Browsing by Author "Gonzalez-Martinez, Luis"

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    Spectral reflectance modeling by wavelength Selection : studying the scope for blueberry physiological breeding under contrasting water supply and heat conditions
    (MDPI, 2019) Lobos, Gustavo A.; Escobar-Opazo, Alejandro; Estrada, Felix; Romero-Bravo, Sebastian; Garriga, Miguel; del Pozo, Alejandro; Poblete-Echeverria, Carlos; Gonzalez-Talice, Jaime; Gonzalez-Martinez, Luis; Caligari, Peter
    To overcome the environmental changes occurring now and predicted for the future, it is essential that fruit breeders develop cultivars with better physiological performance. During the last few decades, high-throughput plant phenotyping and phenomics have been developed primarily in cereal breeding programs. In this study, plant reflectance, at the level of the leaf, was used to assess several physiological traits in five Vaccinium spp. cultivars growing under four controlled conditions (no-stress, water deficit, heat stress, and combined stress). Two modeling methodologies [Multiple Linear Regression (MLR) and Partial Least Squares (PLS)] with or without (W/O) prior wavelength selection (multicollinearity, genetic algorithms, or in combination) were considered. PLS generated better estimates than MLR, although prior wavelength selection improved MLR predictions. When data from the environments were combined, PLS W/O gave the best assessment for most of the traits, while in individual environments, the results varied according to the trait and methodology considered. The highest validation predictions were obtained for chlorophyll a/b (R²Val ≤ 0.87), maximum electron transport rate (R²Val ≤ 0.60), and the irradiance at which the electron transport rate is saturated (R²Val ≤ 0.59). The results of this study, the first to model modulated chlorophyll fluorescence by reflectance, confirming the potential for implementing this tool in blueberry breeding programs, at least for the estimation of a number of important physiological traits. Additionally, the differential effects of the environment on the spectral signature of each cultivar shows this tool could be directly used to assess their tolerance to specific environments.
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    Thermal imaging reliability for estimating grain yield and carbon isotope discrimination in wheat genotypes : importance of the environmental conditions
    (MDPI, 2019-06-13) Romero-Bravo, Sebastian; Mendez-Espinoza, Ana Maria; Garriga, Miguel; Estrada, Felix; Escobar, Alejandro; Gonzalez-Martinez, Luis; Poblete-Echeverria, Carlos; Sepulveda, Daniel; Matus, Ivan; Castillo, Dalma; del Pozo, Alejandro; Lobos, Gustavo A.
    Canopy temperature (Tc) by thermal imaging is a useful tool to study plant water status and estimate other crop traits. This work seeks to estimate grain yield (GY) and carbon discrimination (Δ13C) from stress degree day (SDD = Tc − air temperature, Ta), considering the effect of a number of environmental variables such as the averages of the maximum vapor pressure deficit (VPDmax) and the ambient temperature (Tmax), and the soil water content (SWC). For this, a set of 384 and a subset of 16 genotypes of spring bread wheat were evaluated in two Mediterranean-climate sites under water stress (WS) and full irrigation (FI) conditions, in 2011 and 2012, and 2014 and 2015, respectively. The relationship between the GY of the 384 wheat genotypes and SDD was negative and highly significant in 2011 (r2 = 0.52 to 0.68), but not significant in 2012 (r2 = 0.03 to 0.12). Under WS, the average GY, Δ13C, and SDD of wheat genotypes growing in ten environments were more associated with changes in VPDmax and Tmax than with the SWC. Therefore, the amount of water available to the plant is not enough information to assume that a particular genotype is experiencing a stress condition.