Marine
biofouling refers to the unwanted accumulation of fouling organisms,
such as barnacles, on artificial surfaces, resulting in severe consequences
for marine industries. Meleagrin is a potential nontoxic antifoulant
that is isolated from the fungus Penicillium sp.;
however, its mechanistic effect mode of action on larval settlement
remains unknown. Here, we applied iTRAQ coupled with 2D LC–MS/MS
proteomic analysis to investigate the effect of meleagrin on the proteomic
expression profile of cyprid development and aging in the barnacle Balanus amphitrite. Fifty
proteins were differentially expressed in response to treatment with
meleagrin, among which 26 proteins were associated with cyprid development/aging
and 24 were specifically associated with the meleagrin treatment.
The 66 proteins that were associated with aging only remained unaltered
during exposure to meleagrin. Using KEGG analysis, those proteins
were assigned to several groups, including metabolic pathways, ECM–receptor
interactions, and the regulation of the actin cytoskeleton. Among
the 24 proteins that were not related to the development/aging process,
expression of the cyprid major protein (CMP), a vitellogenin-like
protein, increased after the meleagrin treatment, which suggested
that meleagrin might affect the endocrine system and prevent the larval
molting cycle. With the exception of the chitin binding protein that
mediates the molting process and ATPase-mediated energy processes,
the majority of proteins with significant effects in previous studies
in response to cyprid treatment with butenolide and polyether B remained
unchanged in the present study, suggesting that meleagrin may exhibit
a different mechanism.