Pigment and Fatty Acid Heterogeneity in the Sea Slug <i>Elysia crispata</i> Is Not Shaped by Habitat Depth

Pigment and Fatty Acid Heterogeneity in the Sea Slug <i>Elysia crispata</i> Is Not Shaped by Habitat Depth

Long-term retention of functional chloroplasts in animal cells occurs only in sacoglossan sea slugs. Analysis of molecules related to the maintenance of these organelles can provide valuable information on this trait (kleptoplasty). The goal of our research was to characterize the pigment and fatty...

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Auteurs principaux: Xochitl Guadalupe Vital, Felisa Rey, Paulo Cartaxana, Sónia Cruz, Maria Rosário Domingues, Ricardo Calado, Nuno Simões
Format: article
Langue:EN
Publié: MDPI AG 2021
Sujets:
Mollusca
Heterobranchia
kleptoplasty
lipidomics
phospholipids
glycolipids
Veterinary medicine
SF600-1100
Zoology
QL1-991
Accès en ligne:https://doaj.org/article/a5aa74d69edf41e3bba656b0c06fe6dd
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Résumé:Long-term retention of functional chloroplasts in animal cells occurs only in sacoglossan sea slugs. Analysis of molecules related to the maintenance of these organelles can provide valuable information on this trait (kleptoplasty). The goal of our research was to characterize the pigment and fatty acid (FA) composition of the sea slug <i>Elysia crispata</i> and their associated chloroplasts that are kept functional for a long time, and to quantify total lipid, glycolipid and phospholipid contents, identifying differences between habitats: shallow (0–4 m) and deeper (8–12 m) waters. Specimens were sampled and analyzed after a month of food deprivation, through HPLC, GC-MS and colorimetric methods, to ensure an assessment of long-term kleptoplasty in relation to depth. Pigment signatures indicate that individuals retain chloroplasts from different macroalgal sources. FA classes, phospholipid and glycolipid contents displayed dissimilarities between depths. However, heterogeneities in pigment and FA profiles, as well as total lipid, glycolipid and phospholipid amounts in <i>E. crispata</i> were not related to habitat depth. The high content of chloroplast origin molecules, such as Chl <i>a</i> and glycolipids after a month of starvation, confirms that <i>E. crispata</i> retains chloroplasts in good biochemical condition. This characterization fills a knowledge gap of an animal model commonly employed to study kleptoplasty.

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