Development of selectable marker-free transgenic potato plants expressing cry3A against the Colorado potato beetle (Leptinotarsa decemlineata Say).

BACKGROUND: Elimination of selectable marker genes (SMGs) is important for the safe assessment and commercial use of transgenic plants. The destructive and invasive Colorado potato beetle (CPB) poses a serious threat to potato production. In response to this need, selectable marker-free transgenic potato lines expressing cry3A were developed to control the damage and spread of CPB. RESULTS: We simultaneously introduced cry3A and npt II genes harboured in different plasmids into the potato genome using the Agrobacterium-mediated cotransformation method. Four selectable marker-free transgenic potato (CT) lines expressing cry3A were developed by self-crossing segregation and molecular analyses, including Southern blot, western blot and enzyme-linked immunosorbent assay (ELISA) assays. CT lines were used in a resistance bioassay against CPB in the laboratory and field. In the laboratory, CT lines exhibited high resistance to CPB, and 100% mortality of first-instar larvae occurred 6 days after infestation. In the field, untransformed plant leaves were almost entirely consumed, with an average of 155 larvae present per plant 25 days after inoculation. However, CT lines showed no damage symptoms, with approximately 2.5 larvae surviving per plant. CONCLUSION: We successfully eliminated SMGs from the transgenic potato lines expressing cry3A in order to decrease CPB damage, control the spread of this pest eastwards and alleviate the concern regarding the safe assessment of regulatory requirements. © 2015 Society of Chemical Industry.

[Development of transgenic oilseed plants resistant to glyphosate and insects].

In this study, the aroA-M12 gene encoding bacterial 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) and the Btslm recombinant gene encoding Bacillus thuringiensis (Bt) toxin gene were introduced into a Brassica napus variety, Xiangyou No. 15, via Agrobacterium-mediated transformation using glyphosate as a selectable agent. PCR amplification and Southern blot analyses of T0 transgenic plants showed that the alien genes were transferred and integrated stably into the genome of Xiangyou No. 15. Western blot further confirmed that the alien genes were expressed in these plants. Transgenic plants with tolerance to both glyphosate and the tested pest were demonstrated by bioassays. Our result also clearly shows that the aroA-M12 gene can be used as an efficient selectable marker gene instead of antibiotic resistant markers in plant transformation.

[Expression of two plant agglutinin genes in transgenic tobacco plants].

A plant expression vector pBACG containing the DNA sequence coding for Amaranthus caudatus agglutinin (ACA) and a modified Glanthus nivalis agglutinin (GNA) gene was constructed. Leaf explants of Nicotiana tobacum cv. SRI were transformed with A. tumefaciens LBA4404 harbouring the above expression vector. Results from PCR and Southern blotting analysis showed that both the ACA and GNA gene were inserted into the genome of transformed tobacco plants. Western blottingting analysis of soluble protein isolated from transgenic plants showed that ACA and GNA were synthesized. The results from insect bioassay with peach aphids ( Myzus persicae) revealed that the transgenic plants of pBACG had acquired high resistance against peach aphids. The average aphid-inhibition rate reached up to 83.9% and 85.3% for transgenic plants (T0) and their selfed progenies (T1) respectively,indicating that the functions of these two genes were inheritable.

The mitochondrial malate dehydrogenase 1 gene GhmMDH1 is involved in plant and root growth under phosphorus deficiency conditions in cotton.

Cotton, an important commercial crop, is cultivated for its natural fibers, and requires an adequate supply of soil nutrients, including phosphorus, for its growth. Soil phosporus exists primarily in insoluble forms. We isolated a mitochondrial malate dehydrogenase (MDH) gene, designated as GhmMDH1, from Gossypium hirsutum L. to assess its effect in enhancing P availability and absorption. An enzyme kinetic assay showed that the recombinant GhmMDH1 possesses the capacity to catalyze the interconversion of oxaloacetate and malate. The malate contents in the roots, leaves and root exudates was significantly higher in GhmMDH1-overexpressing plants and lower in knockdown plants compared with the wild-type control. Knockdown of GhmMDH1 gene resulted in increased respiration rate and reduced biomass whilst overexpression of GhmMDH1 gave rise to decreased respiration rate and higher biomass in the transgenic plants. When cultured in medium containing only insoluble phosphorus, Al-phosphorus, Fe-phosphorus, or Ca-phosphorus, GhmMDH1-overexpressing plants produced significantly longer roots and had a higher biomass and P content than WT plants, however, knockdown plants showed the opposite results for these traits. Collectively, our results show that GhmMDH1 is involved in plant and root growth under phosphorus deficiency conditions in cotton, owing to its functions in leaf respiration and P acquisition.

