@article {8987, title = {Diversity of Light Sensing Molecules and Their Expression During the Embryogenesis of the Cuttlefish (Sepia officinalis)}, journal = {Frontiers in Physiology}, volume = {11}, year = {2020}, pages = {521989}, keywords = {arrestin, cryptochrome, Development, Eye, opsin, Sepia officinalis}, doi = {10.3389/fphys.2020.521989}, url = {https://hal.sorbonne-universite.fr/hal-02989850}, author = {Bonad{\`e}, Morgane and Ogura, Atsushi and Corre, Erwan and Bassaglia, Yann and Laure Bonnaud-Ponticelli} } @article {4494, title = {Coleoid cephalopod color patterns: Adult skin structures and their emergence during development in sepia officinalis}, journal = {Vie et Milieu}, volume = {66}, year = {2016}, month = {May 2016}, pages = {43-55}, abstract = {

The skin of coleo{\"\i}d cephalopods is a complex tissue that allows the rapid display of numerous changing or static patterns for communication and camouflage. Chromatophores, iridophores, and leucophores are responsible for these properties. Chromatophores are pigmentary neuromuscular organs, directly controlled by the brain. Iridophores are iridescent cells that use platelets of proteins that are arranged into repetitive structures (iridosomes) to produce iridescence; and leucophores are perfect reflectors. The same family of protein (reflectins), initially characterized in iridophores, have been detected (at different levels) in the three structures. Here we review the current knowledge of adult skin and its nervous control and describe the establishment of chromatophores and iridophores during embryonic development in Sepia officinalis.

}, keywords = {Cephalopods, Chromatophores, color pattern, Development, iridophores}, author = {Aude Andouche and Yann Bassaglia} } @article {4493, title = {A developmental table of embryogenesis in Sepia officinalis}, journal = {Vie et Milieu}, volume = {66}, year = {2016}, month = {May 2016}, pages = {11-23}, abstract = {

The development of several cephalopods among them Sepia officinalis (Linnaeus, 1758) has been very carefully described by Naef in the early 20th century. Here an illustrated developmental table of Sepia officinalis is proposed with a morphological description of each stage. The 30 stages are grouped into five steps of development: cleavage (stages 1 to 9), gastrulation (stages 10 to 13), organogenesis, plane phase (stages 14 to 18), organogenesis, extension phase (stages 19 to 22) and organogenesis, growth phase (stages 23 to 30), when the embryo has acquired the general adult conformation. For each stage, morphological identification criteria are proposed in order that this table is used as a lab tool for cephalopod researchers interested in development.

}, keywords = {Cephalopoda, Development, Embryology, Sepia officinalis}, issn = {02408759}, author = {Boletzky, S.V and Aude Andouche and Laure Bonnaud-Ponticelli} } @article {6823, title = {Plasticity and acquisition of the thermal tolerance (upper thermal limit and heat shock response) in the intertidal species Palaemon elegans}, journal = {Journal of Experimental Marine Biology and Ecology}, volume = {484}, year = {2016}, pages = {39 - 45}, abstract = {The marine species sensitivity to climate change will depend on the ways by which these species can adapt to thermal increase and heterogeneity. Here, we present evidence that the intertidal shrimp Palaemon elegans acclimates its thermal tolerance, in response to environmental water temperature, through a significant shift of its upper thermal limit with no concomittant acclimation of the heat shock response (hsp70 stress gene expression threshold). This species is less thermotolerant than its congener Palaemonetes varians, and would therefore potentially be more sensitive to an increase in environmental temperature, such as imposed by global warming. In P. elegans life cycle, physiological adjustments like the shift of the thermal limit and the acquisition of a significant HSR, occurred during the metamorphosis from larvae to post-larvae. This suggests that this step is a genetically-programmed milestone in the process of thermal tolerance acquisition.}, keywords = {acclimation, Caridea, Development, heat stress, hsp70, thermal biology}, issn = {0022-0981}, doi = {https://doi.org/10.1016/j.jembe.2016.07.003}, url = {http://www.sciencedirect.com/science/article/pii/S0022098116301125}, author = {Juliette Ravaux and L{\'e}ger, Nelly and Rabet, Nicolas and Fourgous, Claire and Voland, Guillaume and Magali Zbinden and Bruce Shillito} } @article {6891, title = {Molecular cloning and gene expression of Cg-Foxl2 during the development and the adult gametogenetic cycle in the oyster Crassostrea gigas}, journal = {Comparative Biochemistry and Physiology - Part B: Biochemistry and Molecular Biology}, volume = {154}, year = {2009}, pages = {134-142}, keywords = {Adult gametogenetic cycle, Cg-DMl, Crassostrea gigas, Development, Foxl2, Gonad, Oyster, Sex determination}, doi = {10.1016/j.cbpb.2009.05.011}, url = {https://hal-normandie-univ.archives-ouvertes.fr/hal-02296548}, author = {Naimi, Amine and Anne-Sophie Martinez and Specq, Marie-Laure and Diss, Blandine and Mathieu, Michel and Sourdaine, Pascal} }