Zhihong Lang

Acquiring transgenic tobacco plants with insect resistance and glyphosate tolerance by fusion gene transformation.

AbstractThe advantages of gene ‘stacking’ or ‘pyramiding’ are obvious in genetically modified (GM) crops, and several different multi-transgene-stacking methods are available. Using linker peptides for multiple gene transformation is considered to be a good method to meet a variety of needs. In our experiment, the Bt cry1Ah gene, which encodes the insect-resistance protein, and the mG2-epsps gene, which encodes the glyphosate-tolerance protein, were connected by a 2A or LP4/2A linker. Linker 2A is a peptide from the foot-and-mouth disease virus (FMDV) that has self-cleavage activity. LP4 is a peptide from Raphanus sativus seeds that has a recognition site and is cleaved by a protease. LP4/2A is a hybrid peptide that contains the first 9 amino acids of LP4 and 20 amino acids from 2A. We used the linker peptide to construct four coordinated expression vectors: pHAG, pHLAG, pGAH and pGLAH. Two single gene expression vectors, pSAh and pSmG2, were used as controls. The six expression vectors and the pCAMBIA2301 vector were transferred into tobacco by Agrobacterium tumefaciens-mediated transformation, and 529 transformants were obtained. Molecular detection and bioassay detection data demonstrated that the transgenic tobaccos possessed good pest resistance and glyphosate tolerance. The two genes in the fusion vector were expressed simultaneously. The plants with the genes linked by the LP4/2A peptide showed better pest resistance and glyphosate tolerance than the plants with the genes linked by 2A. The expression level of the two genes linked by LP4/2A was not significantly different from the single gene vector. Key message The expression level of the two genes linked by LP4/2A was higher than those linked by 2A and was not significantly different from the single gene vector.

The influence of Bt-transgenic maize pollen on the bacterial diversity in the midgut of Apis mellifera ligustica

Honeybees are subjected to direct contact with transgenic maize pollen due to their feeding activities on pollen. The potential side effects of transgenic cry1Ah-maize pollen on the midgut bacteria of the larvae and worker bees of Apis mellifera ligustica were investigated through denaturing gradient gel electrophoresis under both laboratory and field conditions. Newly emerged bees were fed transgenic cry1Ah-maize pollen, normal maize pollen, linear cry1Ah gene DNA, supercoiled plasmid DNA, and sugar syrup under the laboratory conditions. The results showed that there were no significant differences in the midgut bacterial community composition among the five treatments. No significant effects were observed in the midgut communities between larvae and adult honeybees fed transgenic cry1Ah-maize pollen and non-transgenic maize pollen in the field trials.

Regulatory modules controlling early shade avoidance response in maize seedlings

BackgroundOptimization of shade avoidance response (SAR) is crucial for enhancing crop yield in high-density planting conditions in modern agriculture, but a comprehensive study of the regulatory network of SAR is still lacking in monocot crops.ResultsIn this study, the genome-wide early responses in maize seedlings to the simulated shade (low red/far-red ratio) and also to far-red light treatment were transcriptionally profiled. The two processes were predominantly mediated by phytochrome B and phytochrome A, respectively. Clustering of differentially transcribed genes (DTGs) along with functional enrichment analysis identified important biological processes regulated in response to both treatments. Co-expression network analysis identified two transcription factor modules as potentially pivotal regulators of SAR and de-etiolation, respectively. A comprehensive cross-species comparison of orthologous DTG pairs between maize and Arabidopsis in SAR was also conducted, with emphasis on regulatory circuits controlling accelerated flowering and elongated growth, two physiological hallmarks of SAR. Moreover, it was found that the genome-wide distribution of DTGs in SAR and de-etiolation both biased toward the maize1 subgenome, and this was associated with differential retention of various cis-elements between the two subgenomes.ConclusionsThe results provide the first transcriptional picture for the early dynamics of maize phytochrome signaling. Candidate genes with regulatory functions involved in maize shade avoidance response have been identified, offering a starting point for further functional genomics investigation of maize adaptation to heavily shaded field conditions.

The Influence of Bt-Transgenic Maize Pollen on the Bacterial Diversity in the Midgut of Chinese Honeybees, Apis cerana cerana

Abstract Using culture-independent technique polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) and conventional culture techniques, ecological risk of transgenic maize pollen on gut bacteria of the Chinese honeybee, Apis cerana cerana , was assessed. Honeybees were fed with Bt-transgenic maize pollen, non-transgenic near isoline pollen, linear cry1Ah gene (800 ng mL −1 ) and supercoiled plasmid DNA (800 ng mL −1 ) under laboratory conditions. The DGGE profile showed that the number of DGGE bands varied from 10.7 to 14.7 per sample, and the Shannons index ranged from 0.85 to 1.00. The similarity calculated by PAST was mostly above 92%, indicating no obvious changes among treatments or within replicates. 14 bacterial strains affiliated with Alphaproteobacteria, Gammaproteobacteria, Firmicutes, and Actinobacteria were isolated and characterized on media under aerobic and anaerobic conditions. These results demonstrated that transgenic cry1Ah maize pollen did not induce significant changes of the honeybee gut bacterial community composition under laboratory conditions.

