The influence of biogeographic history on the functional and phylogenetic diversity of passerine birds in savannas and forests of the Brazilian Amazon.

Passeriformes is the largest and most diverse avian order in the world and comprises the Passeri and Tyranni suborders. These suborders constitute a monophyletic group, but differ in their ecology and history of occupation of South America. We investigated the influence of biogeographic history on functional and phylogenetic diversities of Passeri and Tyranni in forest and savanna habitats in the Brazilian Amazon. We compiled species composition data for 34 Passeriformes assemblages, 12 in savannas and 22 in forests. We calculated the functional (Rao's quadratic entropy, FD Q ) and phylogenetic diversities (mean pairwise distance, MPD, and mean nearest taxon distance, MNTD), and the functional beta diversity to investigate the potential role of biogeographic history in shaping ecological traits and species lineages of both suborders. The functional diversity of Passeri was higher than for Tyranni in both habitats. The MPD for Tyranni was higher than for Passeri in forests; however, there was no difference between the suborders in savannas. In savannas, Passeri presented higher MNTD than Tyranni, while in forest areas, Tyranni assemblages showed higher MNTD than Passeri. We found a high functional turnover (~75%) between Passeri and Tyranni in both habitats. The high functional diversity of Passeri in both habitats is due to the high diversity of ecological traits exhibited by species of this group, which enables the exploitation of a wide variety of resources and foraging strategies. The higher Tyranni MPD and MNTD in forests is likely due to Tyranni being older settlers in this habitat, resulting in the emergence and persistence of more lineages. The higher Passeri MNTD in savannas can be explained by the existence of a larger number of different Passeri lineages adapted to this severe habitat. The high functional turnover between the suborders in both habitats suggests an ecological strategy to avoid niche overlap.

Estrutura filogenética e funcional de assembleias: (re)montando a Ecologia de Comunidades em diferentes escalas espaciais / Phylogenetic and functional assembly structure: (re)assembling the community ecology on different spatial scales

As comunidades são assembléias de espécies co-ocorrentes que interagem potencialmente umas com as outras. Elas são resultado não apenas de uma série de processos ecológicos ou "regras de montagem", mas também de processos evolutivos passados e contínuos. Nos últimos anos, as regras de montagem têm recebido maior atenção dos ecólogos e dois processos diferentes têm sido explorados: os filtros ambientais e a similaridade limitante. Como os processos envolvidos na formação das assembléias parecem variar de uma forma dependente de escala, espera-se que tais regras de montagem tenham diferentes efeitos ao longo de diferentes escalas espaciais. Compreender essa relação entre os processos ecológicos e as escalas espaciais nas quais eles atuam tem sido um grande desafio entre os estudiosos. Nesse contexto, a incorporação de dados filogenéticos e funcionais às abordagens clássicas de diversidade tem estabelecido a base de uma emergente área de pesquisa em ecologia de comunidades, impulsionando o desenvolvimento de muitas ferramentas para detectar a subjacente estrutura das assembléias e, portanto, inferir os processos de montagem responsáveis pela formação das assembléias. Aqui, demonstramos como a utilização de diferentes medidas de diversidade filogenética e funcional juntamente com o uso de diferentes modelos nulos pode ser uma abordagem promissora na solução de paradigmas ainda pouco compreendidos, discutindo como tais métodos podem aumentar o poder preditivo dessa crescente área de pesquisa.

Communities are assemblages of co-occurring species that potentially interact with each other. They are the result not only of a series of ecological processes or "assembly rules", but also of past and ongoing evolutionary processes. In recent years, the assembly rules have received increased attention from ecologists and two different processes have been explored: environmental filtering and limiting similarity. As the processes involved in the formation of the assemblages appear to vary in a manner dependent on scale, it is expected that such assembly rules have different effects over different spatial scales. Understanding this relationship between ecological processes and spatial scales in which they act has been a great challenge among scholars. In this context, the incorporation of phylogenetic and functional data to diversity classical approaches have established the basis for an emerging area of research in community ecology, promoting the development of many tools to detect the underlying structure of the assemblages and, therefore, to infer the processes assembly responsible for the formation of the assemblages. Here, we demonstrate how the use of different measures of phylogenetic and functional diversity along with the use of different null models can be a promising approach in solving paradigms still poorly understood, discussing how such methods can increase the predictive power of this growing area of research.