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| Natura: | Artículo científico |
| Lingua: | en |
| Pubblicazione: |
Global change biology
2025
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| Soggetti: | |
| Accesso online: | https://pubmed.ncbi.nlm.nih.gov/40955567/ |
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| _version_ | 1868266152120025089 |
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| author | Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S |
| author_facet | Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S |
| collection | PubMed - marine biology |
| contents | Multi-Millennial Genetic Resilience of Baltic Diatom Populations Disturbed in the Past Centuries. Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S Diatoms Genetic Variation DNA, Ancient Genome, Mitochondrial Climate Change Little is known about the genetic diversity and stability of natural populations over millennial time scales, although the current biodiversity crisis calls for heightened understanding. Marine phytoplankton, the primary producers forming the basis of food webs in the oceans, play a pivotal role in maintaining marine ecosystems health and serve as indicators of environmental change. This study examines the genetic diversity and shifts in allelic composition in the diatom species Skeletonema marinoi over ~8000 years in the Baltic Sea by analyzing chloroplast and mitochondrial genomes. Sedimentary ancient DNA (sedaDNA) demonstrates the stability and resilience of genetic composition and diversity of this species across millennia in the context of major climate events. Accelerated change in allelic composition is observed from historical periods onwards, coinciding with times of intensifying human activity, like the Roman Empire, the Viking Age, and the Hanseatic Age, suggesting that anthropogenic stressors have profoundly impacted this species for the last two millennia. The data indicate a very high natural stability and resilience of the genomic composition of the species and underscore the importance of uncovering genomic disruptions caused by human impact on organisms, even those not directly exploited, to better predict and manage future biodiversity. |
| format | Artículo científico |
| id | pubmed_40955567 |
| institution | PubMed |
| language | en |
| publishDate | 2025 |
| publisher | Global change biology |
| record_format | pubmed |
| spellingShingle | Multi-Millennial Genetic Resilience of Baltic Diatom Populations Disturbed in the Past Centuries. Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S Diatoms Genetic Variation DNA, Ancient Genome, Mitochondrial Climate Change Multi-Millennial Genetic Resilience of Baltic Diatom Populations Disturbed in the Past Centuries. Schmidt, Alexandra Bolius, Sarah Chagas, Anna Romahn, Juliane Kaiser, Jérôme Arz, Helge W Bálint, Miklós Kremp, Anke Epp, Laura S Diatoms Genetic Variation DNA, Ancient Genome, Mitochondrial Climate Change Little is known about the genetic diversity and stability of natural populations over millennial time scales, although the current biodiversity crisis calls for heightened understanding. Marine phytoplankton, the primary producers forming the basis of food webs in the oceans, play a pivotal role in maintaining marine ecosystems health and serve as indicators of environmental change. This study examines the genetic diversity and shifts in allelic composition in the diatom species Skeletonema marinoi over ~8000 years in the Baltic Sea by analyzing chloroplast and mitochondrial genomes. Sedimentary ancient DNA (sedaDNA) demonstrates the stability and resilience of genetic composition and diversity of this species across millennia in the context of major climate events. Accelerated change in allelic composition is observed from historical periods onwards, coinciding with times of intensifying human activity, like the Roman Empire, the Viking Age, and the Hanseatic Age, suggesting that anthropogenic stressors have profoundly impacted this species for the last two millennia. The data indicate a very high natural stability and resilience of the genomic composition of the species and underscore the importance of uncovering genomic disruptions caused by human impact on organisms, even those not directly exploited, to better predict and manage future biodiversity. |
| title | Multi-Millennial Genetic Resilience of Baltic Diatom Populations Disturbed in the Past Centuries. |
| topic | Diatoms Genetic Variation DNA, Ancient Genome, Mitochondrial Climate Change |
| url | https://pubmed.ncbi.nlm.nih.gov/40955567/ |