Your search keyword '"Pawlowski, J."' showing total 24 results

1. Encapsulated in sediments: eDNA deciphers the ecosystem history of one of the most polluted European marine sites.

Author

Barrenechea Angeles I, Romero-Martínez ML, Cavaliere M, Varrella S, Francescangeli F, Piredda R, Mazzocchi MG, Montresor M, Schirone A, Delbono I, Margiotta F, Corinaldesi C, Chiavarini S, Montereali MR, Rimauro J, Parrella L, Musco L, Dell'Anno A, Tangherlini M, Pawlowski J, and Frontalini F

Subjects

Humans, Animals, Biota, Europe, Human Activities, Geologic Sediments, Ecosystem, Biodiversity

Abstract

The Anthropocene is characterized by dramatic ecosystem changes driven by human activities. The impact of these activities can be assessed by different geochemical and paleontological proxies. However, each of these proxies provides only a fragmentary insight into the effects of anthropogenic impacts. It is highly challenging to reconstruct, with a holistic view, the state of the ecosystems from the preindustrial period to the present day, covering all biological components, from prokaryotes to multicellular eukaryotes. Here, we used sedimentary ancient DNA (sedaDNA) archives encompassing all trophic levels of biodiversity to reconstruct the two century-natural history in Bagnoli-Coroglio (Gulf of Pozzuoli, Tyrrhenian Sea), one of the most polluted marine-coastal sites in Europe. The site was characterized by seagrass meadows and high eukaryotic diversity until the beginning of the 20th century. Then, the ecosystem completely changed, with seagrasses and associated fauna as well as diverse groups of planktonic and benthic protists being replaced by low diversity biota dominated by dinophyceans and infaunal metazoan species. The sedaDNA analysis revealed a five-phase evolution of the area, where changes appear as the result of a multi-level cascade effect of impacts associated with industrial activities, urbanization, water circulation and land-use changes. The sedaDNA allowed to infer reference conditions that must be considered when restoration actions are to be implemented., 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 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

2. Scientific and budgetary trade-offs between morphological and molecular methods for deep-sea biodiversity assessment.

Author

Le JT, Levin LA, Lejzerowicz F, Cordier T, Gooday AJ, and Pawlowski J

Subjects

Biomass, Mining, Surveys and Questionnaires, Biodiversity, Ecosystem

Abstract

Deep-sea biodiversity, a source of critical ecological functions and ecosystem services, is increasingly subject to the threat of disturbance from existing practices (e.g., fishing, waste disposal, oil and gas extraction) as well as emerging industries such as deep-seabed mining. Current scientific tools may not be adequate for monitoring and assessing subsequent changes to biodiversity. In this paper, we evaluate the scientific and budgetary trade-offs associated with morphology-based taxonomy and metabarcoding approaches to biodiversity surveys in the context of nascent deep-seabed mining for polymetallic nodules in the Clarion-Clipperton Zone, the area of most intense interest. For the dominant taxa of benthic meiofauna, we discuss the types of information produced by these methods and use cost-effectiveness analysis to compare their abilities to yield biological and ecological data for use in environmental assessment and management. On the basis of our evaluation, morphology-based taxonomy is less cost-effective than metabarcoding but offers scientific advantages, such as the generation of density, biomass, and size structure data. Approaches that combine the two methods during the environmental assessment phase of commercial activities may facilitate future biodiversity monitoring and assessment for deep-seabed mining and for other activities in remote deep-sea habitats, for which taxonomic data and expertise are limited. Integr Environ Assess Manag 2022;18:655-663. © 2021 SETAC., (© 2021 SETAC.)

Published

2022

3. Broad sampling of monothalamids (Rhizaria, Foraminifera) gives further insight into diversity of non-marine Foraminifera.

Author

Siemensma F, Holzmann M, Apothéloz-Perret-Gentil L, Clauß S, Voelcker E, Bettighofer W, Roshan SK, Walden S, Dumack K, and Pawlowski J

Subjects

Austria, DNA, Protozoan genetics, DNA, Ribosomal genetics, Foraminifera cytology, Foraminifera genetics, Germany, Phylogeny, Soil parasitology, Species Specificity, Biodiversity, Foraminifera classification, Fresh Water parasitology

Abstract

Non-marine foraminifera are among the least known groups of protists and only a handful of species have been described since the 19th century. We collected one naked and five morphologically almost identical organic-walled monothalamid species from freshwater and terrestrial environments from Germany and Austria. One of the species was identified as Lieberkuehnia wageneriClaparède and Lachmann, 1859. As its original description is ambiguous and its type specimen has been lost, a neotype is proposed. We describe four new organic-walled monothalamous foraminifera and a novel Reticulomyxa species both morphologically and genetically. Analyses of molecular data of the different isolates revealed that they are distributed across six different clades. Two new genera, Claparedellus gen. nov. and Velamentofex gen. nov., and five new monothalamous families, Lacogromiidae fam. nov., Limnogromiidae fam. nov., Lieberkuehniidae fam. nov., Edaphoallogromiidae fam. nov. and Velamentofexidae fam. nov., are established., (Copyright © 2020 Elsevier GmbH. All rights reserved.)

Published

2021

4. Ecological variables for deep-ocean monitoring must include microbiota and meiofauna for effective conservation.

Author

Ingels J, Vanreusel A, Pape E, Pasotti F, Macheriotou L, Arbizu PM, Sørensen MV, Edgcomb VP, Sharma J, Sánchez N, Homoky WB, Woulds C, Leduc D, Gooday AJ, Pawlowski J, Dolan JR, Schratzberger M, Gollner S, Schoenle A, Arndt H, and Zeppilli D

Subjects

Oceans and Seas, Biodiversity, Microbiota

Published

2021

5. Planktonic foraminifera genomic variations reflect paleoceanographic changes in the Arctic: evidence from sedimentary ancient DNA.

