Pharmacological characterization of nipecotic acid ethyl ester: A novel cholinergic muscarinic agonist

The aim of this dissertation was to examine the hypothesis that (R)-nipecotic acid ethyl ester ((R)-NAEE) is a cholinergic agonist that is selective for a particular subclass (M$\sb1$ or M$\sb2$) of muscarinic receptors.^ Ligand binding studies indicated that like cholinergic agonists (R)-NAEE selectively interacts with rat heart (M$\sb2$) and brain (M$\sb1$) muscarinic binding sites. Physiological studies revealed that unlike cholinergic agonists (R)-NAEE stimulated only those responses coupled to M$\sb2$ muscarinic receptors (acid secretion, negative inotropic response, smooth muscle contraction). Moreover, in rat brain (R)-NAEE differentiated between M$\sb2$ receptors negatively coupled to adenylate cyclase activity and M$\sb1$ receptors mediating PI turnover, being a weak competitive antagonist at these latter sites. In isolated rat gastric mucosal cells (R)-NAEE also differentiated between two M$\sb2$ coupled responses where it potentiated acid secretion but could not stimulate PI turnover. Atropine, a selective antimuscarinic agent, competitively antagonized all agonist effects of (R)-NAEE.^ Unlike (R)-NAEE, the muscarinic agonist arecoline, which is structurally similar to (R)-NAEE, stimulates both M$\sb1$ and M$\sb2$ receptors. Structure activity studies revealed that saturation of the piperidine ring and the length of the ester side chain of (R)-NAEE are the most important determinants for both M$\sb2$ efficacy and selectivity.^ The results of this dissertation establish that (R)-NAEE is a cholinergic muscarinic receptor agonist that displays greater efficacy at M$\sb2$ than at M$\sb1$ receptors, being a weak antagonist at the M$\sb1$ site. With such selectivity, (R)-NAEE may be regarded as a prototype for a unique class of cholinergic muscarinic M$\sb2$ receptor agonists. Because of these unique properties, (R)-NAEE should be useful in the further characterization of muscarinic receptors, and could lead to the development of a new class of therapeutic agents. ^

VERIFICATION OF DNA PREDICTED PROTEIN SEQUENCES BY ENZYME HYDROLYSIS AND MASS SPECTROMETRIC ANALYSIS

The focus of this thesis lies in the development of a sensitive method for the analysis of protein primary structure which can be easily used to confirm the DNA sequence of a protein's gene and determine the modifications which are made after translation. This technique involves the use of dipeptidyl aminopeptidase (DAP) and dipeptidyl carboxypeptidase (DCP) to hydrolyze the protein and the mass spectrometric analysis of the dipeptide products.^ Dipeptidyl carboxypeptidase was purified from human lung tissue and characterized with respect to its proteolytic activity. The results showed that the enzyme has a relatively unrestricted specificity, making it useful for the analysis of the C-terminal of proteins. Most of the dipeptide products were identified using gas chromatography/mass spectrometry (GC/MS). In order to analyze the peptides not hydrolyzed by DCP and DAP, as well as the dipeptides not identified by GC/MS, a FAB ion source was installed on a quadrupole mass spectrometer and its performance evaluated with a variety of compounds.^ Using these techniques, the sequences of the N-terminal and C-terminal regions and seven fragments of bacteriophage P22 tail protein have been verified. All of the dipeptides identified in these analysis were in the same DNA reading frame, thus ruling out the possibility of a single base being inserted or deleted from the DNA sequence. The verification of small sequences throughout the protein sequence also indicates that no large portions of the protein have been removed after translation. ^