Your search keyword '"Weiner, Agnes K. M."' showing total 27 results

1. Taxonomic and abundance biases affect the record of marine eukaryotic plankton communities in sediment DNA archives.

Author

Nguyen, Ngoc‐Loi, Pawłowska, Joanna, Zajaczkowski, Marek, Weiner, Agnes K. M., Cordier, Tristan, Grant, Danielle M., De Schepper, Stijn, and Pawłowski, Jan

Subjects

MARINE sediments, MARINE plankton, WATER depth, PRYMNESIOPHYCEAE, TAPHONOMY, MARINE biodiversity

Abstract

Environmental DNA (eDNA) preserved in marine sediments is increasingly being used to study past ecosystems. However, little is known about how accurately marine biodiversity is recorded in sediment eDNA archives, especially planktonic taxa. Here, we address this question by comparing eukaryotic diversity in 273 eDNA samples from three water depths and the surface sediments of 24 stations in the Nordic Seas. Analysis of 18S‐V9 metabarcoding data reveals distinct eukaryotic assemblages between water and sediment eDNA. Only 40% of Amplicon Sequence Variants (ASVs) detected in water were also found in sediment eDNA. Remarkably, the ASVs shared between water and sediment accounted for 80% of total sequence reads suggesting that a large amount of plankton DNA is transported to the seafloor, predominantly from abundant phytoplankton taxa. However, not all plankton taxa were equally archived on the seafloor. The plankton DNA deposited in the sediments was dominated by diatoms and showed an underrepresentation of certain nano‐ and picoplankton taxa (Picozoa or Prymnesiophyceae). Our study offers the first insights into the patterns of plankton diversity recorded in sediment in relation to seasonality and spatial variability of environmental conditions in the Nordic Seas. Our results suggest that the genetic composition and structure of the plankton community vary considerably throughout the water column and differ from what accumulates in the sediment. Hence, the interpretation of sedimentary eDNA archives should take into account potential taxonomic and abundance biases when reconstructing past changes in marine biodiversity. [ABSTRACT FROM AUTHOR]

Published

2024

2. The global genetic diversity of planktonic foraminifera reveals the structure of cryptic speciation in plankton

Author

Morard, Raphaël, primary, Darling, Kate F., additional, Weiner, Agnes K. M., additional, Hassenrück, Christiane, additional, Vanni, Chiara, additional, Cordier, Tristan, additional, Henry, Nicolas, additional, Greco, Mattia, additional, Vollmar, Nele M., additional, Milivojevic, Tamara, additional, Rahman, Shirin Nurshan, additional, Siccha, Michael, additional, Meilland, Julie, additional, Jonkers, Lukas, additional, Quillévéré, Frédéric, additional, Escarguel, Gilles, additional, Douady, Christophe J., additional, de Garidel‐Thoron, Thibault, additional, de Vargas, Colomban, additional, and Kucera, Michal, additional

Published

2024

3. Single-cell transcriptomics supports presence of cryptic species and reveals low levels of population genetic diversity in two testate amoebae morphospecies with large population sizes

Author

Weiner, Agnes K M, primary, Sehein, Taylor, additional, Cote-L'Heureux, Auden, additional, Sleith, Robin S, additional, Greco, Mattia, additional, Malekshahi, Clara, additional, Ryan-Embry, Chase, additional, Ostriker, Naomi, additional, and Katz, Laura A, additional

Published

2023

4. Sedimentary ancient DNA: a new paleogenomic tool for reconstructing the history of marine ecosystems

Author

Nguyen, Ngoc-Loi, primary, Devendra, Dhanushka, additional, Szymańska, Natalia, additional, Greco, Mattia, additional, Angeles, Inès Barrenechea, additional, Weiner, Agnes K. M., additional, Ray, Jessica Louise, additional, Cordier, Tristan, additional, De Schepper, Stijn, additional, Pawłowski, Jan, additional, and Pawłowska, Joanna, additional

