Development of an Agrobacterium-mediated CRISPR/Cas9 gene editing system in jute(Corchorus capsularis)

Jute(Corchorus capsularis L.)is the second most important natural plant fiber source after cotton.However,developing an efficient gene editing system for jute remains a challenge.In this study,the transgenic hairy root system mediated by Agrobacterium rhizogenes strain K599 was developed for Meifeng 4,an elite jute variety widely cultivated in China.The transgenic hairy root system for jute was verified by subcellular localization and bimolecular fluorescence complementation(BiFC)assays.The CHLOROPLASTOS ALTERADOS 1(CcCLA1)gene,which is involved in the development of chloroplasts,was targeted for editing at two sites in Meifeng 4.Based on this hairy root transformation,the gRNA scaffold was placed under the control of cotton ubiquitin GhU6.7 and-GhU6.9 promoters,respectively,to assess the efficiency of gene editing.Results indicated the 50.0%(GhU6.7)and 38.5%(GhU6.9)editing events in the target 2 alleles(gRNA2),but no mutation was detected in the target 1 allele(gRNA1)in transgenic-positive hairy roots.CcCLA1 gene editing at gRNA2 under the control of GhU6.7 in Meifeng 4 was also carried out by Agrobacterium tumefaciens-mediated transformation.Two CcCLA1 mutants were albinic,with a gene editing efficiency of 5.3%.These findings confirm that the CRISPR/Cas9 system,incorporating promoter GhU6.7,can be used as a gene editing tool for jute.

Development of an Agrobacterium-mediated CRISPR/Cas9 system in pea(Pisum sativum L.)

Pea(Pisum sativum L.)is an annual cool-season legume crop.Owing to its role in sustainable agriculture as both a rotation and a cash crop,its global market is expanding and increased production is urgently needed.For both technical and regulatory reasons,neither conventional nor transgenic breeding techniques can keep pace with the demand for increased production.In answer to this challenge,CRISPR/Cas9 genome editing technology has been gaining traction in plant biology and crop breeding in recent years.However,there are currently no reports of the successful application of the CRISPR/Cas9 genome editing technology in pea.We developed a transient transformation system of hairy roots,mediated by Agrobacterium rhizogenes strain K599,to validate the efficiency of a CRISPR/Cas9 system.Further optimization resulted in an efficient vector,PsU6.3-tRNA-PsPDS3-en35S-PsCas9.We used this optimized CRISPR/Cas9 system to edit the pea phytoene desaturase(PsPDS)gene,causing albinism,by Agrobacterium-mediated genetic transformation.This is the first report of successful generation of gene-edited pea plants by this route.

Establishment of the Agrobacterium-mediated Genetic Transformation System of Ginkgo biloba and the Construction of the Expression Vector of Gb-DXR

[Objective] The research aimed to provide reference for increasing the genetic transformation efficiency of Ginkgo biloba mediated by Agrobacterium.[Method] Taking the mature embryos of Ginkgo biloba seeds as explants,after 48 hours＇ pre-cultivation on MS medium in the absence of phytohormone,GUS gene was transmitted into embryos of Ginkgo biloba mediated by three kinds of Agrobacterium.Transient expression of GUS gene activity was observed through histochemical staining,and the influencing factors of the expression of GUS gene were analyzed.And the expression vector of 1-deoxy-D-xylulose-5-phosphate reductoisomerase in the biosynthesis approach of biobalide precursor of Ginkgo biloba was constructed.[Result] A more suitable genetic transformation scheme was obtained as follows：taking embryos of Ginkgo biloba as explants,using EHA105 Agrobacterium with pCAMBIA1304＋ for infection,co-culture for 3 days and GUS staining.The results showed that transient expression rate of GUS after transformation was higher.[Conclusion] The research provide a more effective method for further study on the transgene of Ginkgo biloba.

