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  • 1
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    Genetic structure of Baltic Mytilus populations (2017)
    PANGAEA
    In:  Supplement to: Stuckas, Heiko; Knöbel, Loreen; Schade, Hanna; Breusing, Corinna; Hinrichsen, Hans-Harald; Bartel, Anja; Langguth, Klaudia; Melzner, Frank (2017): Combining hydrodynamic modelling with genetics: Can passive larval drift shape the genetic structure of Baltic Mytilus populations? Molecular Ecology, https://doi.org/10.1111/mec.14075
    Details
    Publication Date: 2023-01-13
    Description: While secondary contact between Mytilus edulis and M. trossulus in North America results in mosaic hybrid zone formation, both species form a hybrid swarm in the Baltic. Despite pervasive gene flow, Baltic Mytilus species maintain substantial genetic and phenotypic differentiation. Exploring mechanisms underlying the contrasting genetic composition in Baltic Mytilus species will allow insights into processes such as speciation or adaptation to extremely low salinity. Previous studies in the Baltic indicated that only weak interspecific reproductive barriers exist and discussed the putative role of adaptation to environmental conditions. Using a combination of hydrodynamic modelling and multilocus genotyping we investigate how oceanographic conditions influence passive larval dispersal and hybrid swarm formation in the Baltic. By combining our analyses with previous knowledge we show a genetic transition of Baltic Mytilus species along longitude 12°-13°E, i.e. a virtual line between Malmö (Sweden) and Stralsund (Germany). Although larval transport only occurs over short distances (10-30 km), limited larval dispersal could not explain the position of this genetic transition zone. Instead, the genetic transition zone is located at the area of maximum salinity change (15 to 10 psu). Thus, we argue that selection results in weak reproductive barriers and local adaptation. This scenario could maintain genetic and phenotypic differences between Baltic Mytilus species despite pervasive introgressive hybridization.
    Keywords: AHP; AHS; AKO; Allele; BAR; Code; Date/Time of event; DIVER; ECK; ESH; Event label; FLB; FSD; GEO; GLT; GRO; GWZ; HEL; HLG; HON; Identification; KAP; LATITUDE; Location; LONGITUDE; MAH; Mussels_Aarhus; Mussels_Ahrenshoop; Mussels_Askoe; Mussels_Barhoeft; Mussels_Dranske; Mussels_Eckernfoerde; Mussels_Fehmarnsund; Mussels_Flensburg; Mussels_Gelting; Mussels_Gollwitz; Mussels_Groemitz; Mussels_Hel; Mussels_Helgoland; Mussels_Kappeln; Mussels_KielFjord_Eastshore; Mussels_KielFjord_GEOMAR; Mussels_KielFjord_Hoern; Mussels_KielFjord_ShipMuseum; Mussels_Maasholm; Mussels_PennCove; Mussels_Steinbeck; Mussels_Tjaernoe; Mussels_Usedom; Mussels_Warnemuende; Mussels_Wendtorf; PCO; RUD; Sample code/label; Sampling by diver; SMU; STB; TJ; USE; WMU; WNF
    Type: Dataset
    Format: text/tab-separated-values, 6267 data points
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    DATA PANGAEA
  • 2
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    Allele shift under laboratory selection and local adaptation to low salinity in Baltic Sea mytilid mussels (2018)
    PANGAEA
    Details
    Publication Date: 2023-02-06
    Description: Baltic blue mussels colonise and dominate benthic habitats with much lower salinity than any other marine mytilid population globally. Surprisingly, all Baltic populations are hybrids of Mytilus edulis x M. trossulus genotypes with the former dominating hybrid genotypes in the western (high salinity) and the latter in the eastern part of the Baltic (low salinity). Here, we tested if low salinity selects for M. trossulus dominated hybrid genotypes and whether populations along the salinity gradient are locally adapted to their specific salinity regimes. Using laboratory larval rearing trials, we can show that Baltic M. trossulus hybrids have higher fitness when exposed to salinities 〈10 psu whereas Baltic M. edulis hybrids have higher fitness at a salinity of 16 psu. In addition, we can demonstrate that populations from the centre of the hybrid cline can be selected towards Baltic M. trossulus hybrids at low salinities, with allele shifts significantly beyond genetic drift expectations. We conclude that salinity driven selection can shape mussel populations and hence allows for local adaptation to extremely low environmental salinity. Future climate change driven desalination therefore has the potential to shift the Baltic Sea hybrid gradient to the west, with important implications for ecology and aquaculture.
    Type: Dataset
    Format: application/vnd.openxmlformats-officedocument.spreadsheetml.sheet, 67.6 kBytes
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    DATA PANGAEA
  • 3
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    Salinity Driven Selection and Local Adaptation in Baltic Sea Mytilid Mussels (2021)
    Frontiers Media
    Details
    Publication Date: 2021-08-13
    Description: Baltic blue mussels can colonise and dominate habitats with far lower salinity (
    Electronic ISSN: 2296-7745
    Topics: Biology
    Published by Frontiers Media
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    PAPER CURRENT
  • 4
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    Combining hydrodynamic modelling with genetics: can passive larval drift shape the genetic structure of Baltic Mytilus populations? (2017)
    Wiley
    In:  Molecular Ecology, 26 (10). pp. 2765-2782.