Acquisition of Insect-Resistant Transgenic Maize Harboring a Truncated cry1Ah Gene via Agrobacterium-Mediated Transformation

A novel insecticidal gene cry1Ah was cloned from Bacillus thuringiensis isolate BT8 previously for plant genetic engineering improvement. Truncated active Cry1Ah toxin has a toxicity level similar to that of the full-length Cry1Ah toxin. In this study, plant expression vector pMhGM harboring truncated cry1Ah gene was transformed into maize (Zea mays L.) immature embryos by Agrobacterium tumefaciens-mediated transformation at which maize alcohol dehydrogenase matrix attachment regions (madMARs) were incorporated on both sides of the gene expression cassette to improve gene expression. A total of 23 PCR positive events were obtained with a transformation efficiency of 5% around. Bioassay results showed that events 1-4 and 1-5 exhibited enhanced resistance to the Asian corn borer (Ostrinia furnacalis). These two events were further confirmed by molecular analysis. Southern blot suggested that a single copy of the cry1Ah gene was successfully integrated into the maize genome. Western blot and ELISA showed that the foreign gene cry1Ah was expressed stably at high level in maize and could be inherited stably over generations. The results of a bioassay of T1-T4 transgenic maize plants indicated that the transgenic plants were highly toxic to the Asian corn borer and their resistance could be inherited stably from generation to generation. Thus, events 1-4 and 1-5 are good candidates for the breeding of insect-resistant maize.

Transcriptome profiling revealed novel transcriptional regulators in maize responses to Ostrinia furnacalis and jasmonic acid

Chewing insects cause severe yield losses in crop production worldwide. Crop plants counteract chewing insects by transcriptionally promoting a repertoire of defense gene products that are either toxic to, or attractive to the natural enemies of, pest insects. However, the complexity of the transcriptional reprogramming in plant defense response against chewing insects is still not well understood. In this study, the genome-wide early responses in maize seedlings to Asian corn borer (ACB, Ostrinia furnacalis) and also to jasmonic acid(JA), the pivotal phytohormone controlling plant defense response against herbivory, were transcriptionally profiled by RNA-Seq. Clustering of differentially expressed genes (DEGs) along with functional enrichment analysis revealed important biological processes regulated in response to ACB infestation and/or jasmonic acid. Moreover, DEGs with distinct expression patterns were differentially enriched with diverse families of cis-elements on their promoters. Multiple inventories of differentially expressed transcription factors (DETFs) in each DEG group were also analyzed. A transient expression assay using transfected maize protoplastswas established to examine the potential roles of DETFs in maize defense response and JA signaling, and this was used to show that ZmNAC60, an ACB- and JA-inducible DETF, represented a novel positive regulator of JA and defense pathway genes. This study provided a comprehensive transcriptional picture for the early dynamics of maize defense responses and JA signaling, and the identification of DETFs offered potential targets for further functional genomics investigation of master regulators in maize defense responses against herbivory.

Developing transgenic maize （Zea mays L.） with insect resistance and glyphosate tolerance by fusion gene transformation

Abstract Using linker peptide LP4/2A for multiple gene transformation is considered to be an effective method to stack or pyramid several traits in plants. Bacillus thuringiensis (Bt) cry gene and epsps (5-enolpyruvylshikimate-3-phosphate synthase) gene are two important genes for culturing pest-resistant and glyphosate-tolerant crops. We used linker peptide LP4/2A to connect the Bt cry1Ah gene with the 2mG2-epsps gene and combined the wide-used manA gene as a selective marker to construct one coordinated expression vector called p2EPUHLAGN. The expression vector was transferred into maize by Agrobacterium tumefaciens-mediated transformation, and 60 plants were obtained, 40% of which were positive transformants. Molecular detection demonstrated that the two genes in the fusion vector were expressed simultaneously and spliced correctly in translation processing; meanwhile bioassay detection proved the transgenic maize had preferable pest resistance and glyphosate tolerance. Therefore, linker peptide LP4/2A provided a simple and reliable strategy for producing gene stacking in maize and the result showed that the fusion gene transformation system of LP4/2A was feasible in monocot plants.

