Your search keyword '"Gene stacking"' showing total 171 results

1. Chapter 21 - Metabolic genes: a toolbox for crop improvement by mitigating the effects of metal and waterlogging stress

Author

Sonia, Kumari, Nisha, Manne, Hemanthkumar, Kodidhala, Vaishnavi, Sushil, Avtar, Ram, Jattan, Minakshi, Rani, Babita, Peddinti, Gurumurthy, and Rati, Sunayana

Published

2025

2. The B Chromosome: An Optimum Platform For Maize Minichromosome Engineering.

Author

Liu, Xin, Chen, Ziqian, and Shi, Xiaowen

Subjects

*ARTIFICIAL chromosomes, *PLANT breeding, *EXTREME weather, *DIETARY patterns, *PLANT chromosomes

Abstract

AbstractThe synthesis of maize artificial chromosomes/minichromosomes holds great promise in preparing worldwide maize production to address the challenges of frequent extreme weather events, population growth, and evolving dietary patterns. Using artificial chromosomes can mitigate the drawbacks associated with conventional transgenic approaches, such as random integration, linkage drag, and unpredictable expression levels. While the application of de novo assembly in constructing plant artificial chromosomes has been constrained by the complexity of the epigenetic nature of plant centromeres, a promising strategy involves a top-down approach through truncating a nonessential supernumerary chromosome, such as the maize B chromosome. This review summarizes the genetic and epigenetic characteristics of the B chromosome and highlights the advantages of engineering it into a minichromosome platform (miniB). We also review the progress, potential applications, and prospects of miniB chromosome engineering. Taken together, the development of the engineered miniB platform shows great potential for breeding high-yield, high-quality, and multiple stress-tolerant maize varieties. [ABSTRACT FROM AUTHOR]

Published

2024

3. Maize yields have stagnated in sub‐Sahara Africa: a possible transgenic solution to weed, pathogen and insect constraints.

Author

Gressel, Jonathan, Mbogo, Peter, Kanampiu, Fred, and Christou, Paul

Subjects

PEST control, INSECT pathogens, INSECT genes, WITCHWEEDS, ENGINEERS, WEEDS

Abstract

Despite major breeding efforts by various national and international agencies, yields for the ~40 million hectares of maize, the major food crop in sub‐Saharan Africa, have stagnated at <2 tons/ha/year for the past decade, one‐third the global average. Breeders have succeeded in breeding increased yield with a modicum of tolerance to some single‐weed or pathogen stresses. There has been minimal adoption of these varieties because introgressing polygenic yield and tolerance traits into locally adapted material is very challenging. Multiple traits to deal with pests (weeds, pathogens, and insects) are needed for farmer acceptance, because African fields typically encounter multiple pest constraints. Also, maize has no inherent resistance to some of these pest constraints, rendering them intractable to traditional breeding. The proposed solution is to simultaneously engineer multiple traits into one genetic locus. The dominantly inherited multi‐pest resistance trait single locus can be bred simply into locally adapted, elite high‐yielding material, and would be valuable for farmers, vastly increasing maize yields, and allowing for more than regional maize sufficiency. © 2024 The Author(s). Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

4. Combined Use of Unidirectional Site-Specific Recombination System and CRISPR-Cas Systems for Plant Genome Editing

Author

Yau, Yuan-Yeu, Easterling, Mona, Neal Stewart, C., Jr, Kumar, Ashwani, editor, Arora, Sudipti, editor, Ogita, Shinjiro, editor, Yau, Yuan-Yeu, editor, and Mukherjee, Krishnendu, editor

Published

2024

5. Minimizing IP issues associated with gene constructs encoding the Bt toxin - a case study

Author

Md Mahmudul Hassan, Francis Tenazas, Adam Williams, Jing-wen Chiu, Charles Robin, Derek A. Russell, and John F. Golz

Subjects

Bacillus thuringiensis, Insecticidal gene, Bt toxin, Gene stacking, Diamondback moth, Cry1B, Biotechnology, TP248.13-248.65

Abstract

Abstract Background As part of a publicly funded initiative to develop genetically engineered Brassicas (cabbage, cauliflower, and canola) expressing Bacillus thuringiensis Crystal (Cry)-encoded insecticidal (Bt) toxin for Indian and Australian farmers, we designed several constructs that drive high-level expression of modified Cry1B and Cry1C genes (referred to as Cry1B M and Cry1C M ; with M indicating modified). The two main motivations for modifying the DNA sequences of these genes were to minimise any licensing cost associated with the commercial cultivation of transgenic crop plants expressing Cry M genes, and to remove or alter sequences that might adversely affect their activity in plants. Results To assess the insecticidal efficacy of the Cry1B M /Cry1C M genes, constructs were introduced into the model Brassica Arabidopsis thaliana in which Cry1B M /Cry1C M expression was directed from either single (S4/S7) or double (S4S4/S7S7) subterranean clover stunt virus (SCSV) promoters. The resulting transgenic plants displayed a high-level of Cry1B M /Cry1C M expression. Protein accumulation for Cry1C M ranged from 5.18 to 176.88 µg Cry1CM/g dry weight of leaves. Contrary to previous work on stunt promoters, we found no correlation between the use of either single or double stunt promoters and the expression levels of Cry1B M /Cry1C M genes, with a similar range of Cry1C M transcript abundance and protein content observed from both constructs. First instar Diamondback moth (Plutella xylostella) larvae fed on transgenic Arabidopsis leaves expressing the Cry1B M /Cry1C M genes showed 100% mortality, with a mean leaf damage score on a scale of zero to five of 0.125 for transgenic leaves and 4.2 for wild-type leaves. Conclusions Our work indicates that the modified Cry1 genes are suitable for the development of insect resistant GM crops. Except for the PAT gene in the USA, our assessment of the intellectual property landscape of components presents within the constructs described here suggest that they can be used without the need for further licensing. This has the capacity to significantly reduce the cost of developing and using these Cry1 M genes in GM crop plants in the future.

Published

2024

6. A novel nucleic acid linker for multi‐gene expression enhances plant and animal synthetic biology.

Author

Ma, Xuhui, Yue, Qun, Miao, Liqing, Li, Suzhen, Tian, Jian, Si, Wei, Zhang, Liwen, Yang, Wenzhu, Zhou, Xiaojin, Zhang, Junmin, Chen, Rumei, Xu, Yuquan, and Liu, Xiaoqing

Subjects

*GENE expression, *NUCLEIC acids, *SYNTHETIC biology, *GENETIC translation, *T cells, *ASTAXANTHIN

Abstract

SUMMARY: The production of compact vectors for gene stacking is hindered by a lack of effective linkers. Here, we report that a 26‐nt nucleic acid linker, NAL1, from the fungus Glarea lozoyensis and its truncated derivatives could connect two genes as a bicistron, enabling independent translation in a maize protoplast transient expression system and human 293 T cells. The optimized 9‐nt NAL10 linker was then used to connect four genes driven by a bidirectional promoter; this combination was successfully used to reconstruct the astaxanthin biosynthesis pathway in transgenic maize. The short and efficient nucleic acid linker NAL10 can be widely used in multi‐gene expression and synthetic biology in animals and plants. [ABSTRACT FROM AUTHOR]

Published

2024

7. Minimizing IP issues associated with gene constructs encoding the Bt toxin - a case study.

Author

Hassan, Md Mahmudul, Tenazas, Francis, Williams, Adam, Chiu, Jing-wen, Robin, Charles, Russell, Derek A., and Golz, John F.

Subjects

DIAMONDBACK moth, CROPS, BACILLUS thuringiensis, COLE crops, INSECT development, CANOLA, TOXINS, PLASMODIOPHORA brassicae

Abstract

Background: As part of a publicly funded initiative to develop genetically engineered Brassicas (cabbage, cauliflower, and canola) expressing Bacillus thuringiensis Crystal (Cry)-encoded insecticidal (Bt) toxin for Indian and Australian farmers, we designed several constructs that drive high-level expression of modified Cry1B and Cry1C genes (referred to as Cry1BM and Cry1CM; with M indicating modified). The two main motivations for modifying the DNA sequences of these genes were to minimise any licensing cost associated with the commercial cultivation of transgenic crop plants expressing CryM genes, and to remove or alter sequences that might adversely affect their activity in plants. Results: To assess the insecticidal efficacy of the Cry1BM/Cry1CM genes, constructs were introduced into the model Brassica Arabidopsis thaliana in which Cry1BM/Cry1CM expression was directed from either single (S4/S7) or double (S4S4/S7S7) subterranean clover stunt virus (SCSV) promoters. The resulting transgenic plants displayed a high-level of Cry1BM/Cry1CM expression. Protein accumulation for Cry1CM ranged from 5.18 to 176.88 µg Cry1CM/g dry weight of leaves. Contrary to previous work on stunt promoters, we found no correlation between the use of either single or double stunt promoters and the expression levels of Cry1BM/Cry1CM genes, with a similar range of Cry1CM transcript abundance and protein content observed from both constructs. First instar Diamondback moth (Plutella xylostella) larvae fed on transgenic Arabidopsis leaves expressing the Cry1BM/Cry1CM genes showed 100% mortality, with a mean leaf damage score on a scale of zero to five of 0.125 for transgenic leaves and 4.2 for wild-type leaves. Conclusions: Our work indicates that the modified Cry1 genes are suitable for the development of insect resistant GM crops. Except for the PAT gene in the USA, our assessment of the intellectual property landscape of components presents within the constructs described here suggest that they can be used without the need for further licensing. This has the capacity to significantly reduce the cost of developing and using these Cry1M genes in GM crop plants in the future. [ABSTRACT FROM AUTHOR]

