Efeitos de secas extremas na fenologia, crescimento e desempenho ecofisiológico de espécies nativas de campo rupestre

In the past years, extreme droughts have been frequently recorded in several tropical regions. Plants in tropical mountains are particularly sensitive to changes in climate little is known about the plant physiological adjustments and responses to changes in rainfall patterns. Our objective was to evaluate the phenological and ecophysiological responses of six dominant species with contrasting life forms in campos rupestres under an extreme drought condition. We studied two rosettes species (Vellozia nivea and Vellozia aff. variabilis) and four shrubs (Campomanesia pubecens, Eremanthus seidelii, Mimosa clausenii e Vernonia warmingiana). We implemented a rainwater exclusion experiment with 12 plots (4x4 meters), in which eight was considered drought treatment and four control treatment. We monitored several aspects of the plant ecophysiology, such as gas exchange using instantaneous measurements and stable isotope as integrators of leaf functioning, pressure-volume curves, vulnerability curves, non-structural carbohydrates (NSC) in roots, growth, biomass and leaf phenology. Species showed a continuum of water use strategies, varying from anysohydric (C. pubecens) to completely isohydric (E. seidelii) species. The relationship between ?18OCELL and gsMAX was negative and significant only for isohydric species. The use of dual isotopic approach also was valid only for isohydric species. Across species, we found a strong positive relationship between ?18OCELL and NSC% for individuals under drought treatment, suggesting that the use of NSC% reserves in water stress conditions can affect leaf isotope composition. Our results suggest that in communities dominated to species with a great diversity of hydraulic strategies, such as the campos rupestres, ?18OCELL should be used with caution to infer physiological responses. We evaluated a congeneric pair of Velloziaceae species with contrasting strategies to cope with the erratic water availability in campos rupestres. One species is desiccation tolerant (DT) and the other is drought resistance (non-DT). The DT species showed high gsMAX and low WUEi during the rainny season, showing a profligate water use. By contrast, the non-DT showed a conservative water use throughout the year. The DT species also increased the %NSC storage in roots during the prolonged drought, presumably a key mechanism that allow survival to desiccation in this species. The three shrub species (C. pubecens, E. seidelii and M. clausenii) showed different P50 (water potential that corresponds 50% of conductivity loss) and ?TLP (water potential at turgor loss point). The biomass, in general, was little affected by our drought treatment. This three species showed a trade-off between the vulnerability to cavitation and NSC storage, in which, species more resistant to cavitation (more negative P50) showed lower NSC% storage in roots. Our results illustrate the diversity of strategies that plants might present to deal with drought and bring important contributions to understand the functioning of water-limited environments (AU)