Water level regime variation is a crucial driver for taxonomic, functional, and phylogenetic diversity in seasonally flooded tropical forests.

Floodplains contribute significantly to terrestrial ecosystem service provision but are also among the most vulnerable and degraded ecosystems worldwide. Heterogeneity in floodplain properties arises from variations in river-specific flood regimes, watershed characteristics, and valley morphology, influencing seasonally flooded forests' taxonomic, functional, and phylogenetic diversity. This study addresses persisting knowledge gaps in floodplain ecology, focusing on the seasonally dry tropics. We explore the relationships between flood regime, environmental conditions, vegetation composition, functional and phylogenetic diversity, and the impact of environmental variables on above-ground biomass (AGB) and ecological strategies. The study spans six rivers in southeastern Brazil's main river basins: Rio Grande and São Francisco. We identified five eco-units in each floodplain based on flooding regimes and surveyed six plots per eco-unit. We measured trees with DBH > 5 cm and collected functional traits, along with detailed soil, climate, and water level data. We calculated plot-level floristic composition, taxonomic, functional, and phylogenetic diversity, wood density, and AGB. Functional and phylogenetic dissimilarity were analyzed, and the effects of climate, soil, and hydrological variables were quantified using generalized linear mixed models. We show how flood frequency and duration affect floristic composition across the floodplains. Taxonomic and phylogenetic diversity responded to climate, soil, and hydrological variables, while functional diversity responded primarily to hydrological variables, emphasizing the role of environmental filtering. Hydrological seasonality, soil fertility, and flood regime emerged as key factors shaping community structure and ecological strategies in the studied seasonally flooded tropical forests. Plot-level AGB responded to phosphorus but not to climate or hydrological variables. The study also highlights functional and phylogenetic dissimilarities among eco-units and basins, indicating potential climate change impacts.

Biochar effects on NTFP-enriched secondary forest growth and soil properties in Amazonian Ecuador.

Deforestation in the Amazon has resulted in large areas of depleted soils on abandoned pastures and agricultural sites that present a restoration challenge central to protecting biodiversity and ecosystem function in the region. Biochar - charcoal made from waste materials - can improve soil physical, chemical, and biological properties, but the few tropical field trials to date do not give consistent results regarding tree growth. This study presents three years of soil performance and tree growth of a secondary forest shading nontimber forest product (NTFP) plantations of Ocotea quixos (Lauraceae), Myroxylon balsamum (Fabaceae), and their mixture. Open kiln and traditional mound biochars were added at 10 t ha-1 at two sites with contrasting soil types. Biochar additions resulted in pronounced effects on soil properties that varied over time and with depth in the soil profile. Biochar additions generally increased soil organic matter, electrical conductivity, and plant nutrients (in particular K, Ca, and N), but there were interactive effects of NTFP treatments, and stronger responses on the poorer soil type. Biochar amendments resulted in increased tree growth, with a 29 ± 12% increase in aboveground biomass (AGB) on plots amended with kiln biochar and a 23 ± 9% increase in plots with mound biochar compared to controls. Tree species also varied in growth responses to biochar additions, with the largest increases observed in Jaccaranda copaia and Piptocoma discolor. Significant interactions between biochar and NTFP treatments were also seen for tree growth responses, such as Cecropia spp., which only showed increased biomass on mound biochar plots planted with Ocotea quixos. Overall, our results demonstrate a stronger effect of biochar in less favorable soil conditions, and an overriding effect of the legume NTFP in richer soils, and suggest that additions of biochar and legumes are important options to increase productivity and ecological resilience in tropical forest restoration.

Giants of the Amazon: How does environmental variation drive the diversity patterns of large trees?

For more than three decades, major efforts in sampling and analyzing tree diversity in South America have focused almost exclusively on trees with stems of at least 10 and 2.5 cm diameter, showing highest species diversity in the wetter western and northern Amazon forests. By contrast, little attention has been paid to patterns and drivers of diversity in the largest canopy and emergent trees, which is surprising given these have dominant ecological functions. Here, we use a machine learning approach to quantify the importance of environmental factors and apply it to generate spatial predictions of the species diversity of all trees (dbh ≥ 10 cm) and for very large trees (dbh ≥ 70 cm) using data from 243 forest plots (108,450 trees and 2832 species) distributed across different forest types and biogeographic regions of the Brazilian Amazon. The diversity of large trees and of all trees was significantly associated with three environmental factors, but in contrasting ways across regions and forest types. Environmental variables associated with disturbances, for example, the lightning flash rate and wind speed, as well as the fraction of photosynthetically active radiation, tend to govern the diversity of large trees. Upland rainforests in the Guiana Shield and Roraima regions had a high diversity of large trees. By contrast, variables associated with resources tend to govern tree diversity in general. Places such as the province of Imeri and the northern portion of the province of Madeira stand out for their high diversity of species in general. Climatic and topographic stability and functional adaptation mechanisms promote ideal conditions for species diversity. Finally, we mapped general patterns of tree species diversity in the Brazilian Amazon, which differ substantially depending on size class.