Published

2024

8. Metabolic Pathway Engineering Improves Dendrobine Production in Dendrobium catenatum.

Author

Zhao, Meili, Zhao, Yanchang, Yang, Zhenyu, Ming, Feng, Li, Jian, Kong, Demin, Wang, Yu, Chen, Peng, Wang, Meina, and Wang, Zhicai

Subjects

*BIOSYNTHESIS, *DENDROBIUM, *QUALITY control standards, *GENE expression, *GENETIC engineering, *GENE regulatory networks, *CYTOCHROME P-450

Abstract

The sesquiterpene alkaloid dendrobine, widely recognized as the main active compound and a quality control standard of medicinal orchids in the Chinese Pharmacopoeia, demonstrates diverse biological functions. In this study, we engineered Dendrobium catenatum as a chassis plant for the production of dendrobine through the screening and pyramiding of key biosynthesis genes. Initially, previously predicted upstream key genes in the methyl-D-erythritol 4-phosphate (MEP) pathway for dendrobine synthesis, including 4-(Cytidine 5′-Diphospho)-2-C-Methyl-d-Erythritol Kinase (CMK), 1-Deoxy-d-Xylulose 5-Phosphate Reductoisomerase (DXR), 2-C-Methyl-d-Erythritol 4-Phosphate Cytidylyltransferase (MCT), and Strictosidine Synthase 1 (STR1), and a few downstream post-modification genes, including Cytochrome P450 94C1 (CYP94C1), Branched-Chain-Amino-Acid Aminotransferase 2 (BCAT2), and Methyltransferase-like Protein 23 (METTL23), were chosen due to their deduced roles in enhancing dendrobine production. The seven genes (SG) were then stacked and transiently expressed in the leaves of D. catenatum, resulting in a dendrobine yield that was two-fold higher compared to that of the empty vector control (EV). Further, RNA-seq analysis identified Copper Methylamine Oxidase (CMEAO) as a strong candidate with predicted functions in the post-modification processes of alkaloid biosynthesis. Overexpression of CMEAO increased dendrobine content by two-fold. Additionally, co-expression analysis of the differentially expressed genes (DEGs) by weighted gene co-expression network analysis (WGCNA) retrieved one regulatory transcription factor gene MYB61. Overexpression of MYB61 increased dendrobine levels by more than two-fold in D. catenatum. In short, this work provides an efficient strategy and prospective candidates for the genetic engineering of D. catenatum to produce dendrobine, thereby improving its medicinal value. [ABSTRACT FROM AUTHOR]

Published

2024

9. Enhancing Nutritional Quality of Crops Through Genetic Engineering

Author

Sahoo, Debee Prasad, Panda, Chetan, Barbosa-Cánovas, Gustavo V., Series Editor, Aguilera, José Miguel, Advisory Editor, Candoğan, Kezban, Advisory Editor, Hartel, Richard W., Advisory Editor, Ibarz, Albert, Advisory Editor, Peleg, Micha, Advisory Editor, Rahman, Shafiur, Advisory Editor, Rao, M. Anandha, Advisory Editor, Roos, Yrjö, Advisory Editor, Welti-Chanes, Jorge, Advisory Editor, Hebbar, H. Umesh, editor, Sharma, Richa, editor, Chaurasiya, Ram Saran, editor, Ranjan, Shivendu, editor, and Raghavarao, K.S.M.S., editor

Published

2023

10. In-planta production of the biodegradable polyester precursor 2-pyrone-4,6-dicarboxylic acid (PDC): Stacking reduced biomass recalcitrance with value-added co-product

Author

Lin, Chien-Yuan, Vuu, Khanh M, Amer, Bashar, Shih, Patrick M, Baidoo, Edward EK, Scheller, Henrik V, and Eudes, Aymerick

Subjects

Biological Sciences, Industrial Biotechnology, Affordable and Clean Energy, Arabidopsis, Biomass, Lignin, Polyesters, Pyrones, Gene stacking, Shikimate pathway, Co-product, 2-Pyrone-4, 6-dicarboxylic acid, 2-Pyrone-4, 6-dicarboxylic acid, Biotechnology, Biochemistry and cell biology, Industrial biotechnology

Abstract

2-Pyrone-4,6-dicarboxylic acid (PDC), a chemically stable intermediate that naturally occurs during microbial degradation of lignin by bacteria, represents a promising building block for diverse biomaterials and polyesters such as biodegradable plastics. The lack of a chemical synthesis method has hindered large-scale utilization of PDC and metabolic engineering approaches for its biosynthesis have recently emerged. In this study, we demonstrate a strategy for the production of PDC via manipulation of the shikimate pathway using plants as green factories. In tobacco leaves, we first showed that transient expression of bacterial feedback-resistant 3-deoxy-D-arabinoheptulosonate 7-phosphate synthase (AroG) and 3-dehydroshikimate dehydratase (QsuB) produced high titers of protocatechuate (PCA), which was in turn efficiently converted into PDC upon co-expression of PCA 4,5-dioxygenase (PmdAB) and 4-carboxy-2-hydroxymuconate-6-semialdehyde dehydrogenase (PmdC) derived from Comamonas testosteroni. We validated that stable expression of AroG in Arabidopsis in a genetic background containing the QsuB gene enhanced PCA content in plant biomass, presumably via an increase of the carbon flux through the shikimate pathway. Further, introducing AroG and the PDC biosynthetic genes (PmdA, PmdB, and PmdC) into the Arabidopsis QsuB background, or introducing the five genes (AroG, QsuB, PmdA, PmdB, and PmdC) stacked on a single construct into wild-type plants, resulted in PDC titers of ~1% and ~3% dry weight in plant biomass, respectively. Consistent with previous studies of plants expressing QsuB, all PDC producing lines showed strong reduction in lignin content in stems. This low lignin trait was accompanied with improvements of biomass saccharification efficiency due to reduced cell wall recalcitrance to enzymatic degradation. Importantly, most transgenic lines showed no reduction in biomass yields. Therefore, we conclude that engineering plants with the proposed de-novo PDC pathway provides an avenue to enrich biomass with a value-added co-product while simultaneously improving biomass quality for the supply of fermentable sugars. Implementing this strategy into bioenergy crops has the potential to support existing microbial fermentation approaches that exploit lignocellulosic biomass feedstocks for PDC production.

Published

2021

11. Targeted DNA insertion in plants

Author

Dong, Oliver Xiaoou and Ronald, Pamela C

Subjects

Biological Sciences, Genetics, Human Genome, Biotechnology, Agrobacterium, Crops, Agricultural, DNA, Plant, Gene Transfer Techniques, Genome, Plant, Plants, Genetically Modified, Transformation, Genetic, plant genetic engineering, plant genome editing, plant genetics, targeted gene insertion, gene stacking

Abstract

Conventional methods of DNA sequence insertion into plants, using Agrobacterium-mediated transformation or microprojectile bombardment, result in the integration of the DNA at random sites in the genome. These plants may exhibit altered agronomic traits as a consequence of disruption or silencing of genes that serve a critical function. Also, genes of interest inserted at random sites are often not expressed at the desired level. For these reasons, targeted DNA insertion at suitable genomic sites in plants is a desirable alternative. In this paper we review approaches of targeted DNA insertion in plant genomes, discuss current technical challenges, and describe promising applications of targeted DNA insertion for crop genetic improvement.

Published

2021

12. Improving rice blast resistance by stacking of two broad spectrum resistance gene Pi9 and Pi54 in cultivar CO 51 through marker assisted selection

Author

Samuthirapandi, S., Thiyagarajan, T., Viswabharathy, S., Bharathi, A., Rohit, K., Ranjani, R. Veera, Sudha, M., Krishnan, C. Gopala, Kalaimagal, T., Raveendran, M., and Manonmani, S.

Published

2023

13. Nannochloropsis artificial chromosomes (NannoACs) loom on the horizon.

Author

Guo, Li and Yang, Guanpin

Subjects

*ARTIFICIAL chromosomes, *MICROALGAE, *GENETIC transformation, *TRANSGENES, *EPISOMES

Abstract

Species in genus Nannochloropsis, especially N. oceanica and N. gaditana, have been evolving as the model microalgae for both application and theory studies. The position effect of genome integration, the carrying capability limitation of integrative vectors and the instability of non-integrative vectors have hindered Nannochloropsis genetic modification with concatenate genes and extremely long DNA fragments. The molecular tools including genetic transformation, homologous recombination, gene edition, gene stacking and episome vectors for transient gene expression and diverse reporters and selection markers have been rapidly developing in Nannochloropsis species. The construction of animal and plant artificial chromosomes with "top down" strategy has set fine examples for the construction of Nannochloropsis artificial chromosomes (NannoACs). It seems that the methods and materials to set the foundation for constructing NannoACs are at hands. In this review, we outlined the current status of transgenes in Nannochloropsis species, summarized the limitations of both integrative and non-integrative vectors, and proposed a tentative approach to construct NannoACs by doubling and stabilizing the genome first, and then truncating the natural chromosomes. NannoACs once constructed will facilitate transferring the desired traits and concatenate genes into Nannochloropsis genetic backgrounds, thus contributing towards its genetic improvement and synthetic biological studies. [ABSTRACT FROM AUTHOR]

Published

2023

14. Pyramiding of transcription factor, PgHSF4, and stress-responsive genes of p68, Pg47, and PsAKR1 impart multiple abiotic stress tolerance in rice (Oryza sativa L.).

Author

Sheela, H. S., Vennapusa, Amaranatha R., Melmaiee, Kalpalatha, Prasad, T. G., and Reddy, Chandrashekar P.

