Fast neutron-induced structural rearrangements at a soybean NAP1 locus result in gnarled trichomes

Campbell, Ben; Hofstad, Anna N.; Sreekanta, Suma; Fu, Fengli; Kono, Thomas J. Y.; O’Rourke, Jamie A.; Vance, Carroll P.; Muehlbauer, Gary J.; Stupar, Robert M.

doi:10.1007/s00122-016-2735-x

Cited by 40 publications

(43 citation statements)

References 91 publications

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“…of FN mutagenesis in case of reverse genetics techniques for polyploidy plant species such as wheat poses challenges due to high similarity amongst homoeologous loci [39]. Multiple complex chromosomal rearrangements result from FN mutagenesis and impede gene identification and isolation in crop plants [59]. Several strategies have been suggested to minimize the disadvantages of FN mutagenesis viz.…”

Section: Challenges For the Efficient Utilization Of Fn Mutagenesis Amentioning

confidence: 99%

Fast Neutron Mutagenesis in Plants: Advances, Applicability and Challenges

Kumawat¹,

Rana²,

Bansal³

et al. 2019

Preprint

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Fast neutron (FN) radiation mediated mutagenesis is a unique approach among the several induced mutagenesis methods being used in plant science in terms of impacted mutations. The FN mutagenesis usually creates deletions from a few bases to several million bases (Mb). A library of random deletion generated using FN mutagenesis lines can provide indispensable resources for the reverse genetic approaches. In this review, information from several efforts made using FN mutagenesis has been compiled to understand the type of induced mutations, frequency, and genetic stability. Concerns regarding the utilization of FN mutagenesis technique for a plant with different level of ploidy and genome complexity are discussed. We have highlighted the utility of next-generation sequencing techniques which can be efficiently utilized for the characterization of mutant lines as well as for the mapping of causal mutations. Pros and cons of Mut-map, MutChromSeq, exon capture, whole genome sequencing, MutRen-Seq, and different tilling approaches can be used for the detection of FN-induced mutation has also been discussed. Genomic resources developed using the FN mutagenesis have been catalogued wooing to meaningful utilization of the available resources. The information provided here will be helpful for the efficient exploration for the crop improvement programs and for better understanding of genetic regulations.

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Section: Challenges For the Efficient Utilization Of Fn Mutagenesis Amentioning

confidence: 99%

Fast Neutron Mutagenesis in Plants: Advances, Applicability and Challenges

Kumawat¹,

Rana²,

Bansal³

et al. 2019

Preprint

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“…Therefore, the samples from the F2 population, which were generated by Tartary buckwheat and rice-Tartary, were precious for BSA. The BSA method has been successfully used to detect candidate gene for vital phenotypic characteristics in many other major crops, such as maize [31], barley [32], soybean [33,34], cucumber [35], tomato [36], and chickpea [37]. In this study, an obvious and significant peak in the SNP-index plot for K21 and the final delta SNP-index indicate a single region underlying the easy dehulling in rice-Tartary.…”

Section: Discussionmentioning

confidence: 80%

Identification of Genetic Locus Underlying Easy Dehulling in Rice-Tartary for Easy Postharvest Processing of Tartary Buckwheat

Zhang

Liu

2020

Genes

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As a highly nutritious crop, Tartary buckwheat (Fagopyrum tartaricum) strongly adapts and grows in adverse environments and is widely grown in Asia. However, its flour contains a large proportion of the hull that adheres to the testa layer of the groats and is difficult to be removed in industrial processing. Fortunately, rice-Tartary, with the loose and non-adhering hull, provides potentiality of improving Tartary buckwheat that can dehull easily. Here, we performed high-throughput sequencing for two parents (Tartary buckwheat and rice-Tartary) and two pools (samples from the F2 population) and obtained 101 Gb raw sequencing data for further analysis. Sequencing reads were mapped to the reference genome of Tartary buckwheat, and a total of 633,256 unique SNPs and 270,181 unique indels were found in these four samples. Then, based on the Bulked Segregant Analysis (BSA), we identified a candidate genetic region, containing 45 impact SNPs/indels and 36 genes, that might underly non-adhering hull of rice-Tartary and should have value for breeding easy dehulling Tartary buckwheat.

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“…Genome‐wide sequencing can detect mutations in mutant populations and so identify candidate genes in forward genetic screens (Tsai et al ., ), but this depends on the availability of a reference genome sequence (Hwang et al ., ; Campbell et al ., ) which is not yet available for pea. Insertion mutagenesis can also tag genes facilitating their isolation (Schauser et al ., ; Tadege et al ., ; Urbański et al ., ), but in pea insertion mutagenesis is not available.…”

Section: Discussionmentioning

confidence: 99%

“…Analysis of soybean FN mutant populations has highlighted the advantages of other genome-wide approaches such as resequencing or array hybridization when a reference genome sequence is available (Hwang et al, 2015;Campbell et al, 2016); these two studies also emphasize that in some cases simple deletions may not be the most frequent type of mutation. In both of these cases genomic rearrangements rather than deletions were detected.…”

Section: New Phytologistmentioning

confidence: 99%

Identification of Stipules reduced, a leaf morphology gene in pea (Pisum sativum)

et al. 2018

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Pea (Pisum sativum) is one of relatively few genetically amenable plant species with compound leaves. Pea leaves have a variety of specialized organs: leaflets, tendrils, pulvini and stipules, which enable the identification of mutations that transform or affect distinct parts of the leaf. Characterization of these mutations offers insights into the development and evolution of novel leaf traits. The previously characterized morphological gene Cochleata, conferring stipule identity, was known to interact with Stipules reduced (St), which conditions stipule size in pea, but the St gene remained unknown. Here we analysed Fast Neutron irradiated pea mutants by restriction site associated DNA sequencing. We identified St as a gene encoding a C2H2 zinc finger transcription factor that is regulated by Cochleata. St regulates both cell division and cell expansion in the stipule. Our approach shows how systematic genome-wide screens can be used successfully for the analysis of traits in species for which whole genome sequences are not available.

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Fast neutron-induced structural rearrangements at a soybean NAP1 locus result in gnarled trichomes

Cited by 40 publications

References 91 publications

Fast Neutron Mutagenesis in Plants: Advances, Applicability and Challenges

Fast Neutron Mutagenesis in Plants: Advances, Applicability and Challenges

Identification of Genetic Locus Underlying Easy Dehulling in Rice-Tartary for Easy Postharvest Processing of Tartary Buckwheat

Identification of Stipules reduced, a leaf morphology gene in pea (Pisum sativum)

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