Published

2023

5. Nomenclature for the Nameless: A Proposal for an Integrative Molecular Taxonomy of Cryptic Diversity Exemplified by Planktonic Foraminifera

Author

Morard, Raphaël, Escarguel, Gilles, Weiner, Agnes K. M., André, Aurore, Douady, Christophe J., Wade, Christopher M., Darling, Kate F., Ujiié, Yurika, Seears, Heidi A., Quillévéré, Frédéric, de Garidel-Thoron, Thibault, de Vargas, Colomban, and Kucera, Michal

Published

2016

6. Sedimentary ancient DNA: a new paleogenomic tool for reconstructing the history of marine ecosystems

Author

Nguyen, Ngoc-Loi, Devendra, Dhanushka, Szymanska, Natalia, Greco, Mattia, Barrenechea Angeles, Inés Andrea, Weiner, Agnes K. M., Ray, Jessica Louise, Cordier, Tristan, De Schepper, Stijn, Pawłowski, Jan, and Pawłowska, Joanna

Abstract

Sedimentary ancient DNA (sedaDNA) offers a novel retrospective approach to reconstructing the history of marine ecosystems over geological timescales. Until now, the biological proxies used to reconstruct paleoceanographic and paleoecological conditions were limited to organisms whose remains are preserved in the fossil record. The development of ancient DNA analysis techniques substantially expands the range of studied taxa, providing a holistic overview of past biodiversity. Future development of marine sedaDNA research is expected to dramatically improve our understanding of how the marine biota responded to changing environmental conditions. However, as an emerging approach, marine sedaDNA holds many challenges, and its ability to recover reliable past biodiversity information needs to be carefully assessed. This review aims to highlight current advances in marine sedaDNA research and to discuss potential methodological pitfalls and limitations.

Published

2023

7. The Development of Ocean Currents and the Response of the Cryosphere on the Southwest Svalbard Shelf Over the Holocene

Author

Devendra, Dhanushka, primary, Łącka, Magdalena, additional, Szymańska, Natalia, additional, Szymczak-Żyła, Małgorzata, additional, Krajewska, Magdalena, additional, Weiner, Agnes K. M., additional, De Schepper, Stijn, additional, Simon, Margit Hildegard, additional, and Zajączkowski, Marek, additional

Published

2023

8. Foraminifera as a model of the extensive variability in genome dynamics among eukaryotes

Author

Goetz, Eleanor J., primary, Greco, Mattia, additional, Rappaport, Hannah B., additional, Weiner, Agnes K. M., additional, Walker, Laura M., additional, Bowser, Samuel, additional, Goldstein, Susan, additional, and Katz, Laura A., additional

Published

2022

9. Additional results from Reproduction dynamics of planktonic microbial eukaryotes in the open ocean

Author

Weinkauf, Manuel F. G., Siccha, Michael, and Weiner, Agnes K. M.

Abstract

Additional details of the reproduction model and supplementary results.

Published

2022

10. Reproduction dynamics of planktonic microbial eukaryotes in the open ocean

Author

Weinkauf, Manuel F. G., primary, Siccha, Michael, additional, and Weiner, Agnes K. M., additional

Published

2022

11. Epigenetics as Driver of Adaptation and Diversification in Microbial Eukaryotes

Author

Weiner, Agnes K. M., primary and Katz, Laura A., additional

Published

2021

12. Reproduction strategies in a marine protist: A digital experiment

Author

Weinkauf, Manuel F. G., primary, Siccha, Michael, additional, and Weiner, Agnes K. M., additional

Published

2021

13. Reproduction of a marine planktonic protist: Individual success versus population survival

Author

Weinkauf, Manuel F. G., primary, Siccha, Michael, additional, and Weiner, Agnes K. M., additional

Published

2020

14. Phylogenomics of the Epigenetic Toolkit Reveals Punctate Retention of Genes across Eukaryotes

Author

Weiner, Agnes K M, primary, Cerón-Romero, Mario A, additional, Yan, Ying, additional, and Katz, Laura A, additional