Abstract

Abiotic stresses such as drought, salinity, and heat stress significantly affect rice crop growth and production. Under uncertain climatic conditions, the concurrent multiple abiotic stresses at different stages of rice production became a major challenge for agriculture. Hence, improving rice’s multiple abiotic stress tolerance is essential to overcome unprecedented challenges under adverse environmental conditions. A significant challenge for rice breeding programs in improving abiotic stress tolerance involves multiple traits and their complexity. Multiple traits must be targeted to improve multiple stress tolerance in rice and uncover the mechanisms. With this hypothesis, in the present study gene stacking approach is used to integrate multiple traits involved in stress tolerance. Themultigene transgenics co-expressing Pennisetum glaucum 47 (Pg47), Pea 68 (p68), Pennisetum glaucum Heat Shock Factor 4(PgHSF4), and Pseudomonas Aldo Keto Reductase 1 (PsAKR1) genes in the rice genotype (AC39020) were developed using the in-planta transformation method. The promising transgenic lines maintained higher yields under semiirrigated aerobic cultivation (moisture stress). These 15 promising transgenic rice seedlings showed improved shoot and root growth traits under salinity, accelerating aging, temperature, and oxidative stress. They showed better physiological characteristics, such as chlorophyll content, membrane stability, and lower accumulation of reactive oxygen species, under multiple abiotic stresses than wild-type. Enhanced expression of transgenes and other stress-responsive downstream genes such as HSP70, SOD, APX, SOS, PP2C, and P5CS in transgenic lines suggest the possible molecular mechanism for imparting the abiotic stress tolerance. This study proved that multiple genes stacking as a novel strategy induce several mechanisms and responsible traits to overcome multiple abiotic stresses. This multigene combination can potentially improve tolerance to multiple abiotic stress conditions and pave the way for developing climate-resilient crops. [ABSTRACT FROM AUTHOR]

Published

2023

15. Bxb1-att Site-Specific Recombination System-Mediated Autoexcision to Prevent Environmental Transgene Escape

Author

Easterling, Mona, Yau, Yuan-Yeu, Arora, Sudipti, editor, Kumar, Ashwani, editor, Ogita, Shinjiro, editor, and Yau, Yuan -Yeu, editor

Published

2022

16. Pyramiding of transcription factor, PgHSF4, and stress-responsive genes of p68, Pg47, and PsAKR1 impart multiple abiotic stress tolerance in rice (Oryza sativa L.)

Author

H. S. Sheela, Amaranatha R. Vennapusa, Kalpalatha Melmaiee, T. G. Prasad, and Chandrashekar P. Reddy

Subjects

abiotic stress, multiple genes, transgenics, gene stacking, stress tolerance, trait, Plant culture, SB1-1110

Abstract

Abiotic stresses such as drought, salinity, and heat stress significantly affect rice crop growth and production. Under uncertain climatic conditions, the concurrent multiple abiotic stresses at different stages of rice production became a major challenge for agriculture. Hence, improving rice’s multiple abiotic stress tolerance is essential to overcome unprecedented challenges under adverse environmental conditions. A significant challenge for rice breeding programs in improving abiotic stress tolerance involves multiple traits and their complexity. Multiple traits must be targeted to improve multiple stress tolerance in rice and uncover the mechanisms. With this hypothesis, in the present study gene stacking approach is used to integrate multiple traits involved in stress tolerance. The multigene transgenics co-expressing Pennisetum glaucum 47 (Pg47), Pea 68 (p68), Pennisetum glaucum Heat Shock Factor 4(PgHSF4), and Pseudomonas Aldo Keto Reductase 1 (PsAKR1) genes in the rice genotype (AC39020) were developed using the in-planta transformation method. The promising transgenic lines maintained higher yields under semi-irrigated aerobic cultivation (moisture stress). These 15 promising transgenic rice seedlings showed improved shoot and root growth traits under salinity, accelerating aging, temperature, and oxidative stress. They showed better physiological characteristics, such as chlorophyll content, membrane stability, and lower accumulation of reactive oxygen species, under multiple abiotic stresses than wild-type. Enhanced expression of transgenes and other stress-responsive downstream genes such as HSP70, SOD, APX, SOS, PP2C, and P5CS in transgenic lines suggest the possible molecular mechanism for imparting the abiotic stress tolerance. This study proved that multiple genes stacking as a novel strategy induce several mechanisms and responsible traits to overcome multiple abiotic stresses. This multigene combination can potentially improve tolerance to multiple abiotic stress conditions and pave the way for developing climate-resilient crops.

Published

2023

17. Molecular Breeding for Incorporation of Submergence Tolerance and Durable Bacterial Blight Resistance into the Popular Rice Variety 'Ranidhan'.

Author

Mohapatra, Shibani, Barik, Saumya Ranjan, Dash, Prasanta K., Lenka, Devidutta, Pradhan, Kartika Chandra, Raj K. R, Reshmi, Mohanty, Shakti Prakash, Mohanty, Mihir Ranjan, Sahoo, Ambika, Jena, Binod Kumar, Panda, Alok Kumar, Panigrahi, Debabrata, Dash, Sushanta Kumar, Meher, Jitendriya, Sahoo, Chitta Ranjan, Mukherjee, Arup Kumar, Das, Lipi, Behera, Lambodar, and Pradhan, Sharat Kumar

Subjects

*DRUG resistance in bacteria, *RICE, *GENE targeting, *BIOLOGICAL assay, *RICE breeding, *PHENOTYPES

Abstract

Ranidhan is a popular late-maturing rice variety of Odisha state, India. The farmers of the state suffer heavy loss in years with flash floods as the variety is sensitive to submergence. Bacterial blight (BB) disease is a major yield-limiting factor, and the variety is susceptible to the disease. BB resistance genes Xa21, xa13, and xa5, along with the Sub1 QTL, for submergence stress tolerance were transferred into the variety using marker-assisted backcross breeding approach. Foreground selection using direct and closely linked markers detected the progenies carrying all four target genes in the BC1F1, BC2F1, and BC3F1 generations, and the positive progenies carrying these genes with maximum similarity to the recipient parent, Ranidhan, were backcrossed into each segregating generation. Foreground selection in the BC1F1 generation progenies detected all target genes in 11 progenies. The progeny carrying all target genes and similar to the recipient parent in terms of phenotype was backcrossed, and a total of 321 BC2F1 seeds were produced. Ten progenies carried all target genes/QTL in the BC2F1 generation. Screening of the BC3F1 progenies using markers detected 12 plants carrying the target genes. A total of 1270 BC3F2 seeds were obtained from the best BC3F1 progeny. Foreground selection in the BC3F2 progenies detected four plants carrying the target genes in the homozygous condition. The bioassay of the pyramided lines conferred very high levels of resistance to the predominant isolates of bacterial blight pathogen. These BB pyramided lines were submergence-tolerant and similar to Ranidhan in 13 agro-morphologic and grain quality traits; hence, they are likely to be adopted by farmers. [ABSTRACT FROM AUTHOR]

Published

2023

18. Stacking herbicide detoxification and resistant genes improves glyphosate tolerance and reduces phytotoxicity in tobacco (Nicotiana tabacum L.) and rice (Oryza sativa L.).

Author

Vennapusa, Amaranatha Reddy, Agarwal, Subham, Rao Hm, Hanumanth, Aarthy, Thiagarayaselvam, Babitha, K.C., Thulasiram, Hirekodathakallu V., Kulkarni, Mahesh J., Melmaiee, Kalpalatha, Sudhakar, Chinta, Udayakumar, M., and S Vemanna, Ramu

Subjects

*TOBACCO, *GLYPHOSATE, *RICE, *HERBICIDES, *HERBICIDE-resistant crops, *HERBICIDE residues

Abstract

Glyphosate residues retained in the growing meristematic tissues or in grains of glyphosate-resistant crops affect the plants physiological functions and crop yield. Removing glyphosate residues in the plants is desirable with no penalty on crop yield and quality. We report a new combination of scientific strategy to detoxify glyphosate that reduces the residual levels and improve crop resistance. The glyphosate detoxifying enzymes Aldo-keto reductase (AKR1) and mutated glycine oxidase (mGO) with different modes of action were co-expressed with modified EPSPS , which is insensitive to glyphosate in tobacco (Nicotiana tabacum L.) and rice (Oryza sativa L.). The transgenic tobacco plants expressing individual PsAKR1 , mGO, CP4-EPSPS , combinations of PsAKR1:CP4EPSPS, PsAKR1:mGO, and multigene with PsAKR1: mGO: CP4EPSPS genes were developed. The bio-efficacy studies of in-vitro leaf regeneration on different concentrations of glyphosate, seedling bioassay, and spray on transgenic tobacco plants demonstrate that glyphosate detoxification with enhanced resistance. Comparative analysis of the transgenic tobacco plants reveals that double and multigene expressing transgenics had reduced accumulation of shikimic acid, glyphosate, and its primary residue AMPA, and increased levels of sarcosine were observed in all PsAKR1 expressing transgenics. The multigene expressing rice transgenics showed improved glyphosate resistance with yield maintenance. In summary, results suggest that stacking genes with two different detoxification mechanisms and insensitive EPSPS is a potential approach for developing glyphosate-resistant plants with less residual content. • Glyphosate residues that remain in the plant tissues are phytotoxic. • Multigene expression improved glyphosate resistance in tobacco and rice. • The glyphosate detoxification genes significantly reduced herbicide residues. • Multigene expression sustained physiological and yield performance. • Stacking detoxifying and insensitive genes is a potential approach for GR plants. [ABSTRACT FROM AUTHOR]

Published

2022

19. Progress and prospectus in genetics and genomics of Phytophthora root and stem rot resistance in soybean (Glycine max L.)

