TY - JOUR
T1 - Cloning and characterization of four novel coral acid-rich proteins that precipitate carbonates in vitro
AU - Mass, Tali
AU - Drake, Jeana L.
AU - Haramaty, Liti
AU - Kim, J. Dongun
AU - Zelzion, Ehud
AU - Bhattacharya, Debashish
AU - Falkowski, Paul G.
N1 - Funding Information: This research was supported by National Science Foundation Grant EF1041143 to P.G.F. We are grateful to J. Yaiullo of the Long Island Aquarium and F. Natale of the Institute of Marine and Coastal Sciences for providing and maintaining the corals used in this study. We thank members of the Genome Cooperative at Rutgers University for aid in generating and analyzing the draft genome data. We thank L. Fisher, K. Thamatrakoln, L. Mintz, K. Wyman, J. Kalansky, S. Murali, and V. Yamazaki for advice and technical support.
PY - 2013/6/17
Y1 - 2013/6/17
N2 - Biomineralization is a widely dispersed and highly regulated but poorly understood process by which organisms precipitate minerals from a wide variety of elements [1]. For many years, it has been hypothesized that the biological precipitation of carbonates is catalyzed by and organized on an extracellular organic matrix containing a suite of proteins, lipids, and polysaccharides [2, 3]. The structures of these molecules, their evolutionary history, and the biophysical mechanisms responsible for calcification remain enigmatic. Despite the recognition that mineralized tissues contain proteins that are unusually rich in aspartic and glutamic acids [4-6], the role of these proteins in biomineralization remains elusive [5, 6]. Here we report, for the first time, the identification, cloning, amino acid sequence, and characterization of four highly acidic proteins, derived from expression of genes obtained from the common stony coral, Stylophora pistillata. Each of these four proteins can spontaneously catalyze the precipitation of calcium carbonate in vitro. Our results demonstrate that coral acid-rich proteins (CARPs) not only bind Ca 2+ stoichiometrically but also precipitate aragonite in vitro in seawater at pH 8.2 and 7.6, via an electrostatic interaction with protons on bicarbonate anions. Phylogenetic analysis suggests that at least one of the CARPs arose from a gene fusion. Similar, highly acidic proteins appear to have evolved several times independently in metazoans through convergence. Based purely on thermodynamic grounds, the predicted change in surface ocean pH in the next decades would appear to have minimal effect on the capacity of these acid-rich proteins to precipitate carbonates.
AB - Biomineralization is a widely dispersed and highly regulated but poorly understood process by which organisms precipitate minerals from a wide variety of elements [1]. For many years, it has been hypothesized that the biological precipitation of carbonates is catalyzed by and organized on an extracellular organic matrix containing a suite of proteins, lipids, and polysaccharides [2, 3]. The structures of these molecules, their evolutionary history, and the biophysical mechanisms responsible for calcification remain enigmatic. Despite the recognition that mineralized tissues contain proteins that are unusually rich in aspartic and glutamic acids [4-6], the role of these proteins in biomineralization remains elusive [5, 6]. Here we report, for the first time, the identification, cloning, amino acid sequence, and characterization of four highly acidic proteins, derived from expression of genes obtained from the common stony coral, Stylophora pistillata. Each of these four proteins can spontaneously catalyze the precipitation of calcium carbonate in vitro. Our results demonstrate that coral acid-rich proteins (CARPs) not only bind Ca 2+ stoichiometrically but also precipitate aragonite in vitro in seawater at pH 8.2 and 7.6, via an electrostatic interaction with protons on bicarbonate anions. Phylogenetic analysis suggests that at least one of the CARPs arose from a gene fusion. Similar, highly acidic proteins appear to have evolved several times independently in metazoans through convergence. Based purely on thermodynamic grounds, the predicted change in surface ocean pH in the next decades would appear to have minimal effect on the capacity of these acid-rich proteins to precipitate carbonates.
UR - http://www.scopus.com/inward/record.url?scp=84879290118&partnerID=8YFLogxK
U2 - https://doi.org/10.1016/j.cub.2013.05.007
DO - https://doi.org/10.1016/j.cub.2013.05.007
M3 - Article
C2 - 23746634
SN - 0960-9822
VL - 23
SP - 1126
EP - 1131
JO - Current Biology
JF - Current Biology
IS - 12
ER -