RAPID PHOTOSYNTHETIC ADAPTATION TO HEAT-STRESS TRIGGERED IN POTATO LEAVES BY MODERATELY ELEVATED-TEMPERATURES

Photosystem II (PSII) is considered to be one of the most thermolabile aspects of photosynthesis. In vivo measurements of chlorophyll fluorescence and photosynthetic oxygen evolution in 25-degrees-C-grown potato leaves (cv. Haig) indicated that the threshold temperature T(C) above which PSII denatures was indeed rather low - about 38-degrees-C - with temperatures higher than T(C) causing a rapid and irreversible loss of PSII activity. The present study demonstrates the existence of adaptive processes which rapidly adjust the in vivo thermal stability of PSII in response to temperature increase. Transfer of potato leaves from 25-degrees-C to temperatures slightly lower than T(C) (between 30 and 35-degrees-C) was observed to cause an upward shift of the T(C) value without any appreciable loss of PSII activity. This increase in PSII thermotolerance was substantial (around +5-degrees-C in the Haig cultivar), rapid (with a half-time of approximately 20 min) and slowly reversible at 25-degrees-C (>24h). As a consequence, high temperatures (e.g. 40-degrees-C) which caused a complete and irreversible inhibition of the PSII function had very little effect in 35-degrees-C-treated leaves, thus suggesting that the above-described PSII changes could be of prime importance for the plant's behaviour in the field. Accordingly, the rise in T(C) at 35-degrees-C was much larger (+8-degrees-C) in Sahel, a stress-resistant potato variety, than in the heat-sensitive Haig cultivar.