Author

Pawłowska J, Wollenburg JE, Zajączkowski M, and Pawlowski J

Subjects

Arctic Regions, Evolution, Molecular, Foraminifera classification, Fossils, Paleography, Phylogeny, Biodiversity, DNA, Ancient analysis, Foraminifera genetics, Foraminifera growth & development, Genetic Variation, Genomics methods, Geologic Sediments analysis

Abstract

Deciphering the evolution of marine plankton is typically based on the study of microfossil groups. Cryptic speciation is common in these groups, and large intragenomic variations occur in ribosomal RNA genes of many morphospecies. In this study, we correlated the distribution of ribosomal amplicon sequence variants (ASVs) with paleoceanographic changes by analyzing the high-throughput sequence data assigned to Neogloboquadrina pachyderma in a 140,000-year-old sediment core from the Arctic Ocean. The sedimentary ancient DNA demonstrated the occurrence of various N. pachyderma ASVs whose occurrence and dominance varied through time. Most remarkable was the striking appearance of ASV18, which was nearly absent in older sediments but became dominant during the last glacial maximum and continues to persist today. Although the molecular ecology of planktonic foraminifera is still poorly known, the analysis of their intragenomic variations through time has the potential to provide new insight into the evolution of marine biodiversity and may lead to the development of new and important paleoceanographic proxies.

Published

2020

6. Diatom diversity through HTS-metabarcoding in coastal European seas.

Author

Piredda R, Claverie JM, Decelle J, de Vargas C, Dunthorn M, Edvardsen B, Eikrem W, Forster D, Kooistra WHCF, Logares R, Massana R, Montresor M, Not F, Ogata H, Pawlowski J, Romac S, Sarno D, Stoeck T, and Zingone A

Subjects

DNA Barcoding, Taxonomic, DNA, Protozoan chemistry, Diatoms classification, Metagenome, Oceans and Seas, Phylogeny, RNA, Ribosomal genetics, Biodiversity, DNA, Protozoan genetics, Diatoms genetics

Abstract

Diatoms constitute a diverse lineage of unicellular organisms abundant and ecologically important in aquatic ecosystems. Compared to other protists, their biology and taxonomy are well-studied, offering the opportunity to combine traditional approaches and new technologies. We examined a dataset of diatom 18S rRNA- and rDNA- (V4 region) reads from different plankton size-fractions and sediments from six European coastal marine sites, with the aim of identifying peculiarities and commonalities with respect to the whole protistan community. Almost all metabarcodes (99.6%) were assigned to known genera (121) and species (236), the most abundant of which were those already known from classic studies and coincided with those seen in light microscopy. rDNA and rRNA showed comparable patterns for the dominant taxa, but rRNA revealed a much higher diversity particularly in the sediment communities. Peculiar to diatoms is a tight bentho-pelagic coupling, with many benthic or planktonic species colonizing both water column and sediments and the dominance of planktonic species in both habitats. Overall metabarcoding results reflected the marked specificity of diatoms compared to other protistan groups in terms of morphological and ecological characteristics, at the same time confirming their great potential in the description of protist communities.

Published

2018

7. Supervised machine learning outperforms taxonomy-based environmental DNA metabarcoding applied to biomonitoring.

Author

Cordier T, Forster D, Dufresne Y, Martins CIM, Stoeck T, and Pawlowski J

Subjects

Biomarkers analysis, Computer Simulation, RNA, Ribosomal genetics, Bacteria classification, Biodiversity, DNA Barcoding, Taxonomic methods, Environmental Monitoring methods, Eukaryota classification, Metagenomics methods, Supervised Machine Learning

Abstract

Biodiversity monitoring is the standard for environmental impact assessment of anthropogenic activities. Several recent studies showed that high-throughput amplicon sequencing of environmental DNA (eDNA metabarcoding) could overcome many limitations of the traditional morphotaxonomy-based bioassessment. Recently, we demonstrated that supervised machine learning (SML) can be used to predict accurate biotic indices values from eDNA metabarcoding data, regardless of the taxonomic affiliation of the sequences. However, it is unknown to which extent the accuracy of such models depends on taxonomic resolution of molecular markers or how SML compares with metabarcoding approaches targeting well-established bioindicator species. In this study, we address these issues by training predictive models upon five different ribosomal bacterial and eukaryotic markers and measuring their performance to assess the environmental impact of marine aquaculture on independent data sets. Our results show that all tested markers are yielding accurate predictive models and that they all outperform the assessment relying solely on taxonomically assigned sequences. Remarkably, we did not find any significant difference in the performance of the models built using universal eukaryotic or prokaryotic markers. Using any molecular marker with a taxonomic range broad enough to comprise different potential bioindicator taxa, SML approach can overcome the limits of taxonomy-based eDNA bioassessment., (© 2018 John Wiley & Sons Ltd.)

Published

2018

8. The future of biotic indices in the ecogenomic era: Integrating (e)DNA metabarcoding in biological assessment of aquatic ecosystems.