Dataset on wood density of trees in ecotone forests in Northern Brazilian Amazonia.

Wood density is expressed by the ratio between dry weight and fresh volume of a sample piece. The value of this measure is an important variable for assessing wood functional properties, successional stages and biomass/carbon stock estimates in different terrestrial ecosystems. Wood density data were collected for tree species from ecotone forests of the northern Brazilian Amazonia. We sampled 680 individuals with stem diameter ≥10 cm. For each sampled individual measurements were taken for three stem variables: bark thickness (mm), bark density (g cm-3) and wood density (g cm-3). This dataset is intended to improve biomass and carbon estimates of forests in the northern ecotone region of Brazilian Amazonia, an area poorly known in terms of ecosystem dynamics.

Diametric structure of a deciduous forest fragment in the agribusiness region of western Santa Catarina State, Brazil / Estrutura diamétrica de um fragmento de floresta decidual na região do agronegócio no oeste catarinense

Forest structure studies may be carried out through the diametric distribution of individuals within a population, which is defined by characterizing the number of trees per unit area and diameter class intervals. The De Liocourt's q quotient can be used to assess the relationship between recruitment and mortality in forest communities because when a constant ratio occurs between the classes, it represents that the recruitment rate is similar to the mortality rate and the distribution can be considered as regular or balanced. This study aims to analyze the diametric structure of the arboreal component of a seasonal deciduous forest fragment located in the Peixe River Valley, Midwest of Santa Catarina State, Brazil. The sampled individuals were distributed in diameter classes with an amplitude of 5 cm, in which the center of the first class presented a value of 6.5 cm. Subsequently, the observed and estimated diametric distribution curves were constructed for the overall sampling and for species with the highest importance value (IV) and with different ecological attributes. The study area presented a deficit of trees in the overall and per species diameter classes when compared to a balanced forest. The De Liocourt's q quotient can be used to assess the diametric structure of deciduous forest fragments.

Estudos de estrutura florestal podem ser realizados através da distribuição dos diâmetros de indivíduos dentro de uma população, que é definida pela caracterização do número de árvores por unidade de área e intervalos de classe de diâmetro. O quociente Q de De Liocourt pode ser usado para avaliar a relação entre recrutamento e mortalidade nas comunidades florestais, porque quando uma relação constante ocorre entre as classes, ela representa que a taxa de recrutamento é semelhante à taxa de mortalidade e a distribuição pode ser considerada como regular ou equilibrado. Este estudo tem como objetivo analisar a estrutura diamétrica do componente arbóreo de um fragmento da floresta decidual localizado na região do vale do Rio Peixe, meio-oeste do Estado de Santa Catarina, Brasil. Os indivíduos amostrados foram distribuídos em classes de diâmetro com uma amplitude de 5 cm, no qual o centro da primeira classe apresentou um valor de 6,5 cm. Posteriormente, as curvas de distribuição dos diâmetros observadas e estimadas foram construídas para a amostragem global e para espécies com maiores valores de importância (IV) e com diferentes atributos ecológicos. A área de estudo apresentou déficit de árvores nas classes de diâmetro geral e por espécie em comparação com uma floresta equilibrada. O quociente Q de De Liocourt pode ser usado para avaliar a estrutura diametral dos fragmentos de floresta deciduais.

Comparative foliar metabolomics of a tropical and a temperate forest community.

