Phylogeography of Acartia tonsa Dana, 1849 (Calanoida: Copepoda) and phylogenetic reconstruction of the genus Acartia Dana, 1846

Figueroa, Nicole J.; Figueroa, Diego F.; Hicks, David W.

doi:10.1007/s12526-020-01043-1

Cited by 16 publications

(17 citation statements)

References 76 publications

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“…With these rates, all the three pairs of cryptic species in our data would have diverged already in the Miocene, from 6 to 26 Ma (Table 7). While this appears unexpected in the context of European biogeography, in the context of copepod systematics these estimates are not exceptional: similar or even deeper cryptic lineages are frequently observed [20,21,26,44,45,[89][90][91]104,105]. Several studies on the phylogeography of freshwater copepods (including European populations) have pointed to the Early Miocene as a possible time of initial divergence [21,26,76].…”

Section: Age Of Diversitymentioning

confidence: 92%

“…It should be noted that copepod populations also overall show extreme mitochondrial DNA diversity [90]. Interestingly, this is not only for geographically isolated freshwater populations, but also for marine species, where populations from relatively close locations can demonstrate high variability [11,20,[44][45][46][47]50,[86][87][88][89][90][91][92]. These "intra-species" levels are extraordinary in comparison with vertebrate and invertebrate taxa, which commonly show <3% intraspecific and >2% interspecific variation [93][94][95].…”

Section: Cryptic Diversificationmentioning

confidence: 99%

“…No morphological differences were found in populations of N. hibernica (Kochanova, unpubl. ) The slow rate of morphological evolution relative to molecular evolution is emerging as a general pattern in copepods [41,91,[104][105][106], and indicates that modern morphological resemblance does not necessarily mirror cladogenetic events [11,77].…”

Section: Speciesmentioning

confidence: 99%

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Patterns of Cryptic Diversity and Phylogeography in Four Freshwater Copepod Crustaceans in European Lakes

et al. 2021

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Comparative phylogeography has become a powerful approach in exploring hidden or cryptic diversity within widespread species and understanding how historical and biogeographical factors shape the modern patterns of their distribution. Most comparative phylogeographic studies so far focus on terrestrial and vertebrate taxa, while aquatic invertebrates (and especially freshwater invertebrates) remain unstudied. In this article, we explore and compare the patterns of molecular diversity and phylogeographic structure of four widespread freshwater copepod crustaceans in European water bodies: the harpacticoids Attheyella crassa, Canthocamptus staphylinus and Nitokra hibernica, and the cyclopoid Eucyclops serrulatus, using sequence data from mtDNA COI and nuclear ITS/18S rRNA genes. The three taxa A. crassa, C. staphylinus and E. serrulatus each consist of deeply diverged clusters and are deemed to represent complexes of species with largely (but not completely) non-overlapping distributions, while in N. hibernica only little differentiation was found, which may however reflect the geographically more restricted sampling. However, the geographical patterns of subdivision differ. The divisions in A. crassa and E. serrulatus follow an east–west pattern in Northern Europe whereas that in C. staphylinus has more of a north–south pattern, with a distinct Fennoscandian clade. The deep mitochondrial splits among populations of A. crassa, C. staphylinus and E. serrulatus (model-corrected distances 26–36%) suggest that divergence of the lineages predate the Pleistocene glaciations. This study provides an insight into cryptic diversity and biogeographic distribution of freshwater copepods.

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Section: Age Of Diversitymentioning

confidence: 92%

Section: Cryptic Diversificationmentioning

confidence: 99%

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Patterns of Cryptic Diversity and Phylogeography in Four Freshwater Copepod Crustaceans in European Lakes

et al. 2021

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“…COI barcode reference sequences are available for many-if not most-of the more abundant and/or ecologically important species from coastal ocean areas, as well as surface layers (epipelagic zone) of the open ocean. Additional effort is needed for taxonomically challenging taxa, including species of the genus Acartia (Figueroa et al 2020) and family Paracalanidae (Cornils and Held 2014;Moon et al 2010), as well as representatives of bathy-and abyssopelagic taxa, which remain under-sampled. Rapid progress is being made with COI barcoding of copepods.…”

