Synthesis and characterization of photolabile derivatives of serotonin for chemical kinetic investigations of the serotonin 5-HT(3) receptor.

A series of photolabile o-nitrobenzyl derivatives of serotonin (caged serotonin) were synthesized: the amine-linked serotonin derivatives N-(2-nitrobenzyl) serotonin (Bz-5HT) and N-(alpha-carboxy-2-nitrobenzyl) serotonin (N-CNB-5HT), and O-alpha-carboxy-2-nitrobenzyl) serotonin (O-CNB-5HT), which has the caging group attached to the phenolic OH group. All the derivatives released free serotonin when excited by 308-nm or 337-nm laser pulses. The time constant of serotonin release from N-CNB-5HT was 1. 2 ms, with a quantum yield of 0.08. This is too slow for rapid chemical kinetic measurements. O-CNB-5HT is suitable for transient kinetic investigations of the serotonin 5-HT(3) receptor. It released serotonin with a time constant of 16 micros and a quantum yield of 0.03. The biological properties of O-CNB-5HT were evaluated, and the applicability of the compound for kinetic studies of the 5-HT(3) receptor was demonstrated. O-CNB-5HT does not activate the 5-HT(3) receptor by itself, nor does it modulate the response of a cell when co-applied with serotonin. When irradiated with a 337-nm laser pulse, O-CNB-5HT released free serotonin that evoked 5-HT(3) receptor-mediated whole-cell currents in NIE-115 mouse neuroblastoma cells.

Quantitative liquid chromatographic-tandem mass spectrometric determination of orlistat in plasma with a quadrupole ion trap.

This report evaluates the use of a quadrupolar ion trap for quantitation in a bioanalytical laboratory. The evaluation was accomplished with the cross-validation of an LC-MS-MS quantitative method previously validated on a triple quadrupole mass spectrometer. The method was a multi-level determination of the anti-obesity drug, orlistat, in human plasma. The method has been refined previously on a triple quadrupole instrument to provide rapid sample throughput with robust reproducibility at sub-nanogram detection limits. Optimization of the method on the ion trap required improved chromatographic separation of orlistat from interfering plasma matrix components coextracted during the initial liquid-liquid extraction of plasma samples. The ion trap produces full-scan collision-induced dissociation mass spectra containing characteristic orlistat fragment ions that are useful for quantitation. Data collection on the ion trap required a precursor ion isolation width of 3.0 Da and optimal quantitative results were obtained when three fragment ions were monitored with a 1.8 Da window for each ion. Although a direct cross-validation between the ion trap and the tandem triple quadrupole mass spectrometer was not possible, quantitative results for orlistat comparable to those obtained from the triple quadrupole instrument were achieved by the ion trap with the modified method. The limit of quantitation for orlistat in plasma on the ion trap was 0.3 ng ml(-1) with a linear dynamic range of 0.3 to 10 ng ml(-1). Precision and accuracy varied from 4 to 15% over the quantitation range. The overall results provide an example of the utility of an ion trap in bioanalytical work.

Immunoaffinity Ultrafiltration with Ion Spray HPLC/MS for Screening Small-Molecule Libraries.

A solution-phase screening method for libraries of pharmaceutically relevant molecules is presented. The technique is applicable to screening combinatorial libraries of 20-30 closely related molecules. In this report, individual benzodiazepines are selected from a multicomponent library mixture by formation in solution of noncovalent immunoaffinity complexes with antibodies raised to therapeutically proven drugs such as nitrazepam, temazepam, or oxazepam. Captured compounds are separated from nonspecifically bound library components by centrifugal ultrafiltration. The specifically selected molecules retained on the filter are subsequently liberated from the antibodies by acidification and analyzed by HPLC coupled with pneumatically assisted electrospray (ion spray) ionization mass spectrometric detection. Competition by the benzodiazepines for limited antibody binding sites is controlled by varying the stoichiometry of the complexation mixture. This procedure selects library components with the greatest affinity for a particular antibody. Specific capture of benzodiazepines is demonstrated by screening both a pool of structurally similar benzodiazepines and a more complex mixture of benzodiazepines with an additional set of unrelated compounds. Affinity ultrafiltration and electrospray mass spectrometry complement each other to enhance screening and identification of pooled drug candidates and potentially can be extended to other small-molecule combinatorial libraries and macromolecular receptor preparations.

Synthesis and characterization of a caged receptor ligand suitable for chemical kinetic investigations of the glycine receptor in the 3-microseconds time domain.

