Drivers of global pre‐industrial patterns of species turnover in planktonic foraminifera

Rillo, Marina C.; Woolley, Skipton N. C.; Hillebrand, Helmut

doi:10.1111/ecog.05892

Cited by 18 publications

(27 citation statements)

References 54 publications

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“…Among few exceptions conducted for marine microorganisms, Holman et al (2021) found that protists and bacteria followed biogeographic structure consistent with metazoans along the coastline of South Africa. Rillo et al (2022) showed that marine planktonic foraminifera are not limited by dispersal among bioregions. These opposing findings call for more research about marine microorganism biogeography and its underlying drivers.…”

Section: Introductionmentioning

confidence: 99%

Regional and local environment drive biogeographic patterns in intertidal microorganisms

Chen

Zhang

et al. 2022

Journal of Biogeography

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Aim: Understanding large-scale spatial distribution patterns is not only a central goal of ecology but is also essential for conservation planning. Nevertheless, the biogeographical patterns of diversity and composition remain unclear for microorganisms and the role of various factors in structuring their assemblages is still poorly known.Here, we tested whether the diversity and community structure of ciliates are driven by both local environmental and regional dispersal-related processes.Location: Coasts of China.Taxon: Benthic ciliates. Methods:We sampled ciliates at 30 sandy beaches covering a latitudinal range of over 2500 km from October to November 2020. We first used generalized linear models to examine the most important predictors of ciliate alpha diversity. Then, distancebased linear models (DistLM) were used to identify the relative importance of local and regional variables in explaining community structure variability. We further used nonmetric multidimensional scaling (NMDS) and permutational multivariate analysis of variance (PERMANOVA) to reveal patterns in community structure. Results:We found that local environmental factors including beach index (BI), salinity and mean particle size (MPS) were more important in shaping ciliate alpha diversity than latitude. However, the Shannon alpha diversity index decreased with latitude, perhaps due to anthropogenic disturbances. DistLM analysis emphasized regional processes in shaping community structure. Both NMDS and PERMANOVA supported a clear separation among the three clusters matching with the ecoregional delineations suggested for macroorganisms. We also note that community trait composition was partially explained by a local factor, i.e. the maximum spring tide range of beaches.Main conclusions: Ciliate communities were driven by both local environmental and regional factors. We suggest that these biogeographic patterns may have stemmed from large-scale environmental filtering related to the outflow of Yangtze River, rather than from dispersal limitation or historical events. The current study provides a new understanding of the biogeographic patterns and underlying mechanisms of marine microorganisms, thus helping improve their management and conservation in the face of future global change.

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Section: Introductionmentioning

confidence: 99%

Regional and local environment drive biogeographic patterns in intertidal microorganisms

Chen

Zhang

et al. 2022

Journal of Biogeography

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“…The resulting graphs would have shown the contribution of differences in environmental variables to turnover and made interpreting results difficult. Instead, GDM relates changes in temporal turnover to gradients in environmental variables using monotonic I-spline functions (Rillo et al, 2022). In the resulting plots, the maximum height of each curve displays how much overall turnover is explained by each environmental variable.…”

Section: Temporal Turnover Modelsmentioning

confidence: 99%

Modeling drivers of biodiversity change emphasizes the need for multivariate assessments and rescaled targeting for management

Dajka

Carvalho

Ryabov

et al. 2022

Conservat Sci and Prac

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The current policy and goals aimed to conserve biodiversity and manage biodiversity change are often formulated at the global scale. At smaller scales however, biodiversity change is more nuanced leading to a plethora of trends in different metrics of alpha diversity and temporal turnover. Therefore, largescale policy targets do not translate easily into local to regional management decisions for biodiversity. Using long-term monitoring data from the Wadden Sea (Southern North Sea), joining structural equation models and general dissimilarity models enabled a better overview of the drivers of biodiversity change. Few commonalities emerged as birds, fish, macroinvertebrates, and phytoplankton differed in their response to certain drivers of change. These differences were additionally dependent upon the biodiversity aspect in question and which environmental data were recorded in each monitoring program. No single biodiversity metric or model sufficed to capture all ongoing change, which requires an explicitly multivariate approaches to biodiversity assessment in local ecosystem management.