Published

2020

15. High Diversity of Testate Amoebae (Amoebozoa, Arcellinida) Detected by HTS Analyses in a New England Fen using Newly Designed Taxon‐specific Primers

Author

Ruggiero, Alistaire, primary, Grattepanche, Jean‐David, additional, Weiner, Agnes K. M., additional, and Katz, Laura A., additional

Published

2020

16. Genetic and morphological divergence in the warm-water planktonic foraminifera genus Globigerinoides

Author

Morard, Raphaël, Füllberg, Angelina, Brummer, Geert-Jan A., Greco, Mattia, Jonkers, Lukas, Wizemann, André, Weiner, Agnes K. M., Darling, Kate, Siccha, Michael, Ledevin, Ronan, Kitazato, Hiroshi, de Garidel-Thoron, Thibault, de Vargas, Colomban, Kucera, Michal, Center for Marine Environmental Sciences [Bremen] (MARUM), Universität Bremen, Utrecht University [Utrecht], Leibniz Centre for Tropical Marine Research (ZMT), University of Edinburgh, De la Préhistoire à l'Actuel : Culture, Environnement et Anthropologie (PACEA), Université de Bordeaux (UB)-Centre National de la Recherche Scientifique (CNRS), Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Centre européen de recherche et d'enseignement des géosciences de l'environnement (CEREGE), Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Station biologique de Roscoff (SBR), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Natural Environment Research Council of the United Kingdom (NER/J/S2000/00860 and NE/D009707/1), the Leverhulme Trust and the Carnegie Trust for the Universities of Scotland, from DFG-Research Center/Cluster of Excellence ‘The Ocean in the Earth System’, from the Deutsche Forschungsgemeinschaft KU2259/19 and through the Cluster of Excellence 'The Ocean Floor – Earth’s Uncharted Interface'., ANR-09-BLAN-0348,POSEIDON(2009), ANR-06-JCJC-0142,PALEO-CTD,PALeo-Hydroloy : Exploiting Oceanic Cryptic Taxonomic Diversity of planktonic foraminifera(2006), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Collège de France (CdF)-Institut national des sciences de l'Univers (INSU - CNRS)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), ANR-09-BLAN-0348,POSEIDON,PrOtiSts EcologIcal bioDiversity in Tara-OceaNs(2009), ANR-JCJC06-0142-PALEO-CTD,ANR-JCJC06-0142-PALEO-CTD, Earth and Climate, Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Collège de France (CdF (institution))-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Recherche Agronomique (INRA), University of St Andrews. School of Geography & Sustainable Development, Frontalini, Fabrizio, and Centre National de la Recherche Scientifique (CNRS)-Université de Bordeaux (UB)

Subjects

Computer and Information Sciences, Evolutionary Processes, Speciation, QH301 Biology, Science, Foraminifera, QH426 Genetics, [SDV.BID]Life Sciences [q-bio]/Biodiversity, [SDV.MP.PRO]Life Sciences [q-bio]/Microbiology and Parasitology/Protistology, QH301, Genetics, Morphogenesis, Animals, Evolutionary Systematics, QH426, Phylogeny, Data Management, Taxonomy, Evolutionary Biology, Phylogenetic analysis, Geography, Population Biology, Cryptic speciation, Ecology and Environmental Sciences, Organisms, Biology and Life Sciences, Paleontology, Eukaryota, Genetic Variation, DAS, Plankton, Invertebrates, Biological Evolution, Phylogenetics, Phylogeography, Biogeography, Earth Sciences, Medicine, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Paleogenetics, Population Genetics, Research Article, Developmental Biology