Agrobacterium-mediated Transformation of Kentucky Bluegrass

Embryogenic calli of Kentucky bluegrass, named Md, were induced from mature seeds and embryos, and proliferated on medium K3 containing 2,4-dichlorophenoxyacetic acid (2,4-D, 10.0 mumol/L), 6-benzylaminopurine (BAR, 0.5 mumol/L) and K5 which was the K3 medium supplemented with cupric sulfa (0.5 mumol/L) under dim-light condition (20-30 mumol.m(-2).s-1, 16 h light) at 24 degreesC. Embryogenic calli were transformed with plasmids pDM805 Carring bar and gus genes, Which was mediated by an Agrobacterium strain AGL1, four transgenic lines were obtained. The important factors that affect the transformation efficiency and obtain desirable number of transgenic plants included: (1) the quality of embryogenic calli; (2) light condition and time of co-cultivation; (3) concentration of antibiotics used for suppressing the overgrowth of Agrobacterium in the course of transformed plant regeneration; (4) selection pressure, etc. The micro nutrient of cupric had significant influence on the quality of embryogenic calli. This presentation is the first successful protocol of Kentucky bluegrass transformation mediated by Agrobacterium.

Agrobacterium-Mediated Transformation of Rice: Constraints and Possible Solutions

Genetic transformation of rice(Oryza sativa L.) by introducing beneficial traits is now a central research instrument in plant physiology and a practical tool for plant improvement. Many approaches are verified for stable introduction of foreign genes into the plant genome. The review examined the different constraints that limit the success of rice genetic transformation via Agrobacterium-mediated approach and suggested possible solutions. Explant identification, gene transfer technique and construct to tailor the integration, transgene expression without collateral to genetic damage and transformant selection are among the technical challenges affecting the rice transformation. Despite the contests, Agrobacteriummediated transformation system has been a better option for producing transgenic rice varieties because of its exact T-DNA processing and simple integration of low copy-number transgene. This information is necessary for improving the transformation system for recalcitrant rice varieties.

Agrobacterium-Mediated Transfer of Arabidopsis ICE1 Gene into Lemon (Citrus Limon (L.) Burm. F. cv. Eureka)

The Arabidopsis ICEI （inducer of CBF expression 1） gene was cloned through RT-PCR of Arabidopsis cDNAs and introduced into the lemon （Citrus Limon （L.） Burm. F. cv. Eureka） genome using Agrobacterium-mediated transformation method. Epicotyl segments from in vitro grown lemon seedlings were co-cultivated with A. tumefaciens strain EHA 105 carrying the binary plasmid pMVICE1, whose T-DNA region contain ICEI gene driven by 35S CaMV promoter. Among 320 epicotyl segments inoculated, 71 explants responded and regenerated 51 elongated shoots. These shoots were subjected to an extra month of kanamycin exposure. In this way, the number of escapes reduced. Thirteen of 31 survived shoots formed roots and 7 were tested positive using PCR technique. Southern blot analyses confirmed PCR results and demonstrated that more than two copies of the ICE1 gene were integrated into the lemon genome.

In planta Agrobacterium-Mediated Transformation of Rice

The floral-dip transformation, the simplest technique, is no requirement of tissue culture procedure, and can directly transfer the interest gene into plant reproductive cells. It has been successfully applied to various plant species. In this study, the optimal conditions of a floral-dip method for production of transgenic rice variety RD41 were explored. The simple and effective inoculation medium was composed of Murashige and Skoog(MS) medium, 5% sucrose, 44 nmol/L benzylaminopurine, and 0.075% surfactant Tween-20 with pH 5.7. The transformation efficiencies of Agrobacterium tumefaciens strains AGL1 and EHA105 were compared with the Agrobacterium density at OD_(600) = 0.8–1.0 and the co-cultivation at 25 ℃ for 48 h. A. tumefaciens strain EHA105 gave slightly higher transformation efficiency than AGL1, with statistically non-significant difference. The floral-drop transformation using the optimal floral-dip conditions showed higher transformation efficiency than the floral-dip method, but the dropped flowers turned brown and died within 2 d. Production of transgenic rice variety RD41 by the floral-dip method was achieved using A. tumefaciens strain EHA105 with the optimal conditions. Screening for the gus A gene by PCR using the gus A specific primers in the T_0 lines, there were 4 transgenic lines from 286 T_0 lines(1.4% transformation efficiency). However, histochemical glucuronidase(GUS) assay demonstrated that only three of four transgenic lines exhibited gus A expression. These results indicated that floral-dip transformation is a potential tool for production of the transgenic rice, which can be used for molecular breeding via genetic engineering in the future.

