The oral antihypertensive activity of the methylated derivatives of phenyl-2-aminoethyl sulfide.

We have reported previously that phenyl-2-aminoethyl sulfide and its derivatives are excellent substrates for dopamine-beta-monooxygenase and produce an antihypertensive effect in spontaneously hypertensive rats after i.p. administration. In the studies reported herein, we demonstrate that alpha-methyl-phenyl-2-aminoethyl sulfide and 4-hydroxy-alpha-methyl-phenyl-2-aminoethyl sulfide, the methylated and hydroxymethylated derivatives of phenyl-2-aminoethyl sulfide, respectively, decrease mean arterial pressure in conscious, unrestrained spontaneously hypertensive rats after p.o. administration. This antihypertensive effect after p.o. administration occurs without the undesirable transient rise in blood pressure observed previously after i.p. administration. Results using the methodology of food-reinforced operant conditioned behavior are consistent with the interpretation that the ring hydroxylated derivatives, 4-hydroxy-phenyl-2-aminoethyl sulfide and 4-hydroxy-alpha-methyl-phenyl-2-aminoethyl sulfide, do not penetrate into the central nervous system. This finding supports our contention that the primary site of action for the antihypertensive activity of the sulfides may be the peripheral adrenergic nerve ending. In view of the current high degree of interest in chiral development, the enantiomeric specificity of the antihypertensive activity of alpha-methyl-phenyl-2-aminoethyl sulfide was also evaluated. Results from these studies demonstrate that the (S)-enantiomer of alpha-methyl-phenyl-2-aminoethyl sulfide is more effective in lowering blood pressure after p.o. administration than the (R)-enantiomer. The implications of our findings in terms of the mechanism of action of these compounds are discussed.

HPLC-based method for determination of absolute configuration of alpha-chiral amines.

We introduce a novel, HPLC-based method for facile determination of the absolute configuration of alpha-chiral amines. Our method is easily applied to a variety of compounds, including amino acid derivatives. The method involves initial derivatization of the chiral amine analyte with the chiral derivatizing reagent, N-succinimidyl alpha-methoxyphenylacetate (SMPA), to produce the corresponding diastereomeric adducts. Inspection of a particular rotomer of the SMPA adduct and application of simple rules correlates absolute configuration and HPLC elution order. A key aspect of our method is that it can be used to determine absolute configuration without using enantiomeric standards of the amine analytes. Furthermore, it is of utmost significance that our method can also be used to determine absolute configuration even when only one analyte enantiomer of unknown absolute configuration is present, as is often the case for enzymatic products, naturally derived compounds, or enantiomerically enriched compounds prepared via chiral syntheses. We have observed strict adherence between predicted and observed absolute configuration for a wide variety of alpha-chiral amines. The chromatographic method we present in this paper is very practical and has several important advantages over NMR-based approaches which have been previously developed. For example, microgram quantities of an analyte in a complex enzymatic mixture can be directly analyzed by our HPLC-based method while the impurities often preclude definitive proton assignments in the NMR approach.

Activation of an adrenergic pro-drug through sequential stereoselective action of tandem target enzymes.

The synthetic amino acid, 3,4-dihydroxyphenylserine (DOPS) has been of great interest for many years as an adrenergic pro-drug, since the L-threo diastereomer of DOPS can be a precursor of R-(-)-norepinephrine, the natural form of this neurotransmitter. We now report bioactivation of DOPS to the potent pharmacological agent, noradrenalone (arterenone), via sequential stereoselective action by two target enzymes--dopamine beta-monooxygenase (DBM) and L-aromatic amino acid decarboxylase (AADC)--acting in tandem. Enzymatic activation is stereospecific, with only the L-erythro DOPS diastereomer producing noradrenalone; this is consistent with the known stereospecificities of AADC and DBM. These results provide a heretofore unrecognized rationale for the bioactivity of L-erythro DOPS and provide a basis for the design of new adrenergic pro-drugs.

The enantiomeric specificity of the antihypertensive activity of 1-(phenylthio)-2-aminopropane, a synthetic substrate analogue for dopamine beta-monooxygenase.

We have found that (R,S)-1-(phenylthio)-aminopropane (4a), a synthetic alternate substrate for the terminal enzyme of norepinephrine biosynthesis, dopamine beta-monooxygenase (DBM), is both an indirect sympathomimetic and a potent antihypertensive agent in spontaneously hypertensive rats. We demonstrate herein that there is a distinct enantiospecific difference in the activities of (R)-1-(phenylthio)-2-aminopropane (4b) and (S)-1-(phenylthio)-2-aminopropane (4c). We find that 4c, the more potent DBM substrate analogue, exhibits both the indirect sympathomimetic activity and the antihypertensive activity previously observed for the racemate and inhibits the active transport of catecholamines at the nerve terminal. In contrast, 4b, which is less potent as a DBM substrate or as an inhibitor of catecholamine uptake, does not exhibit an indirect sympathomimetic effect and is not an effective antihypertensive agent. These results suggest that the greater selectivity of the S enantiomer for both the catecholamine reuptake transporter and the target enzyme DBM accounts for its greater potency as an indirect-acting sympathomimetic agent as well as its activity as an antihypertensive agent. These results are also consistent with the hypothesized mechanism of action of this class of sulfur-containing DBM substrate analogues.

N-succinimidyl methoxyphenylacetic acid ester, an amine-directed chiral derivatizing reagent suitable for enzymatic scale resolutions.

A chiral derivatizing reagent, N-succinimidyl-2-(S)-methoxy-2-phenylacetic acid ester (SMPA), directed toward reaction with primary amine-containing compounds has been synthesized and characterized. This reagent is suitable for HPLC resolution from enzymatic-scale reactions where only microgram quantities of chiral products may be obtainable. SMPA derivatization was shown to be effective in the resolution of the enantiomers of a number of different racemic compounds. SMPA was used to resolve the diastereoisomeric derivatives of a previously unknown enzymatically oxygenated product, allowing determination of the stereochemical course of the enzymatic reaction. SMPA is easily prepared from an inexpensive, commercially available, and enantiomerically pure precursor with the formation of a shelf-stable crystalline product which is utilizable in water-containing solutions. In addition to its usefulness for micro-determinations, SMPA is useful for preparative-scale resolutions of enantiomers since the reagent is cleaved from the diastereoisomeric derivative by acid hydrolysis.