Abstract

This work was supported by grants from ANR-09-BLAN-0348 POSEIDON, ANR-JCJC06-0142-PALEO-CTD, from Natural Environment Research Council of the United Kingdom (NER/J/S2000/00860 and NE/D009707/1), the Leverhulme Trust and the Carnegie Trust for the Universities of Scotland, from DFG-Research Center/Cluster of Excellence ‘The Ocean in the Earth System’, from the Deutsche Forschungsgemeinschaft KU2259/19 and through the Cluster of Excellence “The Ocean Floor – Earth’s Uncharted Interface”. The planktonic foraminifera genus Globigerinoides provides a prime example of a species-rich genus in which genetic and morphological divergence are uncorrelated. To shed light on the evolutionary processes that lead to the present-day diversity of Globigerinoides, we investigated the genetic, ecological and morphological divergence of its constituent species. We assembled a global collection of single-cell barcode sequences and show that the genus consists of eight distinct genetic types organized in five extant morphospecies. Based on morphological evidence, we reassign the species Globoturborotalita tenella to Globigerinoides and amend Globigerinoides ruber by formally proposing two new subspecies, G. ruber albus n.subsp. and G. ruber ruber in order to express their subspecies level distinction and to replace the informal G. ruber “white” and G. ruber “pink”, respectively. The genetic types within G. ruber and Globigerinoides elongatus show a combination of endemism and coexistence, with little evidence for ecological differentiation. CT-scanning and ontogeny analysis reveal that the diagnostic differences in adult morphologies could be explained by alterations of the ontogenetic trajectories towards final (reproductive) size. This indicates that heterochrony may have caused the observed decoupling between genetic and morphological diversification within the genus. We find little evidence for environmental forcing of either the genetic or the morphological diversification, which allude to biotic interactions such as symbiosis, as the driver of speciation in Globigerinoides. Publisher PDF

Published

2019

17. Seasonal and interannual variability in population dynamics of planktic foraminifers off Puerto Rico (Caribbean Sea)

Author

Jentzen, Anna, Schönfeld, Joachim, Weiner, Agnes K. M., Weinkauf, Manuel F. G., Nürnberg, Dirk, and Kucera, Michal

Subjects

Assemblage structure, Climate, ddc:550, Planktonic Foraminifera, Atlantic Ocean

Abstract

The state of a population of planktic foraminifers at a certain time reflects multiple processes in the upper ocean, including environmental conditions to which the population was exposed during its growth, the age of the cohorts, and spatiotemporal patchiness. We carried out depth-stratified (0–60, 60–100 m) replicated sampling off Puerto Rico in autumn 2012, revisiting three stations previously sampled in autumn 1994 and spring 1995, in order to analyze seasonal and interannual variability of planktic foraminifers and the stable isotopic composition of their tests. The merged dataset from all three sampling campaigns allows us to assess short- and long-term changes in foraminiferal population dynamics and the spatial assemblage coherency along the shelf edge. All three sample series cover more than 2 weeks during either spring (1995) or autumn (1994, 2012) and include the time of the full moon when reproduction of some surface-dwelling planktic foraminifers has been postulated to take place. Our analyses indicate that interannual variability affected the faunal composition, and both autumn assemblages were characterized by oligotrophic tropical species, dominated by Trilobatus sacculifer and Globigerinoides ruber (white and pink variety). However, G. ruber (white) had a higher abundance in 1994 (37 %) than in 2012 (3.5 %), which may be partially due to increasing sea surface temperatures since the 1990s. Between 60 and 100 m water depth, a different faunal composition with a specific stable oxygen isotope signature provides evidence for the presence of the Subtropical Underwater at the sampling site. Measurements on T. sacculifer sampled in autumn 2012 revealed that test size, calcification and incidence of sac-like chambers continued to increase after full moon, and thus no relation to the synodic lunar reproduction cycle was recognized. During autumn 2012, outer bands of hurricane Sandy passed the Greater Antilles and likely affected the foraminifers. Lower standing stocks of living planktic foraminifers and lower stable carbon isotope values from individuals collected in the mixed layer likely indicate the response to increased rainfall and turbidity in the wake of the hurricane.

