Litcius/Paper detail

High night temperature during maize post‐flowering increases night respiration and reduces photosynthesis, growth and kernel number

Belén Araceli Kettler, Constanza S. Carrera, Federico David Nalli Sonzogni, Samuel Trachsel, Fernando H. Andrade, Nicolás Neiff

2022Journal of Agronomy and Crop Science36 citationsDOIOpen Access PDF

Abstract

Abstract In the last years globally, daily night‐time low temperatures have increased more than twice compared with maximum temperatures. There is little evidence about maize growth and yield responses to high night temperature (HNT) under field conditions. In this study, we aimed to (i) evaluate the effect of HNT during post‐flowering on kernel number (KN), crop growth rate expressed in chronological days and thermal units (CGR D and CGR TU , respectively), radiation use efficiency (RUE), night respiration (Rn), net photosynthesis (Amax), chlorophyll fluorescence and cell membrane stability (CMS), and (ii) identify associations among the measured physiological traits. Two hybrids (Te, temperate; and St, subtropical) were exposed to two thermal conditions from R1 + 2d to R1 + 16d: (i) HNT from 1900 to 0700 h, and (ii) ambient night temperature (ANT). The HNT resulted in reductions in KN (8%), CGR D (11%), and CGR TU (19%), with non‐significant changes in kernel weight and grain yield. Reductions in KN were better explained by drops in CGR TU than in CGR D . Under HNT, Amax significantly decreased ( p < 0.05; 17%, among experiments and hybrids) with insignificant changes in CMS and chlorophyll fluorescence. HNT caused a larger effect on Rn in Te (+40%) than in St. We found a strong negative relationship between Rn and Amax, indicating that high Rn might exhibit an indirect effect on Amax, altering carbon balance and growth.

Topics & Concepts

PhotosynthesisRespirationChlorophyll fluorescenceHorticultureAnimal scienceTemperate climateChlorophyllChemistryAgronomyBiologyBotanyCrop Yield and Soil FertilityClimate change impacts on agriculturePlant responses to elevated CO2