Defining durum wheat ideotypes adapted to Mediterranean environments through remote sensing traits

Adrian Gracia-Romero; Thomas Vatter; Shawn C Kefauver; Fatima Zahra Rezzouk; Joel Segarra; María Teresa Nieto-Taladriz; Nieves Aparicio; José Luis Araus

doi:10.3389/fpls.2023.1254301

Defining durum wheat ideotypes adapted to Mediterranean environments through remote sensing traits

Front Plant Sci. 2023 Sep 5:14:1254301. doi: 10.3389/fpls.2023.1254301. eCollection 2023.

Authors

Adrian Gracia-Romero¹, Thomas Vatter¹, Shawn C Kefauver¹, Fatima Zahra Rezzouk¹, Joel Segarra¹, María Teresa Nieto-Taladriz², Nieves Aparicio³, José Luis Araus¹

Affiliations

¹ Integrative Crop Ecophysiology Group, Plant Physiology Section, Faculty of Biology, University of Barcelona, Barcelona, Spain and AGROTECNIO (Center for Research in Agrotechnology), Lleida, Spain.
² Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (INIA), Madrid, Spain.
³ Agro-technological Institute of Castilla y León (ITACyL), Valladolid, Spain.

Abstract

An acceleration of the genetic advances of durum wheat, as a major crop for the Mediterranean region, is required, but phenotyping still represents a bottleneck for breeding. This study aims to define durum wheat ideotypes under Mediterranean conditions by selecting the most suitable phenotypic remote sensing traits among different ones informing on characteristics related with leaf pigments/photosynthetic status, crop water status, and crop growth/green biomass. A set of 24 post-green revolution durum wheat cultivars were assessed in a wide set of 19 environments, accounted as the specific combinations of a range of latitudes in Spain, under different management conditions (water regimes and planting dates), through 3 consecutive years. Thus, red-green-blue and multispectral derived vegetation indices and canopy temperature were evaluated at anthesis and grain filling. The potential of the assessed remote sensing parameters alone and all combined as grain yield (GY) predictors was evaluated through random forest regression models performed for each environment and phenological stage. Biomass and plot greenness indicators consistently proved to be reliable GY predictors in all of the environments tested for both phenological stages. For the lowest-yielding environment, the contribution of water status measurements was higher during anthesis, whereas, for the highest-yielding environments, better predictions were reported during grain filling. Remote sensing traits measured during the grain filling and informing on pigment content and photosynthetic capacity were highlighted under the environments with warmer conditions, as the late-planting treatments. Overall, canopy greenness indicators were reported as the highest correlated traits for most of the environments and regardless of the phenological moment assessed. The addition of carbon isotope composition of mature kernels was attempted to increase the accuracies, but only a few were slightly benefited, as differences in water status among cultivars were already accounted by the measurement of canopy temperature.

Keywords: UAV; canopy temperature; carbon isotope composition; highthroughput phenotyping; vegetation indices.

Grants and funding

We acknowledge the support of the Spanish project The correct project is PID2019-106650RB-C2, without the 1 at the end from the Ministerio de Ciencia e Innovación. AG-R is a recipient of a FPI doctoral fellowship from the same institution. We also acknowledge the support from the Institut de Recerca de l’Aigua and the Universitat de Barcelona. JA acknowledges support from the Institució Catalana de Inves-tigació i Estudis Avançats (ICREA) Academia, Generalitat de Catalunya, Spain.