5 research outputs found
Seasonal drought limits tree species across the Neotropics
AcceptedArticle in Press© 2016 Nordic Society Oikos.Within the tropics, the species richness of tree communities is strongly and positively associated with precipitation. Previous research has suggested that this macroecological pattern is driven by the negative effect of water-stress on the physiological processes of most tree species. This implies that the range limits of taxa are defined by their ability to occur under dry conditions, and thus in terms of species distributions predicts a nested pattern of taxa distribution from wet to dry areas. However, this 'dry-tolerance' hypothesis has yet to be adequately tested at large spatial and taxonomic scales. Here, using a dataset of 531 inventory plots of closed canopy forest distributed across the western Neotropics we investigated how precipitation, evaluated both as mean annual precipitation and as the maximum climatological water deficit, influences the distribution of tropical tree species, genera and families. We find that the distributions of tree taxa are indeed nested along precipitation gradients in the western Neotropics. Taxa tolerant to seasonal drought are disproportionally widespread across the precipitation gradient, with most reaching even the wettest climates sampled; however, most taxa analysed are restricted to wet areas. Our results suggest that the 'dry tolerance' hypothesis has broad applicability in the world's most species-rich forests. In addition, the large number of species restricted to wetter conditions strongly indicates that an increased frequency of drought could severely threaten biodiversity in this region. Overall, this study establishes a baseline for exploring how tropical forest tree composition may change in response to current and future environmental changes in this region.This paper is a product of the RAINFOR and ATDN networks and of ForestPlots.net
researchers (http://www.forestplots.net). RAINFOR and ForestPlots have been
supported by a Gordon and Betty Moore Foundation grant, the European Unionâs
Seventh Framework Programme (283080, âGEOCARBONâ; 282664,
âAMAZALERTâ); European Research Council (ERC) grant âTropical Forests in the
Changing Earth Systemâ (T-FORCES), and Natural Environment Research Council
(NERC) Urgency Grant and NERC Consortium Grants âAMAZONICAâ
(NE/F005806/1) and âTROBITâ (NE/D005590/1). Additional funding for fieldwork was
provided by Tropical Ecology Assessment and Monitoring (TEAM) Network, a
collaboration among Conservation International, the Missouri Botanical Garden, the
Smithsonian Institution, and the Wildlife Conservation Society. A.E.M. receives a PhD
scholarship from the T-FORCES ERC grant. O.L.P. is supported by an ERC Advanced
Grant and a Royal Society Wolfson Research Merit Award. We thank Jon J. Lloyd,
Chronis Tzedakis, David Galbraith, and two anonymous reviewers for helpful
comments and Dylan Young for helping with the analyses. This study would not be
possible without the extensive contributions of numerous field assistants and rural
communities in the Neotropical forests. Alfredo AlarcĂłn, Patricia Alvarez Loayza,
PlĂnio Barbosa Camargo, Juan Carlos Licona, Alvaro Cogollo, Massiel Corrales
Medina, Jose Daniel Soto, Gloria Gutierrez, Nestor Jaramillo Jarama, Laura Jessica
Viscarra, Irina Mendoza Polo, Alexander Parada Gutierrez, Guido Pardo, Lourens
Poorter, Adriana Prieto, Freddy Ramirez Arevalo, AgustĂn Rudas, Rebeca Sibler and
Javier Silva Espejo additionally contributed data to this study though their RAINFOR
participations. We further thank those colleagues no longer with us, Jean Pierre Veillon,
Samuel Almeida, Sandra Patiño and Raimundo Saraiva. Many data come from Alwyn
Gentry, whose example has inspired new generations to investigate the diversity of the
Neotropics
Seasonal drought limits tree species across the Neotropics
Within the tropics, the species richness of tree communities is strongly and positively associated with precipitation. Previous research has suggested that this macroecological pattern is driven by the negative effect of water-stress on the physiological processes of most tree species. This process implies that the range limits of taxa are defined by their ability to occur under dry conditions, and thus in terms of species distributions it predicts a nested pattern of taxa distribution from wet to dry areas. However, this âdry-toleranceâ hypothesis has yet to be adequately tested at large spatial and taxonomic scales. Here, using a dataset of 531 inventory plots of closed canopy forest distributed across the Western Neotropics we investigated how precipitation, evaluated both as mean annual precipitation and as the maximum climatological water deficit, influences the distribution of tropical tree species, genera and families. We find that the distributions of tree taxa are indeed nested along precipitation gradients in the western Neotropics. Taxa tolerant to seasonal drought are disproportionally widespread across the precipitation gradient, with most reaching even the wettest climates sampled; however, most taxa analysed are restricted to wet areas. Our results suggest that the âdry toleranceâ hypothesis has broad applicability in the world's most species-rich forests. In addition, the large number of species restricted to wetter conditions strongly indicates that an increased frequency of drought could severely threaten biodiversity in this region. Overall, this study establishes a baseline for exploring how tropical forest tree composition may change in response to current and future environmental changes in this region
Disentangling regional and local tree diversity in the Amazon
This is the author accepted manuscript. The final version is available from Wiley via the DOI in this recordWe analyzed the most extensive data set of tree inventory plots spread over the complete Amazon basin and Guiana shield. We aimed to separate the regional and local tree alphaâdiversity to investigate the drivers of diversity at the relevant scale. Our results are consistent with the partitioning of total tree alphaâdiversity into regional and local components, which are controlled by evolutionaryâ and ecological processes, respectively. Regional diversity is correlated with palaeoâclimatic stability (31%), and longâterm largeâscale ecosystem dynamics (14%), as represented by the age of the geological formation. Both mechanisms contribute to high diversity in the central to western Amazon. Actual rainfall seasonality is correlated with regional tree diversity to a certain extent (19%), but we argue that this is of little consequence for the evolutionary drivers of the regional species pool. Frequency of disturbance is the main process driving local diversity, although its explanatory power is relatively small (17%).The first author was supported by PANâAMAZONIA project, Inst. Internacional de Educação do Brasil (BECA program) and Conselho Nacional de CiĂȘncia e Tecnologia (CNPq â Brazil)