Agroinfiltration is a newly developed plant transient gene expression technique, which is simple, rapid and reproducible. It has been widely used in analyses of foreign gene expression, hypersensitive reaction, gene silencing, promoter activity and identification of new disease-resistance genes. In this paper, we describe the principle and the operation procedure of Agroinfiltration and its application in diverse aspects of plant molecular biology research. Our experiences in modification of the Agroinfiltration technique are also provided.
Agrobacterium tumefaciens ; genetics ; Genetic Vectors ; genetics ; Plants ; genetics ; Plants, Genetically Modified ; Research Design

Insecticidal protein genes from Bacillus thuringiensis are currently the most widely used insect-resistant genes. They have been transferred to many crops for breeding and production. Among them, cotton, maize, potato and other insect-resistant crops are commercialized, creating considerable economic benefit. In this review, we summarized advances in identifying functional genes and transgenic crops for insect resistance, compared different strategies for enhancing vigor of insecticidal protein and utilizing gene stacking as well as listing valuable groups of stacked genes. In addition, the methods for multiple gene transformation was discussed.
Animals ; Bacterial Proteins ; genetics ; Crops, Agricultural ; genetics ; Endotoxins ; genetics ; Hemolysin Proteins ; genetics ; Insecta ; Plants, Genetically Modified

Marker-free plants have been public concern. Co-transformation and site-specific recombination system are more important methods in self-gene excision. We reviewed the Cre/lox site-specific system and its applications in plants, also, we discussed perspectives of the system in according with our experience.
DNA, Plant ; genetics ; Genes, Plant ; genetics ; Genetic Markers ; Integrases ; Plants, Genetically Modified ; genetics ; Recombination, Genetic

In genetic modification of plants, once the transformants are obtained, selection markers are no longer required in mature plants. At present, the Cre/lox site-specific recombination system is most widely used to eliminate the selectable marker genes from the transgenic plants. In this study, attempt was made to favour the selection of marker-free plants in the re-transformation method. Green fluorescent protein (GFP) can be directly visualized in living cells, tissues or organisms under UV illumination. This advantage of GFP is exploited in the development of a practical approach in which GFP is used as a visual marker to monitor the removal of the selectable marker gene from transgenic plants. For that purpose, the pGNG binary vector was constructed, in which the GFP gene (gfp) was linked to the expression cassette Nos P-nptII-NosT and the two units were cloned between two directly-orientated lox sites. The CaMV 35S promoter was placed before the first lox site and used to drive GFP expression. The beta-glucuronidase gene (gus) of Escherichia coli was cloned behind the second lox site without a promoter, thus would not be expressed in this position. Tobacco plants were first transformed with pGNG and selected on kanamycin (Kan)-containing media. Regenerated transgenic shoots were readily singled out by GFP fluorescence. The GFP-expressing plants were then re-transformed with pCambia1300-Cre containing hygromycin phosphotransferase gene (hpt) as a selectable marker gene. The Cre-mediated recombination resulted in the elimination of lox-flanked genes, herein gfp and nptII, from the plant genome and brought the GUS gene next to the 35S promoter. Our data demonstrated that transgenic plants free of nptII were easily selected by monitoring the loss of green fluorescence, and at the same time, GUS (here as a target protein) was expressed in the nptII-free plants. Finally, hpt and cre were removed from the progenies of the nptII-free plants by gene segregation.
Genetic Markers ; Green Fluorescent Proteins ; genetics ; Plants, Genetically Modified ; genetics ; Plasmids ; Recombination, Genetic ; Tobacco ; genetics

Recombinant proteins provide new means for disease treatment, while creating considerable economic benefits. Using commercial crops (mainly tobacco), cereal crops, legumes, and vegetable crops to produce recombinant proteins with medicinal value is a hot-spot for research in "molecular farming". Although many recombinant proteins have been expressed in plants, only a small number have been successfully put into use. To overcome the problems that greatly hamper the development of recombinant protein production in plants, researchers have improved expression systems to increase the yield of recombinant proteins. Starting from analyzing the problems of low yield and/or low biological activity of recombinant proteins produced by plants, the optimization strategies to solve these problems were reviewed, and future research directions for improving the yield of recombinant proteins produced by plants were proposed.
Crops, Agricultural/genetics* ; Plant Proteins/metabolism* ; Plants, Genetically Modified/genetics* ; Recombinant Proteins ; Tobacco/genetics*

