Apelin is the endogenous ligand of the APJ receptor, a member of the G-protein-coupled receptor family. The apelin-APJ complex has been detected in many tissues and is emerging as a promising target for several pathophysiological conditions. There is currently little information on the structure-activity relationship (SAR) of the apelin hormone. In an effort to better delineate SAR, we synthesized analogues of apelin-13 modified at selected positions with unnatural amino acids, with a particular emphasis on the C-terminal portion. Analogues were then tested in binding and functional assays by evaluating Gi/o-mediated decreases in cAMP levels and by assessing β-arrestin2 recruitment to the APJ receptor. The plasma stability of new compounds was also assessed. Several analogues were found to possess increased binding and higher stability than the parent peptide.
Based on the crystal structure of chitosanase from Streptomyces sp. N174, we have calculated theoretical pK a values of the ionizable groups of this protein using a combination of the boundary element method and continuum electrostatics. The pK a value obtained for Arg 205 , which is located in the catalytic cleft, was abnormally high (>20.0), indicating that the guanidyl group may interact strongly with nearby charges. Chitosanases possessing mutations in this position (R205A, R205H, and R205Y), produced by Streptomyces lividans expression system, were found to have less than 0.3% of the activity of the wild type enzyme and to possess thermal stabilities 4 -5 kcal/mol lower than that of the wild type protein.
We have investigated the mechanism of the interaction of Streptomyces sp. N174 chitosanase with glucosamine hexasaccharide [(GlcN)(6)] by site-directed mutagenesis, thermal unfolding, and (GlcN)(6) digestion experiments, followed by theoretical calculations. From the energy-minimized model of the chitosanase-(GlcN)(6) complex structure (Marcotte et al., 1996), Asp57, which is present in all known chitosanases, was proposed to be one of the amino acid residues that interacts with the oligosaccharide substrate. The chitosanase gene was mutated at Asp57 to Asn (D57N) and Ala (D57A), and the relative activities of the mutated chitosanases were found to be 72 and 0.5% of that of the wild type, respectively. The increase in the transition temperature of thermal unfolding (T(m)), usually observed upon the addition of (GlcN)(n) to chitosanase mutants unaffected in terms of substrate binding, was considerably suppressed in the D57A mutant. These data suggest that Asp57 is important for substrate binding. The experimental time-courses of [(GlcN)(6)] degradation were analyzed by a theoretical model in order to obtain the binding free energy values of the individual subsites of the chitosanases. A (-3, -2, -1, +1, +2, +3) subsite model agreed best with the experimental data. This analysis also indicated that the mutation of Asp57 affects substrate affinity at subsite (-2), suggesting that Asp57 most likely participates in the substrate binding at this subsite.
The 3D structure-oriented alignment of the primary sequences of fourteen chitosanases, mainly of bacterial origin and belonging to families 46 and 80 of glycoside hydrolases, resulted in the identification of the following pattern common to all these enzymes: E-[DNQ]-x(8,17)-Y-x(7)-D-x-[RD]-[GP]-x-[TS]-x(3)-[AIVFLY]-G- x(5,11)-D. This pattern is proposed as the molecular signature of the chitosanases from families 46 and 80. It includes several amino acids essential for enzyme activity and (or) stability as shown by site-directed mutagenesis studies on the chitosanase from Streptomyces sp. N174. In particular, it includes two carboxylic residues directly involved in catalysis. We suggest that there is a continuum of sequence similarity between all the analyzed chitosanases, and that all these enzymes should probably be classified in one family.
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