Abstract
Global climate change accompanied by continuous increases in atmospheric carbon dioxide (CO2) concentration and temperature affects the growth and yield of important crops. The present study investigated the effect of elevated temperature and CO2 concentrations on the growth, yield, and photosynthesis of potato (Solanum tuberosum L. cv. Superior) crops using Korean Soil-Plant-Atmosphere-Research chambers that allow the regulation of temperature and CO2 concentration under daylight conditions. Based on the average temperature from 1991 to 2010 in the Jeonju area, South Korea, potato plants were exposed to four different conditions: ambient weather (400 μmol mol-1, aCaT), elevated temperature (+4°C, aCeT), elevated CO2 concentration (800 μmol mol-1, eCaT), and concurrently elevated CO2 concentration and temperature (eCeT). Under aCeT conditions, the temperature exceeded the optimal growth temperature range towards the late growth phase that decreased stomatal conductance and canopy net photosynthetic rate and subsequently reduced biomass and tuber yield. Stomatal conductance and chlorophyll concentration were lower under eCaT conditions than under aCaT conditions, whereas late-growth phase biomass and tuber yield were greater. Compared to other conditions, eCeT yielded a distinct increase in growth and development and canopy net photosynthetic rate during tuber initiation and bulking. Consequently, biomass and canopy net photosynthesis increased, and tuber yield increased by 20.3%, which could be attributed to the increased tuber size, rather than increased tuber number. Elevated CO2 reduced chlorophyll, magnesium, and phosphorus concentrations; reducing nitrogen concentration (by approximately 39.7%) increased the C:N ratio. The data indicate that future climate conditions will likely change nutrient concentration and quality of crops. The present study shows that while elevated temperature may negatively influence the growth and yield of potato crops, especially towards the late-growth phase, the concurrent and appropriate elevation of CO2 and temperature could promote balanced development of source and sink organs and positively effect potato productivity and quality.
Highlights
Global climate change has accelerated since the beginning of the 21st century
At 35 Days After Emergence (DAE), plant height was significantly higher under the aCeT and elevated CO2 concentration and temperature (eCeT) conditions compared to aCaT and elevated CO2 and ambient temperature (eCaT) conditions (P < 0.001), whereas neither the number of branches nor leaf area was significantly affected
At 58 DAE, the total biomass was significantly higher under the eCaT and eCeT conditions, and the total biomass of plants grown under the eCaT and eCeT conditions was significantly higher by 25.6% and 59.2%, respectively, compared to the aCaT condition (P < 0.001)
Summary
Global climate change has accelerated since the beginning of the 21st century. For example, the atmospheric CO2 concentration in 1880 was 280 μmol mol-1 but it has increased continuously since the industrial revolution and is currently at least 400 μmol mol-1. Based on the Representative Concentration Pathway (RCP) Scenario 8.5 of the Intergovernmental Panel on Climate Change [2], atmospheric temperature could rise by as much as 4.8 ̊C by around 2100 and the CO2 concentration could reach 940 μmol mol-1. These predicted increases in atmospheric CO2 concentration and temperature are anticipated to affect crop productivity and quality [3,4,5]. Each crop variety exhibits different response patterns to changes in temperature and CO2 concentration [6,7,8]
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