Published

2019

18. Caught in the act: Anatomy of an ongoing benthic-planktonic transition in a marine protist

Author

Kucera, Michal, Silye, Lorand, Weiner, Agnes K. M., Darling, Kate, Lübben, Birgit, Holzmann, Maria, Pawlowski, Jan, Schönfeld, Joachim, Morard, Raphael, Kucera, Michal, Silye, Lorand, Weiner, Agnes K. M., Darling, Kate, Lübben, Birgit, Holzmann, Maria, Pawlowski, Jan, Schönfeld, Joachim, and Morard, Raphael

Abstract

The transition from benthos to plankton requires multiple adaptations, yet so far it remains unclear how these are acquired in the course of the transition. To investigate this process, we analyzed the genetic diversity and distribution patterns of a group of foraminifera of the genus Bolivina with a tychopelagic mode of life (same species occurring both in benthos and plankton). We assembled a global sequence data set for this group from single-cell DNA extractions and occurrences in metabarcodes from pelagic environmental samples. The pelagic sequences all cluster within a single monophyletic clade within Bolivina. This clade harbors three distinct genetic lineages, which are associated with incipient morphological differentiation. All lineages occur in the plankton and benthos, but only one lineage exhibits no limit to offshore dispersal and has been shown to grow in the plankton. These observations indicate that the emergence of buoyancy regulation within the clade preceded the evolution of pelagic feeding and that the evolution of both traits was not channeled into a full transition into the plankton. We infer that in foraminifera, colonization of the planktonic niche may occur by sequential cooptation of independently acquired traits, with holoplanktonic species being recruited from tychopelagic ancestors

Published

2017

19. Methodology for Single-Cell Genetic Analysis of Planktonic Foraminifera for Studies of Protist Diversity and Evolution

Author

Weiner, Agnes K. M., Morard, Raphael, Weinkauf, Manuel F. G., Darling, Kate F., André, Aurore, Quillévéré, Frédéric, Ujiie, Yurika, Douady, Christophe J., De Vargas, Colomban, Kucera, Michal, Weiner, Agnes K. M., Morard, Raphael, Weinkauf, Manuel F. G., Darling, Kate F., André, Aurore, Quillévéré, Frédéric, Ujiie, Yurika, Douady, Christophe J., De Vargas, Colomban, and Kucera, Michal

Abstract

Single-cell genetic analysis is an essential method to investigate the biodiversity and evolutionary ecology of marine protists. In protist groups that do not reproduce under laboratory conditions, this approach provides the only means to directly associate molecular sequences with cell morphology. The resulting unambiguous taxonomic identification of the DNA sequences is a prerequisite for barcoding and analyses of environmental metagenomic data. Extensive single-cell genetic studies have been carried out on planktonic foraminifera over the past 20 years to elucidate their phylogeny, cryptic diversity, biogeography, and the relationship between genetic and morphological variability. In the course of these investigations, it has become evident that genetic analysis at the individual specimen level is confronted by innumerable challenges ranging from the negligible amount of DNA present in the single cell to the substantial amount of DNA contamination introduced by endosymbionts or food particles. Consequently, a range of methods has been developed and applied throughout the years for the genetic analysis of planktonic foraminifera in order to enhance DNA amplification success rates. Yet, the description of these methods in the literature rarely occurred with equivalent levels of detail and the different approaches have never been compared in terms of their efficiency and reproducibility. Here, aiming at a standardization of methods, we provide a comprehensive review of all methods that have been employed for the single-cell genetic analysis of planktonic foraminifera. We compile data on success rates of DNA amplification and use these to evaluate the effects of key parameters associated with the methods of sample collection, storage and extraction of single-cell DNA. We show that the chosen methods influence the success rates of single-cell genetic studies, but the differences between them are not sufficient to hinder comparisons between studies carried out by diffe

Published

2016

20. Methodology for Single-Cell Genetic Analysis of Planktonic Foraminifera for Studies of Protist Diversity and Evolution