Plant enemies that attack chemically similar host species are thought to mediate competitive exclusion of chemically similar plants and select for chemical divergence among closely related species. This hypothesis predicts that plant defenses should diverge rapidly, minimizing phylogenetic signal. To evaluate this prediction, we quantified metabolomic similarity for 203 tree species that represent >89% of all individuals in large forest plots in Maryland and Panama. We constructed molecular networks based on mass spectrometry of all 203 species, quantified metabolomic similarity for all pairwise combinations of species, and used phylogenetically independent contrasts to evaluate how pairwise metabolomic similarity varies phylogenetically. Leaf metabolomes exhibited clear phylogenetic signal for the temperate plot, which is inconsistent with the prediction. In contrast, leaf metabolomes lacked phylogenetic signal for the tropical plot, with particularly low metabolomic similarity among congeners. In addition, community-wide variation in metabolomes was much greater for the tropical community, with single tropical genera supporting greater metabolomic variation than the entire temperate community. Our results are consistent with the hypothesis that stronger plant-enemy interactions lead to more rapid divergence and greater metabolomic variation in tropical than temperate plants. Additional community-level foliar metabolomes will be required from tropical and temperate forests to evaluate this hypothesis.

Short-term effects of drought on tropical forest do not fully predict impacts of repeated or long-term drought: gas exchange versus growth.

Are short-term responses by tropical rainforest to drought (e.g. during El Niño) sufficient to predict changes over the long-term, or from repeated drought? Using the world's only long-term (16-year) drought experiment in tropical forest we examine predictability from short-term measurements (1-2 years). Transpiration was maximized in droughted forest: it consumed all available throughfall throughout the 16 years of study. Leaf photosynthetic capacity [Formula: see text] was maintained, but only when averaged across tree size groups. Annual transpiration in droughted forest was less than in control, with initial reductions (at high biomass) imposed by foliar stomatal control. Tree mortality increased after year three, leading to an overall biomass loss of 40%; over the long-term, the main constraint on transpiration was thus imposed by the associated reduction in sapwood area. Altered tree mortality risk may prove predictable from soil and plant hydraulics, but additional monitoring is needed to test whether future biomass will stabilize or collapse. Allocation of assimilate differed over time: stem growth and reproductive output declined in the short-term, but following mortality-related changes in resource availability, both showed long-term resilience, with partial or full recovery. Understanding and simulation of these phenomena and related trade-offs in allocation will advance more effectively through greater use of optimization and probabilistic modelling approaches.This article is part of a discussion meeting issue 'The impact of the 2015/2016 El Niño on the terrestrial tropical carbon cycle: patterns, mechanisms and implications'.

Rare genotype advantage promotes survival and genetic diversity of a tropical palm.

Negative density dependence, where survival decreases as density increases, is a well-established driver of species diversity at the community level, but the degree to which a similar process might act on the density or frequency of genotypes within a single plant species to maintain genetic diversity has not been well studied in natural systems. In this study, we determined the maternal genotype of naturally dispersed seeds of the palm Oenocarpus bataua within a tropical forest in northwest Ecuador, tracked the recruitment of each seed, and assessed the role of individual-level genotypic rarity on survival. We demonstrate that negative frequency-dependent selection within this species conferred a survival advantage to rare maternal genotypes and promoted population-level genetic diversity. The strength of the observed rare genotype survival advantage was comparable to the effect of conspecific density regardless of genotype. These findings corroborate an earlier, experimental study and implicate negative frequency-dependent selection of genotypes as an important, but currently underappreciated, determinant of plant recruitment and within-species genetic diversity. Incorporating intraspecific genetic variation into studies and theory of forest dynamics may improve our ability to understand and manage forests, and the processes that maintain their diversity.

Inferring forest fate from demographic data: from vital rates to population dynamic models.

As population-level patterns of interest in forests emerge from individual vital rates, modelling forest dynamics requires making the link between the scales at which data are collected (individual stems) and the scales at which questions are asked (e.g. populations and communities). Structured population models (e.g. integral projection models (IPMs)) are useful tools for linking vital rates to population dynamics. However, the application of such models to forest trees remains challenging owing to features of tree life cycles, such as slow growth, long lifespan and lack of data on crucial ontogenic stages. We developed a survival model that accounts for size-dependent mortality and a growth model that characterizes individual heterogeneity. We integrated vital rate models into two types of population model; an analytically tractable form of IPM and an individual-based model (IBM) that is applied with stochastic simulations. We calculated longevities, passage times to, and occupancy time in, different life cycle stages, important metrics for understanding how demographic rates translate into patterns of forest turnover and carbon residence times. Here, we illustrate the methods for three tropical forest species with varying life-forms. Population dynamics from IPMs and IBMs matched a 34 year time series of data (albeit a snapshot of the life cycle for canopy trees) and highlight differences in life-history strategies between species. Specifically, the greater variation in growth rates within the two canopy species suggests an ability to respond to available resources, which in turn manifests as faster passage times and greater occupancy times in larger size classes. The framework presented here offers a novel and accessible approach to modelling the population dynamics of forest trees.

