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5. Expanding the scope of plant genome engineering with Cas12a orthologs and highly multiplexable editing systems

Author

Zhang, Yingxiao, Ren, Qiurong, Tang, Xu, Liu, Shishi, Malzahn, Aimee A., Zhou, Jianping, Wang, Jiaheng, Yin, Desuo, Pan, Changtian, Yuan, Mingzhu, Huang, Lan, Yang, Han, Zhao, Yuxin, Fang, Qing, Zheng, Xuelian, Tian, Li, Cheng, Yanhao, Le, Ysa, McCoy, Bailey, Franklin, Lidiya, Selengut, Jeremy D., Mount, Stephen M., Que, Qiudeng, Zhang, Yong, and Qi, Yiping

Published
2021
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10. Elite, transformable haploid inducers in maize

Author

Delzer, Brent, Liang, Dawei, Szwerdszarf, David, Rodriguez, Isadora, Mardones, Gonzalo, Elumalai, Sivamani, Johnson, Francine, Nalapalli, Samson, Egger, Rachel, Burch, Erin, Meier, Kerry, Wei, Juan, Zhang, Xiujuan, Gui, Huaping, Jin, Huaibing, Guo, Huan, Yu, Kun, Liu, Yubo, Breitinger, Becky, Poets, Ana, Nichols, Jason, Shi, Wan, Skibbe, David, Que, Qiudeng, and Kelliher, Timothy

Published
2024
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14. Advances in Agrobacterium-mediated Maize Transformation

Author

Zhong, Heng, primary, Elumalai, Sivamani, additional, Nalapalli, Samson, additional, Richbourg, Lee, additional, Prairie, Anna, additional, Bradley, David, additional, Dong, Shujie, additional, Su, Xiujuan Jenny, additional, Gu, Weining, additional, Strebe, Tim, additional, Shi, Liang, additional, and Que, Qiudeng, additional

Published
2017
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17. Rice RS2‐9 , which is bound by transcription factor OSH1, blocks enhancer–promoter interactions in plants

Author

Liu, Huawei, primary, Jiang, Li, additional, Wen, Zhifeng, additional, Yang, Yingjun, additional, Singer, Stacy D., additional, Bennett, Dennis, additional, Xu, Wenying, additional, Su, Zhen, additional, Yu, Zhifang, additional, Cohn, Jonathan, additional, Chae, Hyunsook, additional, Que, Qiudeng, additional, Liu, Yue, additional, Liu, Chang, additional, and Liu, Zongrang, additional

Published
2021
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18. Efficient Targeted Mutagenesis Mediated by CRISPR-Cas12a Ribonucleoprotein Complexes in Maize

Author

Dong, Shujie, primary, Qin, Yinping Lucy, additional, Vakulskas, Christopher A., additional, Collingwood, Michael A., additional, Marand, Mariam, additional, Rigoulot, Stephen, additional, Zhu, Ling, additional, Jiang, Yaping, additional, Gu, Weining, additional, Fan, Chunyang, additional, Mangum, Anna, additional, Chen, Zhongying, additional, Yarnall, Michele, additional, Zhong, Heng, additional, Elumalai, Sivamani, additional, Shi, Liang, additional, and Que, Qiudeng, additional

Published
2021
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21. Rice RS2‐9, which is bound by transcription factor OSH1, blocks enhancer–promoter interactions in plants.

Author

Liu, Huawei, Jiang, Li, Wen, Zhifeng, Yang, Yingjun, Singer, Stacy D., Bennett, Dennis, Xu, Wenying, Su, Zhen, Yu, Zhifang, Cohn, Jonathan, Chae, Hyunsook, Que, Qiudeng, Liu, Yue, Liu, Chang, and Liu, Zongrang

Subjects
TRANSCRIPTION factors, RICE, TOBACCO, BINDING sites, GENETIC regulation
Abstract

