removing the selectable marker gene from callus or other tissues such as embryos and kernels.Communicated by D. Hoisington     

选择标记可去除的植物高效表达载体的构建

在常用的植物组成型表达载体pBI121的选择标记基因NPTII两侧插入同向的lox位点并用多克隆位点(MCS)取代了GUS基因序列,构建了NPTII基因可被去除的和可插入目的基因的通用植物表达载体pBI121-lox-MCS。替换pBI121-lox-MCS中驱动目的基因表达的35S启动子,可构建成一系列具有其他表达特性的植物表达载体,如本文描述的韧皮部特异表达载体pBdENP-lox-MCS。为方便地筛选去除选择标记基因的转基因植物,还构建了绿色荧光蛋白(GFP)表达框与NPTII表达框连锁的pBI121-gfp-lox-MCS载体。上述植物表达载体可广泛应用于培育选择标记可去除的转基因植物。     

Establishment of neomycin phosphotransferase II (<Emphasis Type="Italic">nptII</Emphasis>) selection for transformation of soybean somatic embryogenic cultures

Soybean transformation is limited by the lack of multiple efficient selectable marker systems. Biolistic transformation of somatic proliferative embryogenic cultures, one of the commonly used soybean transformation methods, relies largely on hygromycin phosphotransferase II (hptII) selection. The purpose of the present study was to establish another efficient selectable marker system to facilitate multiple gene transformations of soybean. We tested neomycin phosphotransferase II (nptII) that has been used successfully in cotyledonary node transformation, but with limited success in transformation of embryogenic cultures. Transgenic events were obtained using nptII with improved G418 selection without generating escapes. G418 selection required longer recovery and selection periods, and resulted in a lower efficiency of initial transformants compared to hygromycin selection. Six independent fertile transgenic plants were recovered using nptII and G418, a frequency similar to that obtained with hygromycin selection. Soybean embryogenic cultures co-transformed with the hptII and nptII markers showed resistance to both hygromycin B and G418, while regeneration and plant fertility were not adversely affected. The nptII will be useful as a second selectable marker for multiple gene transformations in basic and applied soybean research.     

Agrobacterium-mediated co-transformation of rice using two selectable marker genes derived from rice genome components

A method for Agrobacterium-mediated co-transformation of rice (Oryza sativa L.) was developed using rice-derived selection markers. Two T-DNAs were efficiently introduced into separate loci using selectable marker gene cassettes consisting of the mutated acetolactate synthase gene (mALS) under the control of the callus-specific promoter (CSP) (CSP:mALS) and the ferredoxin nitrite reductase gene (NiR) under the control of its own promoter (NiR P:NiR). The CSP:mALS gene cassette confers sulfonylurea herbicide resistance to transgenic rice callus. The NiR P:NiR construct complements NiR-deficient mutant cultivars such as ‘Koshihikari’, which are defective in the regulation of nitrogen metabolism. In the present study, the CaMV35S:GUS and CaMV35S:GFP gene cassettes were co-introduced into the ‘Koshihikari’ genome using our system. Approximately 5–10 independent transgenic lines expressing both the GUS and GFP reporters were obtained from 100 Agrobacterium co-inoculated calli. Furthermore, transgenic ‘Koshihikari’ rice lines with reduced content of two major seed allergen proteins, the 33 and 14–16?kDa allergens, were generated by this co-transformation system. The present results indicate that the generation of selectable antibiotic resistance marker gene-free transgenic rice is possible using our rice-derived selection marker co-transformation system. Key message An improved rice transformation method was developed based on Agrobacterium-mediated co-transformation using two rice genome-derived selectable marker gene cassettes.     

Introduction and constitutive expression of a tobacco hornworm (<Emphasis Type="Italic">Manduca sexta</Emphasis>) chitinase gene in soybean

Summary Embryogenic soybean [Glycine max (L.) Merrill] cultures were transformed with a Manduca sexta chitinase (msc) gene using microprojectile bombardment. A 1.7 kb DNA fragment encoding a tobacco hornworm chitinase was cloned into the rice transformation vector pGL2, under the control of the maize ubiquitin promoter and linked to the hpt gene as a selectable marker. After bombardment, hygromycin-resistant tissues were isolated and cultured to give rise to clones of transgenic material. Four hygromycin-resistant clones were converted into plants. Two clones were positive for the msc gene via polymerase chain reaction (PCR) and Southern blot analysis. The integration inheritance, and expression of transgenes were confirmed by molecular analysis of transgenic soybean plants. Progeny analysis showed that the introduced genes were inherited and segregated in a 3:1 Mendelian fashion. DNA blot experiments and progeny inheritance analysis indicated that the plants contained several copies of the msc gene and that the insertion occurred at a single locus. Northern blotting analysis confirmed the expression of the transgenes. Western blot analysis of transgenic plants and their progeny revealed the presence of a protein with a molecular weight of 48kDa that reacted with the Manduca sexta antibody. Progeny from the chitinase-positive plants were tested for their resistance to the soybean cyst nematode. Plants expressing the insect chitinase did not manifest enhanced resistance to the soybean cyst nematode.     

Multiple inserts of gene of interest and selectable marker gene are co-integrated and stably transmitted as a single genetic locus in transgenic soybean plants

Particle bombardment has been used for soybean transformation for more than 20 yr, but the integration and segregation of transgene inserts in the soybean genome have not been clearly documented. Over the past 5 yr, we processed several hundred transgenic events. In each experiment, the expression cassettes of the gene of interest (GOI) and hygromycin selectable marker gene (SMG) were co-bombarded into soybean at a 1:1 molecular ratio. More than 75% of hygromycin-resistant events also carried the GOI. Molecular analysis of transgenic plants revealed that most events carried multiple inserts of the GOI and the SMG. The GOI and the SMG were linked in selfed T1 and T2 progeny. Segregation analysis of progeny indicated that, in over 98% of the transgenic events, the multiple inserts of the GOI were integrated into the same genetic locus resulting in a 3:1 segregation ratio. Furthermore, the multiple inserts of the GOI are transmitted into succeeding generations, and no recombinants were found. These data indicate that in soybean plants, co-bombarded genes are preferentially integrated and stably segregated as a single genetic locus.