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Construction and optimization of a genetic transformation system for efficient expression of human insulin-GFP fusion gene in flax

The human insulin gene modified with a C-peptide was synthesized according to the plant-preferred codon, and a fusion gene expression vector of insulin combined with green fluorescent protein (GFP) was constructed. The optimization of the flax callus culturing was undertaken, and a more efficient Ag...

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Published in:	Bioresources and bioprocessing 2024-08, Vol.11 (1), p.83-13, Article 83
Main Authors:	Zhao, Wei, Zhang, Rui, Zhou, Luyang, Zhang, Zhongxia, Du, Fei, Wu, Ruoyu, Kong, Jing, An, Shengjun
Format:	Article
Language:	English
Subjects:	Addition polymerization Agrobacterium-induced infection Antibiotics Biochemical Engineering Callus Callus culture Chemistry Chemistry and Materials Science Concentration gradient Culture Environmental Engineering/Biotechnology Flax Flax callus Fluorescence Fusion protein Gene expression Gene fusion Genetic transformation Green fluorescent protein Hygromycin Hypocotyls Industrial and Production Engineering Insulin Insulin-GFP Optimization Polymerase chain reaction Proteins Protoplasts Screening Verification Western blotting
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creator	Zhao, Wei Zhang, Rui Zhou, Luyang Zhang, Zhongxia Du, Fei Wu, Ruoyu Kong, Jing An, Shengjun
description	The human insulin gene modified with a C-peptide was synthesized according to the plant-preferred codon, and a fusion gene expression vector of insulin combined with green fluorescent protein (GFP) was constructed. The optimization of the flax callus culturing was undertaken, and a more efficient Agrobacterium -mediated genetic transformation of the flax hypocotyls was achieved. The critical concentration values of hygromycin on the flax hypocotyl development, as well as on its differentiated callus, were explored by the method of antibiotic gradient addition, and the application of antibiotic screening for the verification of positive calluses was assessed. The fusion gene of insulin and GFP was successfully inserted into the flax genome and expressed, as confirmed through polymerase chain reaction and Western blotting. In conclusion, we have established a flax callus culture system suitable for insulin expression. By optimizing the conditions of the flax callus induction, transformation, screening, and verification of a transgenic callus, we have provided an effective way to obtain insulin. Moreover, the herein-employed flax callus culture system could provide a feasible, cheap, and environmentally friendly platform for producing bioactive proteins. Graphical Abstract
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The optimization of the flax callus culturing was undertaken, and a more efficient Agrobacterium -mediated genetic transformation of the flax hypocotyls was achieved. The critical concentration values of hygromycin on the flax hypocotyl development, as well as on its differentiated callus, were explored by the method of antibiotic gradient addition, and the application of antibiotic screening for the verification of positive calluses was assessed. The fusion gene of insulin and GFP was successfully inserted into the flax genome and expressed, as confirmed through polymerase chain reaction and Western blotting. In conclusion, we have established a flax callus culture system suitable for insulin expression. By optimizing the conditions of the flax callus induction, transformation, screening, and verification of a transgenic callus, we have provided an effective way to obtain insulin. Moreover, the herein-employed flax callus culture system could provide a feasible, cheap, and environmentally friendly platform for producing bioactive proteins. 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Bioprocess</addtitle><addtitle>Bioresour Bioprocess</addtitle><description>The human insulin gene modified with a C-peptide was synthesized according to the plant-preferred codon, and a fusion gene expression vector of insulin combined with green fluorescent protein (GFP) was constructed. The optimization of the flax callus culturing was undertaken, and a more efficient Agrobacterium -mediated genetic transformation of the flax hypocotyls was achieved. The critical concentration values of hygromycin on the flax hypocotyl development, as well as on its differentiated callus, were explored by the method of antibiotic gradient addition, and the application of antibiotic screening for the verification of positive calluses was assessed. The fusion gene of insulin and GFP was successfully inserted into the flax genome and expressed, as confirmed through polymerase chain reaction and Western blotting. 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subjects	Addition polymerization Agrobacterium-induced infection Antibiotics Biochemical Engineering Callus Callus culture Chemistry Chemistry and Materials Science Concentration gradient Culture Environmental Engineering/Biotechnology Flax Flax callus Fluorescence Fusion protein Gene expression Gene fusion Genetic transformation Green fluorescent protein Hygromycin Hypocotyls Industrial and Production Engineering Insulin Insulin-GFP Optimization Polymerase chain reaction Proteins Protoplasts Screening Verification Western blotting
title	Construction and optimization of a genetic transformation system for efficient expression of human insulin-GFP fusion gene in flax
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