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“…However, geographic variability of simple community parameters of a planktonic group has been found to be stable enough in time and space, to reflect the spatial characteristics that approach biogeographical distributions (Angel, 1991). Previous studies, focused on free floating unicellular plankton organisms, including foraminifera, have been used to understand the drivers behind species diversity distribution (Rutherford et al, 1999;Hillebrand and Azovsky, 2001;Martiny et al, 2006;Cermeño and Falkowski, 2009;Rodrıǵuez-Ramos et al, 2015;Fenton et al, 2016;Rillo et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Previous works studying the ForCenS database were all unanimous that temperature is the main driver of foraminifera community changes and respective biodiversity (e.g. Morey et al, 2005;Fenton et al, 2016;Rillo et al, 2022). However, differences arise in terms of the other drivers that were found to be important, mostly according to the environmental datasets used.…”

Section: Introductionmentioning

confidence: 99%

Ocean kinetic energy and photosynthetic biomass are important drivers of planktonic foraminifera diversity in the Atlantic Ocean

et al. 2022

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To assess the anthropogenic effect on biodiversity, it is essential to understand the global diversity distribution of the major groups at the base of the food chain, ideally before global warming initiation (1850 Common Era CE). Since organisms in the plankton are highly interconnected and carbonate synthesizing species have a good preservation state in the Atlantic Ocean, the diversity distribution pattern of planktonic foraminifera from 1741 core-top surface sediment samples (expanded ForCenS database) provides a case study to comprehend centennial to decadal time-averaged diversity patterns at pre-1970 CE times, the tempo of the substantial increase in tropospheric warming. In this work, it is hypothesized and tested for the first time, that the large-scale diversity patterns of foraminifera communities are determined by sea surface temperature (SST, representing energy), Chl-a (a surrogate for photosynthetic biomass), and ocean kinetic energy (as EKE). Alpha diversity was estimated using species richness (S), Shannon Wiener index (H), and Simpson evenness (E), and mapped using geostatistical approaches. The three indices are significantly related to SST, Chl-a, and EKE (71-88% of the deviance in the generalized additive mixed model, including a spatial component). Beta diversity was studied through species turnover using gradient forest analysis (59% of the variation). The primary community thresholds of foraminifera species turnover were associated with 5-10 °C and 22-28 °C SST, 0.05-0.15 mg m-3 Chl-a, and 1.2-2.0 cm2 s-2 log10 EKE energy, respectively. Six of the most important foraminifera species identified for the environmental thresholds of beta diversity are also fundamental in transfer functions, further reinforcing the approaches used. The geographic location of the transition between the four main biogeographic zones was redefined based on the results of beta diversity analysis and incorporating the new datasets, identifying the major marine latitudinal gradients, the most important upwelling areas (Benguela Current, Canary Current), the Equatorial divergence, and the subtropical fronts (Gulf Stream-North Atlantic Drift path in the north, and the South Atlantic current in the south). In conclusion, we provide statistical proof that energy (SST), food supply (Chl-a), and currents (EKE) are the main environmental drivers shaping planktonic foraminifera diversity in the Atlantic ocean and define the associated thresholds for species change on those variables.

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Drivers of global pre‐industrial patterns of species turnover in planktonic foraminifera

Cited by 18 publications

References 54 publications

Regional and local environment drive biogeographic patterns in intertidal microorganisms

Regional and local environment drive biogeographic patterns in intertidal microorganisms

Modeling drivers of biodiversity change emphasizes the need for multivariate assessments and rescaled targeting for management

Ocean kinetic energy and photosynthetic biomass are important drivers of planktonic foraminifera diversity in the Atlantic Ocean

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