Class I cyclic nucleotide phosphodiesterases (PDEs) share a catalytic domain containing 18 invariant residues. In cGMP-binding cGMP-specific PDE (PDE5), we showed previously that point mutation of nine of these profoundly decreases k(cat) when the assay is conducted in the presence of Mg(2+); seven of these are in the prototypical metal-binding motifs A and B (HX(3)HX(n)()E) that we identified earlier. Tandem arrangement of two of these metal-binding motifs in PDEs is novel, and whether residues within these motifs are involved in metal support of catalytic activity is a fundamental question in this field. This report shows that mutation of either His-607 (A motif) or His-643 (B motif) to alanine profoundly diminishes support of PDE catalysis by Mn(2+) or Mg(2+), but mutation of His-647 in B motif or of Glu in either motif does not. H607A and H643A mutants have much greater maximum catalytic rates supported by Mn(2+) than that by Mg(2+); catalytic activity of H603A mutant is supported weakly by either. In H607A and H643A, K(a)s for Mn(2+) and Mg(2+) are increased, but the effect of Mn(2+) is 2-fold greater than that of Mg(2+) in each. Mutation of any of the other conserved residues (Asn-604, Asp-644, His-675, Asp-714, and Asp-754) causes unremarkable changes in Mn(2+) or Mg(2+) support of catalysis. This study identifies specific residues in PDE5 that contribute to interactions with catalytically relevant metals. The combined data suggest that despite a high degree of sequence similarity between each HX(3)HX(n)()E motif in PDEs and certain metallo-endopeptidases, PDEs employ a distinct complement of residues for interacting with metals involved in catalysis.
SUMMARYThe clinical properties (efficacy and safety profile) of a medicine are related not only to its mode of action, but also to its selectivity for its target (usually a receptor or enzyme) and are also influenced by its pharmacokinetic properties (absorption, distribution, metabolism and elimination). The growing number of phosphodiesterase inhibitors that are selective for phosphodiesterase‐5 (PDE5) represent a promising new class of compounds that are useful for the treatment of erectile dysfunction and perhaps other disorders. Some of the basic pharmacodynamic and pharmacokinetic parameters that describe drug action are discussed with regard to the new PDE5 inhibitors. Central topics reviewed are the concentration that produces a given in vitro response, or potency (IC50), maximum plasma concentration (Cmax), time to Cmax (Tmax), half‐life (t½), area under the curve (AUC), bioavailability, onset and duration of action, and the balance to achieve optimum safety and efficacy. To illustrate these concepts, a group of inhibitors with varying selectivities and potencies for PDE5 (theophylline, IBMX, zaprinast, sildenafil, tadalafil and vardenafil) are discussed. Each drug has its own set of unique pharmacological characteristics based on its specific molecular structure, enzyme inhibition profile and pharmacokinetic properties. Each PDE5 inhibitor has a distinct selectivity that contributes to its safety profile. As with all new drugs, and especially those in a new class, careful evaluation will be necessary to ensure the optimal use of the PDE5 inhibitors.
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