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FIND-IT：绿色进化的加速性状发展。

FIND-IT: Accelerated trait development for a green evolution.

作者信息

Knudsen Søren, Wendt Toni, Dockter Christoph, Thomsen Hanne Cecilie, Rasmussen Magnus, Egevang Jørgensen Morten, Lu Qiongxian, Voss Cynthia, Murozuka Emiko, Østerberg Jeppe Thulin, Harholt Jesper, Braumann Ilka, Cuesta-Seijo Jose A, Kale Sandip M, Bodevin Sabrina, Tang Petersen Lise, Carciofi Massimiliano, Pedas Pai Rosager, Opstrup Husum Jeppe, Nielsen Martin Toft Simmelsgaard, Nielsen Kasper, Jensen Mikkel K, Møller Lillian Ambus, Gojkovic Zoran, Striebeck Alexander, Lengeler Klaus, Fennessy Ross T, Katz Michael, Garcia Sanchez Rosa, Solodovnikova Natalia, Förster Jochen, Olsen Ole, Møller Birger Lindberg, Fincher Geoffrey B, Skadhauge Birgitte

机构信息

Carlsberg Research Laboratory, J.C. Jacobsens Gade 4, DK-1799 Copenhagen V, Denmark.

Plant Biochemistry Laboratory, Centre for Synthetic Biology, Department of Plant and Environmental Sciences, University of Copenhagen, Thorvaldsensvej 40, DK-1871 Frederiksberg C, Denmark.

出版信息

Sci Adv. 2022 Aug 26;8(34):eabq2266. doi: 10.1126/sciadv.abq2266. Epub 2022 Aug 24.

DOI:10.1126/sciadv.abq2266

PMID:36001660

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9401622/

Abstract

Improved agricultural and industrial production organisms are required to meet the future global food demands and minimize the effects of climate change. A new resource for crop and microbe improvement, designated FIND-IT (Fast Identification of Nucleotide variants by droplet DigITal PCR), provides ultrafast identification and isolation of predetermined, targeted genetic variants in a screening cycle of less than 10 days. Using large-scale sample pooling in combination with droplet digital PCR (ddPCR) greatly increases the size of low-mutation density and screenable variant libraries and the probability of identifying the variant of interest. The method is validated by screening variant libraries totaling 500,000 barley () individuals and isolating more than 125 targeted barley gene knockout lines and miRNA or promoter variants enabling functional gene analysis. FIND-IT variants are directly applicable to elite breeding pipelines and minimize time-consuming technical steps to accelerate the evolution of germplasm.

摘要

为满足未来全球粮食需求并尽量减少气候变化的影响，需要改良农业和工业生产生物。一种用于作物和微生物改良的新资源，称为FIND-IT（通过液滴数字PCR快速鉴定核苷酸变体），可在不到10天的筛选周期内超快速鉴定和分离预定的目标遗传变体。将大规模样本合并与液滴数字PCR（ddPCR）相结合，大大增加了低突变密度和可筛选变体文库的规模以及鉴定感兴趣变体的概率。该方法通过筛选总计500,000个大麦个体的变体文库并分离出125多个靶向大麦基因敲除系以及能够进行功能基因分析的miRNA或启动子变体进行了验证。FIND-IT变体可直接应用于优良育种流程，并尽量减少耗时的技术步骤，以加速种质进化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/08f8/9401622/da1ffe7ea1ff/sciadv.abq2266-f1.jpg

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FIND-IT：绿色进化的加速性状发展。

FIND-IT: Accelerated trait development for a green evolution.

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