Novel throughput phenotyping platforms in plant genetic studies

被引:164
|
作者
Montes, Juan M. [1 ]
Melchinger, Albrecht E. [1 ]
Reif, Jochen C. [1 ]
机构
[1] Univ Hohenheim, Inst Plant Breeding Seed Sci & Populat Genet, D-70593 Stuttgart, Germany
来源
TRENDS IN PLANT SCIENCE | 2007年 / 12卷 / 10期
关键词
D O I
10.1016/j.tplants.2007.08.006
中图分类号
Q94 [植物学];
学科分类号
071001 ;
摘要
Unraveling the genetic basis of complex traits in plants is limited by the lack of appropriate phenotyping platforms that enable high-throughput screening of many genotypes in multilocation field trials. Near-infrared spectroscopy on agricultural harvesters and spectral reflectance of plant canopies have recently been reported as promising components of novel phenotyping platforms. Understanding the genetic basis of complex traits is now within reach with the use of these new techniques.
引用
收藏
页码:433 / 436
页数:4
相关论文
共 50 条
  • [1] Pitfalls and potential of high-throughput plant phenotyping platforms
    Poorter, Hendrik
    Hummel, Gregoire M.
    Nagel, Kerstin A.
    Fiorani, Fabio
    von Gillhaussen, Philipp
    Virnich, Olivia
    Schurr, Ulrich
    Postma, Johannes A.
    van de Zedde, Rick
    Wiese-Klinkenberg, Anika
    [J]. FRONTIERS IN PLANT SCIENCE, 2023, 14
  • [2] High throughput plant phenotyping in agriculture
    Ramya, K. T.
    Fiyaz, R. Abdul
    Ajay, B. C.
    [J]. CURRENT SCIENCE, 2013, 105 (04): : 434 - 435
  • [3] High-throughput phenotyping platforms for pulse crop biofortification
    Madurapperumage, Amod
    Naser, M. Z.
    Boatwright, Lucas
    Bridges, William
    Vandemark, George
    Thavarajah, Dil
    [J]. PLANTS PEOPLE PLANET, 2024,
  • [4] Roadmap to High Throughput Phenotyping for Plant Breeding
    Kim J.Y.
    [J]. Journal of Biosystems Engineering, 2020, 45 (1) : 43 - 55
  • [5] Methods of high-throughput plant phenotyping for large-scale breeding and genetic experiments
    D. A. Afonnikov
    M. A. Genaev
    A. V. Doroshkov
    E. G. Komyshev
    T. A. Pshenichnikova
    [J]. Russian Journal of Genetics, 2016, 52 : 688 - 701
  • [6] High-Throughput Phenotyping and QTL Mapping Reveals the Genetic Architecture of Maize Plant Growth
    Zhang, Xuehai
    Huang, Chenglong
    Wu, Di
    Qiao, Feng
    Li, Wenqiang
    Duan, Lingfeng
    Wang, Ke
    Xiao, Yingjie
    Chen, Guoxing
    Liu, Qian
    Xiong, Lizhong
    Yang, Wanneng
    Yan, Jianbing
    [J]. PLANT PHYSIOLOGY, 2017, 173 (03) : 1554 - 1564
  • [7] Heliaphen, an Outdoor High-Throughput Phenotyping Platform for Genetic Studies and Crop Modeling
    Gosseau, Florie
    Blanchet, Nicolas
    Vares, Didier
    Burger, Philippe
    Campergue, Didier
    Colombet, Celine
    Gody, Louise
    Lievin, Jean-Francois
    Mangin, Brigitte
    Tison, Gilles
    Vincourt, Patrick
    Casadebaig, Pierre
    Langlade, Nicolas
    [J]. FRONTIERS IN PLANT SCIENCE, 2019, 9
  • [8] Methods of high-throughput plant phenotyping for large-scale breeding and genetic experiments
    Afonnikov, D. A.
    Genaev, M. A.
    Doroshkov, A. V.
    Komyshev, E. G.
    Pshenichnikova, T. A.
    [J]. RUSSIAN JOURNAL OF GENETICS, 2016, 52 (07) : 688 - 701
  • [9] A Comprehensive Review of High Throughput Phenotyping and Machine Learning for Plant Stress Phenotyping
    Gill, Taqdeer
    Gill, Simranveer K.
    Saini, Dinesh K.
    Chopra, Yuvraj
    de Koff, Jason P.
    Sandhu, Karansher S.
    [J]. PHENOMICS, 2022, 2 (03): : 156 - 183
  • [10] A Comprehensive Review of High Throughput Phenotyping and Machine Learning for Plant Stress Phenotyping
    Taqdeer Gill
    Simranveer K. Gill
    Dinesh K. Saini
    Yuvraj Chopra
    Jason P. de Koff
    Karansher S. Sandhu
    [J]. Phenomics, 2022, 2 : 156 - 183
12345