Author

Subhash Chandra, Mukesh Choudhary, Pravin K. Bagaria, Vennampally Nataraj, Giriraj Kumawat, Jeet Ram Choudhary, Humira Sonah, Sanjay Gupta, Shabir Hussain Wani, and Milind B. Ratnaparkhe

Subjects

soybean, Phytophthora, disease resistance, gene stacking, sustainable management, genomic approaches, Genetics, QH426-470

Abstract

Soybean is one of the largest sources of protein and oil in the world and is also considered a “super crop” due to several industrial advantages. However, enhanced acreage and adoption of monoculture practices rendered the crop vulnerable to several diseases. Phytophthora root and stem rot (PRSR) caused by Phytophthora sojae is one of the most prevalent diseases adversely affecting soybean production globally. Deployment of genetic resistance is the most sustainable approach for avoiding yield losses due to this disease. PRSR resistance is complex in nature and difficult to address by conventional breeding alone. Genetic mapping through a cost-effective sequencing platform facilitates identification of candidate genes and associated molecular markers for genetic improvement against PRSR. Furthermore, with the help of novel genomic approaches, identification and functional characterization of Rps (resistance to Phytophthora sojae) have also progressed in the recent past, and more than 30 Rps genes imparting complete resistance to different PRSR pathotypes have been reported. In addition, many genomic regions imparting partial resistance have also been identified. Furthermore, the adoption of emerging approaches like genome editing, genomic-assisted breeding, and genomic selection can assist in the functional characterization of novel genes and their rapid introgression for PRSR resistance. Hence, in the near future, soybean growers will likely witness an increase in production by adopting PRSR-resistant cultivars. This review highlights the progress made in deciphering the genetic architecture of PRSR resistance, genomic advances, and future perspectives for the deployment of PRSR resistance in soybean for the sustainable management of PRSR disease.

Published

2022

20. Efficient Gene Stacking in Rice Using the GAANTRY System

Author

Leyla T. Hathwaik, James Horstman, James G. Thomson, and Roger Thilmony

Subjects

Agrobacterium, Gene stacking, Genetic engineering, Oryza sativa, Site-specific recombinase, Plant culture, SB1-1110

Abstract

Abstract Genetic engineering of rice provides a means for improving rice grain quality and yield, and the introduction and expression of multiple genes can produce new traits that would otherwise be difficult to obtain through conventional breeding. GAANTRY (Gene Assembly in Agrobacterium by Nucleic acid Transfer using Recombinase technologY) was previously shown to be a precise and robust system to stably stack ten genes (28 kilobases (kb)) within an Agrobacterium virulence plasmid Transfer-DNA (T-DNA) and obtain high-quality Arabidopsis and potato transgenic events. To determine whether the GAANTRY system can be used to engineer a monocotyledonous crop, two new T-DNA constructs, carrying five (16.9 kb) or eleven (37.4 kb) cargo sequences were assembled and transformed into rice. Characterization of 53 independent transgenic events demonstrated that more than 50% of the plants carried all of the desired cargo sequences and exhibited the introduced traits. Additionally, more than 18% of the lines were high-quality events containing a single copy of the introduced transgenes and were free of sequences from outside of the T-DNA. Therefore, GAANTRY provides a simple, precise and versatile tool for transgene stacking in rice and potentially other cereal grain crops.

Published

2021

21. Site-Specific Sequence Exchange Between Homologous and Non-homologous Chromosomes

Author

Qian Yin, Ruyu Li, and David W. Ow

Subjects

gene stacking, transgene replacement, transgene translocation, GMO, recombinase, Cre, Plant culture, SB1-1110

Abstract

Transgene integration typically takes place in an easy-to-transform laboratory variety before the transformation event is introgressed through backcrosses to elite cultivars. As new traits are added to existing transgenic lines, site-specific integration can stack new transgenes into a previously created transgenic locus. In planta site-specific integration minimizes the number of segregating loci to assemble into a breeding line, but cannot break genetic linkage between the transgenic locus and nearby undesirable traits. In this study, we describe an additional feature of an in planta gene-stacking scheme, in which the Cre (control of recombination) recombinase not only deletes transgenic DNA no longer needed after transformation but also mediates recombination between homologous or non-homologous chromosomes. Although the target site must first be introgressed through conventional breeding, subsequent transgenes inserted into the same locus would be able to use Cre-mediated translocation to expedite a linkage drag-free introgression to field cultivars.

Published

2022

22. Evaluating the pesticidal impact of plant protease inhibitors: lethal weaponry in the co‐evolutionary battle.

Author

Pandey, Ankesh, Yadav, Reena, and Sanyal, Indraneel

Subjects

COEVOLUTION, PLANT defenses, PEST control, TRANSGENIC plants, PROTEASE inhibitors, GENOME editing, SERINE proteinase inhibitors

Abstract

In the arsenal of plant defense, protease inhibitors (PIs) are well‐designed defensive products to counter field pests. PIs are produced in plant tissues by means of 'stable defense metabolite' and triggered on demand as the perception of the signal and well established as a part of plant active defense. PIs have been utilized for approximately four decades, initially as a gene‐alone approach that was later replaced by multiple gene pyramiding/gene stacking due to insect adaptability towards the PI alone. By considering the adaptive responses of the pest to the single insecticidal gene, the concept of gene pyramiding gained continuous appreciation for the development of transgenic crops to deal with co‐evolving pests. Gene pyramiding approaches are executed to bypass the insectʼs adaptive responses against PIs. Stacking PIs with additional insecticidal proteins, plastid engineering, recombinant proteinase inhibitors, RNAi‐based methods and CRISPR/Cas9‐mediated genome editing are the advanced tools and methods for next‐generation pest management. Undoubtedly, the domain associated with the mechanism of PIs in the course of plant–pest interactions will occupy a central role for the advancement of more efficient and sustainable pest control strategies. © 2021 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2022

23. Site-Specific Sequence Exchange Between Homologous and Non-homologous Chromosomes.

Author

Yin, Qian, Li, Ruyu, and Ow, David W.

Subjects

HOMOLOGOUS chromosomes, TRANSGENES, RECOMBINASES, LOCUS (Genetics), INTROGRESSION (Genetics), DNA

Abstract

Transgene integration typically takes place in an easy-to-transform laboratory variety before the transformation event is introgressed through backcrosses to elite cultivars. As new traits are added to existing transgenic lines, site-specific integration can stack new transgenes into a previously created transgenic locus. In planta site-specific integration minimizes the number of segregating loci to assemble into a breeding line, but cannot break genetic linkage between the transgenic locus and nearby undesirable traits. In this study, we describe an additional feature of an in planta gene-stacking scheme, in which the Cre (control of recombination) recombinase not only deletes transgenic DNA no longer needed after transformation but also mediates recombination between homologous or non-homologous chromosomes. Although the target site must first be introgressed through conventional breeding, subsequent transgenes inserted into the same locus would be able to use Cre-mediated translocation to expedite a linkage drag-free introgression to field cultivars. [ABSTRACT FROM AUTHOR]

Published

2022

24. Targeted DNA insertion in plants.

Author

Oliver Xiaoou Dong and Ronald, Pamela C.

Subjects

*PLANT DNA, *PLANT genomes, *DNA sequencing, *GENE silencing, *PLANT genetics

Abstract

Conventional methods of DNA sequence insertion into plants, using Agrobacterium-mediated transformation or microprojectile bombardment, result in the integration of the DNA at random sites in the genome. These plants may exhibit altered agronomic traits as a consequence of disruption or silencing of genes that serve a critical function. Also, genes of interest inserted at random sites are often not expressed at the desired level. For these reasons, targeted DNA insertion at suitable genomic sites in plants is a desirable alternative. In this paper we review approaches of targeted DNA insertion in plant genomes, discuss current technical challenges, and describe promising applications of targeted DNA insertion for crop genetic improvement. [ABSTRACT FROM AUTHOR]

Published

2021

25. Stacked insecticidal genes in potatoes exhibit enhanced toxicity against Colorado potato beetle, Leptinotarsa decemlineata (Coleoptera: Chrysomelidae).

Author

Salim, Muhammad, Bakhsh, Allah, and Gökçe, Ayhan

Subjects

*COLORADO potato beetle, *CHRYSOMELIDAE, *BEETLES, *IMIDACLOPRID, *INSECT mortality, *POTATOES, *TRANSGENIC plants

Abstract

The present study was performed to express stacked insecticidal genes in potato cv. Lady Olympia and Agria to encode resistance against Colorado potato beetle (CPB), Leptinotarsa decemlineata (Say). Bacillus thuringiensis (Bt) gene (cry3A), synthetic hybrid (SN-19) and plant proteinase inhibitor Oryza cystatin II (OCII) cloned in pCAMBIA1301 binary vector in two different combinations as of DS-1 (cry3A + SN-19 genes) and DS-2 (OCII + SN-19 genes) constructs and further transformed to two potato cultivars using Agrobacterium-mediated transformation. All molecular analyses confirmed gene integration and expression in a total of 27 primary transformants in both Agria and Lady Olympia. Insecticidal effects of T0 progeny transgenic potato plants were tested against CPB under laboratory conditions. Transgenic plants of Agria and Lady Olympia transformed with DS-1 and DS-2 constructs caused 100% mortality to all larval stages and adults of CPB. However, 100% mortality of tested insects took a longer time in the adult stage (10–14 days) compared to larval stages (2–6 days). Foliage consumption by L2-L4 larval stages and adults of CPB was significantly reduced in Agria and Lady Olympia plants transformed with DS-1 and DS-2 constructs, as compared to their control plants. Lower foliage consumption of transgenic plants by L1 larval stages was also observed, but the reduction was only statistically significant for some of the tested plants. These promising results indicate that the transgenic potato plants exhibit a high potential in controlling CPB population and are a useful tool in the management of imidacloprid-resistant CPB. [ABSTRACT FROM AUTHOR]

