Your search keyword '"Fontrodona-Eslava, Ada"' showing total 3 results

1. Numerical abundance and biomass reveal different temporal trends of functional diversity change in tropical fish assemblages.

Author

Fontrodona‐Eslava, Ada, Deacon, Amy E., Ramnarine, Indar W., and Magurran, Anne E.

Subjects

*ALTERNATIVE currencies, *FRESHWATER biodiversity, *FRESHWATER fishes, *HARD currencies, *BIOLOGISTS

Abstract

Understanding how the biodiversity of freshwater fish assemblages changes over time is an important challenge. Until recently most emphasis has been on taxonomic diversity, but it is now clear that measures of functional diversity (FD) can shed new light on the mechanisms that underpin this temporal change. Fish biologists use different currencies, such as numerical abundance and biomass, to measure the abundance of fish species. Nonetheless, because they are not necessarily equivalent, these alternative currencies have the potential to reveal different insights into trends of FD in natural assemblages. In this study, the authors asked how conclusions about temporal trends in FD are influenced by the way in which the abundance of species has been quantified. To do this, the authors computed two informative metrics, for each currency, for 16 freshwater fish assemblages in Trinidad's Northern Range that had been surveyed repeatedly over 5 years. The authors found that numerical abundance and biomass uncover different directional trends in these assemblages for each facet of FD, and as such inform hypotheses about the ways in which these systems are being restructured. On the basis of these results, the authors concluded that a combined approach, in which both currencies are used, contributes to our understanding of the ecological processes that are involved in biodiversity change in freshwater fish assemblages. [ABSTRACT FROM AUTHOR]

Published

2021

2. Synthesis reveals approximately balanced biotic differentiation and homogenization.

Author

Blowes, Shane A., McGill, Brian, Brambilla, Viviana, Chow, Cher F. Y., Engel, Thore, Fontrodona-Eslava, Ada, McGlinn, Daniel, Moyes, Faye, Sagouis, Alban, Shimadzu, Hideyasu, van Klink, Roel, Wu-Bing Xu, Gotelli, Nicholas J., Magurran, Anne, Dornelas, Maria, and Chase, Jonathan M.

Subjects

*ENDANGERED species, *SPATIAL variation

Abstract

It is commonly thought that the biodiversity crisis includes widespread declines in the spatial variation of species composition, called biotic homogenization. Using a typology relating homogenization and differentiation to local and regional diversity changes, we synthesize patterns across 461 metacommunities surveyed for 10 to 91 years, and 64 species checklists (13 to 500+ years). Across all datasets, we found that no change was the most common outcome, but with many instances of homogenization and differentiation. A weak homogenizing trend of a 0.3% increase in species shared among communities/year on average was driven by increased numbers of widespread (high occupancy) species and strongly associated with checklist data that have longer durations and large spatial scales. At smaller spatial and temporal scales, we show that homogenization and differentiation can be driven by changes in the number and spatial distributions of both rare and common species. The multiscale perspective introduced here can help identify scale-dependent drivers underpinning biotic differentiation and homogenization. [ABSTRACT FROM AUTHOR]

Published

2024

3. Widespread shifts in body size within populations and assemblages.

Author

Martins, Inês S., Schrodt, Franziska, Blowes, Shane A., Bates, Amanda E., Bjorkman, Anne D., Brambilla, Viviana, Carvajal-Quintero, Juan, Chow, Cher F. Y., Daskalova, Gergana N., Edwards, Kyle, Eisenhauer, Nico, Field, Richard, Fontrodona-Eslava, Ada, Henn, Jonathan J., van Klink, Roel, Madin, Joshua S., Magurran, Anne E., McWilliam, Michael, Moyes, Faye, and Pugh, Brittany

Subjects

*BODY size, *TIME series analysis, *PRICES, *BIOMASS, *FISH diversity

Abstract

Biotic responses to global change include directional shifts in organismal traits. Body size, an integrative trait that determines demographic rates and ecosystem functions, is thought to be shrinking in the Anthropocene. Here, we assessed the prevalence of body size change in six taxon groups across 5025 assemblage time series spanning 1960 to 2020. Using the Price equation to partition this change into within-species body size versus compositional changes, we detected prevailing decreases in body size through time driven primarily by fish, with more variable patterns in other taxa. We found that change in assemblage composition contributes more to body size changes than within-species trends, but both components show substantial variation in magnitude and direction. The biomass of assemblages remains quite stable as decreases in body size trade off with increases in abundance. [ABSTRACT FROM AUTHOR]

Published

2023