Local neighbourhood and regional climatic contexts interact to explain tree performance.

Tree neighbourhood modelling has significantly contributed to our understanding of the mechanisms structuring communities. Investigations into the impact of neighbouring crowding on tree performance have generally been conducted at local scales, missing important regional-scale context such as the suitability of the climate for each species. Favourable climates may enhance tree performance, but this may come at the cost of increased neighbourhood crowding and competition negatively impacting survival and growth. Through the synthesis of continental-scale forest inventory and trait datasets from the northeast USA and Puerto Rico we present an analytical approach that elucidates the important interactions between local competitive and regional climatic contexts. Our results show strong asymmetries in competitive interactions and significant niche differences that are dependent on habitat suitability. The strong interaction between local neighbourhood and regional climate highlights the need for models that consider the interaction between these two processes that have been previously ignored.

Tropical rainforests that persisted: inferences from the Quaternary demographic history of eight tree species in the Guiana shield.

How Quaternary climatic and geological disturbances influenced the composition of Neotropical forests is hotly debated. Rainfall and temperature changes during and/or immediately after the last glacial maximum (LGM) are thought to have strongly affected the geographical distribution and local abundance of tree species. The paucity of the fossil records in Neotropical forests prevents a direct reconstruction of such processes. To describe community-level historical trends in forest composition, we turned therefore to inferential methods based on the reconstruction of past demographic changes. In particular, we modelled the history of rainforests in the eastern Guiana Shield over a timescale of several thousand generations, through the application of approximate Bayesian computation and maximum-likelihood methods to diversity data at nuclear and chloroplast loci in eight species or subspecies of rainforest trees. Depending on the species and on the method applied, we detected population contraction, expansion or stability, with a general trend in favour of stability or expansion, with changes presumably having occurred during or after the LGM. These findings suggest that Guiana Shield rainforests have globally persisted, while expanding, through the Quaternary, but that different species have experienced different demographic events, with a trend towards the increase in frequency of light-demanding, disturbance-associated species.

Analysis of effectiveness of three forest interventionist techniques and proposal of a new and integrated model of forest restoration.

We assessed the efficacy of three different forest intervention techniques, in terms of phytosociological and edaphic responses, that were implemented in 2007. In a farm where trees are planted and managed for cellulose production as well as set aside for environmental conservation, four stands were analysed: three of them were considered degraded and were managed using different intervention techniques (transposition, perch, and abandonment), and a fourth stand comprising pristine vegetation was considered a control (reference). Floristic and phytosociology data were collected in three 10 × 10 m plots established in each stand. Also, a total of 48 soil samples were collected to analyse physical and chemical attributes of the topsoil for the different stands. In terms of biodiversity, all the treatments showed significantly lower values when compared to the reference area. However, the soils in all the treatment and reference stands are similar in terms of physical and chemical attributes. Taking into account the specificities of each restoration technique, we verified that the integrated use of a set of management practices, constituted by the (1) abandonment of the area and (2) following a selective killing of the eucalyptus, is the most suitable and promising model to provide fast and effective restoration in terms of environmental indicators.

Distribuição de abundância de espécies da comunidade arbórea do topo de um morro na floresta estacional subtropical / Species abundance distribution in tree community of a hill top in subtropical seasonal forest