Author

Pawlowski J, Kelly-Quinn M, Altermatt F, Apothéloz-Perret-Gentil L, Beja P, Boggero A, Borja A, Bouchez A, Cordier T, Domaizon I, Feio MJ, Filipe AF, Fornaroli R, Graf W, Herder J, van der Hoorn B, Iwan Jones J, Sagova-Mareckova M, Moritz C, Barquín J, Piggott JJ, Pinna M, Rimet F, Rinkevich B, Sousa-Santos C, Specchia V, Trobajo R, Vasselon V, Vitecek S, Zimmerman J, Weigand A, Leese F, and Kahlert M

Subjects

Ecosystem, Biodiversity, DNA Barcoding, Taxonomic, Environmental Monitoring methods

Abstract

The bioassessment of aquatic ecosystems is currently based on various biotic indices that use the occurrence and/or abundance of selected taxonomic groups to define ecological status. These conventional indices have some limitations, often related to difficulties in morphological identification of bioindicator taxa. Recent development of DNA barcoding and metabarcoding could potentially alleviate some of these limitations, by using DNA sequences instead of morphology to identify organisms and to characterize a given ecosystem. In this paper, we review the structure of conventional biotic indices, and we present the results of pilot metabarcoding studies using environmental DNA to infer biotic indices. We discuss the main advantages and pitfalls of metabarcoding approaches to assess parameters such as richness, abundance, taxonomic composition and species ecological values, to be used for calculation of biotic indices. We present some future developments to fully exploit the potential of metabarcoding data and improve the accuracy and precision of their analysis. We also propose some recommendations for the future integration of DNA metabarcoding to routine biomonitoring programs., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

9. Taxonomy-free molecular diatom index for high-throughput eDNA biomonitoring.

Author

Apothéloz-Perret-Gentil L, Cordonier A, Straub F, Iseli J, Esling P, and Pawlowski J

Subjects

Diatoms classification, Rivers microbiology, Switzerland, Biodiversity, DNA Barcoding, Taxonomic methods, Diatoms genetics, Metagenomics methods

Abstract

Current biodiversity assessment and biomonitoring are largely based on the morphological identification of selected bioindicator taxa. Recently, several attempts have been made to use eDNA metabarcoding as an alternative tool. However, until now, most applied metabarcoding studies have been based on the taxonomic assignment of sequences that provides reference to morphospecies ecology. Usually, only a small portion of metabarcoding data can be used due to a limited reference database and a lack of phylogenetic resolution. Here, we investigate the possibility to overcome these limitations using a taxonomy-free approach that allows the computing of a molecular index directly from eDNA data without any reference to morphotaxonomy. As a case study, we use the benthic diatoms index, commonly used for monitoring the biological quality of rivers and streams. We analysed 87 epilithic samples from Swiss rivers, the ecological status of which was established based on the microscopic identification of diatom species. We compared the diatom index derived from eDNA data obtained with or without taxonomic assignment. Our taxonomy-free approach yields promising results by providing a correct assessment for 77% of examined sites. The main advantage of this method is that almost 95% of OTUs could be used for index calculation, compared to 35% in the case of the taxonomic assignment approach. Its main limitations are under-sampling and the need to calibrate the index based on the microscopic assessment of diatoms communities. However, once calibrated, the taxonomy-free molecular index can be easily standardized and applied in routine biomonitoring, as a complementary tool allowing fast and cost-effective assessment of the biological quality of watercourses., (© 2017 John Wiley & Sons Ltd.)

Published

2017

10. High-throughput sequencing and morphology perform equally well for benthic monitoring of marine ecosystems.

Author

Lejzerowicz F, Esling P, Pillet L, Wilding TA, Black KD, and Pawlowski J

Subjects

Animals, Computational Biology methods, DNA Barcoding, Taxonomic, Environmental Monitoring, High-Throughput Nucleotide Sequencing, Aquatic Organisms, Biodiversity, Ecosystem

Abstract

Environmental diversity surveys are crucial for the bioassessment of anthropogenic impacts on marine ecosystems. Traditional benthic monitoring relying on morphotaxonomic inventories of macrofaunal communities is expensive, time-consuming and expertise-demanding. High-throughput sequencing of environmental DNA barcodes (metabarcoding) offers an alternative to describe biological communities. However, whether the metabarcoding approach meets the quality standards of benthic monitoring remains to be tested. Here, we compared morphological and eDNA/RNA-based inventories of metazoans from samples collected at 10 stations around a fish farm in Scotland, including near-cage and distant zones. For each of 5 replicate samples per station, we sequenced the V4 region of the 18S rRNA gene using the Illumina technology. After filtering, we obtained 841,766 metazoan sequences clustered in 163 Operational Taxonomic Units (OTUs). We assigned the OTUs by combining local BLAST searches with phylogenetic analyses. We calculated two commonly used indices: the Infaunal Trophic Index and the AZTI Marine Biotic Index. We found that the molecular data faithfully reflect the morphology-based indices and provides an equivalent assessment of the impact associated with fish farms activities. We advocate that future benthic monitoring should integrate metabarcoding as a rapid and accurate tool for the evaluation of the quality of marine benthic ecosystems.

Published

2015

11. Next-generation environmental diversity surveys of foraminifera: preparing the future.

Author

Pawlowski J, Lejzerowicz F, and Esling P

Subjects

High-Throughput Nucleotide Sequencing standards, High-Throughput Nucleotide Sequencing trends, Research standards, Research trends, Biodiversity, Environment, Foraminifera classification

Abstract

Foraminifera are commonly defined as marine testate protists, and their diversity is mainly assessed on the basis of the morphology of their agglutinated or mineralized tests. Diversity surveys based on environmental DNA (eDNA) have dramatically changed this view by revealing an unexpected diversity of naked and organic-walled lineages as well as detecting foraminiferal lineages in soil and freshwater environments. Moreover, single-cell analyses have allowed discrimination among genetically distinctive types within almost every described morphospecies. In view of these studies, the foraminiferal diversity appeared to be largely underestimated, but its accurate estimation was impeded by the low speed and coverage of a cloning-based eDNA approach. With the advent of high-throughput sequencing (HTS) technologies, these limitations disappeared in favor of exhaustive descriptions of foraminiferal diversity in numerous samples. Yet, the biases and errors identified in early HTS studies raised some questions about the accuracy of HTS data and their biological interpretation. Among the most controversial issues affecting the reliability of HTS diversity estimates are (1) the impact of technical and biological biases, (2) the sensitivity and specificity of taxonomic sequence assignment, (3) the ability to distinguish rare species, and (4) the quantitative interpretation of HTS data. Here, we document the lessons learned from previous HTS surveys and present the current advances and applications focusing on foraminiferal eDNA. We discuss the problems associated with HTS approaches and predict the future trends and avenues that hold promises for surveying foraminiferal diversity accurately and efficiently., (© 2014 Marine Biological Laboratory.)

