Robert F. Bruns

Inhibition of protein kinase C by calphostin C is light-dependent

Calphostin C, a secondary metabolite of the fungus Cladosporium cladosporioides, inhibits protein kinase C by competing at the binding site for diacylglycerol and phorbol esters. Calphostin C is a polycyclic hydrocarbon with strong absorbance in the visible and ultraviolet ranges. In characterizing the activity of this compound, we unexpectedly found that the inhibition of [3H]phorbol dibutyrate binding was dependent on exposure to light. Ordinary fluorescent light was sufficient for full activation. The inhibition of protein kinase C activity in cell-free systems and intact cells also required light. Light-dependent cytotoxicity was seen at concentrations about 5-fold higher than those inhibiting protein kinase C.

Species differences in affinities of non-peptide antagonists for substance p receptors

In the present study, affinities of (±)-CP-96,345 and analogs in [ 125 I]SP binding were determined in various tissues derived from several species. The resulting IC 50 values segregate into discrete groups according to species rather than tissue, indicating the existence of species differences in NK-1 receptors

The Neuropeptide Y Y1 Antagonist, 1229U91, A Potent Agonist for the Human Pancreatic Polypeptide-Preferring (NPY Y4) Receptor

Recently, a novel high-affinity peptide antagonist, 1229U91, was published as a selective neuropeptide Y Y1 antagonist. The selectivity of 1229U91 was evaluated in the human NPY Y1 receptor containing cell line, SK-N-MC, and cells containing the cloned human NPY Y2, the pancreatic polypeptide-preferring (NPY Y4), and the NPY Y5 receptors. 1229U91 potently displaced [125I]-peptide YY (PYY) binding to human NPY Y1 receptors (IC50 = 0.245+/-0.004 nM, n = 4). but displayed little affinity for the human NPY Y2 and Y5 receptors (IC50 > 1000 nM). Interestingly, 1229U91 displaced [125I]-PYY with even greater affinity at the human NPY Y4 receptor (IC50 = 0.081+/-0.009 nM, n = 4). Using a cyclic AMP accumulation assay, 1229U91 blocked NPY inhibition of forskolin-induced adenylate cyclase activity in NPY Y1 receptor containing SK-N-MC cells. In the human NPY Y4 receptor expressing cell line, 1229U91 did not block pancreatic polypeptide (PP) inhibition of forskolin stimulated adenylate cyclase. However, in the absence of PP, 1229U91 was able to inhibit forskolin stimulated cyclic AMP accumulation (IC50 = 7.16+/-2.8 nM, n = 4). We conclude that 1229U91 binds non-selectively with high affinity to both human NPY Y1 and Y4 receptors. Furthermore, 1229U91 displays antagonist activity at the NPY Y1 receptor, while having agonist activity at the NPY Y4 receptor.

Role of Adenosine in Energy Supply/Demand Balance

Abstract The central paradigm of adenosine research is the idea that adenosine controls energy supply/demand balance. According to this theory, AMP is hydrolyzed to adenosine during conditions of hypoxia, ischemia, or exercise. Adenosine then redresses local energy deficits by reducing energy demand and increasing energy supply.

Structure-Activity Relationships of Adenosine A1 and A2 Receptors

Philidor once said that pawns are the soul of chess. In a similar way, it might be said that structure-activity relationships are the soul of receptorology. Structure-activity relationships are used to define receptors, to identify the selective agonists and antagonists that are used as pharmacological tools to study the roles of receptors, and ultimately to develop drugs that act via modulation of receptors.

Cyclosporin A is a substance P (tachykinin NK1) receptor antagonist

The immunosuppressive cyclic undecapeptide, cyclosporin A, inhibited the binding of [125I]substance P to tachykinin NK1 receptors expressed by human IM-9 lymphoblastoid cells, U-373 MG human astrocytoma cells and guinea pig lung parenchyma with IC50 values of 425 +/- 58, 783 +/- 180, and 784 +/- 163 nM respectively. The dihydro derivative of cyclosporin A (dihydro-cyclosporin A) was an equally effective inhibitor, but the O-acetylated derivative (cyclosporin A-OAc) was 3-4 fold less potent. The cyclosporin compounds also inhibited [125I]neurokinin A binding to human NK2 receptors with potencies slightly less than at NK1 sites. In contrast, they were 8-20-fold less effective inhibitors of [125I]MePhe7-neurokinin B binding to guinea pig NK3 receptors (p < 0.001). Thus, the cyclosporin A compounds showed selectivity for NK1 and NK2 receptors. The structure-activity pattern for the effects of cyclosporin A compounds at tachykinin receptors differs from the pattern previously described for their immunosuppressive activity. All three compounds inhibited substance P induced interleukin-6 (IL-6) secretion from U-373 MG astrocytoma cells with potencies similar to their NK1 receptor binding affinities. In addition, cyclosporin A blocked substance P induced phosphatidylinositol (PI) turnover in U-373 MG cells without blocking the corresponding response to histamine. This novel pharmacological profile of the cyclosporin A compounds as NK1 receptor antagonists does not appear to correlate with other known in vitro cyclosporin A functions.

Functional activity of the adenosine binding enhancer, PD 81,723, in the in vitro hippocampal slice.

The adenosine receptor binding enhancer, PD 81,723, enhances the inhibitory effects of exogenously applied adenosine in a dose-dependent manner in hippocampal brain slices. Extracellular recordings were obtained from the CA1 cell layer while electrically stimulating the stratum radiatum. Application of 1, 10 or 32 microM PD 81,723 in the presence of adenosine resulted in a dose-dependent reduction in the amplitude of the population spike which could be partially reversed by theophylline. In addition, hippocampal slices exposed to adenosine showed greater paired-pulse facilitation compared to control and this facilitation was significantly enhanced by the presence of PD 81,723. PD 81,723 had no effect when administered alone, but required the presence of adenosine. These results demonstrate that in addition to enhancing adenosine receptor binding, PD 81,723 also enhances the functional activity of adenosine in the hippocampal slice.

Diphenylpyrazolidinone and benzodiazepine cholecystokinin antagonists: A case of convergent evolution in medicinal chemistry

Abstract Two recently described classes of nonpeptide cholecystokinin receptor antagonists contain diphenylpyrazolidinone and benzodiazepine substructures, respectively. Although the origins and development of these series were completely independent, the low energy conformations predicted by modeling showed remarkable three-dimensional homology between the structures.

Structure-activity relationships of a series of 1-substituted-4-methylbenzimidazole neuropeptide Y-1 receptor antagonists.

The characterization of a novel series of NPY-1 receptor antagonists derived from the 4-methylbenzimidazole 4 is described. Appropriate substitution on the piperidyl nitrogen of 4 led to systematic increases in Y-1 receptor affinity, to approximately 50-fold, and to the discovery of the importance of a second basic substituent.

Rapid parallel synthesis applied to the optimization of a series of potent nonpeptide neuropeptide Y-1 receptor antagonists

Abstract This study describes the integrated application of parallel synthesis and computational chemistry to the design of potent nonpeptide antagonists for the neuropeptide Y-1 (NPY1) receptor. A lead molecule was modeled in the active site of the NPY1 receptor, and a potentially fruitful region for analog construction was identified. Synthesis of suitable scaffolds followed by solution phase generation of a small library of analogs produced a compound with 5-fold improvement in binding over the already potent lead. This new compound was shown to be an unanticipated side product of the parallel synthesis reaction.