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Molecular complexity and gene expression controlling cell turnover during a digestive cycle of carnivorous sponge Lycopodina hypogea
Author(s) -
Emilie Le Goff,
Camille MartinandMari,
Khalid Belkhir,
Jean Vacelet,
Sabine Nidelet,
Nelly Godefroy,
Stephen Baghdiguian
Publication year - 2022
Publication title -
cell and tissue research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.64
H-Index - 137
eISSN - 1432-0878
pISSN - 0302-766X
DOI - 10.1007/s00441-022-03610-3
Subject(s) - biology , cell cycle , microbiology and biotechnology , transcriptome , function (biology) , in silico , gene , homeostasis , multicellular organism , digestion (alchemy) , evolutionary biology , genetics , computational biology , gene expression , chemistry , chromatography
Lycopodina hypogea is a carnivorous sponge that tolerates laboratory husbandry very well. During a digestion cycle, performed without any digestive cavity, this species undergoes spectacular morphological changes leading to a total regression of long filaments that ensure the capture of prey and their reformation at the end of the cycle. This phenomenon is a unique opportunity to analyze the molecular and cellular determinants that ensure digestion in the sister group of all other metazoans. Using differential transcriptomic analysis coupled with cell biology studies of proliferation, differentiation, and programmed cell deaths (i.e., autophagy and the destructive/constructive function of apoptosis), we demonstrate that the molecular and cellular actors that ensure digestive homeostasis in a sister group of all remaining animals are similar in variety and complexity to those controlling tissue homeostasis in higher vertebrates. During a digestion cycle, most of these actors are finely tuned in a coordinated manner. Our data benefits from complementary approaches coupling in silico and cell biology studies and demonstrate that the nutritive function is provided by the coordination of molecular network that impacts the cells turnover in the entire organism.

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