Published

2014

12. The Marine Microbial Eukaryote Transcriptome Sequencing Project (MMETSP): illuminating the functional diversity of eukaryotic life in the oceans through transcriptome sequencing.

Author

Keeling PJ, Burki F, Wilcox HM, Allam B, Allen EE, Amaral-Zettler LA, Armbrust EV, Archibald JM, Bharti AK, Bell CJ, Beszteri B, Bidle KD, Cameron CT, Campbell L, Caron DA, Cattolico RA, Collier JL, Coyne K, Davy SK, Deschamps P, Dyhrman ST, Edvardsen B, Gates RD, Gobler CJ, Greenwood SJ, Guida SM, Jacobi JL, Jakobsen KS, James ER, Jenkins B, John U, Johnson MD, Juhl AR, Kamp A, Katz LA, Kiene R, Kudryavtsev A, Leander BS, Lin S, Lovejoy C, Lynn D, Marchetti A, McManus G, Nedelcu AM, Menden-Deuer S, Miceli C, Mock T, Montresor M, Moran MA, Murray S, Nadathur G, Nagai S, Ngam PB, Palenik B, Pawlowski J, Petroni G, Piganeau G, Posewitz MC, Rengefors K, Romano G, Rumpho ME, Rynearson T, Schilling KB, Schroeder DC, Simpson AG, Slamovits CH, Smith DR, Smith GJ, Smith SR, Sosik HM, Stief P, Theriot E, Twary SN, Umale PE, Vaulot D, Wawrik B, Wheeler GL, Wilson WH, Xu Y, Zingone A, and Worden AZ

Subjects

Databases, Factual, Molecular Sequence Data, Sequence Analysis, Biodiversity, Environmental Microbiology, Eukaryota, Oceans and Seas, Transcriptome

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2014

13. Patterns of rare and abundant marine microbial eukaryotes.

Author

Logares R, Audic S, Bass D, Bittner L, Boutte C, Christen R, Claverie JM, Decelle J, Dolan JR, Dunthorn M, Edvardsen B, Gobet A, Kooistra WH, Mahé F, Not F, Ogata H, Pawlowski J, Pernice MC, Romac S, Shalchian-Tabrizi K, Simon N, Stoeck T, Santini S, Siano R, Wincker P, Zingone A, Richards TA, de Vargas C, and Massana R

Subjects

Atlantic Ocean, Base Sequence, Cluster Analysis, Europe, High-Throughput Nucleotide Sequencing, Mediterranean Sea, Molecular Sequence Data, North Sea, Population Density, RNA, Ribosomal, 18S genetics, Species Specificity, Biodiversity, Eukaryota genetics, Eukaryota physiology, Marine Biology statistics & numerical data, Microbiota genetics, Phylogeny

Abstract

Background: Biological communities are normally composed of a few abundant and many rare species. This pattern is particularly prominent in microbial communities, in which most constituent taxa are usually extremely rare. Although abundant and rare subcommunities may present intrinsic characteristics that could be crucial for understanding community dynamics and ecosystem functioning, microbiologists normally do not differentiate between them. Here, we investigate abundant and rare subcommunities of marine microbial eukaryotes, a crucial group of organisms that remains among the least-explored biodiversity components of the biosphere. We surveyed surface waters of six separate coastal locations in Europe, independently considering the picoplankton, nanoplankton, and microplankton/mesoplankton organismal size fractions., Results: Deep Illumina sequencing of the 18S rRNA indicated that the abundant regional community was mostly structured by organismal size fraction, whereas the rare regional community was mainly structured by geographic origin. However, some abundant and rare taxa presented similar biogeography, pointing to spatiotemporal structure in the rare microeukaryote biosphere. Abundant and rare subcommunities presented regular proportions across samples, indicating similar species-abundance distributions despite taxonomic compositional variation. Several taxa were abundant in one location and rare in other locations, suggesting large oscillations in abundance. The substantial amount of metabolically active lineages found in the rare biosphere suggests that this subcommunity constitutes a diversity reservoir that can respond rapidly to environmental change., Conclusions: We propose that marine planktonic microeukaryote assemblages incorporate dynamic and metabolically active abundant and rare subcommunities, with contrasting structuring patterns but fairly regular proportions, across space and time., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

14. A critique of Rossberg et al.: Noise obscures the genetic signal of meiobiotal ecospecies in ecogenomic datasets.

Author

Morgan MJ, Bass D, Bik H, Birky CW, Blaxter M, Crisp MD, Derycke S, Fitch D, Fontaneto D, Hardy CM, King AJ, Kiontke KC, Moens T, Pawlowski JW, Porazinska D, Tang CQ, Thomas WK, Yeates DK, and Creer S

Subjects

Humans, Biodiversity, Genetic Variation, Phylogeny

Published

2014

15. Ultra-deep sequencing of foraminiferal microbarcodes unveils hidden richness of early monothalamous lineages in deep-sea sediments.

