Determinants of adenophostin A binding to inositol trisphosphate receptors.

Inositol 1,4,5-trisphosphate (IP(3)) receptors from cerebellum and recombinant type 1 IP(3) receptors expressed in Sf9 cells had indistinguishable affinities for IP(3) ( K (d)=6.40+/-0.48 nM) and adenophostin A ( K (d)=0.89+/-0.05 nM). In cytosol-like medium, each of the three mammalian IP(3) receptor subtypes when expressed in Sf9 cells bound adenophostin A with greater affinity than IP(3). It has been suggested that adenophostin A binds with high affinity only in the presence of ATP, but we found that adenophostin A similarly displaced [(3)H]IP(3) from type 1 IP(3) receptors whatever the ATP concentration. N-terminal fragments of the type 1 receptor were expressed with and without the S1 splice site; its removal had no effect on [(3)H]IP(3) binding to the 1-604 protein, but abolished binding to the 224-604 protein. The 1-604 fragment and full-length receptor bound adenophostin A with the same affinity, but the fragment had 3-fold greater affinity for IP(3), suggesting that C-terminal residues selectively inhibit IP(3) binding. The 224-604S1(+) fragment bound IP(3) and adenophostin A with increased affinity, but as with the 1-604 fragment it bound adenophostin A with only 2-fold greater affinity than IP(3). High-affinity binding of adenophostin A may be partially determined by its 2'-phosphate interacting more effectively than the 1-phosphate of IP(3) with residues within the IP(3)-binding core. This may account for the 2-fold greater affinity of adenophostin A relative to IP(3) for the minimal IP(3)-binding domain. In addition we suggest that C-terminal residues, which impede access of IP(3), may selectively interact with adenophostin A to allow it unhindered access to the IP(3)-binding domain

Orally bioavailable small molecule drug protects memory in Alzheimer's disease models

Oligomers of beta-amyloid (Aβ) are implicated in the early memory impairment seen in Alzheimer's disease before to the onset of discernable neurodegeneration. Here, the capacity of a novel orally bioavailable, central nervous system-penetrating small molecule 5-aryloxypyrimidine, SEN1500, to prevent cell-derived (7PA2 [conditioned medium] CM) Aβ-induced deficits in synaptic plasticity and learned behavior was assessed. Biochemically, SEN1500 bound to Aβ monomer and oligomers, produced a reduction in thioflavin-T fluorescence, and protected a neuronal cell line and primary cortical neurons exposed to synthetic soluble oligomeric Aβ1–42. Electrophysiologically, SEN1500 alleviated the in vitro depression of long-term potentiation induced by both synthetic Aβ1–42 and 7PA2 CM, and alleviated the in vivo depression of long-term potentiation induced by 7PA2 CM, after systemic administration. Behaviorally, oral administration of SEN1500 significantly reduced memory-related deficits in operant responding induced after intracerebroventricular injection of 7PA2 CM. SEN1500 reduced cytotoxicity, acute synaptotoxicity, and behavioral deterioration after in vitro and in vivo exposure to synthetic Aβ and 7PA2 CM, and shows promise for development as a clinically viable disease-modifying Alzheimer's disease treatment