Experimental evidence of antimicrobial activity in Antarctic seaweeds: ecological role and antibiotic potential

Seaweeds contain a wide range of secondary metabolites which serve multiple functions, including chemical and ecological mediation with microorganisms. Moreover, owing to their diverse bioactivity, including their antibiotic properties, they show potential for human use. Nonetheless, the chemical ec...

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Bibliographic Details
Published in:Polar Biology
Main Authors: Martín-Martín, Rafael P., Carcedo-Forés, Marta, Camacho-Bolós, Pablo, García-Aljaro, Cristina, Preckler, Carlos Angulo, Avila, Conxita, Lluch, Jordi Rull, Garreta, Amelia Gómez
Format: Article in Journal/Newspaper
Language:English
Published: Springer 2022
Subjects:
Online Access:https://hdl.handle.net/10037/25960
https://doi.org/10.1007/s00300-022-03036-1
Description
Summary:Seaweeds contain a wide range of secondary metabolites which serve multiple functions, including chemical and ecological mediation with microorganisms. Moreover, owing to their diverse bioactivity, including their antibiotic properties, they show potential for human use. Nonetheless, the chemical ecology of seaweeds is not equally understood across different regions; for example, Antarctic seaweeds are among the lesser studied groups. With the aim of improving our current understanding of the chemical ecology and potential bioactivity of Antarctic seaweeds, we performed a screening of antibiotic activity using crude extracts from 22 Antarctic macroalgae species. Extractions were performed separating lipophilic and hydrophilic fractions at natural concentrations. Antimicrobial activity assays were performed using the disk diffusion method against seven Antarctic bacteria and seven human pathogenic surrogates. Our results showed that red seaweeds (especially Delisea pulchra) inhibited a larger number of microorganisms compared with brown seaweeds, and that lipophilic fractions were more active than hydrophilic ones. Both types of bacteria tested (Gram negative and Gram positive) were inhibited, especially by butanolic fractions, suggesting a trend of non-specific chemical defence. However, Gram-negative bacteria and one pathogenic fungus showed greater resistance. Our study contributes to the evidence of antimicrobial chemical interactions between Antarctic seaweeds and sympatric microorganisms, as well as the potential of seaweed extracts for pharmacological applications.