Author

Lecroq B, Lejzerowicz F, Bachar D, Christen R, Esling P, Baerlocher L, Østerås M, Farinelli L, and Pawlowski J

Subjects

Base Sequence, Geography, Oceans and Seas, Biodiversity, DNA Barcoding, Taxonomic methods, Foraminifera classification, Foraminifera genetics, Geologic Sediments parasitology, High-Throughput Nucleotide Sequencing methods, Phylogeny

Abstract

Deep-sea floors represent one of the largest and most complex ecosystems on Earth but remain essentially unexplored. The vastness and remoteness of this ecosystem make deep-sea sampling difficult, hampering traditional taxonomic observations and diversity assessment. This problem is particularly true in the case of the deep-sea meiofauna, which largely comprises small-sized, fragile, and difficult-to-identify metazoans and protists. Here, we introduce an ultra-deep sequencing-based metagenetic approach to examine the richness of benthic foraminifera, a principal component of deep-sea meiofauna. We used Illumina sequencing technology to assess foraminiferal richness in 31 unsieved deep-sea sediment samples from five distinct oceanic regions. We sequenced an extremely short fragment (36 bases) of the small subunit ribosomal DNA hypervariable region 37f, which has been shown to accurately distinguish foraminiferal species. In total, we obtained 495,978 unique sequences that were grouped into 1,643 operational taxonomic units, of which about half (841) could be reliably assigned to foraminifera. The vast majority of the operational taxonomic units (nearly 90%) were either assigned to early (ancient) lineages of soft-walled, single-chambered (monothalamous) foraminifera or remained undetermined and yet possibly belong to unknown early lineages. Contrasting with the classical view of multichambered taxa dominating foraminiferal assemblages, our work reflects an unexpected diversity of monothalamous lineages that are as yet unknown using conventional micropaleontological observations. Although we can only speculate about their morphology, the immense richness of deep-sea phylotypes revealed by this study suggests that ultra-deep sequencing can improve understanding of deep-sea benthic diversity considered until now as unknowable based on a traditional taxonomic approach.

Published

2011

16. Eukaryotic richness in the abyss: insights from pyrotag sequencing.

Author

Pawlowski J, Christen R, Lecroq B, Bachar D, Shahbazkia HR, Amaral-Zettler L, and Guillou L

Subjects

Animals, Geologic Sediments, Oceans and Seas, RNA, Ribosomal, 18S genetics, Biodiversity, Eukaryota classification, Eukaryota genetics, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, RNA methods

Abstract

Background: The deep sea floor is considered one of the most diverse ecosystems on Earth. Recent environmental DNA surveys based on clone libraries of rRNA genes confirm this observation and reveal a high diversity of eukaryotes present in deep-sea sediment samples. However, environmental clone-library surveys yield only a modest number of sequences with which to evaluate the diversity of abyssal eukaryotes., Methodology/principal Findings: Here, we examined the richness of eukaryotic DNA in deep Arctic and Southern Ocean samples using massively parallel sequencing of the 18S ribosomal RNA (rRNA) V9 hypervariable region. In very small volumes of sediments, ranging from 0.35 to 0.7 g, we recovered up to 7,499 unique sequences per sample. By clustering sequences having up to 3 differences, we observed from 942 to 1756 Operational Taxonomic Units (OTUs) per sample. Taxonomic analyses of these OTUs showed that DNA of all major groups of eukaryotes is represented at the deep-sea floor. The dinoflagellates, cercozoans, ciliates, and euglenozoans predominate, contributing to 17%, 16%, 10%, and 8% of all assigned OTUs, respectively. Interestingly, many sequences represent photosynthetic taxa or are similar to those reported from the environmental surveys of surface waters. Moreover, each sample contained from 31 to 71 different metazoan OTUs despite the small sample volume collected. This indicates that a significant faction of the eukaryotic DNA sequences likely do not belong to living organisms, but represent either free, extracellular DNA or remains and resting stages of planktonic species., Conclusions/significance: In view of our study, the deep-sea floor appears as a global DNA repository, which preserves genetic information about organisms living in the sediment, as well as in the water column above it. This information can be used for future monitoring of past and present environmental changes.

Published

2011

17. Bipolar gene flow in deep-sea benthic foraminifera.

Author

Pawlowski J, Fahrni J, Lecroq B, Longet D, Cornelius N, Excoffier L, Cedhagen T, and Gooday AJ

Subjects

Antarctic Regions, Arctic Regions, Evolution, Molecular, Geography, Oceans and Seas, Phylogeny, RNA, Ribosomal chemistry, Biodiversity, Gene Flow

Abstract

Despite its often featureless appearance, the deep-ocean floor includes some of the most diverse habitats on Earth. However, the accurate assessment of global deep-sea diversity is impeded by a paucity of data on the geographical ranges of bottom-dwelling species, particularly at the genetic level. Here, we present molecular evidence for exceptionally wide distribution of benthic foraminifera, which constitute the major part of deep-sea meiofauna. Our analyses of nuclear ribosomal RNA genes revealed high genetic similarity between Arctic and Antarctic populations of three common deep-sea foraminiferal species (Epistominella exigua, Cibicides wuellerstorfi and Oridorsalis umbonatus), separated by distances of up to 17, 000 km. Our results contrast with the substantial level of cryptic diversity usually revealed by molecular studies, of shallow-water benthic and planktonic marine organisms. The very broad ranges of the deep-sea foraminifera that we examined support the hypothesis of global distribution of small eukaryotes and suggest that deep-sea biodiversity may be more modest at global scales than present estimates suggest.