[Inheritance and segregation of transformants in cotton with two types of insect-resistant genes].

A plant expression vector containing a chemeric Bt29K gene coding for the active Cry1Ac protein and the arrowhead proteinase inhibition gene API-B was introduced into an elite cotton cultivar Jihe 321 by Agrobactertium tumefaciens. Some insect-resistant cotton lines were developed. Segregation and stabilization of insect-resistant genes in six transformation lines were studied. Based on the results of kanamycin resistant test and insect bioassay using Heliethis armigera, PCR detection and Southern-blot, we found that the inheritance and segregation of Bt gene were complicated, some transformants were in accordance with Mendelian patterns of inheritance in the ratio of insect-resistant plants to non-resistant plants in Ti progeny, yet others were non-Mendelian patterns. But the inheritance and segregation of Bt gene in homozygous transformation lines were one or two pairs of major dominant genes through crossing of insect resistant homozygous lines with non-transformation cotton variety. That the insect resistance phenotype was conditioned by one or two pairs of dominant genes was ascertained in this study. There were two copies of Bt genes in two transformation lines DR248 and DR193, which was reported for the first time. The results were confirmed by Southern-blot. Through observation of segregation population of transgenic plants at different generations, we found that the exogenous Bt gene in cotton genome showed unstable in inheritance in early generations, but the gene could be stabilized through resistance screening generation by generation. The unstability of Bt gene may mean that it need time for the gene to compatibilize cotton genome.

[Transgenic cotton plants of chitinase and glucanase genes and their performance of resistance to Verticillium dahliea].

The two disease-resistance genes chitinase and glucanase, which were respectively directed by commelina yellow mottle virus promoter (CoYMV, vascular specific) and CaMV35S promoter, were introduced into cotton genome via Agrobacterium tumefaciens. Transgenic plants were obtained from two popularly cultivated varieties Jihe321 and CRIC35. After screening by spraying kanamycin over unfolding leaves, the kanamycin resistance (KmR) plants were tested by PCR and Southern blot. The results showed that there were one or two inserts of transgenes in cotton genome. Performance test of resistance of T3 families in field and greenhouse showed that seven lines were resistant or tolerant to Verticillium dahliea. Meanwhile, the resistance at seedling stage in greenhouse was in accordance with that at the boll-setting stage in field. Among the seven lines, D9910, D9915 and D9919 had a disease resistance index of 6.5, 9.4 and 9.5, respectively in field, which showed a high resistance level. Genetics analysis of the three lines showed a classical Mendelian pattern of one pair of genes, which meant that each of the three lines contains one copy of transgene. Southern blotting also confirmed the copy number of inserts.

[A study on introduction of chitinase gene and beta-1,3-glucanase gene into restorer line of dian-type hybrid rice (Oryza sativa L.) and enhanced resistance to blast (Magnaporthe grisea)].

Plasmid pBLGC containing chitinase gene from Phaseolus limensis and beta-1,3-glucanase gene from Nicotiana tabacum was bombarded into the restorer line "Nan29" of Dian-type hybrid rice (Oryza sativa L. ssp. japonica) from Yunnan province of South-west China. 93 regenerants were obtained from the calli that were resistant to G418 (100 to 150 mg/L) on NB medium. Using beta-1,3 glucanase gene as the probe, 17 of the regenerants were identified to be transgenic lines by dot blotting and the foreign genes construction were integrated into the genomes of T1 lines by Southern blotting hybridization. Two foreign genes were inherited stably to T4 generation according to PCR results of the lines. The resistance to rice blast of six transgenic lines were evaluated by inoculating four violent biological races of Magnaporthe grisea from Yunnan province and inducing the disease in the field. The results indicated that the resistance to rice blast of transgenic lines were enhanced to varying degrees compared with the receptor line and the transgenic lines could be used in rice blast resistant breeding.

[Construction of selectable marker-removable plant expression vectors].

The commonly used plant constitutive expression vector pBI121 was modified by insertion of two directly orientated lox sites each at one end of the selectable marker gene NPTII and by replacing the GUS gene with a sequence composed of multiple cloning sites (MCS). The resulting plant expression vector pBI121-lox-MCS is widely usable to accommodate various target genes through the MCS, and more importantly to allow the NPTII gene removed from transformed plants upon the action of the Cre recombinase. In addition, the CaMV 35S promoter located upstream of the MCS can be substituted with any other promoters to form plant vectors with expression features specified by the introduced promoters. Provided in this paper is an example that an enhanced phloem-specific promoter of the pumpkin PP2 gene (named dENP) was used to construct an NPTII-removable phloem-specific expression vector pBdENP-lox-MCS. Moreover, to facilitate screening of selectable marker-removed gene and the composite sequence is flanked by lox sites. Thus the selectable marker-free plants can be visually identified by loss of GFP fluorescence. The above newly created plant expression vectors can be used to develop selectable marker-removable transgenic plants for a variety of purposes.

