We report the X-ray crystal structure of a phosphodiesterase (PDE) that includes both catalytic and regulatory domains. PDE2A (215-900) crystallized as a dimer in which each subunit had an extended organization of regulatory GAF-A and GAF-B and catalytic domains connected by long ␣-helices. The subunits cross at the GAF-B/ catalytic domain linker, and each side of the dimer contains in series the GAF-A and GAF-B of one subunit and the catalytic domain of the other subunit. A dimer interface extends over the entire length of the molecule. The substrate binding pocket of each catalytic domain is occluded by the H-loop. We deduced from comparisons with structures of isolated, ligand-bound catalytic subunits that the H-loop swings out to allow substrate access. However, in dimeric PDE2A (215-900), the H-loops of the two catalytic subunits pack against each other at the dimer interface, necessitating movement of the catalytic subunits to allow for H-loop movement. Comparison of the unliganded GAF-B of PDE2A (215-900) with previous structures of isolated, cGMP-bound GAF domains indicates that cGMP binding induces a significant shift in the GAF-B/catalytic domain linker. We propose that cGMP binding to GAF-B causes movement, through this linker region, of the catalytic domains, such that the H-loops no longer pack at the dimer interface and are, instead, free to swing out to allow substrate access. This increase in substrate access is proposed as the basis for PDE2A activation by cGMP and may be a general mechanism for regulation of all PDEs.cGMP activation ͉ GAF domains ͉ PDE-2A T he cyclic nucleotides cAMP and cGMP are ubiquitous intracellular signaling molecules that mediate a vast array of biological processes throughout the body. The means by which these two molecules participate in diverse functions, in different cell types and within single cells, involves tight regulation of the spatial and temporal residence of their concentrations. The phosphodiesterases (PDEs) are a superfamily of enzymes that metabolically inactivate cAMP and cGMP (1) to play key roles in both these aspects of regulation. The PDEs are modular enzymes characterized by a relatively conserved C-terminal catalytic domain and a more variable N-terminal domain involved in regulation of activity, subcellular localization, and interactions with other proteins. There are 11 PDE gene families, with different families encoded by one to four genes, and further diversity derived from alternative splicing. The PDE families differ broadly in specificity and affinity for cAMP and cGMP. Much has been learned about the molecular bases for these differences from studies of X-ray crystal structures of the catalytic domains of
The Saccharomyces cerevisiae a1 homeodomain is expressed as a soluble protein in Escherichia coli when cultured in minimal medium. Nuclear magnetic resonance (NMR) spectra of previously prepared a1 homeodomain samples contained a subset of doubled and broadened resonances. Mass spectroscopic and NMR analysis demonstrates that the heterogeneity is largely due to a lysine misincorporation at the arginine (Arg) 115 site. Arg 115 is coded by the 5'-AGA-3' sequence, which is quite rare in E. coli genes. Lower level mistranslation at three other rare arginine codons also occurs. The percentage of lysine for arginine misincorporation in a1 homeodomain production is dependent on media composition. The dnaY gene, which encodes the rare 5'-AGA-3' tRNA(ARG), was co-expressed in E. coli with the a1-encoding plasmid to produce a homogeneous recombinant a1 homeodomain. Co-expression of the dnaY gene completely blocks mistranslation of arginine to lysine during a1 overexpression in minimal media, and homogeneous protein is produced.
Phosphodiesterase 2A (PDE2A) inhibitors have been reported to demonstrate in vivo activity in preclinical models of cognition. To more fully explore the biology of PDE2A inhibition, we sought to identify potent PDE2A inhibitors with improved brain penetration as compared to current literature compounds. Applying estimated human dose calculations while simultaneously leveraging synthetically enabled chemistry and structure-based drug design has resulted in a highly potent, selective, brain penetrant compound 71 (PF-05085727) that effects in vivo biochemical changes commensurate with PDE2A inhibition along with behavioral and electrophysiological reversal of the effects of NMDA antagonists in rodents. This data supports the ability of PDE2A inhibitors to potentiate NMDA signaling and their further development for clinical cognition indications.
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