Your search keyword '"Barbara Stenni"' showing total 2 results

1. OUP accepted manuscript

Author

Paolo Bertoncin, Andrea Nardini, Barbara Stenni, Valentino Casolo, Alberto Pallavicini, Stefano Martellos, Anna Dal Borgo, Valentina Torboli, Sabine Rosner, and Tadeja Savi

Subjects

0106 biological sciences, Canopy, 0303 health sciences, education.field_of_study, Water transport, Physiology, Ecology, Ecological Modeling, fungi, Population, food and beverages, Xylem, Climate change, Woodland, Management, Monitoring, Policy and Law, Biology, 01 natural sciences, 03 medical and health sciences, Tracheid, education, 030304 developmental biology, 010606 plant biology & botany, Nature and Landscape Conservation, Woody plant

Abstract

Ongoing climate change is apparently increasing tree mortality rates, and understanding mechanisms of drought-induced tree decline can improve mortality projections. Differential drought impact on conspecific individuals within a population has been reported, but no clear mechanistic explanation for this pattern has emerged. Following a severe drought (summer 2012), we monitored over a 3-year period healthy (H) and declining (D) Pinus nigra trees co-occurring in a karstic woodland to highlight eventual individual-specific physiological differences underlying differential canopy dieback. We investigated differences in water and carbon metabolism, and xylem anatomy as a function of crown health status, as well as eventual genotypic basis of contrasting drought responses. H and D trees exploited the same water pools and relied on similar hydraulic strategies to cope with drought stress. Genetic analyses did not highlight differences between groups in terms of geographical provenance. Hydraulic and anatomical analyses showed conflicting results. The hydraulic tracheid diameter and theoretical hydraulic conductivity were similar, but D trees were characterized by lower water transport efficiency, greater vulnerability to xylem conduit implosion and reduced carbohydrate stores. Our results suggest that extreme drought events can have different impacts on conspecific individuals, with differential vulnerability to xylem embolism likely playing a major role in setting the fate of trees under climate change.

Published

2019

2. Drought-induced dieback of

Author

Tadeja, Savi, Valentino, Casolo, Anna, Dal Borgo, Sabine, Rosner, Valentina, Torboli, Barbara, Stenni, Paolo, Bertoncin, Stefano, Martellos, Alberto, Pallavicini, and Andrea, Nardini

Subjects

carbon metabolism, water status, rooting depth, parasitic diseases, fungi, food and beverages, Black pine, drought, plastome, Research Article

Abstract

Extreme summer droughts induced differential impacts in a population of Pinus nigra trees. We analyzed eventual physiological differences between desiccated and healthy trees. Desiccated trees were more vulnerable to drought-induced xylem embolism, and were also suffering from depletion of carbohydrate reserves. Our data suggest that genotypic or phenotypic intraspecific variability can play fundamental roles in defining individual drought responses/impacts, dictating the fate of single trees under global-change-type droughts., Ongoing climate change is apparently increasing tree mortality rates, and understanding mechanisms of drought-induced tree decline can improve mortality projections. Differential drought impact on conspecific individuals within a population has been reported, but no clear mechanistic explanation for this pattern has emerged. Following a severe drought (summer 2012), we monitored over a 3-year period healthy (H) and declining (D) Pinus nigra trees co-occurring in a karstic woodland to highlight eventual individual-specific physiological differences underlying differential canopy dieback. We investigated differences in water and carbon metabolism, and xylem anatomy as a function of crown health status, as well as eventual genotypic basis of contrasting drought responses. H and D trees exploited the same water pools and relied on similar hydraulic strategies to cope with drought stress. Genetic analyses did not highlight differences between groups in terms of geographical provenance. Hydraulic and anatomical analyses showed conflicting results. The hydraulic tracheid diameter and theoretical hydraulic conductivity were similar, but D trees were characterized by lower water transport efficiency, greater vulnerability to xylem conduit implosion and reduced carbohydrate stores. Our results suggest that extreme drought events can have different impacts on conspecific individuals, with differential vulnerability to xylem embolism likely playing a major role in setting the fate of trees under climate change.

Published

2018