Modelos ecológicos de distribuição de espécies (DAEs) em uma comunidade arbórea foram investigados para constatar: (i) se as variáveis ambientais são divididas de maneira estocástica e de modo similar entre as espécies; (ii) se cada espécie exaure mais da metade do nicho ecológico existente; (iii) se a comunidade arbórea possui muitas espécies com níveis intermediários de abundância e poucas espécies raras e comuns; (iv) e se, na sucessão secundária, as espécies colonizadoras tardias têm as maiores necessidades de um nicho especializado, de tal modo que são mais raras que as espécies colonizadoras iniciais. Obteve-se os dados em oito unidades amostrais de dimensões de 20m x 50m, distribuídas sistematicamente, perfazendo 0,8ha de amostra; ajustaram-se cinco modelos de DAEs (broken-stick, niche-preemption, log-normal, Zipf e Zipf-Mandelbrot) para a amostra e para as unidades amostrais; os critérios de acurácia dos modelos foram: Akaike, Bayesiano e Deviance. O modelo ecológico de DAEs que descreveu o ranking/abundância das espécies para a comunidade arbórea foi o Zipf-Mandelbrot. Os modelos ecológicos de DAEs que caracterizaram as unidades amostrais foram: niche-preemption, Zipf e Zipf-Mandelbrot. O modelo Zipf-Mandelbrot postula a colonização das espécies sob as exigências de condições ambientais prévias para o estabelecimento, assim, detecta-se uma comunidade arbórea em estágio de maturidade. Os modelos ecológicos de DAEs obtidos para as unidades amostrais, separadamente, evidenciam a disparidade da distribuição de abundância de espécies no interior da comunidade arbórea, que se interpretou como o efeito da heterogeneidade das condições e dos recursos ambientais, além de perturbações naturais, que originam um mosaico vegetacional.

Ecological Models of Species abundance distribution (SADs) of a tree community were investigated to find: (i) if environmental variables are divided stochastically and similarly between species; (ii) if each species exhausts more than half of the existing ecological niche; (iii) if the tree community has many species with intermediate levels of abundance and a few rare and common species; (iv) and if, in secondary succession, the later colonizing species have greatest needs for a specialized niche, so, they are more rare than the initial colonizers species. The data were obtained in eight sampling units with dimensions of 20m x 50m, distributed in a systematic way, totaling 0.8 ha sample; grouped in five models of SADs (broken-stick, niche-preemption, lognormal, Zipf and Zipf-Mandelbrot) for the sample of the tree community and the eight sampling units; the criteria of accuracy of the models were: Akaike, Bayesian and Deviance. The ecological model described the SADs that rank/abundance of tree species for ecological community which was the Zipf-Mandelbrot. The ecological models of SADs that characterized the eight sampling units were niche-preemption, Zipf and Zipf-Mandelbrot. The Zipf-Mandelbrot model postulates the colonization of species under the requirements of environmental preconditions for the establishment of the species, and thus detects up an arboreal community stage of maturity. The ecological models of SADs obtained for the sampling units, separately, show the disparity in the distribution of species abundance within the tree community that was interpreted as the effect of heterogeneity of conditions and environmental resources, and natural disturbances, originating a mosaic vegetation.

Distribuição de abundância de espécies da comunidade arbórea do topo de um morro na floresta estacional subtropical / Species abundance distribution in tree community of a hill top in subtropical seasonal forest

Modelos ecológicos de distribuição de espécies (DAEs) em uma comunidade arbórea foram investigados para constatar: (i) se as variáveis ambientais são divididas de maneira estocástica e de modo similar entre as espécies; (ii) se cada espécie exaure mais da metade do nicho ecológico existente; (iii) se a comunidade arbórea possui muitas espécies com níveis intermediários de abundância e poucas espécies raras e comuns; (iv) e se, na sucessão secundária, as espécies colonizadoras tardias têm as maiores necessidades de um nicho especializado, de tal modo que são mais raras que as espécies colonizadoras iniciais. Obteve-se os dados em oito unidades amostrais de dimensões de 20m x 50m, distribuídas sistematicamente, perfazendo 0,8ha de amostra; ajustaram-se cinco modelos de DAEs (broken-stick, niche-preemption, log-normal, Zipf e Zipf-Mandelbrot) para a amostra e para as unidades amostrais; os critérios de acurácia dos modelos foram: Akaike, Bayesiano e Deviance. O modelo ecológico de DAEs que descreveu o ranking/abundância das espécies para a comunidade arbórea foi o Zipf-Mandelbrot. Os modelos ecológicos de DAEs que caracterizaram as unidades amostrais foram: niche-preemption, Zipf e Zipf-Mandelbrot. O modelo Zipf-Mandelbrot postula a colonização das espécies sob as exigências de condições ambientais prévias para o estabelecimento, assim, detecta-se uma comunidade arbórea em estágio de maturidade. Os modelos ecológicos de DAEs obtidos para as unidades amostrais, separadamente, evidenciam a disparidade da distribuição de abundância de espécies no interior da comunidade arbórea, que se interpretou como o efeito da heterogeneidade das condições e dos recursos ambientais, além de perturbações naturais, que originam um mosaico vegetacional.(AU)

