Abstract

The tuber yield of potatoes is vulnerable to high temperature and is challenged by the asymmetric increase in day and night temperatures. This study aimed to evaluate photosynthesis, biomass growth, tuber mass distribution, and dry tuber yield in early harvested potatoes that were field-grown under high day and night temperature conditions during different growth stages. Potatoes were exposed to ambient (control), high night temperature (HNT; 19:00–7:00), high day temperature (HDT; 7:00–19:00), and high day/night temperature (HDNT; all day) for 14 days during tuber initiation (TI) or tuber bulking (TB) using portable, temperature-controlled plastic houses that were controlled to increase the temperature by 4.0°C. During TI, HNT delayed tuber development, thus altering tuber mass distribution by reducing the yield proportion of large tubers of >100 g (-53.7%) and lowering early harvest index (-16.1%), causing a significant yield loss (-17.2%) without interfering with photosynthesis. In contrast, HDT decreased early tuber yield (-18.1%) by reducing photosynthetic sources, which was probably attributed to decreased photosynthetic efficiency through a feedback inhibition. However, HDT altered neither tuber mass distribution nor early harvest index. HDNT during TI exhibited all the aforementioned effects of HNT and HDT (i.e., cumulative effects): reduced yield proportion of large tubers (-46.7%), decreased early harvest index (-23.7%), and reduced photosynthetic rate; thus, HDNT caused the highest yield loss (-30.3%). During TB, when the tubers were fully developed, the thermal effects decreased because most of the effects were either directly or indirectly linked to tuber development. These results provide comprehensive insight to the differential mechanisms of potato yield loss under high day and night temperatures and show that further field experiments should be conducted to cope with the threat of global warming on potato production.

Highlights

  • The global daily mean temperature is expected to increase by 1.0– 3.7◦C by the end of the 21st century (IPCC, 2013)

  • Relative humidity was not altered by high night temperature (HNT), whereas high day temperature (HDT) and high day/night temperature (HDNT) decreased relative humidity by −2.5 and −2.0%p, respectively

  • The results of this study showed that the responses of photosynthesis and early tuber growth to high day and night temperatures in potato were quite different, the response of early tuber yield was similar

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Summary

Introduction

The global daily mean temperature is expected to increase by 1.0– 3.7◦C by the end of the 21st century (IPCC, 2013). It is reported that crop growth and yield are adversely affected by high day temperature (Matsui et al, 1997; Elía et al, 2018) or high night temperature (Prasad and Djanaguiraman, 2011; García et al, 2015). The adverse effects of increased mean daily temperature on potato yield has been recently evaluated with greenhouse or growth chamber experiments (Kim et al, 2017; Rykaczewska, 2017) and modeling studies (Fleisher et al, 2017). Leaf photosynthesis is known to be less sensitive to high temperature than tuber development, with an optimum temperature of approximately 24◦C (Ku et al, 1977; Leach et al, 1982; Timlin et al, 2006). It has been suggested that reduction of photosynthesis under high temperature is mainly caused by decreased efficiency of photosystem II rather than decreased stomatal conductance (Dwelle et al, 1981; Prange et al, 1990)

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