ForCenS, a curated database of planktonic foraminifera census counts in marine surface sediment samples

Siccha, Michael; Kučera, Michal

doi:10.1038/sdata.2017.109

Cited by 93 publications

(118 citation statements)

References 41 publications

(42 reference statements)

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“…We used the Aze et al () Cenozoic phylogeny of macroperforate species as a basis to obtain phylogenetic relationships among extant PF. Following the taxonomic standardization of Siccha and Kucera (), we updated the taxon names in the Aze et al () phylogeny, removed synonyms and added newly recognized species (Supporting Information Figure S1). The final phylogeny includes 33 species (Supporting Information Figure S1); the 14 species not present in the phylogeny (e.g., microperforates) were excluded from the phylogenetic analysis.…”

Section: Methodsmentioning

confidence: 99%

“…We used the Aze et al (2011) lineage phylogeny of macroperforate Cenozoic planktonic Foraminifera for this figure F I G U R E 2 (a) Map of modern planktonic Foraminifera (PF) abundance data. Green dots, spatial data: 3,053 ocean-floor coretop samples, each with data on relative abundance of all the species present in the sample (usually larger than 150 μm; Siccha & Kucera, 2017). Orange triangles, temporal data: 35 sediment traps, each with data on abundance (shell flux) time series of PF species.…”

Section: Introductionmentioning

confidence: 99%

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On the mismatch in the strength of competition among fossil and modern species of planktonic Foraminifera

Rillo

Sugawara

Cabella

et al. 2019

Global Ecol Biogeogr

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Aim Many clades display the macroevolutionary pattern of a negative relationship between standing diversity and diversification rates. Competition among species has been proposed as the main mechanism that explains this pattern. However, we currently lack empirical insight into how the effects of individual‐level ecological interactions scale up to affect species diversification. Here, we investigate a clade that shows evidence for negative diversity‐dependent diversification in the fossil record and test whether the clade's modern communities show a corresponding signal of interspecific competition. Location World's oceans. Time period Holocene. Major taxa studied Planktonic Foraminifera (Rhizaria). Methods We explore spatial and temporal ecological patterns expected under interspecific competition. Firstly, we use a community phylogenetics approach to test for signs of local competitive exclusion among ecologically similar species (defined as closely related or of similar shell sizes) by combining species relative abundances in seafloor sediments. Secondly, we analyse whether population abundances of co‐occurring species covary negatively through time using sediment trap time‐series spanning 1–12 years. Results The great majority of the assemblages are indistinguishable from randomly assembled communities, showing no significant spatial co‐occurrence patterns regarding phylogeny or size similarity. Through time, most species pairs correlated positively, indicating synchronous rather than compensatory population dynamics. Main conclusions We found no detectable evidence for interspecific competition structuring extant planktonic Foraminifera communities. Species co‐occurrences and population dynamics are likely regulated by the abiotic environment and/or distantly related species, rather than intra‐clade density‐dependent processes. This interpretation contradicts the idea that competition drives the clade's macroevolutionary dynamics. One way to better integrate community ecology and macroevolution is to consider that diversification dynamics are influenced by groups that interact ecologically even when distantly related.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the mismatch in the strength of competition among fossil and modern species of planktonic Foraminifera

Rillo

Sugawara

Cabella

et al. 2019

Global Ecol Biogeogr

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“…For instance, in the modern tropical Caribbean, reproduction of G. truncatulinoides is inhibited by strong thermocline in well-stratified waters (Schmuker and Schiebel, 2000). This is in contrast to the subtropical N. Atlantic where winter sea surface cooling (T<23°C) and deep mixing occur alongside with increase of G. truncatulinoides 230 up to 15% (Levitus et al, 2013;Siccha and Kučera, 2017). It could, therefore, be proposed that the overall abundance of G. truncatulinoides in our subtropical settings was at least partly controlled by oceanic conditions occurring nearer to the sea surface (Mulitza et al, 1997;Jonkers and Kučera, 2016).…”

Section: Terminationmentioning

confidence: 80%

“…Also shown in (B-E) are modern relative foraminiferal abundances (average value ±1s) around Bahama Bank, computed using 7 nearest samples from Siccha and Kučera (2017) (Gibson and Peterson, 2014), (E-F) d 13 C values measured in 625 benthic foraminifera and relative abundances of G. ruber (total) and G. sacculifer from ODP Site 1063 . …”