Effect of Phytosulfokine-α on Agrobacterium-Mediated Transformation in Rice

Phytosulfokine- α （PSK- α ）, a biologically active peptide acting as a growth factor, plays a key role in cellular differentiation and proliferation. To test if PSK- α has some influence on agrobacterium-mediated transformation in rice, PSK-α at a series of concentrations was added into co-culture medium respectively. The results showed that PSK- α indeed affected the recovery of resistant calli and the transformation frequency of rice varieties Taipei 309 and Lijiangxintuanheigu, PSK- α at the concentration of 10 nmol/L could increase induction of resistant callus and efficiency of transformation, with a 11% and 4.9% top increase, respectively than the control. However, PSK- αat 200 nmol/L could inhibit the induction of the resistant calli. Further more, the effect of PSK-α on agrobacterium-mediated transformation is related with the concentration of 2, 4-D in selection medium. Higher induction rate of resistant calli was obtained from tissues treated with PSK- α plus 2 mg/L 2, 4-D.

Agrobacterium-Mediated Transformation of Embryogenic Calli of Anliucheng and Regeneration of Plants Containing the Chimaeric Ribonuclease Gene

Anliucheng (Citrus sinensis Osbeck), a very seedy and widely spread acidless sweet orange cul-tivar in south of China, was transformed by the strain of Agrobacterium Tumefaciens EHA105 carrying pTA29-barnase gene, which will induce pollen sterility in transgenic plants. The embryogenic calli of Anliucheng were co-cultivated with Agrobacterium tumefaciens for 3 days, and then transferred to selective medium containing 50 mg I/1 basta (a kind of herbicide) for 5 weeks. The resistant calli were recovered and regenerated 118 embryoids. A total of 13 entire plants were obtained after micro-grafted on trifoliate orange. These regenerated plants were verified by PCR amplification and confirmed by PCR-Southern blotting analysis.

Efficient Regeneration and Agrobacterium-mediated Transformation of Brassica napus Cultivar Qingza No.5

Using the hypocotyl and cotyledon explants of Brassica napus L. cuhivar Qingza No. 5 as receptors, hormone combinations in bud differentiation medi- um, bud growth medium and rooting medium were optimized to establish an efficient plantlet regeneration system of B. napus cuhivar Qingza No. 5. The results showed that the highest differentiation efficiency of hypocotyls of B. napus cuhivar Qingza No. 5 reached about 90%, which was three times that of cotyledons. The appropriate differentiation medium was MSB ＋ 5 mg/L thidiazuron （TDZ） ＋7.5 mg/L AgNO3 ＋ 0.1 mg/L NAA ＋ 2 mg/L proline （L-pro） ＋ 250 mg/L casein acid hydrolysate （CH） ＋ 3% sucrose; the appropriate growth medium was 1/2 MSB ＋ 1 mg/L IBA ＋ 2 mg/L L-pro ＋ 250 mg/L CH ＋ 1.5% sucrose; the ap- propriate rooting medium was 1/2 MSB ＋ 0.2 mg/L IAA ＋ 1.5% sucrose. On this basis, a binary expression vector harboring insect resistance gene B12 was constructed and introduced into B. napus hypocotyls by Agrobacterium-mediated transformation. Positive plants were screened using hygromycin and carbenicillin. Transgenic plants were verified by PCR and GUS histochemical staining. The results showed that insect resistance gene B12 was successfully integrated into the nu- clear genome of B. napus plants and could be expressed normally. Leaves of transgenic plants with high expression levels were collected for indoor inoculation test with Plutella xylotella larvae to evaluate insect resistance of transgenic plants.

Screening Chinese soybean genotypes for Agrobacterium-mediated genetic transformation suitability

The Agrobacterium-mediated transformation system is the most commonly used method in soybean transformation.Screening of soybean genotypes favorable for Agrobacterium-infection and tissue regeneration is the most important step to establish an efficient genetic transformation system.In this study,twenty soybean genotypes that originated from different soybean production regions in China were screened for transient infection,regeneration capacity,and stable transgenic efficiency.Three genotypes,Yuechun 04-5,Yuechun 03-3,and Tianlong 1,showed comparable stable transgenic efficiencies with that of the previously reported American genotypes Williams 82 and Jack in our experimental system.For the Tianlong 1,the average stable transformation efficiency is 4.59%,higher than that of control genotypes(Jack and Williams 82),which is enough for further genomic research and genetic engineering.While polymerase chain reaction(PCR),LibertyLink strips,and β-glucuronidase(GUS) staining assays were used to detect the insertion and expression of the transgene,leaves painted with 135 mg/L Basta could efficiently identify the transformants.

