A <scp>COMPASS</scp> histone <scp>H3K4</scp> trimethyltransferase pentamer transactivates drought tolerance and growth/biomass production in <i>Populus trichocarpa</i>

Zhang, Baofeng; Wang, Zhuwen; Dai, Xiufang; Gao, Jinghui; Zhao, Jinfeng; Ma, Rong; Chen, Yanjie; Sun, Yi; Ma, Hongyan; Li, Shuang; Zhou, Chenguang; Wang, Jack P.; Li, Wei

doi:10.1111/nph.19481

Cited by 2 publications

(1 citation statement)

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“…These plant stress factors prompt us to explore innovative technologies for ensuring the growth and ultimate yield of plants. To overcome the challenges of drought stress in poplar plants, there are 2 typical solutions: improving plant management (e.g., water deficiency plant detection) and improving plants (e.g., cultivation of drought-resistant poplar varieties) [ 9 , 10 ]. Under traditional planting methods, the discrimination of water-deficient plants or the screening of drought-resistant varieties rely on manual monitoring.…”

Section: Introductionmentioning

confidence: 99%

Phenotyping of Drought-Stressed Poplar Saplings Using Exemplar-Based Data Generation and Leaf-Level Structural Analysis

Zhou,

Zhang,

Bian

et al. 2024

Plant Phenomics

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Drought stress is one of the main threats to poplar plant growth and has a negative impact on plant yield. Currently, high-throughput plant phenotyping has been widely studied as a rapid and nondestructive tool for analyzing the growth status of plants, such as water and nutrient content. In this study, a combination of computer vision and deep learning was used for drought-stressed poplar sapling phenotyping. Four varieties of poplar saplings were cultivated, and 5 different irrigation treatments were applied. Color images of the plant samples were captured for analysis. Two tasks, including leaf posture calculation and drought stress identification, were conducted. First, instance segmentation was used to extract the regions of the leaf, petiole, and midvein. A dataset augmentation method was created for reducing manual annotation costs. The horizontal angles of the fitted lines of the petiole and midvein were calculated for leaf posture digitization. Second, multitask learning models were proposed for simultaneously determining the stress level and poplar variety. The mean absolute errors of the angle calculations were 10.7° and 8.2° for the petiole and midvein, respectively. Drought stress increased the horizontal angle of leaves. Moreover, using raw images as the input, the multitask MobileNet achieved the highest accuracy (99% for variety identification and 76% for stress level classification), outperforming widely used single-task deep learning models (stress level classification accuracies of <70% on the prediction dataset). The plant phenotyping methods presented in this study could be further used for drought-stress-resistant poplar plant screening and precise irrigation decision-making.

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Section: Introductionmentioning

confidence: 99%