Currently, transgenic crops create huge economic, social and ecological benefits with the development of its commercial production. For China, the speed of development and commercialization of transgenic crops is a strategic issue for the sustainable agriculture development and the international competitiveness of our agricultural products. In this paper, we compared and analyzed the status of commercialization of transgenic crops in China and world-wide.
Agriculture ; methods ; trends ; China ; Crops, Agricultural ; genetics ; Gene Transfer Techniques ; trends ; Plants, Genetically Modified ; genetics

Gummy stem blight, a plant disease caused by Didymella bryoniae, is one of the major diseases in melon. The disease can seriously reduce melon yield and quality. However, little information is available on the genetics and functional genomics of the fungal pathogen. In this study, we developed an Agrobacterium-mediated transformation system for D. bryoniae by using a universal pathogenic isolate DB11 and the Agrobacterium tumefaciens strain C58C1 carrying plasmid pBIG2RHPH2 harboring the hygromycin B phosphotransferase gene (hph). Total 45 transformants could be obtained per 1 x 10(5) spores when 1 x 10(6) spores per milliliter of D. bryoniae spore suspension were cocultivated with Agrobacterium cells at OD600 = 0.15 for 48 h in the presence of induction medium (pH 5.2) containing acetosyringone at 200 microg/mL and selection medium contained 100 microg/mL of hygromycin B and 200 microg/mL of cefotaxime sodium, ampicillin and tetracycline, respectively. The transformants were stable when grown on PDA medium without hygromycin B for five times and were verified by PCR amplification with the hph primers and by Southern blot analysis with the hph probe. The transformation system will be useful for further studies of functional genes in D. bryoniae.
Agrobacterium tumefaciens ; genetics ; Ascomycota ; genetics ; Cucumis melo ; microbiology ; Plant Diseases ; microbiology ; Plants, Genetically Modified ; Transformation, Genetic

Animals ; Genetic Engineering ; Humans ; Plants, Genetically Modified ; genetics ; Plasmids ; Vaccines, Synthetic ; biosynthesis ; genetics

Chloroplast genetic engineering, offers several advantages over nuclear transformation, including high level of gene expression, increased biosafety, remedying some limitations associated with nuclear genetic transformation, such as gene silencing and the stability of transformed genes. It is now regarded as an attractive new transgenic technique and further development of biotechnology in agriculture. In this article we reviewed the characteristics, applications of chloroplast genetic engineering and its promising prospects were discussed.
Biotechnology ; methods ; Chloroplasts ; genetics ; Genetic Engineering ; methods ; Plants, Genetically Modified ; genetics ; Transformation, Genetic

In this article primary studies of the application of hyperbranched rolling cycle amplification (HRCA) in exogenous genes detection of transgenic plants were done. Four padlock probes were designed according to the sequences of four genes/DNA fragments that are used widely in transgenic plants; part of the sequence of pKK233 was chosen as the linking part of padlock probes and a pair of HRCA primers was designed according to the sequence of linking part. Study of the specificity of ligation in HRCA with isotope labeled padlock probes indicated padlock probes could be ringed effectively only when corresponding target DNA exited in the same reaction system and could not be ringed when there was no corresponding target DNA exited. Ligation time is very different according to the characteristic of target DNA being used. 5 min to 10 min is enough if the target DNA is plasmid; 30 min to 60 min is needed if the target is genome DNA of plant because it's sequence is more complex than that of plasmid's. HRCA time was analyzed which indicated longer reaction time can obviously increase the amount of products. Quantity of enzyme in HRCA was also analyzed. Different amount of enzyme (from 0.5 unit to 4 units) can give similar result when other conditions are not changed. On the basis of the research, transgenic tobacco was detected with these four padlock probes and the results were just as prospective. In order to increase the efficiency of detection, multiplex HRCA (MHRCA)was used. In MHRCA more than one padlock probes are used at the same time in the same reaction system to detect more than one targets. Because the amplification products of MHRCA will be complex and it is almost impossible to analyze with electrophoresis, so reverse-blot is used. Detection results of transgenic tobacco with this method are the same with anticipation. Compare to MPCR method we established before MHRCA is more convenient to operate and more effective in detecting exogenous genes in transgenic plants.
Nucleic Acid Amplification Techniques ; methods ; Plants, Genetically Modified ; genetics ; Plasmids ; Tobacco ; genetics