Section: Copepodamentioning

confidence: 99%

Toward a global reference database of COI barcodes for marine zooplankton

et al. 2021

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Characterization of species diversity of zooplankton is key to understanding, assessing, and predicting the function and future of pelagic ecosystems throughout the global ocean. The marine zooplankton assemblage, including only metazoans, is highly diverse and taxonomically complex, with an estimated ~28,000 species of 41 major taxonomic groups. This review provides a comprehensive summary of DNA sequences for the barcode region of mitochondrial cytochrome oxidase I (COI) for identified specimens. The foundation of this summary is the MetaZooGene Barcode Atlas and Database (MZGdb), a new open-access data and metadata portal that is linked to NCBI GenBank and BOLD data repositories. The MZGdb provides enhanced quality control and tools for assembling COI reference sequence databases that are specific to selected taxonomic groups and/or ocean regions, with associated metadata (e.g., collection georeferencing, verification of species identification, molecular protocols), and tools for statistical analysis, mapping, and visualization. To date, over 150,000 COI sequences for ~ 5600 described species of marine metazoan plankton (including holo- and meroplankton) are available via the MZGdb portal. This review uses the MZGdb as a resource for summaries of COI barcode data and metadata for important taxonomic groups of marine zooplankton and selected regions, including the North Atlantic, Arctic, North Pacific, and Southern Oceans. The MZGdb is designed to provide a foundation for analysis of species diversity of marine zooplankton based on DNA barcoding and metabarcoding for assessment of marine ecosystems and rapid detection of the impacts of climate change.

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“…Among neritic Acartia copepods, A. tonsa also has a wide geographical distribution and different life history strategies including diapausing egg production pro-cesses, in each habitat (Caudill & Bucklin 2004, and citations therein). Molecular techniques revealed that A. tonsa has experienced geographical isolation resulting in the divergence of multiple, distinct cryptic lineages (Caudill & Bucklin 2004, Chen & Hare 2011, Costa et al 2014, Figueroa et al 2020). The results of these studies indicate the possible presence of cryptic species also in A. steueri, and molecular biological methods are considered to be extremely useful for elucidating the diversity of life histories in this copepod.…”

Section: Timing Of Diapausing Egg Productionmentioning

confidence: 99%

Feeding and reproduction including diapausing egg production as cold-water adaptations for overwintering of <i>Acartia steueri</i> (Copepoda, Calanoida) in Okkirai Bay, Sanriku, northern Japan

Yamada

Sato

Kobiyama

et al. 2020

Plankton Benthos Res

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Feeding experiments with a natural microplankton assemblage and egg production experiments with the neritic copepod Acartia steueri were conducted simultaneously in an inlet on the Sanriku coast during autumn. Diapausing egg production status of A. steueri was also investigated. Further, A. steueri dominated during September to October and then gradually decreased until December, before disappearing after January. The dominant microplankton in natural waters during the study period were dinoflagellates, followed by centric and pennate diatoms and oligotrich ciliates. A. steueri fed only on dinoflagellates and oligotrich ciliates at rates of 87.0-309 and 17.7-71.5 cells ind −1 d −1 , respectively. Egg production rate of A. steueri ranged from 1.6 to 15.0 eggs female −1 d −1 and significantly increased as ingestion rates of dinoflagellates and oligotrich ciliates increased. The copepod began producing diapausing eggs in October, and by late December, 86% of the eggs produced were diapausing. The population s egg production rate was highest in September (18,961 eggs m −3 d −1 ) and gradually decreased through the end of December. These dietary and diapausing egg production seasons of A. steueri in the Sanriku area are significantly different from the results of previous studies in the temperate zone, where the copepod mainly fed on diatoms and produced diapausing eggs during spring. A. steueri can alter its feeding habits and the timing of diapausing egg production in response to changes in habitat. The flexibility of this species to environmental change has likely allowed expansion of its geographical distribution.

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Phylogeography of Acartia tonsa Dana, 1849 (Calanoida: Copepoda) and phylogenetic reconstruction of the genus Acartia Dana, 1846

Cited by 16 publications

References 76 publications

Patterns of Cryptic Diversity and Phylogeography in Four Freshwater Copepod Crustaceans in European Lakes

Patterns of Cryptic Diversity and Phylogeography in Four Freshwater Copepod Crustaceans in European Lakes

Toward a global reference database of COI barcodes for marine zooplankton

Feeding and reproduction including diapausing egg production as cold-water adaptations for overwintering of <i>Acartia steueri</i> (Copepoda, Calanoida) in Okkirai Bay, Sanriku, northern Japan

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