Early or late? The role of genotype phenology in determining wheat response to drought under future high atmospheric CO2 levels

Duo Jiang; Gabriel Mulero; David J Bonfil; David Helman

doi:10.1111/pce.14430

Early or late? The role of genotype phenology in determining wheat response to drought under future high atmospheric CO₂ levels

Plant Cell Environ. 2022 Dec;45(12):3445-3461. doi: 10.1111/pce.14430. Epub 2022 Sep 27.

Authors

Duo Jiang¹, Gabriel Mulero¹, David J Bonfil², David Helman^{1

3}

Affiliations

¹ Department of Soil & Water Sciences, Institute of Environmental Sciences, The Robert H. Smith Faculty of Agriculture, Food and Environment, The Hebrew University of Jerusalem, Rehovot, Israel.
² Department of Vegetable and Field Crop Research, Agricultural Research Organization, Gilat Research Center, Gilat, Israel.
³ The Advanced School for Environmental Studies, The Hebrew University of Jerusalem, Jerusalem, Israel.

Abstract

The combination of a future rise in atmospheric carbon dioxide concentration ([CO₂ ]) and drought will significantly impact wheat production and quality. Genotype phenology is likely to play an essential role in such an effect. Yet, its response to elevated [CO₂ ] and drought has not been studied before. Here we conducted a temperature-controlled glasshouse [CO₂ ] enrichment experiment in which two wheat cultivars with differing maturity timings and life cycle lengths were grown under ambient (aCO₂ approximately 400 μmol mol^-1 ) and elevated (eCO₂ approximately 550 μmol mol^-1 ) [CO₂ ]. The two cultivars, bred under dry and warm Mediterranean conditions, were well-watered or exposed to drought at 40% pot holding capacity. We aimed to explore water × [CO₂ ] × genotype interaction in terms of phenology, physiology, and agronomic trait response. Our results show that eCO₂ had a significant effect on plants grown under drought. eCO₂ boosted the booting stage of the late-maturing genotype (cv. Ruta), thereby prolonging its booting-to-anthesis period by approximately 3 days (p < 0.05) while unaffecting the phenological timing of the early-maturing genotype (cv. Zahir). The prolonged period resulted in a much higher carbon assimilation rate, particularly during pre-anthesis (+87% for Ruta vs. +22% for Zahir under eCO₂ ). Surprisingly, there was no eCO₂ effect on transpiration rate and grain protein content in both cultivars and under both water conditions. The higher photosynthesis (and transpiration efficiency) of Ruta was not translated into higher aboveground biomass or grain yield, whereas both cultivars showed a similar increase of approximately 20% in these two traits at eCO₂ under drought. Overall, Zahir, the cultivar that responded the least to eCO_2, had a more efficient source-to-sink balance with a lower sink limitation than Ruta. The complex water × [CO₂ ] × genotype interaction found in this study implies that future projections should account for multifactor interactive effects in modeling wheat response to future climate.

Keywords: CO2; cultivar; drought; genotype phenology; wheat; yield.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Carbon Dioxide / metabolism
Droughts*
Genotype
Triticum* / genetics
Triticum* / metabolism
Water

Substances

Carbon Dioxide
Water