Published

2021

26. Recombinase‐mediated integration of a multigene cassette in rice leads to stable expression and inheritance of the stacked locus

Author

Bhuvan Pathak and Vibha Srivastava

Subjects

Cre‐lox, gene stacking, multigene transformation, site‐specific recombination, trait engineering, Botany, QK1-989

Abstract

Abstract Efficient methods for multigene transformation are important for developing novel crop varieties. Methods based on random integrations of multiple genes have been successfully used for metabolic engineering in plants. However, efficiency of co‐integration and co‐expression of the genes could present a bottleneck. Recombinase‐mediated integration into the engineered target sites is arguably a more efficient method of targeted integration that leads to the generation of stable transgenic lines at a high rate. This method has the potential to streamline multigene transformation for metabolic engineering and trait stacking in plants. Therefore, empirical testing of transgene(s) stability from the multigene site‐specific integration locus is needed. Here, the recombinase technology based on Cre‐lox recombination was evaluated for developing multigenic lines harboring constitutively‐expressed and inducible genes. Targeted integration of a five genes cassette in the rice genome generated a precise full‐length integration of the cassette at a high rate, and the resulting multigenic lines expressed each gene reliably as defined by their promoter activity. The stable constitutive or inducible expression was faithfully transmitted to the progeny, indicating inheritance‐stability of the multigene locus. Co‐localization of two distinctly inducible genes by heat or cold with the strongly constitutive genes did not appear to interfere with each other's expression pattern. In summary, high rate of co‐integration and co‐expression of the multigene cassette installed by the recombinase technology in rice shows that this approach is appropriate for multigene transformation and introduction of co‐segregating traits. Significance Statement Recombinase‐mediated site‐specific integration approach was found to be highly efficacious in multigene transformation of rice showing proper regulation of each gene driven by constitutive or inducible promoter. This approach holds promise for streamlining gene stacking in crops and expressing complex multigenic traits.

Published

2020

27. Stacking of a low-lignin trait with an increased guaiacyl and 5-hydroxyguaiacyl unit trait leads to additive and synergistic effects on saccharification efficiency in Arabidopsis thaliana

Author

Lisanne de Vries, Ruben Vanholme, Rebecca Van Acker, Barbara De Meester, Lisa Sundin, and Wout Boerjan

Subjects

Saccharification, Lignin, Gene stacking, Transaldolase (tra), Cinnamate 4-hydroxylase (c4h), 4-coumarate:CoA ligase (4cl), Fuel, TP315-360, Biotechnology, TP248.13-248.65

Abstract

Abstract Background Lignocellulosic biomass, such as wood and straw, is an interesting feedstock for the production of fermentable sugars. However, mainly due to the presence of lignin, this type of biomass is recalcitrant to saccharification. In Arabidopsis, lignocellulosic biomass with a lower lignin content or with lignin with an increased fraction of guaiacyl (G) and 5-hydroxyguaiacyl (5H) units shows an increased saccharification efficiency. Here, we stacked these two traits and studied the effect on the saccharification efficiency and biomass yield, by combining either transaldolase (tra2), cinnamate 4-hydroxylase (c4h-3), or 4-coumarate:CoA ligase (4cl1-1) with caffeic acid O-methyltransferase (comt-1 or comt-4) mutants. Results The three double mutants (tra2 comt-1, c4h-3 comt-4, and 4cl1-1 comt-4) had a decreased lignin amount and an increase in G and 5H units in the lignin polymer compared to wild-type (WT) plants. The tra2 comt-1 double mutant had a better saccharification efficiency compared to the parental lines when an acid or alkaline pretreatment was used. For the double mutants, c4h-3 comt-4 and 4cl1-1 comt-4, the saccharification efficiency was significantly higher compared to WT and its parental lines, independent of the pretreatment used. When no pretreatment was used, the saccharification efficiency increased even synergistically for these mutants. Conclusion Our results show that saccharification efficiency can be improved by combining two different mutant lignin traits, leading to plants with an even higher saccharification efficiency, without having a yield reduction of the primary inflorescence stem. This approach can help improve saccharification efficiency in bio-energy crops.

Published

2018

28. Engineering in Plant Genome Using Agrobacterium: Progress and Future

Author

Alok, Anshu, Sharma, Shivam, Kumar, Jitesh, Verma, Subodh, Sood, Hemant, Kalia, Vipin Chandra, editor, and Saini, Adesh Kumar, editor

Published

2017

29. Efficient Gene Stacking in Rice Using the GAANTRY System.

Author

Hathwaik, Leyla T., Horstman, James, Thomson, James G., and Thilmony, Roger

Subjects

RICE, GENETIC engineering, GENES, RICE quality, TRANSGENES, GRAIN, RICE yields, TRANSGENE expression

Abstract

Genetic engineering of rice provides a means for improving rice grain quality and yield, and the introduction and expression of multiple genes can produce new traits that would otherwise be difficult to obtain through conventional breeding. GAANTRY (Gene Assembly in Agrobacterium by Nucleic acid Transfer using Recombinase technologY) was previously shown to be a precise and robust system to stably stack ten genes (28 kilobases (kb)) within an Agrobacterium virulence plasmid Transfer-DNA (T-DNA) and obtain high-quality Arabidopsis and potato transgenic events. To determine whether the GAANTRY system can be used to engineer a monocotyledonous crop, two new T-DNA constructs, carrying five (16.9 kb) or eleven (37.4 kb) cargo sequences were assembled and transformed into rice. Characterization of 53 independent transgenic events demonstrated that more than 50% of the plants carried all of the desired cargo sequences and exhibited the introduced traits. Additionally, more than 18% of the lines were high-quality events containing a single copy of the introduced transgenes and were free of sequences from outside of the T-DNA. Therefore, GAANTRY provides a simple, precise and versatile tool for transgene stacking in rice and potentially other cereal grain crops. [ABSTRACT FROM AUTHOR]

Published

2021

30. Nanoparticle-based genetic transformation of Cannabis sativa.

Author

Ahmed, Sajjad, Gao, Xuefei, Jahan, Md. Asraful, Adams, Maxwell, Wu, Nianqiang, and Kovinich, Nik

Subjects

*CANNABIS (Genus), *GENETIC transformation, *MARIJUANA growing, *GOLD nanoparticles, *TRANSGENES, *GREEN fluorescent protein, *POLYETHYLENEIMINE

Abstract

• Nanoparticle-based genetic transformation can transiently overexpress transgenes in intact tissues of Cannabis sativa. • Nanoparticle-based genetic transformation can simultaneously overexpress multiple transgenes. • Cationic polymer-modified silicon-coated gold nanoparticles are an effective carrier to introduce foreign DNA in Cannabis tissues. Cannabis sativa (Cannabis) is a multipurpose plant species consisting of specific lineages that for centuries has either been artificially selected for the production of fiber or the psychoactive drug Δ9-tetrahydrocannabinol (THC). With the recent lifting of previous legal restrictions on consuming Cannabis, there has been a resurgence of interest in understanding and manipulating Cannabis genetics to enhance its compositions. Yet, recently developed approaches are not amenable to high-throughput gene stacking to study multi-genic traits. Here, we demonstrate an efficient nanoparticle-based transient gene transformation protocol where multiple gene plasmids can be expressed simultaneously in intact Cannabis leaf cells in a very short time (5 days). Constructs encoding two soybean transcription factors were co-grafted onto poly-ethylenimine cationic polymer-modified silicon dioxide-coated gold nanoparticles (PEI-Au@SiO 2). Infiltration of the DNA-PEI-Au@SiO 2 into Cannabis leaf tissues resulted in the transcription of both soybean genes and the localization of fluorescent-tagged transcription factor proteins in the nuclei of Cannabis leaf cells including the trichomes, which are the cell types that biosynthesize valuable cannabinoid and terpene metabolites. Our study exemplifies a rapid transient gene transformation approach that will be useful to study the effects of gene stacking in Cannabis. [ABSTRACT FROM AUTHOR]

Published

2021

31. Integrated proteomics and metabolomics analysis of transgenic and gene-stacked maize line seeds.

Author

Liu, Weixiao, Zhao, Haiming, Miao, Chaohua, and Jin, Wujun

Subjects

*PROTEOMICS, *SEEDS, *SHIKIMIC acid, *CORN, *BIOSYNTHESIS, *METABOLOMICS, *METABOLITES

Abstract

Unintended effects of genetically modified (GM) crops may pose safety issues. Omics techniques provide researchers with useful tools to assess such unintended effects. Proteomics and metabolomics analyses were performed for three GM maize varieties, 2A-7, CC-2, and 2A-7×CC-2 stacked transgenic maize, and the corresponding non-GM parent Zheng58. Proteomics revealed 120, 271 and 135 maize differentially expressed proteins (DEPs) in the 2A-7/Zheng58, CC-2/Zheng58 and 2A-7×CC-2/Zheng58 comparisons, respectively. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis showed that most DEPs participated in metabolic pathways and the biosynthesis of secondary metabolite. Metabolomics revealed 179, 135 and 131 differentially accumulated metabolites (DAMs) in the 2A-7/Zheng58, CC-2/Zheng58 and 2A-7×CC-2/Zheng58 comparisons, respectively. Based on KEGG enrichment analysis, most DAMs are involved in the biosynthesis of secondary metabolite and metabolic pathways. According to integrated proteomics and metabolomics analysis, the introduction of exogenous EPSPS did not affect the expression levels of six other enzymes or the abundance of seven metabolites involved in the shikimic acid pathway in CC-2 and 2A-7×CC-2 seeds. Six co-DEPs annotated by integrated proteomics and metabolomics pathway analysis were further analyzed by qRT-PCR. This study successfully employed integrated proteomic and metabolomic technology to assess unintended changes in maize varieties. The results suggest that GM and gene stacking do not cause significantly unintended effects. [ABSTRACT FROM AUTHOR]

Published

2021

32. Recombinase‐mediated integration of a multigene cassette in rice leads to stable expression and inheritance of the stacked locus.

