6533b7d3fe1ef96bd12601a6
RESEARCH PRODUCT
The skeleton of the staghorn coral Acropora millepora: molecular and structural characterization.
Laurent PlasseraudPaula Ramos-silvaNathalie GuichardGérard AlcarazChristophe DurletJaap A. KaandorpMarion CorneillatChristine SternFrédéric MarinFrédéric HerbstGilles Luquetsubject
ProteomicsBiomineralizationPhysiologyCoralCell Membraneslcsh:MedicineSpectrum Analysis RamanBiochemistryAcropora milleporaMaterials PhysicsSpectroscopy Fourier Transform Infraredcristallcsh:ScienceMicrostructurecorailAcetic AcidAminationExtracellular Matrix ProteinsMineralsMultidisciplinarybiologyEcologyMonosaccharidesMineralogyAnthozoaBiochemistryprotéineCoralsPhysical SciencesCellular Structures and OrganellesCrystallizationcalciteResearch ArticleMaterials ScienceProtein domainmatrice extracellulaireMarine BiologyBone and BonesCalcium CarbonateAnthozoamonosaccharideAnimals14. Life underwater[SDV.IB.BIO]Life Sciences [q-bio]/Bioengineering/BiomaterialsIntegrin bindingStaghorn corallcsh:RBiology and Life SciencesProteinsMembrane ProteinsCell Biology[ SDV.IB.BIO ] Life Sciences [q-bio]/Bioengineering/Biomaterialsbiology.organism_classificationTransmembrane ProteinsSolubilityEarth Scienceslcsh:QPhysiological ProcessesGelsFunction (biology)Biomineralizationdescription
15 pages; International audience; The scleractinian coral Acropora millepora is one of the most studied species from the Great Barrier Reef. This species has been used to understand evolutionary, immune and developmental processes in cnidarians. It has also been subject of several ecological studies in order to elucidate reef responses to environmental changes such as temperature rise and ocean acidification (OA). In these contexts, several nucleic acid resources were made available. When combined to a recent proteomic analysis of the coral skeletal organic matrix (SOM), they enabled the identification of several skeletal matrix proteins, making A. millepora into an emerging model for biomineralization studies. Here we describe the skeletal microstructure of A. millepora skeleton, together with a functional and biochemical characterization of its occluded SOM that focuses on the protein and saccharidic moieties. The skeletal matrix proteins show a large range of isoelectric points, compositional patterns and signatures. Besides secreted proteins, there are a significant number of proteins with membrane attachment sites such as transmembrane domains and GPI anchors as well as proteins with integrin binding sites. These features show that the skeletal proteins must have strong adhesion properties in order to function in the calcifying space. Moreover this data suggest a molecular connection between the calcifying epithelium and the skeletal tissue during biocalcification. In terms of sugar moieties, the enrichment of the SOM in arabinose is striking, and the monosaccharide composition exhibits the same signature as that of mucus of acroporid corals. Finally, we observe that the interaction of the acetic acid soluble SOM on the morphology of in vitro grown CaCO3 crystals is very pronounced when compared with the calcifying matrices of some mollusks. In light of these results, we wish to commend Acropora millepora as a model for biocalcification studies in scleractinians, from molecular and structural viewpoints.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2014-01-01 |