Ecological Models of Species abundance distribution (SADs) of a tree community were investigated to find: (i) if environmental variables are divided stochastically and similarly between species; (ii) if each species exhausts more than half of the existing ecological niche; (iii) if the tree community has many species with intermediate levels of abundance and a few rare and common species; (iv) and if, in secondary succession, the later colonizing species have greatest needs for a specialized niche, so, they are more rare than the initial colonizers species. The data were obtained in eight sampling units with dimensions of 20m x 50m, distributed in a systematic way, totaling 0.8 ha sample; grouped in five models of SADs (broken-stick, niche-preemption, lognormal, Zipf and Zipf-Mandelbrot) for the sample of the tree community and the eight sampling units; the criteria of accuracy of the models were: Akaike, Bayesian and Deviance. The ecological model described the SADs that rank/abundance of tree species for ecological community which was the Zipf-Mandelbrot. The ecological models of SADs that characterized the eight sampling units were niche-preemption, Zipf and Zipf-Mandelbrot. The Zipf-Mandelbrot model postulates the colonization of species under the requirements of environmental preconditions for the establishment of the species, and thus detects up an arboreal community stage of maturity. The ecological models of SADs obtained for the sampling units, separately, show the disparity in the distribution of species abundance within the tree community that was interpreted as the effect of heterogeneity of conditions and environmental resources, and natural disturbances, originating a mosaic vegetation.(AU)

Canopy stratification in tropical seasonal forests: how the functional traits of community change among the layers / Estratificação de dossel em florestas estacionais tropicais: como os traços funcionais da comunidade mudam ao longo dos estratos verticais

The discussion of the existence and measurement of layers in forests refers to one of the earliest and most controversial concepts of forest ecology, the stratification. Since there is no consensus on the most appropriate methodology to describe the vertical structure of forest communities, we chose for this paper to develop a methodology that was adequate to represent the stratification observed on site. The objective was to determine the species and functional traits characteristic of each vertical layer in the semideciduous seasonal forests (SSF). The study was conducted in ten fragments (10 ha) located in southeastern Brazil. Stratification was performed according to species using the median and the 3rd quartile (non-parametric statistical analysis) of tree heights were used for canopy stratification the (understory, midstory and canopy). This result shows the small range of the midstorey layer, highlighting the dichotomy between the canopy and understory. The variations found for the quartile and median values represent the history of successional stage of each fragment, allowing variations in the vertical occupation by species of certain layers. The analysis of SSF vertical structure allowed a visualization of the division of species and their respective functional traits performing different ecosystem functions in each layers.

A discussão sobre a existência e medição de camadas em florestas refere-se a um dos conceitos mais antigos e mais controversos em ecologia florestal: a estratificação. Como não há consenso sobre a metodologia mais adequada para descrever a estrutura vertical das comunidades florestais, optamos neste trabalho por desenvolver uma metodologia que se mostrou adequada para representar a estratificação observada no local. O objetivo foi determinar as espécies características e traços funcionais de cada camada vertical em florestas estacionais semideciduais (FES). O estudo foi realizado em 10 fragmentos (10 ha) localizadas no sudeste do Brasil. A estratificação foi realizada por espécie, utilizando a mediana e o terceiro quartil (análise estatística não-paramétrica) da altura das árvores, classificando-as em três categorias: dossel, sub-bosque e estrato intermediário. Os resultados mostram a pequena faixa do estrato intermediário, destacando a dicotomia entre o dossel e sub-bosque. As variações encontradas para os valores de quartis e mediana indicaram o estádio sucessional de cada fragmento, permitindo variações na ocupação vertical das espécies em determinadas camadas. A análise da estrutura vertical SSF permitiu uma visualização da divisão das espécies e das suas respectivas características funcionais, mostrando que cada estrato desempenha funções ecossistêmicas diferentes.