Author

Pathak, Bhuvan and Srivastava, Vibha

Subjects

RICE, CULTIVARS, PLANT genomes, GENETIC regulation

Abstract

Efficient methods for multigene transformation are important for developing novel crop varieties. Methods based on random integrations of multiple genes have been successfully used for metabolic engineering in plants. However, efficiency of co‐integration and co‐expression of the genes could present a bottleneck. Recombinase‐mediated integration into the engineered target sites is arguably a more efficient method of targeted integration that leads to the generation of stable transgenic lines at a high rate. This method has the potential to streamline multigene transformation for metabolic engineering and trait stacking in plants. Therefore, empirical testing of transgene(s) stability from the multigene site‐specific integration locus is needed. Here, the recombinase technology based on Cre‐lox recombination was evaluated for developing multigenic lines harboring constitutively‐expressed and inducible genes. Targeted integration of a five genes cassette in the rice genome generated a precise full‐length integration of the cassette at a high rate, and the resulting multigenic lines expressed each gene reliably as defined by their promoter activity. The stable constitutive or inducible expression was faithfully transmitted to the progeny, indicating inheritance‐stability of the multigene locus. Co‐localization of two distinctly inducible genes by heat or cold with the strongly constitutive genes did not appear to interfere with each other's expression pattern. In summary, high rate of co‐integration and co‐expression of the multigene cassette installed by the recombinase technology in rice shows that this approach is appropriate for multigene transformation and introduction of co‐segregating traits. Significance Statement: Recombinase‐mediated site‐specific integration approach was found to be highly efficacious in multigene transformation of rice showing proper regulation of each gene driven by constitutive or inducible promoter. This approach holds promise for streamlining gene stacking in crops and expressing complex multigenic traits. [ABSTRACT FROM AUTHOR]

Published

2020

33. Microsatellite molecular marker-assisted gene pyramiding for resistance to Asian soybean rust (ASR)

Author

Joselaine Viganó, Alessandro Lucca Braccini, Ivan Schuster, and Vanessa Maria Pereira Silva Menezes

Subjects

Phakopsora pachyrhizi, gene stacking, marker-assisted breeding, durable resistance., Agriculture (General), S1-972

Abstract

The present study aimed at pyramiding ASR-resistance genes through microsatellite (SSR) marker-assisted selection (MAS) and demonstrating the pyramiding steps. To obtain the first generation of gene pyramiding, crosses were made between introduced plants (PI’s), which have the genes Rpp1, Rpp2, Rpp3, Rpp4, and Rpp5. F1 plants from the initial crosses were intercrossed to obtain plants with the four resistance genes (second pyramiding generation). Plants selected from this second generation were again intercrossed (third pyramiding generation) to increase the number of pyramided genes. For MAS, we used informative SSR markers in each cross. SSR markers were considered informative when the source resistance allele containing the target gene could be followed in the progeny, even in crosses between hybrids that both contained the same allele. Markers published in the ASR genetic mapping studies and in the consensus map of the soybean were used. We obtained plants containing from 2 to 4 genes pyramided per plant. These plants can be used as a source of multiple resistance in breeding programmes for obtaining soybean varieties with more durable resistance to ASR.

Published

2018

34. Gene Stacking and Stoichiometric Expression of ER-Targeted Constructs Using "2A" Self-Cleaving Peptides.

Author

Spatola Rossi T, Fricker M, and Kriechbaumer V

Subjects

Transgenes, Endoplasmic Reticulum, Gene Silencing, Peptides genetics, Biotechnology

Abstract

Simultaneous stoichiometric expression of multiple genes plays a major part in modern research and biotechnology. Traditional methods for incorporating multiple transgenes (or "gene stacking") have drawbacks such as long time frames, uneven gene expression, gene silencing, and segregation derived from the use of multiple promoters. 2A self-cleaving peptides have emerged over the last two decades as a functional gene stacking method and have been used in plants for the co-expression of multiple genes under a single promoter. Here we describe design features of multicistronic polyproteins using 2A peptides for co-expression in plant cells and targeting to the endoplasmic reticulum (ER). We designed up to quad-cistronic vectors that could target proteins in tandem to the ER. We also exemplify the incorporation of self-excising intein domains within 2A polypeptides, to remove residue additions. These features could aid in the design of stoichiometric protein co-expression strategies in plants in combination with targeting to different subcellular compartments., (© 2024. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024

35. Advanced genetic tools enable synthetic biology in the oleaginous microalgae Nannochloropsis sp.

Author

Poliner, Eric, Farré, Eva M., and Benning, Christoph

Subjects

*SYNTHETIC biology, *MICROALGAE, *TRIGLYCERIDES, *UNSATURATED fatty acids, *GENOMICS

Abstract

Nannochloropsis is a genus of fast-growing microalgae that are regularly used for biotechnology applications. Nannochloropsis species have a high triacylglycerol content and their polar lipids are rich in the omega-3 long-chain polyunsaturated fatty acid, eicosapentaenoic acid. Placed in the heterokont lineage, the Nannochloropsis genus has a complex evolutionary history. Genome sequences are available for several species, and a number of transcriptomic datasets have been produced, making this genus a facile model for comparative genomics. There is a growing interest in Nannochloropsis species as models for the study of microalga lipid metabolism and as a chassis for synthetic biology. Recently, techniques for gene stacking, and targeted gene disruption and repression in the Nannochloropsis genus have been developed. These tools enable gene-specific, mechanistic studies and have already allowed the engineering of improved Nannochloropsis strains with superior growth, or greater bioproduction. [ABSTRACT FROM AUTHOR]

Published

2018

36. Stacking of mutant genes in the development of “purple tomato” rich in both lycopene and anthocyanin contents.

Author

Hazra, Pranab, Longjam, M., and Chattopadhyay, Arup

Subjects

*PLANT genes, *TOMATO breeding, *MUTANT proteins, *LYCOPENE, *ANTHOCYANIN genetics, TOMATO genetics

Abstract

A conventional breeding approach was framed to combine lycopene enhancing mutant gene, dg or hp-2 dg and anthocyanin synthesizing gene, Aft in one genotype in maximizing the accumulation of both lycopene and anthocyanin pigment in tomato fruit. This breeding scheme involves one crossing, Alisa Craig AftAft  × BCT-115 dgdg followed by two selfings for selection of the desirable double homozygous genotype, AftAft dgdg , the “Purple tomato” based on morphological marker characters conditioned by two genes, dark green fruit of dgdg due to very high total chlorophyll content (18.19 mg/100 g fresh weight) and purple colour for anthocyanin pigment of Aft - gene. Lycopene content in ripe fruits of BCT-115 dgdg (6.22 mg/100 g fresh weight) was 62.41% higher compared to Alisa Craig Aft / Aft while that of Alisa Craig AftAft had high anthocyanin content (14.51 mg/ 100 g fresh weight) contrary to nil in BCT 115 dgdg . Segregation pattern confirmed the expected 3:1 ratio for single dominant Aft gene and 1:3 ratio for single recessive dg gene. The F 2 segregates could be grouped into 5 phenotypic classes in the ratio of 6:3:3:3:1 instead of usual 9:3:3:1 in digenic segregation due to variable expression of anthocyanin in the homozygous ( Aft Aft ) and heterozygous ( Aft aft ) genotype. Of the selfed progeny of the 34 desirable F 2 segregates (dark green fruit with intense anthocyanin pigmentation) clustered in the Group-1 family (F 3 population), 9 segregates bred true confirming the presence of two targeted genes in homozygous condition, AftAft dgdg , the “Purple tomato line”. This breeding approach proved to be a viable option to develop a new variety “Purple tomato” with unique combination of high lycopene (6.13 mg/100 g fresh weight), anthocyanin (20.73 mg/100 g fresh weight) and ascorbic acid (31.56 mg/100 g fresh weight) contents. [ABSTRACT FROM AUTHOR]

Published

2018

37. A versatile and robust Agrobacterium‐based gene stacking system generates high‐quality transgenic Arabidopsis plants.

Author

Collier, Ray, Thomson, James G., and Thilmony, Roger

Subjects

*AGROBACTERIUM, *ARABIDOPSIS thaliana, *GENETIC engineering, *RHIZOBIUM rhizogenes, *PLANT biotechnology

Abstract

Summary: Biotechnology provides a means for the rapid genetic improvement of plants. Although single genes have been important in engineering herbicide and pest tolerance traits in crops, future improvements of complex traits like yield and nutritional quality will likely require the introduction of multiple genes. This research reports a system (GAANTRY; Gene Assembly in Agrobacterium by Nucleic acid Transfer using Recombinase technologY) for the flexible, in vivo stacking of multiple genes within an Agrobacterium virulence plasmid Transfer‐DNA (T‐DNA). The GAANTRY system utilizes in vivo transient expression of unidirectional site‐specific recombinases and an alternating selection scheme to sequentially assemble multiple genes into a single transformation construct. To demonstrate GAANTRY's capabilities, 10 cargo sequences were sequentially stacked together to produce a 28.5‐kbp T‐DNA, which was used to generate hundreds of transgenic events. Approximately 90% of the events identified using a dual antibiotic selection screen exhibited all of the introduced traits. A total of 68% of the tested lines carried a single copy of the selection marker transgene located near the T‐DNA left border, and only 8% contained sequence from outside the T‐DNA. The GAANTRY system can be modified to easily accommodate any method of DNA assembly and generate high‐quality transgenic plants, making it a powerful, yet simple to use tool for plant genetic engineering. [ABSTRACT FROM AUTHOR]

Published

2018

38. Lack of efficacy of transgenic pea (Pisum sativum L.) stably expressing antifungal genes against Fusarium spp. in three years of confined field trials.