    Details
    Publication Date: 2020-02-06
    Description: While secondary contact between Mytilus edulis and Mytilus trossulus in North America results in mosaic hybrid zone formation, both species form a hybrid swarm in the Baltic. Despite pervasive gene flow, Baltic Mytilus species maintain substantial genetic and phenotypic differentiation. Exploring mechanisms underlying the contrasting genetic composition in Baltic Mytilus species will allow insights into processes such as speciation or adaptation to extremely low salinity. Previous studies in the Baltic indicated that only weak interspecific reproductive barriers exist and discussed the putative role of adaptation to environmental conditions. Using a combination of hydrodynamic modelling and multilocus genotyping, we investigate how oceanographic conditions influence passive larval dispersal and hybrid swarm formation in the Baltic. By combining our analyses with previous knowledge, we show a genetic transition of Baltic Mytilus species along longitude 12°-13°E, that is a virtual line between Malmö (Sweden) and Stralsund (Germany). Although larval transport only occurs over short distances (10–30 km), limited larval dispersal could not explain the position of this genetic transition zone. Instead, the genetic transition zone is located at the area of maximum salinity change (15–10 psu). Thus, we argue that selection results in weak reproductive barriers and local adaptation. This scenario could maintain genetic and phenotypic differences between Baltic Mytilus species despite pervasive introgressive hybridization.
    Type: Article , PeerReviewed
    Format: text
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    PAPER (OCEANREP)
  • 5
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    Comparative de novo assembly and annotation of mantle tissue transcriptomes from the Mytilus edulis species complex (M. edulis, M. galloprovincialis, M. trossulus) (2020)
    Elsevier
    Details
    Publication Date: 2023-02-08
    Description: Mytilus mussels (Mytilus edulis (ME), M. trossulus (MT), and M. galloprovincialis (MG)) are of interest in many fields of marine science and have been used as model in evolutionary research. For instance, they form mosaic hybrid zones or hybrid swarms in areas of secondary contact and hence are suited to address questions related to the evolution of reproductive barriers, adaptive hybridization or speciation. While existing genomic information mostly focuses on single species (ME, MG), this project generated RNA seq data of all three species from allopatric populations, i.e. samples representing genetically pure specimens. We investigated adult mantle tissue (four specimens per species), which is functionally involved in processes such as reproduction or biomineralization. The project provides three assembled transcriptomes (post filtering total transcript numbers for ME: 353339, MT: 437827, MG: 290267) representing genes annotated to at least 40 level 2 GO-terms (number (percentage) of annotated transcripts for ME: 44434 (12.6%), MT: 43960 (10%), MG: 60064 (20.7%)). Annotation showed that the most abundant 40 GO-terms are equally well covered by contigs of the three Mytilus transcriptomes. Therefore, this project lays a basis for evolutionary research by providing candidate genes representing various molecular functions such as reproduction, cellular processes or immune response. The potential of the new transcriptomes to address evolutionary questions is further exemplified by a pilot study on ME and MT transcriptomes that used reciprocal blast to identify 7652 one-to-one orthologue pairs of transcripts
    Type: Article , PeerReviewed
    Format: text
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  • 6
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    Salinity Driven Selection and Local Adaptation in Baltic Sea Mytilid Mussels (2021)
    Frontiers
    Details
    Publication Date: 2024-02-07
    Description: Baltic blue mussels can colonise and dominate habitats with far lower salinity (〈 10 psu) than other Mytilus congeners. Pervasive gene flow was observed between Western Baltic Mytilus edulis living at high salinity conditions and Eastern Baltic M. trossulus living at lower salinites, with highest admixture proportions within a genetic transition zone located at intermediate salinities (Darss Sill area). Yet, we do not understand the impacts of low salinity on larval performance, and how salinity may act as an early selective pressure during passive larval drift across salinity gradients. This study tested whether larvae originating from two different populations along the natural salinity cline in the Baltic Sea have highest fitness at their native salinities. Our results suggest that Eastern Baltic M. trossulus (Usedom, 7 psu) and Western Baltic M. edulis (Kiel, 16 psu) larvae display better performance (fitness components: growth, mortality, settlement success) when reared at their respective native salinities. This suggests that these populations are adapted to their local environment. Additionally, species diagnostic markers were used for genetic analyses of transition zone (Ahrenshoop, 11 psu) mussel larvae exposed to low salinity. This revealed that low salinity selection resulted in a shift towards allele frequencies more typical for Eastern Baltic M. trossulus. Thus, salinity acts as a selective pressure during the pre-settlement phase and can shape the genetic composition of Baltic mussel populations driving local adaptation to low salinity. Future climate change driven desalination, therefore, has the potential to shift the Baltic Sea hybrid gradient westward with consequences for benthic ecosystem structure.
    Type: Article , PeerReviewed , info:eu-repo/semantics/article
    Format: text
    Format: text
    Format: text
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