Published

2007

18. First insights into the biodiversity and biogeography of the Southern Ocean deep sea.

Author

Brandt A, Gooday AJ, Brandão SN, Brix S, Brökeland W, Cedhagen T, Choudhury M, Cornelius N, Danis B, De Mesel I, Diaz RJ, Gillan DC, Ebbe B, Howe JA, Janussen D, Kaiser S, Linse K, Malyutina M, Pawlowski J, Raupach M, and Vanreusel A

Subjects

Animals, Antarctic Regions, Invertebrates classification, Invertebrates physiology, Marine Biology, Oceans and Seas, Phylogeny, Biodiversity, Geography, Seawater

Abstract

Shallow marine benthic communities around Antarctica show high levels of endemism, gigantism, slow growth, longevity and late maturity, as well as adaptive radiations that have generated considerable biodiversity in some taxa. The deeper parts of the Southern Ocean exhibit some unique environmental features, including a very deep continental shelf and a weakly stratified water column, and are the source for much of the deep water in the world ocean. These features suggest that deep-sea faunas around the Antarctic may be related both to adjacent shelf communities and to those in other oceans. Unlike shallow-water Antarctic benthic communities, however, little is known about life in this vast deep-sea region. Here, we report new data from recent sampling expeditions in the deep Weddell Sea and adjacent areas (748-6,348 m water depth) that reveal high levels of new biodiversity; for example, 674 isopods species, of which 585 were new to science. Bathymetric and biogeographic trends varied between taxa. In groups such as the isopods and polychaetes, slope assemblages included species that have invaded from the shelf. In other taxa, the shelf and slope assemblages were more distinct. Abyssal faunas tended to have stronger links to other oceans, particularly the Atlantic, but mainly in taxa with good dispersal capabilities, such as the Foraminifera. The isopods, ostracods and nematodes, which are poor dispersers, include many species currently known only from the Southern Ocean. Our findings challenge suggestions that deep-sea diversity is depressed in the Southern Ocean and provide a basis for exploring the evolutionary significance of the varied biogeographic patterns observed in this remote environment.

Published

2007

19. Unexpected foraminiferal diversity revealed by small-subunit rDNA analysis of Antarctic sediment.

Author

Habura A, Pawlowski J, Hanes SD, and Bowser SS

Subjects

Animals, Antarctic Regions, Cluster Analysis, DNA, Protozoan chemistry, DNA, Protozoan isolation & purification, DNA, Ribosomal chemistry, DNA, Ribosomal isolation & purification, Eukaryota genetics, Genes, rRNA genetics, Molecular Sequence Data, Phylogeny, Polymerase Chain Reaction, RNA, Ribosomal, 18S genetics, Seasons, Sequence Analysis, DNA, Biodiversity, Eukaryota classification, Eukaryota isolation & purification, Geologic Sediments parasitology

Abstract

Studies of benthic Foraminifera typically rely on the morphological identification of dried specimens. This approach can introduce sampling bias against small, delicate, or morphologically ambiguous forms. To overcome this limitation, we extracted total DNA from sediment followed by PCR using group- and species-specific primers. Phylogenetic analyses revealed that approximately ninety percent of the PCR products represented previously undescribed sequence types that group with undersampled members of the allogromiid Foraminifera. We also used a modification of this technique to track individual species in sediment fractions too fine for normal morphological identification, and to confirm species placement of morphologically ambiguous foraminiferans. We were able to identify the DNA of several large foraminiferal species in fine fractions in a seasonally-dependent manner, indicating that in some seasons the majority of the standing stock of these species exists as gametes/juveniles. The approach outlined here represents a powerful strategy for exploring the total diversity of benthic foraminiferal communities.

Published

2004

20. Protist metabarcoding and environmental biomonitoring: Time for change.

Author

Pawlowski, J., Lejzerowicz, F., Apotheloz-Perret-Gentil, L., Visco, J., and Esling, P.

Subjects

PROTISTA, ENVIRONMENTAL monitoring, NUCLEOTIDE sequence, BIODIVERSITY, PHYLOGENY, FORAMINIFERA

Abstract

High-throughput amplicon sequencing of environmental DNA and/or RNA proved to be a powerful tool to describe protist diversity. This new approach called also the metabarcoding has totally transformed our view of protist diversity, revealing a large number of novel lineages and expanding the range of protist phylogenetic diversity at almost every taxonomic level. However, until now the objectives of the vast majority of metabarcoding studies were purely academic. Practical applications of protist metabarcoding are surprisingly scarce, despite the fact that several groups of protists are commonly used as bioindicators of environmental impacts in freshwater or marine ecosystems. Here, we are reviewing studies that examine the ecological applications of metabarcoding for two groups of well-known protist bioindicators: diatoms and foraminifera. The results of these studies show that despite some biological and technical biases, molecular data quite faithfully reflect the morphology-based biotic indices and provide a similar assessment of ecosystem status. In view of these results, protist metabarcoding appears as a rapid and accurate tool for the evaluation of the quality of aquatic ecosystems. Hence, we plead for integration of protist metabarcoding in future biomonitoring projects as a complement of traditional methods and a source of new biosensors for environmental impact assessment. [ABSTRACT FROM AUTHOR]

Published

2016

21. One-year survey of a single Micronesian reef reveals extraordinarily rich diversity of Symbiodinium types in soritid foraminifera.

Author

Pochon, X., Garcia-Cuetos, L., Baker, A. C., Castella, E., and Pawlowski, J.

Subjects

SORITIDAE, FORAMINIFERA, CORAL reefs & islands, BIODIVERSITY, RIBOSOMES, DNA, GENETICS, PHYLOGENY

Abstract

Recent molecular studies of symbiotic dinoflagellates (genus Symbiodinium) from a wide array of invertebrate hosts have revealed exceptional fine-scale symbiont diversity whose distribution among hosts, regions and environments exhibits significant biogeographic, ecological and evolutionary patterns. Here, similar molecular approaches using the internal transcribed spacer-2 (ITS-2) region were applied to investigate cryptic diversity in Symbiodinium inhabiting soritid foraminifera. Approximately 1,000 soritid specimens were collected and examined during a 12-month period over a 40 m depth gradient from a single reef in Guam, Micronesia. Out of 61 ITS-2 types distinguished, 46 were novel. Most types found are specific for soritid hosts, except for three types (C1, C15 and C19) that are common in metazoan hosts. The distribution of these symbionts was compared with the phylotype of their foraminiferal hosts, based on soritid small subunit ribosomal DNA sequences, and three new phylotypes of soritid hosts were identified based on these sequences. Phylogenetic analyses of 645 host-symbiont pairings revealed that most Symbiodinium types associated specifically with a particular foraminiferal host genus or species, and that the genetic diversity of these symbiont types was positively correlated with the genetic diversity found within each of the three host genera. Compared to previous molecular studies of Symbiodinium from other locations worldwide, the diversity reported here is exceptional and suggests that Micronesian coral reefs are home to a remarkably large Symbiodinium assemblage. [ABSTRACT FROM AUTHOR]