Section: Md99-2202mentioning

confidence: 99%

“…G. sacculifer -it makes up less than 5% of the planktic foraminiferal assemblage around the LBB today (Siccha and Kučera, 2017) -is abundant in the Caribbean Sea and tropical Atlantic and commonly used as a tracer of tropical waters and geographical shifts of the ITCZ (Poore et al, 2003;Vautravers et al, 2007). Also, G. ruber (pink) shows rather coherent abundance maxima in the tropics (between 20°N and 20°S), while no such affinity is observed for G. ruber (white) and G. conglobatus (Siccha and Kučera, 2017;Schiebel and Hemleben, 2017). Therefore, fluctuations in relative 260 abundances of G. sacculifer and G. ruber (pink) are referred here as to represent a warm tropical end-member (Fig.…”

Section: Early Mis 5ementioning

confidence: 99%

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The last interglacial (MIS 5e) cycle at Little Bahama Bank: A history of climate and sea-level changes

Zhuravleva

Bauch

2018

Preprint

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Abstract. Shallow-water sediments of the Bahama region containing the last interglacial (MIS 5e) are ideal to investigate the region's sensitivity to past climatic and sea level changes. Here we present new faunal, isotopic and XRF-sediment core data 10 from the northern slope of the Little Bahama Bank. The results suggest that the bank top remained flooded across the last interglacial "plateau", ~129-117 ka, arguing for a relative sea level above -6 m for this time period. In addition, climatic variability, which today is closely coupled with movements of the intertropical convergence zone (ITCZ), is interpreted based on stable isotopes and foraminiferal assemblage records. During early MIS 5e, the mean annual ITCZ position moved northward in line with increased solar forcing and a recovered Atlantic Meridional Overturning Circulation (AMOC). The 15 early MIS 5e warmth peak was intersected, however, by a millennial-scale cooling event, consistent with a southward shift in the mean annual ITCZ position. This tropical shift is ascribed to the transitional climatic regime of early MIS 5e, characterized by persistent high-latitude freshening and, thereby, unstable AMOC mode. Our records from the Bahama region demonstrate that not only was there a tight relation between local sedimentation regimes and last interglacial sea level history, via the atmospheric forcing we could further infer an intra-interglacial connectivity between the polar and subtropical latitudes that 20 left its imprint also on the ocean circulation.

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Intraspecific size variation in planktonic foraminifera cannot be consistently predicted by the environment

Rillo

Miller

Kučera

et al. 2020

Ecology and Evolution

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The size structure of plankton communities is an important determinant of their functions in marine ecosystems. However, few studies have quantified how organism size varies within species across biogeographical scales. Here, we investigate how planktonic foraminifera, a ubiquitous zooplankton group, vary in size across the tropical and subtropical oceans of the world. Using a recently digitized museum collection, we measured shell area of 3,799 individuals of nine extant species in 53 seafloor sediments. We first analyzed potential size biases in the collection. Then, for each site, we obtained corresponding local values of mean annual sea‐surface temperature (SST), net primary productivity (NPP), and relative abundance of each species. Given former studies, we expected species to reach largest shell sizes under optimal environmental conditions. In contrast, we observe that species differ in how much their size variation is explained by SST, NPP, and/or relative abundance. While some species have predictable size variation given these variables ( Trilobatus sacculifer, Globigerinoides conglobatus, Globigerinella siphonifera, Pulleniatina obliquiloculata, Globorotalia truncatulinoides ), other species show no relationships between size and the studied covariates ( Globigerinoides ruber , Neogloboquadrina dutertrei , Globorotalia menardii, Globoconella inflata ). By incorporating intraspecific variation and sampling broader geographical ranges compared to previous studies, we conclude that shell size variation in planktonic foraminifera species cannot be consistently predicted by the environment. Our results caution against the general use of size as a proxy for planktonic foraminifera environmental optima. More generally, our work highlights the utility of natural history collections and the importance of studying intraspecific variation when interpreting macroecological patterns.

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ForCenS, a curated database of planktonic foraminifera census counts in marine surface sediment samples

Cited by 93 publications

References 41 publications

On the mismatch in the strength of competition among fossil and modern species of planktonic Foraminifera

On the mismatch in the strength of competition among fossil and modern species of planktonic Foraminifera

The last interglacial (MIS 5e) cycle at Little Bahama Bank: A history of climate and sea-level changes

Intraspecific size variation in planktonic foraminifera cannot be consistently predicted by the environment

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