Author

Kahlon, Jagroop Gill, Jacobsen, Hans-Jörg, Chatterton, Syama, Hassan, Fathi, Bowness, Robyne, and Hall, Linda M.

Subjects

*PEA diseases & pests, *TRANSGENIC plants, *ANTIFUNGAL agents, *EXPERIMENTAL agriculture, *PLANT germplasm

Abstract

Fusarium root rot is a major pea disease in Canada and only partial tolerance exists in germplasm. Transgenic technologies may hold promise but the economic benefits of genetically modified (GM) pea will need to surpass the regulatory costs, time and labor involved in bringing a GM crop to market. European pea (Pisum sativum L.) cultivars expressing four antifungal genes, 1-3 β glucanase (G), endochitinase (C) (belonging to PR proteins family), polygalacturonase inhibiting proteins (PGIPs) (P) and stilbene synthase (V) have been transformed for disease tolerance and showed disease tolerance under laboratory conditions. Transgenic lines with four antifungal genes inserted either individually or stacked through crossing were tested for their efficacy against Fusarium root rot (Fusarium avenaceum) in confined trials over three years (2013 to 2015) in comparison with two parental German lines and three Canadian lines. Superior emergence, higher fresh weight or lower disease ratings above and below ground, of transgenic lines in presence of disease inoculum were not observed consistently in the three years of field experiments when compared to the parental and Canadian lines in the presence of disease inoculum. No indication of an advantage of stacked genes over single genes was observed. Most transgenic lines had lower relative gene expression in the roots than in the leaves in greenhouse trials suggesting a possible explanation for poor tolerance to Fusarium root rot. Field trials are necessary to verify the agronomic performance and ecological relevance of the promising effects detected under laboratory conditions. [ABSTRACT FROM AUTHOR]

Published

2018

39. Induction of Targeted Deletions in Transgenic Bread Wheat (Triticum aestivum L.) Using Customized Meganuclease.

Author

Youssef, D., Nihou, A., Partier, A., Tassy, C., Paul, W., Rogowsky, P. M., Beckert, M., and Barret, P.

Subjects

*DELETION mutation, *WHEAT, *ANTIBIOTICS, *FOOD crops, *DNA

Abstract

Biotechnologies offer breeders good opportunities for breakthrough genetic improvements of bread wheat, one of mankind's main food crops. Since the production of the first transgenic wheat, one of the major concerns has been the removal of selective markers, first because of societal concerns about the antibiotic resistance of some of these genes, and second because removal of a selective marker was the first step toward retransformation using the same selection system. Site-directed nucleases are enzymes that cut genomic DNA in vivo at predefined sites. Among them, meganucleases cut DNA at predefined, long DNA (up to 24 nt) sites, thereby enabling single cuts on large genomes including the bread wheat genome (17 Gbp). In this paper, we describe for the first time the use of a customized meganuclease to cut wheat DNA in vivo.We show that double cuts provoked the deletion of previously inserted DNA cassettes containing the DsRed reporter gene, and that in many cases, the meganuclease target site was correctly reconstituted, offering opportunities for subsequent insertion of stacked transgenes to replace the gene of selection. Moreover, perfect deletions were observed not only in the callus after transient expression of the meganucleases, but also in T0 transgenic wheat after stable retransformation with the meganuclease. Future prospects for the removal of selective markers and transgene stacking are discussed. [ABSTRACT FROM AUTHOR]

Published

2018

40. A toolkit for <italic>Nannochloropsis oceanica </italic>CCMP1779 enables gene stacking and genetic engineering of the eicosapentaenoic acid pathway for enhanced long‐chain polyunsaturated fatty acid production.

Author

Poliner, Eric, Pulman, Jane A., Zienkiewicz, Krzysztof, Childs, Kevin, Benning, Christoph, and Farré, Eva M.

Subjects

*MICROALGAE, *EICOSAPENTAENOIC acid, *UNSATURATED fatty acids, *GENE expression, *GENETIC engineering, *ALGAE

Abstract

Summary: Nannochloropsis oceanica is an oleaginous microalga rich in ω3 long‐chain polyunsaturated fatty acids (LC‐PUFAs) content, in the form of eicosapentaenoic acid (EPA). We identified the enzymes involved in LC‐PUFA biosynthesis in N. oceanica CCMP1779 and generated multigene expression vectors aiming at increasing LC‐PUFA content in vivo. We isolated the cDNAs encoding four fatty acid desaturases (FAD) and determined their function by heterologous expression in S. cerevisiae. To increase the expression of multiple fatty acid desaturases in N. oceanica CCMP1779, we developed a genetic engineering toolkit that includes an endogenous bidirectional promoter and optimized peptide bond skipping 2A peptides. The toolkit also includes multiple epitopes for tagged fusion protein production and two antibiotic resistance genes. We applied this toolkit, towards building a gene stacking system for N. oceanica that consists of two vector series, pNOC‐OX and pNOC‐stacked. These tools for genetic engineering were employed to test the effects of the overproduction of one, two or three desaturase‐encoding cDNAs in N. oceanica CCMP1779 and prove the feasibility of gene stacking in this genetically tractable oleaginous microalga. All FAD overexpressing lines had considerable increases in the proportion of LC‐PUFAs, with the overexpression of Δ12 and Δ5 FAD encoding sequences leading to an increase in the final ω3 product, EPA. [ABSTRACT FROM AUTHOR]

Published

2018

41. Development of pGEMINI, a Plant Gateway Destination Vector Allowing the Simultaneous Integration of Two cDNA via a Single LR-Clonase Reaction.

Author

Exposito-Rodriguez, Marino, P. Laissue, Philippe, López-Calcagno, Patricia E., Mullineaux, Philip M., Raines, Christine A., and Simkin, Andrew J.

Subjects

PLANT development, ANTISENSE DNA, GATEWAYS (Computer networks), GENETIC transformation, GENE expression

Abstract

Gateway technology has been used to facilitate the generation of a large number of constructs for the modification of plants for research purposes. However, many of the currently available vectors only allow the integration of a single cDNA of interest into an expression clone. The ability to over-express multiple genes in combination is essential for the study of plant development where several transcripts have a role to play in one or more metabolic processes. The tools to carry out such studies are limited, and in many cases rely on the incorporation of cDNA into expression systems via conventional cloning, which can be both time consuming and laborious. To our knowledge, this study reports on the first development of a vector allowing the simultaneous integration of two independent cDNAs via a single LR-clonase reaction. This vector "pGEMINI" represents a powerful molecular tool offering the ability to study the role of multi-cDNA constructs on plant development, and opens up the process of gene stacking and the study of gene combinations through transient or stable transformation procedures. [ABSTRACT FROM AUTHOR]

Published

2017

42. A new location to split Cre recombinase for protein fragment complementation.

Author

Rajaee, Maryam and Ow, David W.

Subjects

*PLANT DNA, *RECOMBINASES, *INTEGRASES, *DNA-binding proteins, *PLANT hybridization

Abstract

We have previously described a recombinase-mediated gene stacking system in which the Cre recombinase is used to remove lox-site flanked DNA no longer needed after each round of Bxb1 integrase-mediated site-specific integration. The Cre recombinase can be conveniently introduced by hybridization with a cre-expressing plant. However, maintaining an efficient cre-expressing line over many generations can be a problem, as high production of this DNA-binding protein might interfere with normal chromosome activities. To counter this selection against high Cre activity, we considered a split- cre approach, in which Cre activity is reconstituted after separate parts of Cre are brought into the same genome by hybridization. To insure that the recombinase-mediated gene stacking system retains its freedom to operate, we tested for new locations to split Cre into complementing fragments. In this study, we describe testing four new locations for splitting the Cre recombinase for protein fragment complementation and show that the two fragments of Cre split between Lys244 and Asn245 can reconstitute activity that is comparable to that of wild-type Cre. [ABSTRACT FROM AUTHOR]

Published

2017

43. Co-transformation mediated stacking of blast resistance genes Pi54 and Pi54rh in rice provides broad spectrum resistance against Magnaporthe oryzae.

Author

Kumari, Mandeep, Rai, Amit, Devanna, B., Singh, Pankaj, Kapoor, Ritu, Rajashekara, H., Prakash, G., Sharma, Vinay, and Sharma, Tilak

Subjects

*RICE blast disease, *GENES, *FOOD crops, *ABIOTIC stress

Abstract

Key message: This is the first report of stacking two major blast resistance genes in blast susceptible rice variety using co-transformation method to widen the resistance spectrum against different isolates of Magnaporthe oryzae. Abstract: Single resistance ( R-) gene mediated approach for the management of rice blast disease has met with frequent breakdown in resistance response. Besides providing the durable resistance, gene pyramiding or stacking also imparts broad spectrum resistance against plant pathogens, including rice blast. In the present study, we stacked two R-genes; Pi54 and Pi54rh having broad spectrum resistance against multiple isolates of Magnaporthe oryzae ( M. oryzae). Both Pi54 and Pi54rh expressed under independent promoters were transferred into the blast susceptible japonica rice Taipei 309 (TP309) using particle gun bombardment method. Functional complementation analysis of stacked transgenic rice lines showed higher level of resistance to a set of highly virulent M. oryzae isolates collected from different rice growing regions. qRT-PCR analysis has shown M. oryzae induced expression of both the R-genes in stacked transgenic lines. The present study also demonstrated the effectiveness of the strategy for rapid single step gene stacking using co-transformation approach to engineer durable resistance against rice blast disease and also this is the first report in which two blast R-genes are stacked together using co-transformation approach. The two-gene-stacked transgenic line developed in this study can be used further to understand the molecular aspects of defense-related pathways vis-a-vis single R-gene containing transgenic lines. [ABSTRACT FROM AUTHOR]

Published

2017

44. Co-expression of the proteinase inhibitors oryzacystatin I and oryzacystatin II in transgenic potato alters Colorado potato beetle larval development.