Published

2007

22. Environmental RNA outperforms eDNA metabarcoding in assessing impact of marine pollution: A chromium-spiked mesocosm test

Author

Mattia Greco, Franck Lejzerowicz, Emanuela Reo, Antonio Caruso, Antonella Maccotta, Rodolfo Coccioni, Jan Pawlowski, Fabrizio Frontalini, Greco M., Lejzerowicz F., Reo E., Caruso A., Maccotta A., Coccioni R., Pawlowski J., and Frontalini F.

Subjects

Chromium, Environmental Engineering, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, eRNA, General Medicine, General Chemistry, Foraminifera, Mesocosm, Biodiversity, Settore GEO/01 - Paleontologia E Paleoecologia, Ecotoxicology, Pollution, Settore GEO/08 - Geochimica E Vulcanologia, Metabarcoding, Environmental Chemistry, DNA Barcoding, Taxonomic, RNA, eDNA, Ecosystem, Environmental Monitoring

Abstract

Environmental (e)DNA metabarcoding holds great promise for biomonitoring and ecotoxicological applications. However, few studies have compared the performance of eDNA versus eRNA metabarcoding in assessing organismal response to marine pollution, in experimental conditions. Here, we performed a chromium (Cr)-spiked mesocosm experimental test on benthic foraminiferal community to investigate the effects on species diversity by analysing both eDNA and eRNA metabarcoding data across different Cr concentrations in the sediment. Foraminiferal diversity in the eRNA data showed a significant negative correlation with the Cr concentration in the sediment, while a positive response was observed in the eDNA data. The foraminiferal OTUs exhibited a higher turnover rate in eRNA than in the eDNA-derived community. Furthermore, in the eRNA samples, OTUs abundance was significantly affected by the Cr gradient in the sediment (Pseudo-R2 = 0.28, p = 0.05), while no significant trend was observed in the eDNA samples. The correlation between Cr concentration and foraminiferal diversity in eRNA datasets was stronger when the less abundant OTUs (

Published

2022

23. Assessing the effect of mercury pollution on cultured benthic foraminifera community using morphological and eDNA metabarcoding approaches

Author

Maria Pia Nardelli, Mattia Greco, Emanuela Reo, Claudia Cosentino, Rodolfo Coccioni, Franck Lejzerowicz, Giovanna Scopelliti, Maria Teresa Losada, Fabrizio Frontalini, Letizia Di Bella, Jan Pawlowski, Antonella Maccotta, Eric Armynot du Châtelet, Antonio Caruso, Frontalini, F., Greco, M., Di Bella, L., Lejzerowicz, F., Reo, E., Caruso, A., Cosentino, C., Maccotta, A., Scopelliti, G., Nardelli M., P., Losada M., T., Armynot Du Châtelet, Coccioni, R., and Pawlowski, J.

Subjects

0301 basic medicine, Pollution, mercury pollution, Geologic Sediments, media_common.quotation_subject, benthic foraminifera, Benthic foraminifera, Biomonitoring, Mercury pollution, Metabarcoding, Foraminifera, 010501 environmental sciences, Aquatic Science, Oceanography, 01 natural sciences, Mesocosm, 03 medical and health sciences, Biomonitoring, Mediterranean Sea, DNA Barcoding, Taxonomic, Environmental DNA, Seawater, metabarcoding biomonitoring, 0105 earth and related environmental sciences, media_common, biology, Ecology, Benthic foraminifera, Biodiversity, Mercury, DNA, Protozoan, Mercury pollution, biology.organism_classification, Metabarcoding, 030104 developmental biology, Italy, 13. Climate action, Benthic zone, Bioaccumulation, Bioindicator, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Mercury (Hg) is a highly toxic element for living organisms and is known to bioaccumulate and biomagnify. Here, we analyze the response of benthic foraminifera communities cultured in mesocosm and exposed to different concentrations of Hg. Standard morphological analyses and environmental DNA metabarcoding show evidence that Hg pollution has detrimental effects on benthic foraminifera. The molecular analysis provides a more complete view of foraminiferal communities including the soft-walled single-chambered monothalamiids and small-sized hard-shelled rotaliids and textulariids than the morphological one. Among these taxa that are typically overlooked in morphological studies we found potential bioindicators of Hg pollution. The mesocosm approach proves to be an effective method to study benthic foraminiferal responses to various types and concentrations of pollutants over time. This study further supports foraminiferal metabarcoding as a complementary and/or alternative method to standard biomonitoring program based on the morphological identification of species communities.

