Ecophysiological responses of Fucus virsoides (Phaeophyceae, Fucales) to past and present nutrient conditions in the northern Adriatic

Fucus virsoides is a brown seaweed endemic to the Adriatic and the only species of its genus found in the Mediterranean. Historically widespread from the Venice lagoon (Italy) to Albania, this species has suffered a sharp decline and is currently threatened with extinction. Over the past three decad...

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Bibliographic Details
Published in:Marine biology 2024-11, Vol.171 (11), p.205-205, Article 205
Main Authors: Descourvières, Emmanuelle, Mulas, Martina, Natale, Sara, de Pedro, Raquel Sánchez, Alboresi, Alessandro, Solidoro, Cosimo, Bandelj, Vinko, Falace, Annalisa
Format: Article
Language:English
Subjects:
Adults
Albania
Algae
Anthropogenic factors
Biomedical and Life Sciences
decline
Ecophysiology
Ecosystem disturbance
Endangered & extinct species
Endemic species
Environmental changes
Environmental stress
Eutrophic environments
Eutrophication
Fluorimetry
fluorometry
Forest management
Freshwater & Marine Ecology
Fucus
genus
Hypotheses
Italy
Lagoons
Life Sciences
Marine & Freshwater Sciences
Marine biology
Metabolism
Microbiology
Nitrogen
Nutrients
Oceanography
Oligotrophy
Original Paper
Physiological effects
Physiological responses
Physiology
Population decline
Ratios
Salinity
Seaweeds
species
Species extinction
Threatened species
Zoology
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Summary:Fucus virsoides is a brown seaweed endemic to the Adriatic and the only species of its genus found in the Mediterranean. Historically widespread from the Venice lagoon (Italy) to Albania, this species has suffered a sharp decline and is currently threatened with extinction. Over the past three decades, the northern Adriatic has seen a shift towards oligotrophy conditions, yet the ecophysiology of F. virsoides in response to nutrients changes has been poorly studied. Addressing this gap is crucial for understanding the extent to which these environmental changes may have contributed to the species’ decline. To test our hypothesis that nutrient changes might be the primary driver of F. virsoides decline, we conducted a two-week experiment exposing germlings and adults to six different nutrient conditions. These included three Redfield ratios recorded in the Gulf of Trieste in 1996, 2007 and 2017, reflecting the shift from eutrophic to oligotrophic conditions experienced by F. virsoides in the wild. Additionally, the adults were exposed to three supplementary eutrophic conditions (naturally and artificially fertilized). Growth and physiological responses (measured via O 2 evolution and PAM fluorimetry) of F. virsoides to varying nutrient conditions were largely consistent, with only subtle effects observed. Our results highlight the species’ acclimatation potential, suggesting that short-term nutrient changes alone may not fully explain its decline. Understanding F. virsoides resilience to multiple environmental stressors is crucial for developing effective conservation strategies to preserve marine forests in the face of ongoing anthropogenic disturbances.
ISSN:0025-3162
1432-1793
DOI:10.1007/s00227-024-04523-1