Abstract
Copines are highly conserved proteins with lipid-binding activities found in animals, plants, and protists. They contain two calcium-dependent phospholipid binding C2 domains at the amino terminus and a VWA domain at the carboxyl terminus. The biological roles of most copines are not understood and the biochemical properties required for their functions are largely unknown. The Arabidopsis copine gene BON1/CPN1 is a negative regulator of cell death and defense responses. Here we probed the potential biochemical activities of BON1 through mutagenic studies. We found that mutations of aspartates in the C2 domains did not alter plasma membrane localization but compromised BON1 activity. Mutation at putative myristoylation residue glycine 2 altered plasma membrane localization of BON1 and rendered BON1 inactive. Mass spectrometry analysis of BON1 further suggests that the N-peptide of BON1 is modified. Furthermore, mutations that affect the interaction between BON1 and its functional partner BAP1 abolished BON1 function. This analysis reveals an unanticipated regulation of copine protein localization and function by calcium and lipid modification and suggests an important role in protein-protein interaction for the VWA domain of copines.
Highlights
All constructs were transformed into bon[1] mutants, and T2 transgenic plants grown at 22 °C for 3 weeks were analyzed for growth phenotype
We showed for the first time that conserved aspartates mediating calcium binding are required for the biological roles of copine
We did obtain very few wild-type among the much more mutant looking lines with BON1(B3DA) where three aspartates in the C2B domain were mutated. These lines might have a higher expression level to compensate for the reduced activity of the BON1(B3DA) mutant protein
Summary
Structure-Function Analysis of BON1 homology of the VWA domain to protein kinases. A potential myristoylation site was predicted for the Arabidopsis BON1 protein. A hydrophilic cation-binding protein AtPCaP1, and a calcineurin B-like (CBL1) could localize to the plasma membrane through this lipid modification (15, 19, 20). The role of this potential modification in BON1 is unknown. In this study we examined three potential biochemical activities of BON1: calcium binding, myristoylation, and kinase activity. This study reveals unanticipated findings on the function of these domains/motifs and has implications in understanding the regulation and activities of copine proteins in general
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