Author

Cingel, Aleksandar, Savić, Jelena, Lazarević, Jelica, Ćosić, Tatjana, Raspor, Martin, Smigocki, Ann, and Ninković, Slavica

Subjects

*PROTEIN expression, *CYSTEINE proteinase inhibitors, *COLORADO potato beetle, *TRANSGENIC insects, *INSECT larvae, *INSECT development

Abstract

Colorado potato beetle (CPB; Leptinotarsa decemlineata Say, Coleoptera: Chrysomelidae) has shown a remarkable adaptability to a variety of control measures. Although oryzacystatin I and II (OCI and OCII) have potential in controlling pests that use cysteine proteinases for food digestion, expression of a single OC gene in potato exhibited a minimal or no effect on CPB fitness traits. The aim of this study was to examine the effect of coexpressed OCI and OCII in potato ( Solanum tuberosum L.) cultivars Desiree, Dragačevka and Jelica on CPB larvae. Growth parameters, consumption rates and food utilization, as well as activity of proteases of CPB larvae were assayed. Second and third instar larvae fed on transformed leaves molted earlier and had higher relative growth and consumption rates than larvae fed on nontransformed leaves, while efficiency of food utilization was unaffected. In contrast, fourth instar maximum weight gain and amount of leaves consumed were about 20% lower for the larvae fed on transgenic potato. Analysis of total protease activity of third instar larvae revealed reduction in overall proteolytic activity measured by azocasein hydrolysis, accompanied with inhibition of cysteine proteinase activity 24 h after ingestion of potato leaves expressing OCI and OCII. However, after long-term feeding on transformed leaves proteolytic activities of larvae became similar to the controls. Although feeding on OCI/OCII leaves did not affect larval survival, coexpression of OC genes reduced the development time and thus significantly decreased plant damage caused by CPB larvae. [ABSTRACT FROM AUTHOR]

Published

2017

45. The Predicted Cross Value for Genetic Introgression of Multiple Alleles.

Author

Ye Han, Cameron, John N., Lizhi Wang, and Beavis, William D.

Subjects

*ALLELES, *GAMETES, *GENETICS, *BREEDING, *PLANT genetics

Abstract

We consider the plant genetic improvement challenge of introgressing multiple alleles from a homozygous donor to a recipient. First, we frame the project as an algorithmic process that can be mathematically formulated. We then introduce a novel metric for selecting breeding parents that we refer to as the predicted cross value (PCV). Unlike estimated breeding values, which represent predictions of general combining ability, the PCV predicts specific combining ability. The PCV takes estimates of recombination frequencies as an input vector and calculates the probability that a pair of parents will produce a gamete with desirable alleles at all specified loci. We compared the PCV approach with existing estimated-breeding-value approaches in two simulation experiments, in which 7 and 20 desirable alleles were to be introgressed from a donor line into a recipient line. Results suggest that the PCV is more efficient and effective for multi-allelic trait introgression. We also discuss how operations research can be used for other crop genetic improvement projects and suggest several future research directions. [ABSTRACT FROM AUTHOR]

Published

2017

46. Replacement of stacked transgenes in planta.

Author

Chen, Weiqiang, Kaur, Gurminder, Hou, Lili, Li, Ruyu, and Ow, David W.

Subjects

*TRANSGENES, *GREEN fluorescent protein, *PHYTOCHELATINS

Published

2019

47. COLORFUL-Circuit: a platform for rapid multigene assembly, delivery and expression in plants

Author

Hassan eGhareeb, Sabine eLaukamm, and Volker eLipka

Subjects

Synthetic Biology, plant biotechnology, circuit design, Binary vectors, Gene stacking, Multigene coexpression, Plant culture, SB1-1110

Abstract

Advancing basic and applied plant research requires the continuous innovative development of the available technology toolbox. Essential components of this toolbox are methods that simplify the assembly, delivery and expression of multiple transgenes of interest. To allow simultaneous and directional multigene assembly on the same plant transformation vector, several strategies based on overlapping sequences or restriction enzymes have recently been developed. However, the assembly of homologous and repetitive DNA sequences can be inefficient and the frequent occurrence of target sequences recognized by commonly used restriction enzymes can be a limiting factor. Here, we noted that recognition sites for the restriction enzyme SfiI are rarely occurring in plant genomes. This fact was exploited to establish a multigene assembly system called COLORFUL-Circuit. To this end, we developed a set of binary vectors which provide a flexible and cost efficient cloning platform. The gene expression cassettes in our system are flanked with unique SfiI sites, which allow simultaneous multi-gene cassette assembly in a hosting binary vector. We used COLORFUL-Circuit to transiently and stably express up to four fluorescent organelle markers in addition to a selectable marker and analyzed the impact of assembly design on coexpression efficiency. Finally, we demonstrate the utility of our optimized COLORFUL-Circuit system in an exemplary case study, in which we monitored simultaneously the subcellular behavior of multiple organelles in a biotrophic plant-microbe interaction by Confocal Laser Scanning Microscopy.

Published

2016

48. Combining Selective Pressures to Enhance the Durability of Disease Resistance Genes.

Author

Martinez, Fernando

Subjects

MOLECULAR genetics, GENOMES

Abstract

The efficacy of disease resistance genes in plants decreases over time because of the selection of virulent pathogen genotypes. A key goal of crop protection programs is to increase the durability of the resistance conferred by these genes. The spatial and temporal deployment of plant disease resistance genes is considered to be a major factor determining their durability. In the literature, four principal strategies combining resistance genes over time and space have been considered to delay the evolution of virulent pathogen genotypes. We reviewed this literature with the aim of determining which deployment strategy results in the greatest durability of resistance genes. Although theoretical and empirical studies comparing deployment strategies of more than one resistance gene are very scarce, they suggest that the overall durability of disease resistance genes can be increased by combining their presence in the same plant (pyramiding). Retrospective analyses of field monitoring data also suggest that the pyramiding of disease resistance genes within a plant is the most durable strategy. By extension, we suggest that the combination of disease resistance genes with other practices for pathogen control (pesticides, farming practices) may be a relevant management strategy to slow down the evolution of virulent pathogen genotypes. [ABSTRACT FROM AUTHOR]

Published

2016

49. Plant artificial chromosome technology and its potential application in genetic engineering.

Author

Yu, Weichang, Yau, Yuan‐Yeu, and Birchler, James A.

Subjects

*ARTIFICIAL chromosomes, *GENETIC engineering, *PLANT resistance to insects, *PLANT genes, *CROP science

Abstract

Genetic engineering with just a few genes has changed agriculture in the last 20 years. The most frequently used transgenes are the herbicide resistance genes for efficient weed control and the Bt toxin genes for insect resistance. The adoption of the first-generation genetically engineered crops has been very successful in improving farming practices, reducing the application of pesticides that are harmful to both human health and the environment, and producing more profit for farmers. However, there is more potential for genetic engineering to be realized by technical advances. The recent development of plant artificial chromosome technology provides a super vector platform, which allows the management of a large number of genes for the next generation of genetic engineering. With the development of other tools such as gene assembly, genome editing, gene targeting and chromosome delivery systems, it should become possible to engineer crops with multiple genes to produce more agricultural products with less input of natural resources to meet future demands. [ABSTRACT FROM AUTHOR]

Published

2016

50. Expressing stacked HRAP and PFLP genes in transgenic banana has no synergistic effect on resistance to Xanthomonas wilt disease.

Author

Muwonge, Abubaker, Tripathi, Jaindra, Kunert, Karl, and Tripathi, Leena

Subjects

*BANANAS, *TRANSGENIC plants, *WILT diseases, *XANTHOMONAS, *FERREDOXINS, *DISEASE resistance of plants, *GENE expression in plants

Abstract

Banana production in Africa's great lakes region is threatened by the Banana Xanthomonas wilt (BXW) disease caused by Xanthomonas campestris pv. musacearum , a biotrophic pathogen. Transgenic banana plants, cv. “Gonja manjaya,” expressing stacked hypersensitive response-assisting protein gene ( HRAP ) and the plant ferredoxin-like protein gene ( PFLP ) were evaluated for resistance against BXW in comparison to transgenic lines having single gene. Transgenic lines with stacked gene as well as single gene had higher resistance to the pathogen than non-transgenic control plants indicated by either no symptom development or delayed symptoms for completely and partially resistant plants, respectively. Transgenic lines also produced more hydrogen peroxide due to pathogen infection and also had higher transcription of stress response genes encoding NPR1 , a defense response co-transcriptor, the antimicrobial PR-3 and glutathione S-transferase. However, transcription of PR-1 , an indicator for infection with a biotrophic pathogen, was not increased in both stacked and single transgenic lines, indicating a possible shift to infection with a necrotrophic pathogen in plants due to transgenes expression. Expression of stacked HRAP and PFLP genes in transgenic banana lines did not show higher or additive resistance levels against pathogen in comparison to individual genes; however, stacking might provide the benefit of durable resistance in case one transgene function is lost. [ABSTRACT FROM AUTHOR]

Published

2016