Floristic composition and similarity of 15 hectares in Central Amazon, Brazil

The Amazon region is one of the most diverse areas in the world. Research on high tropical forest diversity brings up relevant contributions to understand the mechanisms that result and support such diversity. In the present study we describe the species composition and diversity of 15 one-ha plots in the Amazonian terra firme dense forest in Brazil, and compare the floristic similarity of these plots with other nine one-ha plots. The 15 plots studied were randomly selected from permanent plots at the Embrapa Experimental site, Amazonas State in 2005. The diversity was analysed by using species richness and Shannon’s index, and by applying the Sorensen’s index for similarity and unweighted pair-group average (UPGMA) as clustering method. Mantel test was performed to study whether the differences in species composition between sites could be explained by the geographic distance between them. Overall, we identified 8 771 individuals, 264 species and 51 plant families. Most of the species were concentrated in few families and few had large number of individuals. Families presenting the highest species richness were Fabaceae (Faboideae: 22spp., Mimosoideae: 22spp.), Sapotaceae: 22spp., Lecythidaceae: 15 and Lauraceae: 13. Burseraceae had the largest number of individuals with 11.8% of the total. The ten most abundant species were: Protium hebetatum (1 037 individuals), Eschweilera coriacea (471), Licania oblongifolia (310), Pouteria minima (293), Ocotea cernua (258), Scleronema micranthum (197), Eschweilera collina (176), Licania apelata (172), Naucleopsis caloneura (170) and Psidium araca (152), which represented 36.5% of all individuals. Approximately 49% of species had up to ten individuals and 13% appeared only once in all sampled plots, showing a large occurrence of rare species. Our study area is on a forest presenting a high tree species diversity with Shannon’s diversity index of 4.49. The dendrogram showed two groups of plots with low similarity between them (less than 0.25), and the closer the plots were one to another, more similar in species composition (Mantel R=0.3627, p<0.01). The 15 plots in our study area share more than 50% of their species composition and represent the group of plots that have the shortest distance between each other. Overall, our results highlight the high local and regional heterogeneity of environments in terra firme forests, and the high occurrence of rare species, which should be considered in management and conservation programs in the Amazon rainforest, in order to maintain its structure on the long run. Rev. Biol. Trop. 59 (4): 1927-1938. Epub 2011 December 01.

La región amazónica es una de las más diversas áreas del mundo. Los estudios sobre la gran diversidad de bosques tropicales generan contribuciones relevantes en la comprensión de los mecanismos que originan y apoyan tal diversidad. En el presente estudio se describe la composición de las especies y la diversidad de 15 parcelas de una hectárea en el bosque denso amazónico terra firme en Brasil, y compara la similitud florística de estas parcelas con otras nueve parcelas de una hectárea. Las 15 parcelas estudiadas fueron seleccionadas al azar, en el 2005, de parcelas permanentes en el sitio experimental de Embrapa, Estado de Amazonas. La diversidad fue analizada utilizando la riqueza de especies y el índice de Shannon, así como el índice de Similitud de Sorensen; y como método de agrupación se utilizó el promedio no ponderado por grupo (UPGMA). La prueba de Mantel se llevó a cabo para estudiar si las diferencias en la composición de especies entre los sitios podrían ser explicadas por la distancia geográfica entre ellos. En general, se identificaron 8 771 individuos, 264 especies y 51 familias de plantas. La mayoría de las especies se concentraron en pocas familias y pocas tenían un gran número de individuos. Las familias que presentaron la mayor riqueza de especies fueron: Fabaceae (Faboideae: 22spp, Mimosoideae: 22spp), Sapotaceae: 22spp, Lecythidaceae: 15 y Lauraceae: 13. Burseraceae tuvo el mayor número de individuos con un 11.8% del total. Las diez especies más abundantes fueron: Protium hebetatum (1 037 individuos), Eschweilera coriacea (471), Licania oblongifolia (310), Pouteria minima (293), Ocotea cernua (258), Scleronema micranthum (197), Eschweilera collina (176), Licania apelata (172), Naucleopsis caloneura (170) y Psidium araca (152), que representó un 36.5% de todos los individuos. Aproximadamente en el 49% de las especies se encontraron hasta diez individuos, mientras que el 13% de las especies apareció sólo una vez en todas las parcelas de muestreo, lo que demuestra una alta presencia de especies raras. La zona de estudio se encuentra en un bosque con alta diversidad de especies de árboles, con un índice de diversidad de Shannon de 4.49. El dendrograma mostró dos grupos de parcelas con baja similitud entre ellas (menos de 0.25), y entre más cercanas las parcelas, más similares en composición de especies fueron (Mantel R=0.3627, p<0.01). Las 15 parcelas en nuestra área de estudio compartieron más del 50% de su composición de especies y representaron el grupo de parcelas con la menor distancia entre ellas. En general, nuestros resultados ponen de manifiesto la alta heterogeneidad local y regional de los ambientes de los bosques de terra firme, y la gran concurrencia de especies raras, lo cual debe ser considerado en los planes de manejo y conservación de la selva amazónica, con el fin de mantener su estructura a largo plazo.