SUMMARY: Insulators characterized in Drosophila and mammals have been shown to play a key role in the restriction of promiscuous enhancer–promoter interactions, as well as reshaping the topological landscape of chromosomes. Yet the role of insulators in plants remains poorly understood, in large part because of a lack of well‐characterized insulators and binding factor(s). In this study, we isolated a 1.2‐kb RS2‐9 insulator from the Oryza sativa (rice) genome that can, when interposed between an enhancer and promoter, efficiently block the activation function of both constitutive and floral organ‐specific enhancers in transgenic Arabidopsis and Nicotiana tabacum (tobacco). In the rice genome, the genes flanking RS2‐9 exhibit an absence of mutual transcriptional interactions, as well as a lack of histone modification spread. We further determined that O. sativa Homeobox 1 (OSH1) bound two regions of RS2‐9, as well as over 50 000 additional sites in the rice genome, the majority of which resided in intergenic regions. Mutation of one of the two OSH1‐binding sites in RS2‐9 impaired insulation activity by up to 60%, whereas the mutation of both binding sites virtually abolished insulator function. We also demonstrated that OSH1 binding sites were associated with 72% of the boundaries of topologically associated domains (TADs) identified in the rice genome, which is comparable to the 77% of TAD boundaries bound by the insulator CCCTC‐binding factor (CTCF) in mammals. Taken together, our findings indicate that OSH1‐RS2‐9 acts as a true insulator in plants, and highlight a potential role for OSH1 in gene insulation and topological organization in plant genomes. Significance Statement: The role of insualtor in the regulation of enhancer‐promoter interaction and topological architecture of genomes has been well characterized in mammals but rarely in plants largely due to a lack of a true insualtor. We report the isolation and characterization of an insualtor from rice genome and its binding protein prominently associated with the boundaries of chromatin loops. Our findings are of significance in understanding the insualtor‐based gene regulation and genome demarcation in plants [ABSTRACT FROM AUTHOR]

Published
2022
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24. Maize transformation technology development for commercial event generation

Author

Que, Qiudeng, primary, Elumalai, Sivamani, additional, Li, Xianggan, additional, Zhong, Heng, additional, Nalapalli, Samson, additional, Schweiner, Michael, additional, Fei, Xiaoyin, additional, Nuccio, Michael, additional, Kelliher, Timothy, additional, Gu, Weining, additional, Chen, Zhongying, additional, and Chilton, Mary-Dell M., additional

Published
2014
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26. Molecular studies of Chlorella virus DNA and protein modifications

Author

Que, Qiudeng and Que, Qiudeng

Abstract

Chlorella virus SC-1A encodes at least seven genes related to DNA restriction-modification, including four sequence-specific $\rm N\sp6$-adenine methyltransferases (M.CviSI-SIV), one cytosine methyltransferase (M.CviSV), one endonuclease (R.CviSIII), and one methyltransferase pseudogene. Genes encoding the three methyltransferases, M.CviSI, M.CviSII, and M.CviSIII, were cloned, sequenced, and mapped. The three methyltransferase genes were scattered throughout SC-1A genome. The predicted amino acid sequences of M.CviSI (TGC$\sp{\rm m}$A) and M.CviSIII (TCG$\sp{\rm m}$A) were compared to their isomethylomers; some important sequence motifs are conserved among Chlorella isomethylomers. The sequences of M.CviSII (C$\sp{\rm m}$ATG) and its promoter region were almost identical to those of its isomethylomer M.CviAII (C$\sp{\rm m}$ATG) from virus PBCV-1. Sequencing of a SC-1A genomic fragment revealed the presence of a gene with strong homology with eukaryotic serine/threonine specific protein kinases. The homologous gene from virus PBCV-1 was also cloned and sequenced. The predicted amino acid sequence of the protein kinases from PBCV-1 and SC-1A has 94% identity. Both Chlorella protein kinases contain all the highly conserved motifs present in all eukaryotic serine/threonine specific protein kinases. The Chlorella virus protein kinase was overexpressed in E.coli. Protein kinase activity was restored from the denatured inclusion body by in vitro folding. Both SC-1A and PBCV-1 package protein kinase activity(ies) into their virion. Chlorella virus PBCV-1 contains three glycoproteins, the major capsid protein Vp54 and two minor proteins Vp280 and Vp260. The oligosaccharide(s) are apparently attached via an O-linkage. Vp54, along with two other viral proteins (Vp51 and Vp27.5), are labeled with myristic acid via an amide linkage. The carboxyl-terminal 33 kDa cyanogen bromide cleavage fragment of Vp54 contains both myristylation and glycosylation sites. The putative gene enco

Published
1993

29. CRISPR/LbCas12a-Mediated Genome Editing in Soybean.

Author

Liang D, Liu Y, Li C, Wen Q, Xu J, Geng L, Liu C, Jin H, Gao Y, Zhong H, Dawson J, Tian B, Barco B, Su X, Dong S, Li C, Elumalai S, Que Q, Jepson I, and Shi L