Agrobacterium-mediated delivery of CRISPR/Cas reagents for genome editing in plants enters an era of ternary vector systems

Lack of appropriate methods for delivery of genome-editing reagents is a major barrier to CRISPR/Cas-mediated genome editing in plants.Agrobacterium-mediated genetic transformation(AMGT)is the preferred method of CRISPR/Cas reagent delivery,and researchers have recently made great improvements to this process.In this article,we review the development of AMGT and AMGT-based delivery of CRISPR/Cas reagents.We give an overview of the development of AMGT vectors including binary vector,superbinary vector,dual binary vector,and ternary vector systems.We also review the progress in Agrobacterium genomics and Agrobacterium genetic engineering for optimal strains.We focus in particular on the ternary vector system and the resources we developed.In summary,it is our opinion that Agrobacterium-mediated CRISPR/Cas genome editing in plants is entering an era of ternary vector systems,which are often integrated with morphogenic regulators.The new vectors described in this article are available from Addgene and/or MolecularCloud for sharing with academic investigators for noncommercial research.

A Novel Approach to Functional Analysis of the Ribulose Bisphosphate Carboxylase Small Subunit Gene by Agrobacterium-Mediated Gene Silencing

A novel approach to virus-induced post-transcriptional gene silencing for studying the function of the ribulose bisphosphate carboxylase small subunit （rbcS） gene was established and optimized using potato virus X vector and Nicotiana benthamiana as experimental material. The analysis of silencing phenomena, transcriptional level, protein expression, and pigment measurement showed that the expression of the rbcS endogenous gene was inactivated by the expression of a 500-bp homologous cDNA fragment carried in the virus vector.

Study on the Integration of T-DNA into Lilium longiflorum

[ Objective] The aim of this study is to obtain transgenic Lilium longiflorum Thumb. [ Method] A two-step method of explant and the T-DNA integration technique were employed to transform Lilium longiflorum via Agrobacterium mediated method. [ Result] The best infection effect appeared under the OD600 value of Agrobacterium within 0.6 -0.8, the addition of 250 mg/L AS could increase the transformation efficiency. The optimal concentration of G418 for screening is 50 mg/L. Some putative transgenic plants of Lilium longiflorum with resistance to G418 showed positive in PCR, preliminarily proving that T-DNA gene had integrated into the genome of lily. [ Conclusion] The study may lay a foundation for breeding excellent lily varieties through TDNA integration technique.

Enhancing rice resistance to fungal pathogens by transformation with cell wall degrading enzyme genes from Trichoderma atroviride

Three genes encoding for fungal cell wall degrading enzymes (CWDEs), ech42, nag70 and gluc78 from the biocontrol fungus Trichoderma atroviride were inserted into the binary vector pCAMBIA1305.2 singly and in all possible combinations and transformed to rice plants. More than 1800 independently regenerated plantlets in seven different populations (for each of the three genes and each of the four gene combinations) were obtained. The ech42 gene encoding for an endochitinase increased resistance to sheath blight caused by Rhizoctonia solani, while the exochitinase-encoding gene, nag70, had lesser effect. The expression level of endochitinase but exochitinase was correlated with disease resistance. Nevertheless, exochitinase enhanced the effect of endochitinase on disease resistance when the two genes co-expressed in transgenics. Resistance to Magnaporthe grisea was found in all kinds of regenerated plants including that with single gluc78. A few lines expressing either ech42 or nag70 gene were immune to the disease. Transgenic plants are being tested to further evaluate disease resistance at field level. This is the first report of multiple of expression of genes encoding CWDEs from Trichoderma atroviride that result in resistance to blast and sheath blight in rice.

Development of glyphosate-tolerant transgenic cotton plants harboring the G2-aroA gene

Given that glyphosate weed control is an effective strategy to reduce costs and improve economic outcomes of agricultural production in China,the development of glyphosate-resistant cotton holds great promise.Using an Agrobacterium-mediated transformation method,a new G2-aroA gene that encodes 5-enolpyruvylshikimate-3-phosphate synthase（EPSPS）was transformed into cotton cultivar K312.The transgenic cotton plants were regenerated from a callus tissue culture via kanamycin selection.Ten regenerated cotton plants were obtained and allowed to flower normally to produce fruit.The results from polymerase chain reaction（PCR）and Southern and Western blot analyses indicated that the target gene was integrated into the cotton chromosome and was expressed effectively at the protein level.The glyphosate tolerance analysis showed that the transgenic cotton had a high resistance to glyphosate.Further,even cotton treated with 45.0 mmol L^–1 of glyphosate was able to slowly grow,bloom and seed.The transgenic cotton may be used for cotton breeding research of glyphosate-tolerant cotton.

