Cellular membranes and lipid-binding domains as attractive targets for drug development.

Interdisciplinary research focused on biological membranes has revealed them as signaling and trafficking platforms for processes fundamental to life. Biomembranes harbor receptors, ion channels, lipid domains, lipid signals, and scaffolding complexes, which function to maintain cellular growth, metabolism, and homeostasis. Moreover, abnormalities in lipid metabolism attributed to genetic changes among other causes are often associated with diseases such as cancer, arthritis and diabetes. Thus, there is a need to comprehensively understand molecular events occurring within and on membranes as a means of grasping disease etiology and identifying viable targets for drug development. A rapidly expanding field in the last decade has centered on understanding membrane recruitment of peripheral proteins. This class of proteins reversibly interacts with specific lipids in a spatial and temporal fashion in crucial biological processes. Typically, recruitment of peripheral proteins to the different cellular sites is mediated by one or more modular lipid-binding domains through specific lipid recognition. Structural, computational, and experimental studies of these lipid-binding domains have demonstrated how they specifically recognize their cognate lipids and achieve subcellular localization. However, the mechanisms by which these modular domains and their host proteins are recruited to and interact with various cell membranes often vary drastically due to differences in lipid affinity, specificity, penetration as well as protein-protein and intramolecular interactions. As there is still a paucity of predictive data for peripheral protein function, these enzymes are often rigorously studied to characterize their lipid-dependent properties. This review summarizes recent progress in our understanding of how peripheral proteins are recruited to biomembranes and highlights avenues to exploit in drug development targeted at cellular membranes and/or lipid-binding proteins.

Roles of calcium ions in the membrane binding of C2 domains.

The C2 domain is a membrane-targeting domain found in many cellular proteins involved in signal transduction or membrane trafficking. The majority of C2 domains co-ordinate multiple Ca(2+) ions and bind the membrane in a Ca(2+)-dependent manner. To understand the mechanisms by which Ca(2+) mediates the membrane binding of C2 domains, we measured the membrane binding of the C2 domains of group IV cytosolic phospholipase A(2) (cPLA(2)) and protein kinase C-alpha (PKC-alpha) by surface plasmon resonance and lipid monolayer analyses. Ca(2+) ions mainly slow the membrane dissociation of cPLA(2)-C2, while modulating both membrane association and dissociation rates for PKC-alpha-C2. Further studies with selected mutants showed that for cPLA(2) a Ca(2+) ion bound to the C2 domain of cPLA(2) induces the intra-domain conformational change that leads to the membrane penetration of the C2 domain whereas the other Ca(2+) is not directly involved in membrane binding. For PKC-alpha, a Ca(2+) ion induces the inter-domain conformational changes of the protein and the membrane penetration of non-C2 residues. The other Ca(2+) ion of PKC-alpha-C2 is involved in more complex interactions with the membrane, including both non-specific and specific electrostatic interactions. Together, these studies of isolated C2 domains and their parent proteins allow for the determination of the distinct and specific roles of each Ca(2+) ion bound to different C2 domains.

Differential roles of ionic, aliphatic, and aromatic residues in membrane-protein interactions: a surface plasmon resonance study on phospholipases A2.

The roles of cationic, aliphatic, and aromatic residues in the membrane association and dissociation of five phospholipases A(2) (PLA(2)), including Asp-49 PLA(2) from the venom of Agkistrodon piscivorus piscivorus, acidic PLA(2) from the venom of Naja naja atra, human group IIa and V PLA(2)s, and the C2 domain of cytosolic PLA(2), were determined by surface plasmon resonance analysis. Cationic interfacial binding residues of A. p. piscivorus PLA(2) (Lys-10) and human group IIa PLA(2) (Arg-7, Lys-10, and Lys-16), which mediate electrostatic interactions with anionic membranes, primarily accelerate the membrane association. In contrast, an aliphatic side chain of the C2 domain of cytosolic PLA(2) (Val-97), which penetrates into the hydrophobic core of the membrane and forms hydrophobic interactions, mainly slows the dissociation of membrane-bound protein. Aromatic residues of human group V PLA(2) (Trp-31) and N. n. atra PLA(2) (Trp-61, Phe-64, and Tyr-110) contribute to both membrane association and dissociation steps, and the relative contribution to these processes depends on the chemical nature and the orientation of the side chains as well as their location on the interfacial binding surface. On the basis of these results, a general model is proposed for the interfacial binding of peripheral proteins, in which electrostatic interactions by ionic and aromatic residues initially bring the protein to the membrane surface and the subsequent membrane penetration and hydrophobic interactions by aliphatic and aromatic residues stabilize the membrane-protein complexes, thereby elongating the membrane residence time of protein.

Roles of ionic residues of the C1 domain in protein kinase C-alpha activation and the origin of phosphatidylserine specificity.

On the basis of extensive structure-function studies of protein kinase C-alpha (PKC-alpha), we have proposed an activation mechanism for conventional PKCs in which the C2 domain and the C1 domain interact sequentially with membranes (Medkova, M., and Cho, W. (1999) J. Biol. Chem. 274, 19852-19861). To further elucidate the interactions between the C1 and C2 domains during PKC activation and the origin of phosphatidylserine specificity, we mutated several charged residues in two C1 domains (C1a and C1b) of PKC-alpha. We then measured the membrane binding affinities, activities, and monolayer penetration of these mutants. Results indicate that cationic residues of the C1a domain, most notably Arg(77), interact nonspecifically with anionic phospholipids prior to the membrane penetration of hydrophobic residues. The mutation of a single aspartate (Asp(55)) in the C1a domain to Ala or Lys resulted in dramatically reduced phosphatidylserine specificity in vesicle binding, activity, and monolayer penetration. In particular, D55A showed much higher vesicle affinity, activity, and monolayer penetration power than wild type under nonactivating conditions, i.e. with phosphatidylglycerol and in the absence of Ca(2+), indicating that Asp(55) is involved in the tethering of the C1a domain to another part of PKC-alpha, which keeps it in an inactive conformation at the resting state. Based on these results, we propose a refined model for the activation of conventional PKC, in which phosphatidylserine specifically disrupts the C1a domain tethering by competing with Asp(55), which then leads to membrane penetration and diacylglycerol binding of the C1a domain and PKC activation.