Hyperspectral reflectance reveals critical leaf functional traits indicative of a plant's physiological status, providing a powerful tool for distinguishing seedlings adapted to specific environments. Current research explores intrapopulation variability and the necessity of high-throughput phenotyping (HTP) in forestry for selection of resilient genotypes under changing climatic conditions. However, challenges persist in managing large-scale phenotypic data and in the compatibility of reflectance data acquired from various measurement approaches.
In November 2023, Plant Phenomics published a research article entitled by “ Making the Genotypic Variation Visible: Hyperspectral Phenotyping in Scots Pine Seedlings ”.
This research utilized two non-destructive methods to measure hyperspectral reflectance on 1,788 Scots pine seedlings, distinguishing between lowland and upland ecotypes from the Czech Republic. Leaf level measurements were performed with a spectroradiometer and contact probe (CP) for biconical reflectance factor (BCRF) of needle samples, while proximal canopy measurements employed the same spectroradiometer with a fiber optical cable (OC) under natural light for hemispherical conical reflectance factor (HCRF). Results showed statistically significant differences among pine populations across the entire spectral range. Using machine learning algorithms, the proximal data predicted the different Scots pine populations with up to 83% accuracy.
Specifically, BCRF and HCRF indicated significant differences in pairwise comparisons among populations, particularly in visible (VIS) and near-infrared (NIR) regions. The most pronounced differences occurred in VIS and red edge (RE) for BCRF, while HCRF showed more variance in shortwave infrared (SWIR) regions. Both BCRF and HCRF data maintained similar trends across the very shortwave infrared (VSWIR) spectral range, with BCRF P values generally closer to zero than HCRF in many spectral intervals. Random Forest (RF) and Support Vector Machine (SVM) algorithms were employed to test the prediction accuracy of population origin based on reflectance factors. The highest accuracy was obtained from raw whole seedling HCRF. The importance of specific spectral regions for RF separation was evidenced by peaks in VIS and RE. HCRF displayed more spectral regions with high importance for RF prediction compared to BCRF, which was mainly limited to VIS and RE. This difference likely contributed to the higher prediction accuracy of RF models based on HCRF data.
The study concluded that both leaf-level BCRF and whole seedling HCRF are suitable for hyperspectral phenotyping to differentiate the phenotypic and genetic variation within Scots pine seedlings. Overall, these methods offer valuable tools for forestry and breeding programs, particularly for non-destructive genetic evaluation and effective nursery practices. Despite some limitations related to light conditions and measurement methods, the research demonstrated the potential of using hyperspectral reflectance and machine learning for accurate prediction and classification of tree populations in breeding and conservation efforts.
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References
Authors
Jan Stejskal 1* , Jaroslav Čepl 1 , Eva Neuwirthová 1,3, Olusegun Olaitan Akinyemi 1,2 , Jiří Chuchlík 1 , Daniel Provazník 1 , Markku Keinänen 2,4 , Petya Campbell 5,6 , Jana Albrechtová 3 , Milan Lstibůrek 1 , and Zuzana Lhotáková 3
Affiliations
1 Department of Genetics and Physiology of Forest Trees, Faculty of Forestry and Wood Sciences, Czech University of Life Sciences Prague, Prague, Czech Republic.
2 Department of Environmental and Biological Sciences, University of Eastern Finland, Joensuu, Finland.
3 Department of Experimental Plant Biology, Charles University, Prague, Czech Republic.
4 Center for Photonic Sciences, University of Eastern Finland, Joensuu, Finland.
5 Department of Geography and Environmental Sciences, University of Maryland Baltimore County, Baltimore, MD, USA.
6 Biospheric Sciences Laboratory, NASA Goddard Space Flight Center, Greenbelt, MD, USA.
About Jan Stejskal
He is a researcher in the Department of Genetics and Physiology of Forest Trees at Czech University of Life Sciences Prague. The domain of Dr. Jan Stejskal is the statistical evaluation of complex experiments with the connection of physiological and genetic data. His research includes the design and evaluation of comparative experiments based on growth and physiological traits. He currently focuses on evaluating adaptive traits of selected populations (fertility, phenology, etc.) to test the usability of genetic correlations between physiological, adaptive, and production traits.
Plant Phenomics
Experimental study
Not applicable
Making the Genotypic Variation Visible: Hyperspectral Phenotyping in Scots Pine Seedlings
14-Nov-2023
The authors declare that they have no competing interests.