Abstract
Coffea canephora cultivation areas in Brazil are frequently exposed to successive cycles of water deficit, triggering plant stress responses. In addition to water deficit, increased air temperature can act as a second stress factor. The recurrence of these stress factors may induce plant tolerance mechanisms, potentially mitigating future stress responses even of a different stress nature. We hypothesized that repeated cycles of water deficit can trigger tolerance mechanisms that make C. canephora leaves more resilient to supra-optimal temperatures. To test this hypothesis, young C. canephora plants were grown under non-limited water conditions for seven months (Ψ(mSoil) > -20 kPa), after which they were subjected to two consecutive cycles of water deficit (Ψ(mSoil) < -300 kPa), followed by rehydration. Two clones were used, 'A1' and '3V', previously classified as drought sensitive and tolerant, respectively, considering the dynamics of physiological and architectural responses. After the second cycle, leaf discs were collected from completely expanded leaves formed during the two stress cycles and exposed to heat treatments (35 °C, 40 °C, 45 °C, 50 °C, and 55 °C) for 15 min in a water bath. Chlorophyll a fluorescence emission was then monitored, and the results were analyzed using OJIP transient kinetics and the JIP(Test). High temperatures induced negative changes in both OJIP kinetics and JIP(Test)-derived parameters. A significant increase in F(0) and a reduction in F(M) were observed mainly at 50 °C and 55 °C, due to changes in the stages of the OJIP curve. These changes impacted the "energy connectivity" and consequently the electron transport along the electron transfer chain (ETC), increasing energy dissipation, as confirmed by the JIP(Test) variables. Despite the high temperature impacts, previous water deficit induced heat tolerance in clone 'A1', while it increased sensitivity in clone '3V'. This study suggests that selecting drought-resistant varieties should consider their subsequent response to short high-temperature stress to avoid cross-sensitivity caused by selecting for a single environmental factor.