Hydrolysis of the non-canonical cyclic nucleotide cUMP by PDE9A: kinetics and binding mode.

The non-canonical cyclic nucleotide cUMP and the phosphodiesterase PDE9A both occur in neuronal cells. Using HPLC-coupled tandem mass spectrometry, we characterized the kinetics of PDE9A-mediated cUMP hydrolysis. PDE9A is a low-affinity and high-velocity enzyme for cUMP (Vmax = ~ 6 µmol/min/mg; Km = ~ 401 µM). The PDE9 inhibitor BAY 73-6691 inhibited PDE9A-catalyzed cUMP hydrolysis (Ki = 590 nM). Docking studies indicate two H-bonds between the cUMP uridine moiety and Gln453/Asn405 of PDE9A. By contrast, the guanosine moiety of cGMP forms three H-bonds with Gln453. cCMP is not hydrolyzed at a concentration of 3 µM, but inhibits the PDE9A-catalyzed cUMP hydrolysis at concentrations of 100 µM or more. The probable main reason is that the cytosine moiety cannot act as H-bond acceptor for Gln453. A comparison of PDE9A with PDE7A suggests that the preference of the former for cGMP and cUMP and of the latter for cAMP and cCMP is due to stabilized alternative conformations of the side chain amide of Gln453 and Gln413, respectively. This so-called glutamine switch is known to be involved in the regulation of cAMP/cGMP selectivity of some PDEs.

Anticonvulsant effects after grafting of rat, porcine, and human mesencephalic neural progenitor cells into the rat subthalamic nucleus.

Cell transplantation based therapy is a promising strategy for treating intractable epilepsies. Inhibition of the subthalamic nucleus (STN) or substantia nigra pars reticulata (SNr) is a powerful experimental approach for remote control of different partial seizure types, when targeting the seizure focus is not amenable. Here, we tested the hypothesis that grafting of embryonic/fetal neural precursor cells (NPCs) from various species (rat, human, pig) into STN or SNr of adult rats induces anticonvulsant effects. To rationally refine this approach, we included NPCs derived from the medial ganglionic eminence (MGE) and ventral mesencephalon (VM), both of which are able to develop a GABAergic phenotype. All VM- and MGE-derived cells showed intense migration behavior after grafting into adult rats, developed characteristics of inhibitory interneurons, and survived at least up to 4 months after transplantation. By using the intravenous pentylenetetrazole (PTZ) seizure threshold test in adult rats, transient anticonvulsant effects were observed after bilateral grafting of NPCs derived from human and porcine VM into STN, but not after SNr injection (site-specificity). In contrast, MGE-derived NPCs did not cause anticonvulsant effects after grafting into STN or SNr (cell-specificity). Neither induction of status epilepticus by lithium-pilocarpine to induce neuronal damage prior to the PTZ test nor pretreatment of MGE cells with retinoic acid and potassium chloride to increase differentiation into GABAergic neurons could enhance anticonvulsant effectiveness of MGE cells. This is the first proof-of-principle study showing anticonvulsant effects by bilateral xenotransplantation of NPCs into the STN. Our study highlights the value of VM-derived NPCs for interneuron-based cell grafting targeting the STN.