Constructing the barley model for genetic transformation in Triticeae

Barley（Hordeum vulgare L.） is one of the oldest domesticated crops, showing dramatic adaptation to various climate and environmental conditions. As a major cereal crop, barley ranks the 4th after wheat, maize and rice in terms of planting area and production all over the world. Due to its diploid nature, the cultivated barley is considered as an ideal model to study the polyploid wheat and other Triticeae species. Here, we reviewed the development, optimization, and application of transgenic approaches in barley. The most efficient and robust genetic transformation has been built on the Agrobacterium-mediated transfer in conjunction with the immature embryo-based regeneration. We then discussed future considerations of using more practical technologies in barley transformation, such as the T-DNA/transposon tagging and the genome editing. As a cereal crop amenable to genetic transformation, barley will serve as the most valuable carrier for global functional genomics in Triticeae and is becoming the most practical model for generating value-added products.

Infection of Early and Young Callus Tissues of Indica Rice BPT5204 Enhances Regeneration and Transformation Efficiency

A rapid and reproducible method to develop transgenic plants with enhanced transformation efficiency using Agrobacterium has been developed for the elite indica rice variety BPT 5204. Different rice calli aged from 3 to 30 d were co-cultivated with pre-incubated Agrobacterium suspension culture （LBA4404： pSB1, pCAMBIA1301） and incubated in dark for 3 d. Based on the transient GUS gene expression analysis, 6-day-old young calli showed high transformation frequency followed by 21-day-old ones. Thus, both 6-and 21-day-old calli were used for assessing the stable transformation efficiency. It was observed that the 6-day-old young transformed calli showed about 2-fold higher regeneration frequency when compared with 21-day-old calli. The transformation efficiency was enhanced for young calli to 5.9% compared with 0.8% of the 21-day-old calli. Molecular and genetic analysis of transgenic plants （To） revealed the presence of 1-2 copies of T-DNA integration in transformants and it follows Mendalian ratio in T1 transgenic plants. From the present study, it was concluded that the development of transgenic rice plants in less duration with high regeneration and transformation efficiency was achieved in BPT 5204 by using 6-day-old young calli as explants.

Response of Explants of Calli Rice (<i>Oryza sativa</i>L.) Japonica cv. “Ilmi” to Gene Transformation Using <i>Agrobacterium tumefaciens</i>-Mediated

The AtBI-1 gene encoding the Arabidopsis thaliana Bax inhibitor was introduced into Japonica cultivars of rice (“Ilmi”) by Agrobacterium-mediated transformation, and a large number of transgenic plants were produced. The neomycin phosphotransferase II (NPTII) gene was used as a selectable marker. The activity of neomycin phosphotransferase could be successfully detected in transgenic rice calluses. Introduction of the AtBI-1 gene was also confirmed by PCR using AtBI-1 specific oligonucleotide primers in regenerated plants. Stable integration and expression of the AtbI-1 gene in plants were confirmed by GFP analysis.

Optimization of Agrobacterium tumefaciens-Mediated Genetic Transformation of Maize

Immature embryos of inbred maize(Zea mays)lines(H8183,H8184,and H8185)were used for Agrobacterium infection.We used theβ-glucuronidase gene(GUS)as the target gene and the glufosinate resistance gene(bar)as the selection marker.We conducted research on several aspects,such as different genotypes,coculture conditions,screening agent concentrations,and concentrations of indole-3-butytric acid(IBA),6-benzylaminopurine(6-BA),and ascorbic acid(Vc)in the differentiation medium.We optimized the genetic transformation system,and the obtained results indicated that among the three lines studied,the induction rate of H8185 was the highest at 93.2%,followed by H8184,with H8183 having the lowest induction rate(80.1%).The best coculture method was that using the N6 coculture medium layered with a sterile filter paper.Using orthogonal analysis,we found that the optimal combination of the three factors in the differentiation medium was A_(3)(1 mg mL^(−1)IBA),B_(3)C_(1)(1.6 mg mL^(−1)6-BA),and D_(3)(1.5 mg mL^(−1)Vc).Through GUS staining analysis,Bar test-strip analysis,and polymerase chain reaction,five transgenic plants were finally obtained.This study established the optimal conditions for genetic transformation in maize.