Author

Weiner, Agnes K. M., primary, Morard, Raphael, additional, Weinkauf, Manuel F. G., additional, Darling, Kate F., additional, André, Aurore, additional, Quillévéré, Frédéric, additional, Ujiie, Yurika, additional, Douady, Christophe J., additional, de Vargas, Colomban, additional, and Kucera, Michal, additional

Published

2016

21. PFR2: a curated database of planktonic foraminifera 18S ribosomal DNA as a resource for studies of plankton ecology, biogeography and evolution

Author

Morard, Raphaël, primary, Darling, Kate F., additional, Mahé, Frédéric, additional, Audic, Stéphane, additional, Ujiié, Yurika, additional, Weiner, Agnes K. M., additional, André, Aurore, additional, Seears, Heidi A., additional, Wade, Christopher M., additional, Quillévéré, Frédéric, additional, Douady, Christophe J., additional, Escarguel, Gilles, additional, de Garidel‐Thoron, Thibault, additional, Siccha, Michael, additional, Kucera, Michal, additional, and de Vargas, Colomban, additional

Published

2015

22. PFR2: a curated database of planktonic foraminifera 18S ribosomal DNA as a resource for studies of plankton ecology, biogeography and evolution.

Author

Morard, Raphaël, Darling, Kate F., Mahé, Frédéric, Audic, Stéphane, Ujiié, Yurika, Weiner, Agnes K. M., André, Aurore, Seears, Heidi A., Wade, Christopher M., Quillévéré, Frédéric, Douady, Christophe J., Escarguel, Gilles, Garidel‐Thoron, Thibault, Siccha, Michael, Kucera, Michal, and Vargas, Colomban

Subjects

FORAMINIFERA, ECOLOGY of plankton, RIBOSOMAL DNA, MOLECULAR ecology, TAXONOMY

Abstract

Planktonic foraminifera (Rhizaria) are ubiquitous marine pelagic protists producing calcareous shells with conspicuous morphology. They play an important role in the marine carbon cycle, and their exceptional fossil record serves as the basis for biochronostratigraphy and past climate reconstructions. A major worldwide sampling effort over the last two decades has resulted in the establishment of multiple large collections of cryopreserved individual planktonic foraminifera samples. Thousands of 18S r DNA partial sequences have been generated, representing all major known morphological taxa across their worldwide oceanic range. This comprehensive data coverage provides an opportunity to assess patterns of molecular ecology and evolution in a holistic way for an entire group of planktonic protists. We combined all available published and unpublished genetic data to build PFR2, the Planktonic foraminifera Ribosomal Reference database. The first version of the database includes 3322 reference 18S r DNA sequences belonging to 32 of the 47 known morphospecies of extant planktonic foraminifera, collected from 460 oceanic stations. All sequences have been rigorously taxonomically curated using a six-rank annotation system fully resolved to the morphological species level and linked to a series of metadata. The PFR2 website, available at , allows downloading the entire database or specific sections, as well as the identification of new planktonic foraminiferal sequences. Its novel, fully documented curation process integrates advances in morphological and molecular taxonomy. It allows for an increase in its taxonomic resolution and assures that integrity is maintained by including a complete contingency tracking of annotations and assuring that the annotations remain internally consistent. [ABSTRACT FROM AUTHOR]