The cry3Aa gene of Bacillus thuringiensis Bt886 encodes a toxin against long-horned beetles.

This report describes the identification of a new toxigenic strain of Bacillus thuringiensis specific for long-horned beetles. B. thuringiensis Bt866 encodes a cry3Aa-like gene (Bt886cry3Aa) that is 1,956 bp in length and is predicted to encode an 85.78-kDa protein. The gene is highly similar to cry3Aa1, differing in only six nucleotides and four amino acids. The four disparate amino acids occur within the conserved domains of the Cry3Aa toxin. The expression of Bt866cry3A in Escherichia coli cells resulted in a high level of toxicity toward Apriona germari Hope larvae. More than 75% of the larvae were killed; and the remaining survivors exhibited slower growth. These results indicate that the toxigenic strain Bt886cry3Aa encodes a protein that is specific against long-horned beetles. Genetic engineering of the Bt866cry3Aa gene into poplar plantations may provide resistance to long-horned beetles.

[Cloning of ACA gene promoter and preliminary study of its function].

Using total DNA isolated from Amaranthus caudatus as the template, a DNA fragment of about 700bp upstream of the coding sequence of Amaranthus caudatus agglutinin (ACA) gene was amplified by TAIL-PCR and cloned. To examine the regulatory function of this DNA fragment, it was inserted into a plant expression vector containing GUS gene to substitute the CaMV 35S promoter and the resulted recombinant plasmid was designated as pBpAG. The expression vector pBpAG was transferred to different tissues of plants, via Agrobacterium-mediated transformation in vacuum condition. Transient expression of GUS in the transformed tissues was detected by histochemical GUS staining and the results showed that the GUS activity was expressed specifically in seeds. These preliminary results indicate that this DNA fragment upstream of the ACA coding sequence could very possibly be a promoter with seed specificity. Some putative cis-elements within the promoter were discussed.

[Construction of a vector conferring herbicide and pest resistance in tobacco plant].

A binary plant expression vector, pCM12-slm, carrying the aroAM12 mutant gene encoding bacterial 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) and the Bts1m recombinant gene consisting of 331 N-terminal amino acids of CryIAc and 284 C-terminal amino acids of CryIAb has been constructed. The truncated Bts1 gene was fused with the PR1b signal peptide sequence and expressed in tobacco plants under the control of 2E-CaMV35S promoter and the omega (omega) translation enhancer sequence from tobacco mosaic virus. The mutant aroAM12 was fused with the transit sequence of tobacco EPSPS and expressed in tobacco plants under the control of the CaMV35S promoter. Tobacco leaves were transformed with Agrobacterium tumefaciens LBA4404 harboring the pCM12-slm plasmid, and the transgenic plants were selected directly on medium containing the herbicide. Forty glyphosate resistant plants were regenerated, with a transformation frequency of 27%. Transgenic plants were initially assessed for glyphosate resistance by placing leaf discs on shoot induction media containing the herbicide. Rooted plantlets, propagated from selected transgenic tobacco, were transferred to soil in a greenhouse and tested for glyphosate resistance by spraying them with Roundup at a commercial recommended dose. The glyphosate resistance assay indicated that all the transgenic plants showed highly resistant to the herbicide. The PCR assay showed that the aroAM12 gene was present in all of the 40 T0 transfer plants, and Bts1m genes present in 28 of 40 of the transgenic plants. Southern blot analysis further confirmed that the copy number of the transgenes varied from one to three copies in different transgenic plants. Northern blot and immunodot blot showed that the aroAM12 and Bts1m genes were expressed at the transcription and translation levels. Transgenic plants containing both the aroA M12 and Bts1m genes were further assessed for insect resistance. Tobacco leaves of T0 transgenic plants were infested with tobacco bollworm H. assulta larvae for 6 days. The result (table 1) showed that the survival rate of insect larvae was between 0-10%, and the growth of insect larvae was seriously inhibited, suggesting pCM12-slm as a dual functional vector with potential application in breeding of glyphosate and insect resistance transgenic plants.