Subjects
Glycine max genetics, Glycine max metabolism, Endonucleases genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Genome, Plant genetics, Gene Editing methods, CRISPR-Cas Systems genetics
Abstract

Currently methods for generating soybean edited lines are time-consuming, inefficient, and limited to certain genotypes. Here we describe a fast and highly efficient genome editing method based on CRISPR-Cas12a nuclease system in soybean. The method uses Agrobacterium-mediated transformation to deliver editing constructs and uses aadA or ALS genes as selectable marker. It only takes about 45 days to obtain greenhouse-ready edited plants at higher than 30% transformation efficiency and 50% editing rate. The method is applicable to other selectable markers including EPSPS and has low transgene chimera rate. The method is also genotype-flexible and has been applied to genome editing of several elite soybean varieties., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2023
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30. Automated, High-Throughput Protoplast Transfection for Gene Editing and Transgene Expression Studies.

Author

Rigoulot SB, Barco B, Zhang Y, Zhang C, Meier KA, Moore M, Fabish J, Whinna R, Park J, Seaberry EM, Gopalan A, Dong S, Chen Z, and Que Q

Subjects
Transfection, Transgenes, Plant Leaves genetics, Protoplasts metabolism, Gene Editing
Abstract

In an era of cost-efficient gene synthesis and high-throughput construct assembly, the onus of scientific experimentation is on the rate of in vivo testing for the identification of top performing candidates or designs. Assay platforms that are relevant to the species of interest and in the tissue of choice are highly desirable. A protoplast isolation and transfection method that is compatible with a large repertoire of species and tissues would be the platform of choice. A necessary aspect of this high-throughput screening approach is the need to handle many delicate protoplast samples at the same time, which is a bottleneck for manual operation. Such bottlenecks can be mitigated with the use of automated liquid handlers for the execution of protoplast transfection steps. The method described within this chapter utilizes a 96-well head for simultaneous, high-throughput initiation of transfection. While initially developed and optimized for use with etiolated maize leaf protoplasts, the automated protocol has also been demonstrated to be compatible with other established protoplast systems, such as soybean immature embryo derived protoplast, similarly described within. This chapter also includes instructions for a sample randomization design to reduce the impact of edge effects, which might be present when microplates are used for fluorescence readout following transfection. We also describe a streamlined, expedient, and cost-effective protocol for determining gene editing efficiencies using the T7E1 endonuclease cleavage assay with a publicly available image analysis tool., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2023
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31. Morphogenic Regulators and Their Application in Improving Plant Transformation.

Author

Nalapalli S, Tunc-Ozdemir M, Sun Y, Elumalai S, and Que Q

Subjects
Biotechnology, Crops, Agricultural genetics, Genetic Vectors, Plants, Genetically Modified genetics, Crops, Agricultural growth & development, Plant Development, Plant Proteins genetics, Plant Somatic Embryogenesis Techniques methods, Plants, Genetically Modified growth & development, Transformation, Genetic
Abstract

Generation of plant lines with transgene or edited gene variants is the desired outcome of transformation technology. Conventional DNA-based plant transformation methods are the most commonly used technology but these approaches are limited to a small number of plant species with efficient transformation systems. The ideal transformation technologies are those that allow biotechnology applications across wide genetic background, especially within elite germplasm of major crop species. This chapter will briefly review key regulatory genes involved in plant morphogenesis with a focus on in vitro somatic embryogenesis and their application in improving plant transformation.

Published
2021
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32. Plant DNA Repair Pathways and Their Applications in Genome Engineering.

Author

Que Q, Chen Z, Kelliher T, Skibbe D, Dong S, and Chilton MD

Subjects
DNA Breaks, Double-Stranded, DNA End-Joining Repair genetics, DNA End-Joining Repair physiology, DNA Repair genetics, DNA Repair physiology, Gene Editing, Genetic Engineering, Genome, Plant genetics, DNA, Plant genetics
Abstract

Remarkable progress in the development of technologies for sequence-specific modification of primary DNA sequences has enabled the precise engineering of crops with novel characteristics. These programmable sequence-specific modifiers include site-directed nucleases (SDNs) and base editors (BEs). Currently, these genome editing machineries can be targeted to specific chromosomal locations to induce sequence changes. However, the sequence mutation outcomes are often greatly influenced by the type of DNA damage being generated, the status of host DNA repair machinery, and the presence and structure of DNA repair donor molecule. The outcome of sequence modification from repair of DNA double-strand breaks (DSBs) is often uncontrollable, resulting in unpredictable sequence insertions or deletions of various sizes. For base editing, the precision of intended edits is much higher, but the efficiency can vary greatly depending on the type of BE used or the activity of the endogenous DNA repair systems. This article will briefly review the possible DNA repair pathways present in the plant cells commonly used for generating edited variants for genome engineering applications. We will discuss the potential use of DNA repair mechanisms for developing and improving methodologies to enhance genome engineering efficiency and to direct DNA repair processes toward the desired outcomes.