Published

2015

23. Protists as mediators of complex microbial and viral associations.

Author

Schulz F, Yan Y, Weiner AKM, Ahsan R, Katz LA, and Woyke T

Abstract

Microbial eukaryotes (aka protists) are known for their important roles in nutrient cycling across different ecosystems. However, the composition and function of protist-associated microbiomes remains largely elusive. Here, we employ cultivation-independent single-cell isolation and genome-resolved metagenomics to provide detailed insights into underexplored microbiomes and viromes of over 100 currently uncultivable ciliates and amoebae isolated from diverse environments. Our findings reveal unique microbiome compositions and hint at an intricate network of complex interactions and associations with bacterial symbionts and viruses. We observed stark differences between ciliates and amoebae in terms of microbiome and virome compositions, highlighting the specificity of protist-microbe interactions. Over 115 of the recovered microbial genomes were affiliated with known endosymbionts of eukaryotes, including diverse members of the Holosporales, Rickettsiales, Legionellales, Chlamydiae, Dependentiae , and more than 250 were affiliated with possible host-associated bacteria of the phylum Patescibacteria. We also identified more than 80 giant viruses belonging to diverse viral lineages, of which some were actively expressing genes in single cell transcriptomes, suggesting a possible association with the sampled protists. We also revealed a wide range of other viruses that were predicted to infect eukaryotes or host-associated bacteria. Our results provide further evidence that protists serve as mediators of complex microbial and viral associations, playing a critical role in ecological networks. The frequent co-occurrence of giant viruses and diverse microbial symbionts in our samples suggests multipartite associations, particularly among amoebae. Our study provides a preliminary assessment of the microbial diversity associated with lesser-known protist lineages and paves the way for a deeper understanding of protist ecology and their roles in environmental and human health.

Published

2024

24. Testate amoebae (Arcellinida, Amoebozoa) community diversity in New England bogs and fens assessed through lineage-specific amplicon sequencing.

Author

Dufour OK, Hoffman E, Sleith RS, Katz LA, Weiner AKM, and Sehein TR

Subjects

Ecosystem, Wetlands, Phylogeny, New England, Amoeba genetics, Amoebozoa, Lobosea

Abstract

Testate amoebae (order Arcellinida) are abundant in freshwater ecosystems, including low pH bogs and fens. Within these environments, Arcellinida are considered top predators in microbial food webs and their tests are useful bioindicators of paleoclimatic changes and anthropogenic pollutants. Accurate species identifications and characterizations of diversity are important for studies of paleoclimate, microbial ecology, and environmental change; however, morphological species definitions mask cryptic diversity, which is a common phenomenon among microbial eukaryotes. Lineage-specific primers recently designed to target Arcellinida for amplicon sequencing successfully captured a poorly-described yet diverse fraction of the microbial eukaryotic community. Here, we leveraged the application of these newly-designed primers to survey the diversity of Arcellinida in four low-pH New England bogs and fens, investigating variation among bogs (2018) and then across seasons and habitats within two bogs (2019). Three OTUs represented 66% of Arcellinida reads obtained across all habitats surveyed. 103 additional OTUs were present in lower abundance with some OTUs detected in only one sampling location, suggesting habitat specificity. By establishing a baseline for Arcellinida diversity, we provide a foundation to monitor key taxa in habitats that are predicted to change with increasing anthropogenic pressure and rapid climate change., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier GmbH. All rights reserved.)

Published

2024

25. Taxon-rich transcriptomics supports higher-level phylogeny and major evolutionary trends in Foraminifera.

Author

Sierra R, Mauffrey F, Cruz J, Holzmann M, Gooday AJ, Maurer-Alcalá X, Thakur R, Greco M, Weiner AKM, Katz LA, and Pawlowski J

Subjects

Biological Evolution, Phylogeny, RNA, Ribosomal, 18S genetics, Transcriptome, Foraminifera genetics, Rhizaria genetics

Abstract

Foraminifera, classified in the supergroup Rhizaria, are a common and highly diverse group of mainly marine protists. Despite their evolutionary and ecological importance, only limited genomic data (one partial genome and nine transcriptomic datasets) have been published for this group. Foraminiferal molecular phylogeny is largely based on 18S rRNA gene sequence analysis. However, due to highly variable evolutionary rates of substitution in ribosomal genes plus the existence of intragenomic variation at this locus, the relationships between and within foraminiferal classes remain uncertain. We analyze transcriptomic data from 28 species, adding 19 new species to the previously published dataset, including members of the strongly under-represented class Monothalamea. A phylogenomic reconstruction of Rhizaria, rooted with alveolates and stramenopiles, based on 199 genes and 68 species supports the monophyly of Foraminifera and their sister relationship to Polycystinea. The phylogenomic tree of Foraminifera is very similar to the 18S rRNA tree, with the paraphyletic single-chambered monothalamids giving rise to the multi-chambered Tubothalamea and Globothalamea. Within the Monothalamea, our analyses confirm the monophyly of the giant, deep-sea xenophyophores that branch within clade C and indicate the basal position of monothalamous clades D and E. The multi-chambered Globothalamea are monophyletic and comprise the paraphyletic Textulariida and monophyletic Rotaliida. Our phylogenomic analyses support major evolutionary trends of Foraminifera revealed by ribosomal phylogenies and reinforce their current higher-level classification., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

