Deep machine learning for cell segmentation and quantitative analysis of radial plant growth

IF 3.9 4区 生物学 Q4 Biochemistry, Genetics and Molecular Biology
Alexandra Zakieva , Lorenzo Cerrone , Thomas Greb
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Abstract

Plants produce the major part of terrestrial biomass and are long-term deposits of atmospheric carbon. This capacity is to a large extent due to radial growth of woody species – a process driven by cambium stem cells located in distinct niches of shoot and root axes. In the model species Arabidopsis thaliana, thousands of cells are produced by the cambium in radial orientation generating a complex organ anatomy enabling long-distance transport, mechanical support and protection against biotic and abiotic stressors. These complex organ dynamics make a comprehensive and unbiased analysis of radial growth challenging and asks for tools for automated quantification. Here, we combined the recently developed PlantSeg and MorphographX image analysis tools, to characterize tissue morphogenesis of the Arabidopsis hypocotyl. After sequential training of segmentation models on ovules, shoot apical meristems and adult hypocotyls using deep machine learning, followed by the training of cell type classification models, our pipeline segments complex images of transverse hypocotyl sections with high accuracy and classifies central hypocotyl cell types. By applying our pipeline on both wild type and phloem intercalated with xylem (pxy) mutants, we also show that this strategy faithfully detects major anatomical aberrations. Collectively, we conclude that our established pipeline is a powerful phenotyping tool comprehensively extracting cellular parameters and providing access to tissue topology during radial plant growth.

植物径向生长的细胞分割和定量分析的深度机器学习
植物产生陆地生物量的主要部分,是大气碳的长期沉积物。这种能力在很大程度上是由于木本物种的径向生长——这一过程是由位于茎轴和根轴不同生态位的形成层干细胞驱动的。在模式物种拟南芥中,形成层以径向产生数千个细胞,产生复杂的器官解剖结构,实现远距离运输、机械支持和抵御生物和非生物压力。这些复杂的器官动力学使得对放射状生长进行全面而公正的分析具有挑战性,并需要自动化量化的工具。在这里,我们结合了最近开发的PlantSeg和MorphographX图像分析工具,来表征拟南芥下胚轴的组织形态发生。在使用深度机器学习对胚珠、茎尖分生组织和成体下胚轴的分割模型进行顺序训练,然后对细胞类型分类模型进行训练后,我们的流水线高精度地对横下胚轴切片的复杂图像进行分割,并对中央下胚轴细胞类型进行分类。通过将我们的管道应用于野生型和插入木质部(pxy)突变体的韧皮部,我们还表明这种策略可以忠实地检测主要的解剖畸变。总之,我们得出的结论是,我们建立的管道是一种强大的表型工具,可以全面提取细胞参数,并在径向植物生长过程中提供组织拓扑结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Cells and Development
Cells and Development Biochemistry, Genetics and Molecular Biology-Developmental Biology
CiteScore
2.90
自引率
0.00%
发文量
33
审稿时长
41 days
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