Published
2019
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33. Repurposing Macromolecule Delivery Tools for Plant Genetic Modification in the Era of Precision Genome Engineering.

Author

Que Q, Chilton MM, Elumalai S, Zhong H, Dong S, and Shi L

Subjects
Agrobacterium genetics, Biotechnology instrumentation, Biotechnology methods, Gene Editing instrumentation, Gene Editing trends, Genetic Engineering instrumentation, Genetic Engineering trends, Plants, Genetically Modified genetics, Transformation, Genetic, Gene Editing methods, Gene Transfer Techniques, Genetic Engineering methods, Genome, Plant genetics
Abstract

Efficient delivery of macromolecules into plant cells and tissues is important for both basic research and biotechnology product applications. In transgenic research, the goal is to deliver DNA molecules into regenerable cells and stably integrate them into the genome. Over the past 40 years, many macromolecule delivery methods have been studied. To generate transgenic plants, particle bombardment and Agrobacterium-mediated transformation are the methods of choice for DNA delivery. The rapid advance of genome editing technologies has generated new requirements on large biomolecule delivery and at the same time reinvigorated the development of new transformation technologies. Many of the gene delivery options that have been studied before are now being repurposed for delivering genome editing machinery for various applications. This article reviews the major progress in the development of tools for large biomolecule delivery into plant cells in the new era of precision genome engineering.

Published
2019
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34. Advances in Agrobacterium-mediated Maize Transformation.

Author

Zhong H, Elumalai S, Nalapalli S, Richbourg L, Prairie A, Bradley D, Dong S, Su XJ, Gu W, Strebe T, Shi L, and Que Q

Subjects
Plants, Genetically Modified embryology, Plants, Genetically Modified microbiology, Transgenes, Zea mays embryology, Zea mays microbiology, Agrobacterium tumefaciens physiology, Gene Transfer Techniques, Mannose-6-Phosphate Isomerase genetics, Plants, Genetically Modified genetics, Transformation, Genetic, Zea mays genetics
Abstract

One of the major limitations of maize transformation is the isolation of a large number of immature embryos using the time-consuming manual extraction method. In this article, we describe a novel bulk embryo extraction method for fast isolation of a large number of embryos suitable for both biolistic- and Agrobacterium-mediated transformation. Optimal gene delivery and tissue culture conditions are also described for achieving high efficiency in Agrobacterium-mediated maize transformation using phosphomannose isomerase (PMI) as a selectable marker.

Published
2018
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35. Research note: Maternally-controlled ovule abortion results from cosuppression of dihydroflavonol-4-reductase or flavonoid-3',5'-hydroxylase genes in Petunia hybrida.

Author

Jorgensen RA, Que Q, and Napoli CA

Abstract

Transgenes designed to overexpress anthocyanin genes An6 (encoding dihydroflavonol-4-reductase) or Hf1 (encoding flavonoid-3',5'-hydroxylase) in Petunia hybrida L. produced flower colour phenotypes similar to those caused by sense cosuppression of chalcone synthase (Chs) genes. However, unlike Chs, sense cosuppression of An6 and Hf1 resulted in female infertility in transgenotes exhibiting complete phenotypic suppression of anthocyanins. Female sterility appeared to be due to embryo abortion, with discolouration of ovules first appearing about 4 d post-fertilization, followed by gradual collapse of the ovule. Pollen from cosuppressed, female-sterile transgenotes placed on wild-type stigmas produced normal seed set, indicating that sterility of cosuppressed plants was maternally controlled. We suggest an hypothesis that cosuppression of An6 and Hf1 leads to accumulation of dihydroflavonols in the seed coat, a maternal tissue, and that this accumulation inhibits embryo growth, either directly or indirectly. In this hypothesis, direct inhibition of embryo growth would require that dihydroflavonols diffuse from the seed coat into the embryo and act there, whereas indirect inhibition would require that dihydroflavonols interfere with some capacity of the seed coat to promote embryo growth.

Published
2002
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