Drought tolerance is a critical determinant of tropical plant distributions, researchers working at the Smithsonian Tropical Research Institute in Panama report in the May 3rd issue of Nature. In a novel coupling of experimental measurements and observed plant distributions across a tropical landscape, drought tolerance predicted plant distributions at both local and regional scales. This mechanism to explain a common observation will contribute significantly to models of land use and climate change.
Tropical forest, often called rainforest, conjures up images of verdant, evergreen landscapes. Whereas temperatures may be relatively constant in the tropics, rainfall and water availability often vary dramatically across small distances.
"The Isthmus of Panama is the ideal place to test the idea that the distribution of plant species is influenced by their ability to tolerate a lack of water," said researcher and article author Bettina Engelbrecht of the University of Kaiserslautern in Germany and STRI.
After measuring the drought tolerance of 48 plant species experimentally, scientists looked at the plants’ regional distributions across 122 tropical forest plots set up by the Center for Tropical Forest Science. The plots are distributed over a rainfall gradient from the wet Caribbean slope to the drier Pacific slope.
"It was a surprise that even in humid tropical forests, traditionally viewed as water saturated, plants growing at dry sites were more drought-tolerant than plants growing at wet sites," Engelbrecht said.
The team also evaluated the local distributions of both seedlings and older trees on STRI’s 50-hectare Forest Dynamics plot on Barro Colorado Island, roughly in the middle of the rainfall gradient. Drought tolerance was a stronger predictor of species distributions for saplings and adult trees than for seedlings, implying that plant community composition adjusts in accordance to environmental constraints.
Researchers ruled out several other potential predictors of plant distribution that could be associated with drought tolerance, such as shade tolerance and nutrient availability.
Identifying drought tolerance as a cause of plant distribution patterns significantly advances the understanding of tropical plant diversity and implies that changes in rainfall patterns—a predicted consequence of climate change in the tropics—may give rise to dramatic changes in tropical plant communities.
"In the tropics, climate change does not just mean temperature change—dramatic shifts in rainfall patterns also are expected to occur," said Ben Turner, STRI staff scientist and co-author. "Our research shows that changes in rainfall patterns will have considerable consequences for tropical forests."
