Abstract
Vitamin A is essential for vision and many other biological processes required for human health and survival. Extracellular retinol binding protein (RBP) delivers vitamin A into the cell upon binding to the vitamin A transporter, STRA6. However, when retinol free RBP binds to STRA6, it induces vitamin A transport out of the cell. The bi-directionality of vitamin A transport is thought to be regulated further by an intracellular protein-protein interaction (PPI) between STRA6 and the EF-hand Ca(2+)-binding protein, calmodulin (CaM). Insights regarding how CaM regulates vitamin A transport were originally provided at atomic resolution by a cryoEM structure of the zebrafish STRA6-CaM complex. This cryoEM structure, together with NMR studies, confirmed that three STRA6 helices (i.e., BP0, BP1, and BP2) comprised the CaM-STRA6 binding interface, with BP2 providing the major set of interactions. NMR and other biophysical methods demonstrated that zebrafish BP2 peptide (zfBP2) binding to CaM involved a Ca(2+)-dependent type 2 binding and functional folding mechanism of action, which could influence structural, dynamic, and allosteric functions of STRA6. To expand our understanding of vitamin A transport to a mammalian STRA6 transporter, the backbone and sidechain (1)H(N), (13)C, and (15)N resonances were assigned here for (Ca)CaM (148 residues) when bound to a sheep BP2 peptide (32 residues) (shBP2). Interestingly, the NMR data showed (Ca)CaM resonances were affected differently upon binding shBP2 versus zfBP2. Such differences may be useful for distinguishing important features regarding (Ca)CaM complexes with mammalian versus zebrafish STRA6.