Published

2018

24. DNAqua-Net: Developing new genetic tools for bioassessment and monitoring of aquatic ecosystems in Europe

Author

Jóhannes Guðbrandsson, Peter M. Hollingsworth, Berry van der Hoorn, Irma Vitonytė, Per Sundberg, Agnès Bouchez, Snaedis H. Bjornsdottir, Pavel Stoev, Lyubomir Penev, Vallo Mulk, Trude Vrålstad, Daniel Hering, Ana Rotter, Adam Petrusek, Mary Kelly-Quinn, Jeremy J. Piggott, Emre Keskin, Zuzana Ciamporova-Zatovicova, Martin Pfannkuchen, Astrid Schmidt-Kloiber, Matteo Montagna, Baruch Rinkevich, Martyn Kelly, Roman Wenne, Filipe O. Costa, Atle M. Bones, Diego Fontaneto, Marlen Vasquez Hadjilyra, Maja Mejdandzic, Sigitas Šulčius, Craig R. Primmer, Patricia Mergen, Wolfram Graf, Jan Pawlowski, Alice Valentini, Lieven Bervoets, Belma Kalamujić Stroil, Florian Leese, Costas S. Tsigenopoulos, Kristian Meissner, Frédéric Rimet, Zrinka Ljubešić, Torbjørn Ekrem, Arjen G. C. L. Speksnijder, Kristel Panksep, Marieta Costache, Maria Kahlert, Panagiotis Kasapidis, Bella Japoshvili, Zoltán Csabai, Alexander M. Weigand, Michael Grabowski, Kessy Abarenkov, Wolfgang Wägele, Kristy Deiner, Michael Traugott, Jonas Zimmermann, Jens Carlsson, Anne Winding, Yaron Hershkovitz, Gábor Várbíró, Bojana Zegura, Judit Padisák, Urmas Kõljalg, Florian Altermatt, Elvira Mächler, Jean-François Flot, John Jones, Micaela Hellström, Dirk Steinke, Andrew R. Mahon, Georgina Mircheva, Stina Drakare, Simon Creer, Alfried P. Vogler, Pedro Segurado, Ion Năvodaru, Ángel DelValls, Pedro Beja, Andreja Naumoski, Irena Maček, Marketa Marečková, Pierre Taberlet, J.R. Viguri, Stefano Fazi, Ángel Borja, Malin Strand, Eric Coissac, Guy Woodward, Vera G. Fonseca, Snæbjörn Pálsson, Tina Elersek, Angela Boggero, Cene Fišer, Xavier Turon, Christian Moritz, Fedor Čiampor, Vojislava Bursić, Kat Bruce, Pieter Boets, Sofia Alexandra Ferreira Duarte, European Commission, Leese, F., Altermatt, F., Bouchez, A., Ekrem, T., Hering, D., Meissner, K., Mergen, P., Pawlowski, J., Piggott, J. J., Rimet, F., Steinke, D., Taberlet, P., Weigand, A. M., Abarenkov, K., Beja, P., Bervoets, L., Björnsdóttir, S., Boets, P., Boggero, A., Magnar Bones, A., Borja, Á., Bruce, K., Bursić, V., Carlsson, J., Čiampor, F., Čiamporová-Zatovičová, Z., Coissac, E., Costa, F., Costache, M., Creer, S., Csabai, Z., Deiner, K., Delvalls, Á., Drakare, S., Duarte, S., Eleršek, T., Fazi, S., Fišer, C., Flot, J. F., Fonseca, V., Fontaneto, D., Grabowski, M., Graf, W., Guðbrandsson, J., Hershkovitz, Y., Hollingsworth, P., Japoshvili, B., Jones, J. I., Kahlert, M., Kalamujic Stroil, B., Kasapidis, P., Kelly, M. G., Kelly- Quinn, M., Keskin, E., Kõljalg, U., Ljubešić, Z., Maček, I., Mächler, E., Mahon, A., Marečková, M., Mejdandzic, M., Mircheva, G., Montagna, M., Moritz, C., Mulk, V., Naumoski, A., Navodaru, I., Padisák, J., Pálsson, S., Panksep, K., Penev, L., Petrusek, A., Pfannkuchen, M. A., Primmer, C. R., Rinkevich, B., Rotter, A., Schmidt-Kloiber, A., Segurado, P., Speksnijder, A., Stoev, P., Strand, M., Šulčius, S., Traugott, M., Tsigenopoulos, C., Turon, X., Valentini, A., van der Hoorn, B., Várbíró, G., Vasquez Hadjilyra, M. I., Viguri, J., Vitonytė, I., Vogler, A., Vrålstad, T., Wägele, W., Wenne, R., Winding, A., Woodward, G., Zegura, B., Zimmermann, J., [et al.], Universidad de Cantabria, and Universidade do Minho

Subjects

DNAqua-Net, genetic tools, bioassessment, monitoring, 0106 biological sciences, 0301 basic medicine, Emerging technologies, Ecology (disciplines), water, Biodiversity, dna, Biology, 010603 evolutionary biology, 01 natural sciences, Training (civil), Task (project management), taxonomy, 03 medical and health sciences, 14. Life underwater, lcsh:Science, Ecology, business.industry, Aquatic ecosystem, Environmental resource management, Environmental Sciences (social aspects to be 507), General Medicine, Directive, 6. Clean water, 030104 developmental biology, Conceptual framework, Génétique, cytogénétique, 13. Climate action, Systématique des espèces [zoologie], metabarcoding, lcsh:Q, business

Abstract

24 páginas, 2 figuras, 1 tabla., The protection, preservation and restoration of aquatic ecosystems and their functions are of global importance. For European states it became legally binding mainly through the EUWater Framework Directive (WFD). In order to assess the ecological status of a given water body, aquatic biodiversity data are obtained and compared to a reference water body. The quantified mismatch obtained determines the extent of potential management actions. The current approach to biodiversity assessment is based on morpho-taxonomy. This approach has many drawbacks such as being time consuming, limited in temporal and spatial resolution, and error-prone due to the varying individual taxonomic expertise of the analysts. Novel genomic tools can overcome many of the aforementioned problems and could complement or even replace traditional bioassessment. Yet, a plethora of approaches are independently developed in different institutions, thereby hampering any concerted routine application. The goal of this Action is to nucleate a group of researchers across disciplines with the task to identify gold-standard genomic tools and novel ecogenomic indices for routine application in biodiversity assessments of European fresh- and marine water bodies. Furthermore, DNAqua-Net will provide a platform for training of the next generation of European researchers preparing them for the new technologies. Jointly with water managers, politicians, and other stakeholders, the group will develop a conceptual framework for the standard application of eco-genomic tools as part of legally binding assessments.

Published

2016