During exposure to direct sunlight, leaf temperature increases rapidly and can reach values well above air temperature in temperate forest understories, especially when transpiration is limited due to drought stress, but the physiological effects of such high-temperature events are imperfectly understood. To gain insight into leaf temperature changes in the field and the effects of temperature variation on plant photosynthetic processes, we studied leaf temperature dynamics under field conditions in European aspen (Populus tremula L.) and under nursery conditions in hybrid aspen (P. tremula × P. tremuloides Michaux), and further investigated the heat response of photosynthetic activity in hybrid aspen leaves under laboratory conditions. To simulate the complex fluctuating temperature environment in the field, intact, attached leaves were subjected to short temperature increases (“heat pulses”) of varying duration over the temperature range of 30 °C–53 °C either under constant light intensity or by simultaneously raising the light intensity from 600 μmol m−2 s−1 to 1000 μmol m−2 s−1 during the heat pulse. On a warm summer day, leaf temperatures of up to 44 °C were measured in aspen leaves growing in the hemiboreal climate of Estonia. Laboratory experiments demonstrated that a moderate heat pulse of 2 min and up to 44 °C resulted in a reversible decrease of photosynthesis. The decrease in photosynthesis resulted from a combination of suppression of photosynthesis directly caused by the heat pulse and a further decrease, for a time period of 10–40 min after the heat pulse, caused by subsequent transient stomatal closure and delayed recovery of photosystem II (PSII) quantum yield. Longer and hotter heat pulses resulted in sustained inhibition of photosynthesis, primarily due to reduced PSII activity. However, cellular damage as indicated by increased membrane conductivity was not found below 50 °C. These data demonstrate that aspen is remarkably resistant to short-term heat pulses that are frequent under strongly fluctuating light regimes. Although the heat pulses did not result in cellular damage, heatflecks can significantly reduce the whole plant carbon gain in the field due to the delayed photosynthetic recovery after the heat pulse.
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机译:在阳光直射的过程中,叶片温度迅速升高,并且可以达到温带林下林木中的空气温度以上的高度,特别是在由于干旱胁迫而限制了蒸腾作用的情况下,但这种高温事件的生理影响尚不完全清楚。为了深入了解田间叶片温度变化以及温度变化对植物光合作用的影响,我们研究了欧洲白杨(Populus tremula L.)的田间条件和苗圃条件下杂交白杨(P. tremula)的叶片温度动态× P. tremuloides(Michaux),并进一步研究了在实验室条件下杂交白杨叶片中光合活性的热响应。为了模拟田间复杂的温度波动环境,在恒定的光照强度下或同时在30°C–53°C的温度范围内,完整,附着的叶子经受持续时间短的温度升高(“热脉冲”)将光强度从600μmolm -2 s -1 提高到1000μmolm -2 s -1 在热脉冲期间。在一个温暖的夏日,在爱沙尼亚的半实物气候下生长的白杨树叶中测得的叶温高达44°C。实验室实验表明,适度的2分钟热脉冲和最高44°C导致光合作用的可逆下降。光合作用的降低是由热脉冲直接导致的光合作用抑制与热脉冲之后的10-40分钟的时间进一步降低(由随后的短暂气孔关闭和光系统II的恢复延迟)共同导致的( PSII)量子产率。更长和更热的热脉冲导致光合作用的持续抑制,这主要是由于PSII活性降低。然而,在50℃以下未发现由膜电导率增加所指示的细胞损伤。这些数据表明,白杨对在剧烈波动的光照条件下经常发生的短期热脉冲具有显着的抵抗力。尽管热脉冲不会导致细胞损伤,但是由于热脉冲后光合作用的恢复延迟,热斑可以显着降低田间整株碳的吸收。
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