A Chemo-Ecological Investigation of Topsent, 1905: Identification of Deceptionin and the Effects of Heat Stress and Predation Pressure on Its Terpene Profiles

Overview

Journal Mar Drugs

Publisher MDPI

Specialties Biology
Pharmacology

Date 2023 Sep 27

PMID 37755112

Authors

Paula De Castro-Fernandez

Carlos Angulo-Preckler

Cristina Garcia-Aljaro

Conxita Avila

Adele Cutignano

Affiliations

Soon will be listed here.

Abstract

Marine sponges usually host a wide array of secondary metabolites that play crucial roles in their biological interactions. The factors that influence the intraspecific variability in the metabolic profile of organisms, their production or ecological function remain generally unknown. Understanding this may help predict changes in biological relationships due to environmental variations as a consequence of climate change. The sponge is common in shallow rocky bottoms of the Antarctic Peninsula and is known to produce diterpenes that are supposed to have defensive roles. Here we used GC-MS to determine the major diterpenes in two populations of from two islands, Livingston and Deception Island (South Shetland Islands). To assess the potential effect of heat stress, we exposed the sponge in aquaria to a control temperature (similar to local), heat stress (five degrees higher) and extreme heat stress (ten degrees higher). To test for defence induction by predation pressure, we exposed the sponges to the sea star and the amphipod . Seven major diterpenes were isolated and identified from the samples. While six of them were already reported in the literature, we identified one new aplysulphurane derivative that was more abundant in the samples from Deception Island, so we named it deceptionin (). The samples were separated in the PCA space according to the island of collection, with 9,11-dihydrogracilin A () being more abundant in the samples from Livingston, and deceptionin () in the samples from Deception. We found a slight effect of heat stress on the diterpene profiles of , with tetrahydroaplysulphurin-1 () and the gracilane norditerpene being more abundant in the group exposed to heat stress. Predation pressure did not seem to influence the metabolite production. Further research on the bioactivity of secondary metabolites, and their responses to environmental changes will help better understand the functioning and fate of the Antarctic benthos.

Citing Articles

Chemical Changes Under Heat Stress and Identification of Dendrillolactone, a New Diterpene Derivative with a Rare Rearranged Spongiane Skeleton from the Antarctic Marine Sponge .

Profumo A, Avila C, Cutignano A Mar Drugs. 2025; 23(1).

PMID: 39852512 PMC: 11767012. DOI: 10.3390/md23010010.

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