Isolation of a Crystal Matrix Protein Associated with Calcium Oxalate Precipitation in Vacuoles of Specialized Cells

Xingxiang Li , Dianzhong Zhang , Valerie J. Lynch-Holm , Thomas W. Okita , and Vincent R. Franceschi ^*

Department of Genetics and Cell Biology (X.L.), School of Biological Sciences (D.Z., V.J.L.-H., V.R.F.), and Institute of Biological Chemistry (T.W.O.), Washington State University, Pullman, Washington 99164-4236

^* Corresponding author; email: vfrances{at}mail.wsu.edu.

The formation of calcium (Ca) oxalate crystals is consideredto be a high-capacity mechanism for regulating Ca in many plants.Ca oxalate precipitation is not a stochastic process, suggestingthe involvement of specific biochemical and cellular mechanisms.Microautoradiography of water lettuce (Pistia stratiotes) tissueexposed to ³H-glutamate showed incorporation into developingcrystals, indicating potential acidic proteins associated withthe crystals. Dissolution of crystals leaves behind a crystal-shapedmatrix "ghost" that is capable of precipitation of Ca oxalatein the original crystal morphology. To assess whether this matrixhas a protein component, purified crystals were isolated andanalyzed for internal protein. Polyacrylamide gel electrophoresisrevealed the presence of one major polypeptide of about 55 kDand two minor species of 60 and 63 kD. Amino acid analysis indicatesthe matrix protein is relatively high in acidic amino acids,a feature consistent with its solubility in formic acid butnot at neutral pH. ⁴⁵Ca-binding assays demonstrated the matrixprotein has a strong affinity for Ca. Immunocytochemical localizationusing antibody raised to the isolated protein showed that thematrix protein is specific to crystal-forming cells. Withinthe vacuole, the surface and internal structures of two morphologicallydistinct Ca oxalate crystals, raphide and druse, were labeledby the antimatrix protein serum, as were the surfaces of isolatedcrystals. These results demonstrate that a specific Ca-bindingprotein exists as an integral component of Ca oxalate crystals,which holds important implications with respect to regulationof crystal formation.

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