Processing and targeting of proteins derived from polyprotein with 2A and LP4/2A as peptide linkers in a maize expression system

In the transformation of multiple genes, gene fusion is an attractive alternative to other methods, including sexual crossing, re-transformation, and co-transformation, among others. The 2A peptide from the foot-and-mouth disease virus (FMDV) causes the co-translational “cleavage” of polyprotein and operates in a wide variety of eukaryotic cells. LP4, a linker peptide that originates from a natural polyprotein occurring in the seed of Impatiens balsamina, can be split between the first and second amino acids in post-translational processing. LP4/2A is a hybrid linker peptide that contains the first nine amino acids of LP4 and 20 amino acids of 2A. The three linkers have been used as a suitable technique to link the expression of genes in some transgenic plants, but to date the cleavage efficiency of three linkers have not been comprehensively demonstrated in the same transformation system, especially in the staple crop. To verify the functions of 2A, LP4, and LP4/2A linker peptides in transgenic maize, six fusion protein vectors that each encoded a single open reading frame (ORF) incorporating two report genes, Green Fluorescent Protein (GFP) and β-glucuronidase (GUS), separated by 2A (or modified 2A), LP4 or LP4/2A were assembled to compare the cleavage efficiency of the three linkers in a maize transient expression system. The results demonstrated the more protein production and higher cleavage splicing efficiency with the polyprotein construct linked by the LP4/2A peptide than those of the polyprotein constructs linked by 2A or LP4 alone. Seven other fusion proteins that each encoded a single ORF incorporating two different genes GFP and Red Fluorecent Protein (RFP) with different signal peptides were assembled to study the subcellular localization of genes linked by LP4/2A. The subcellular localization experiments suggested that both types of signal peptide, co-translational and post-translational, could lead their proteins to the target localization in maize protoplast transformed by LP4/2A polyprotein construct and it implied the LP4/2A linker peptide could alleviate the inhibition of 2A processing by the carboxy-terminal region of upstream protein of 2A when translocated into the ER.

Expression of cry2Ah1 and two domain II mutants in transgenic tobacco confers high resistance to susceptible and Cry1Ac-resistant cotton bollworm

To improve the novel Bacillus thuringiensis insecticidal gene cry2Ah1 toxicity, two mutants cry2Ah1-vp (V354VP) and cry2Ah1-sp (V354SP) were performed. SWISS-MODEL analysis showed two mutants had a longer loop located between β-4 and β-5 of domain II, resulting in higher binding affinity with brush border membrane vesicles (BBMV) of Helicoverpa armigera comparing with Cry2Ah1. The cry2Ah1, cry2Ah1-vp, and cry2Ah1-sp were optimized codon usage according to plant codon bias, and named mcry2Ah1, mcry2Ah1-vp, and mcry2Ah1-sp. They were transformed into tobacco via Agrobacterium-mediated transformation and a total of 4, 8, and 24 transgenic tobacco plants were obtained, respectively. The molecular detection showed the exogenous gene was integrated into tobacco genome, and successfully expressed at the transcript and translation levels. Cry2Ah1 protein in transgenic tobacco plants varied from 4.41 to 40.28 μg g−1 fresh weight. Insect bioassays indicated that all transgenic tobacco plants were highly toxic to both susceptible and Cry1Ac-resistant cotton bollworm larvae, and the insect resistance efficiency to Cry1Ac-resistant cotton bollworm was highest in mcry2Ah1-sp transgenic tobacco plants. The results demonstrated that cry2Ah1 was a useful Bt insecticidal gene to susceptible and Cry1Ac-resistant cotton bollworm and had potential application for insect biocontrol and as a candidate for pyramid strategy in Bt crops.

Utilizing modified ubi1 introns to enhance exogenous gene expression in maize (Zea mays L.) and rice (Oryza sativa L.)

Abstract The phenomenon of intron-mediated enhancement (IME) was discovered in 1990 based on the observation that plant introns can stimulate gene expression, particularly in monocots. However, the intrinsic mechanism of IME remains unclear because many studies have yielded various results depending on the promoter, reporter gene, flanking sequences of the intron, and target cell or tissue. In this study, the effect of the first intron of the maize ubiquitin gene ( ubi1 intron) was investigated by changing insertion sites, deleting specific regions and mutating individual motifs in maize ( Zea mays L.) and rice ( Oryza sativa L.) using ubi1 intron-containing GUS (β- glucuronidase ) constructs. In maize callus, the integration of the full-length ubi1 intron into the GUS coding sequence at the +13, +115 and +513 positions by particle bombardment increased GUS activity approximately five-, four- and two-fold, respectively. Eight truncated ubi1 introns in the pSG(13i) N construct significantly influenced GUS gene expression to different degrees in transient assays. Notably, the 3′ region deletions significantly reduced the IME effect, whereas a 142-nt deletion, pSG(13i-P5)N, in the 5′ region caused a 1.5-fold enhancement relative to pSG(13i)N. Furthermore, four site-directed mutageneses were performed in pSG(13i-P5)N; these constructs resulted in the up-regulation of GUS gene expression to different levels. The most effective modified ubi1 intron, pSG(13i-M4)N, was further evaluated and proved in rice using transient experiments. In addition, the sequences flanking the GUS insertion significantly influenced the IME effect of the vectors that were constructed. The modified ubi1 intron had the potential application on crop genetic engineering.