Effects of extreme temperatures and recovery potential of Gongolaria barbata from a coastal lagoon in the northern Adriatic Sea: An ex situ approach.

BACKGROUND AND AIMS:Globally, rising seawater temperatures contribute to the regression of marine macroalgal forests. Along the Istrian coastline (northern Adriatic), an isolated population of Gongolaria barbata persists in a coastal lagoon, representing one of the last marine macroalgal forests in the region. Our objective was to examine the impact of extreme temperatures on morphology and physiology of G. barbata, and test its potential for recovery after simulating marine heatwave (MHW) conditions. METHODS:We explored the occurrence of marine heatwaves in southern Istria, adjacent to the study area, as well as extreme temperatures inside the area itself. Subsequently, we performed a thermotolerance experiment, consisting of a stress and recovery phase where we exposed G. barbata thalli to four extreme (28 °C, 30 °C, 32 °C, 34 °C) and one favourable (18 °C) temperature. We then monitored morphological and physiological responses. KEY RESULTS:Our findings indicate a significant rise in frequency, duration, and intensity of MHWs over decades on the southern Istrian coast. Experimental results show that G. barbata demonstrates both morphological and physiological recovery potential after exposure to temperatures as high as 32 °C. However, exposure to 34 °C led to thallus decay, with limited regeneration ability. CONCLUSIONS:Our results show that G. barbata has a remarkable resilience to long term exposure to extreme temperatures up to 32 °C and suggests that short term exposure to temperatures beyond this, as currently recorded inside the lagoon, do not notably affect the physiology or morphology of local G. barbata. With more MHWs expected in the future, such an adapted population may represent an important donor suitable for future restoration activities along the Istrian coast. These results emphasize the resilience of this unique population, but also warns of the vulnerability of marine macroalgal forests to rising seawater temperatures under rapidly changing climate conditions.