26. Examining the Relationship Between the Testate Amoeba Hyalosphenia papilio (Arcellinida, Amoebozoa) and its Associated Intracellular Microalgae Using Molecular and Microscopic Methods.

Author

Weiner AKM, Cullison B, Date SV, Tyml T, Volland JM, Woyke T, Katz LA, and Sleith RS

Subjects

Symbiosis, Amoeba, Amoebozoa genetics, Chlorella genetics, Lobosea, Microalgae

Abstract

Symbiotic relationships between heterotrophic and phototrophic partners are common in microbial eukaryotes. Among Arcellinida (Amoebozoa) several species are associated with microalgae of the genus Chlorella (Archaeplastida). So far, these symbioses were assumed to be stable and mutualistic, yet details of the interactions are limited. Here, we analyzed 22 single-cell transcriptomes and 36 partially-sequenced genomes of the Arcellinida morphospecies Hyalosphenia papilio, which contains Chlorella algae, to shed light on the amoeba-algae association. By characterizing the genetic diversity of associated Chlorella, we detected two distinct clades that can be linked to host genetic diversity, yet at the same time show a biogeographic signal across sampling sites. Fluorescence and transmission electron microscopy showed the presence of intact algae cells within the amoeba cell. Yet analysis of transcriptome data suggested that the algal nuclei are inactive, implying that instead of a stable, mutualistic relationship, the algae may be temporarily exploited for photosynthetic activity before being digested. Differences in gene expression of H. papilio and Hyalosphenia elegans demonstrated increased expression of genes related to oxidative stress. Together, our analyses increase knowledge of this host-symbiont association and reveal 1) higher diversity of associated algae than previously characterized, 2) a transient association between H. papilio and Chlorella with unclear benefits for the algae, 3) algal-induced gene expression changes in the host., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021 Elsevier GmbH. All rights reserved.)

Published

2022

27. DAPI staining and DNA content estimation of nuclei in uncultivable microbial eukaryotes (Arcellinida and Ciliates).

Author

Munyenyembe K, Timmons C, Weiner AKM, Katz LA, and Yan Y

Subjects

DNA, Indoles, Phylogeny, Staining and Labeling, Ciliophora genetics, Lobosea

Abstract

Though representing a major component of eukaryotic biodiversity, many microbial eukaryotes remain poorly studied, including the focus of the present work, testate amoebae of the order Arcellinida (Amoebozoa) and non-model lineages of ciliates (Alveolata). In particular, knowledge of genome structures and changes in genome content over the often-complex life cycles of these lineages remains enigmatic. However, the limited available knowledge suggests that microbial eukaryotes have the potential to challenge our textbook views on eukaryotic genomes and genome evolution. In this study, we developed protocols for DAPI (4',6-diamidino-2-phenylindole) staining of Arcellinida nuclei and adapted protocols for ciliates. In addition, image analysis software was used to estimate the DNA content in the nuclei of Arcellinida and ciliates, and the measurements of target organisms were compared to those  of well-known model organisms.The results demonstrate that the methods we have developed for nuclear staining in these lineages are effective and can be applied to other microbial eukaryotic groups by adjusting certain stages in the protocols., (Copyright © 2021 Elsevier GmbH. All rights reserved.)

Published

2021