Here we report the development and characterization of a new photolabile protecting group for the carboxyl group of neurotransmitters, 2-methoxy-5-nitrophenyl. The synthesis and characterization of a photolabile derivative of beta-alanine, caged beta-alanine, are described. beta-Alanine can activate the glycine receptor, a major inhibitory receptor in the mammalian central nervous system; the 2-methoxy-5-nitrophenyl derivative of beta-alanine combined with a laser-pulse photolysis method makes it possible to investigate the chemical kinetic mechanism of the receptor in the 3-microseconds time domain. The derivative is photolyzed by a laser pulse to release free beta-alanine within 3 microseconds and with a product quantum yield of 0.2. In aqueous solution in the dark and at neutral pH, the compound is more stable, by a factor of approximately of 25, than the analogous derivative of glycine [Ramesh, D., Wieboldt, R., Niu, L., Carpenter, B. K., & Hess, G. P. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 11074-11078]. 2-Methoxy-5-nitrophenyl-beta-alanine hydrolyzes in aqueous solution at neutral pH with a t1/2 of approximately 1.5 h. Neither the 2-methoxy-5-nitrophenyl-beta-alanine nor the 2-methoxy-5-nitrophenol photolysis side product activates, inhibits, or potentiates the response of glycine receptors in rat hippocampal neurons to glycine. Photolysis of 2-methoxy-5-nitrophenyl-beta-alanine by irradiation with a 600-ns laser pulse at 333 nm releases beta-alanine, which then activates glycine receptor-channels on neurons equilibrated with the caged compound, as detected by whole-cell current recording. Compared with the analogous derivative of glycine, in terms of quantum yield, photolysis rate, and stability, this new compound is not only a better candidate for use in chemical kinetic investigations of the glycine receptor, but can also be used in determining the location of glycine receptors in neuronal cells.

Photolabile precursors of glutamate: synthesis, photochemical properties, and activation of glutamate receptors on a microsecond time scale.

Newly synthesized photolabile derivatives of glutamate, caged glutamate, that release free glutamate on a microsecond time scale after a pulse of UV laser light are described. 2-Nitrobenzyl derivatives were attached to the amino or carboxyl groups of glutamate. Substitution with a -CO2- group at the benzylic carbon accelerates the photolysis reaction when compared to -H and -CH3 substituents. gamma-O-(alpha-Carboxy-2-nitrobenzyl)glutamate is stable at neutral pH. In 100 mM phosphate buffer at pH 7.0, the compound is photolyzed at 308 nm with a quantum product yield of 0.14. The half-life of the major component of the photolytic reaction, as judged by the transient absorbance change at 430 nm, is 21 microseconds (approximately 90%); the half-life of a minor component (approximately 10%) is 0.2 ms. The amino-linked derivatives have half-lives in the millisecond region and a 4-fold lower quantum yield. The potential of the newly synthesized compound for use in rapid chemical kinetic investigations of glutamate receptors is demonstrated. (i) The caged glutamate at 1 mM concentration does not desensitize glutamate receptors in rat hippocampal neurons. (ii) Caged glutamate (1 mM) does not inhibit activation of the receptors by 50 microM glutamate. (iii) Photolysis of the compound induces rapid onset of transmembrane currents in rat hippocampal neurons.

Synthesis and photochemistry of photolabile derivatives of gamma-aminobutyric acid for chemical kinetic investigations of the gamma-aminobutyric acid receptor in the millisecond time region.

The gamma-aminobutyric acid (GABA) receptor is an abundant neuronal receptor in the mammalian and invertebrate nervous systems and is associated with an inhibitory chloride ion channel. GABA is the endogenous neurotransmitter for the receptor and can trigger both fast activation and a reversible desensitization of the receptor. A series of photolabile amine-linked o-nitrobenzyl derivatives of GABA were synthesized that photolyze rapidly to release free GABA. The photochemical properties of the GABA precursors were determined; the compounds undergo rapid photolysis, initiated with UV irradiation at 308 nm, and release free GABA on a millisecond time scale. The pH of the photolysis medium affects both the quantum yield and the rate of photolysis. For example, the quantum yield observed for N-(alpha-carboxy-2-nitrobenzyl)-gamma-aminobutyric acid increases from 0.06 at pH 5.0 to 0.1 at pH 10.5, and the half-life for the photolytic reaction decreases from 1.0 to 2.5 ms in the same pH range. Photolysis of the compounds induces rapid onset of transmembrane ion currents in mouse cortical neurons. The potential of the new compounds for use in rapid chemical kinetic investigations of the neuronal GABA receptor is demonstrated.

Photolysis of a protecting group for the carboxyl function of neurotransmitters within 3 microseconds and with product quantum yield of 0.2.

The synthesis of a photosensitive blocking group for the carboxyl function of neurotransmitters, in this case glycine, is reported. The compound, 2-methoxy-5-nitrophenyl glycine ester (caged glycine), is photolyzed by a laser pulse at 308 or 337 nm within 3 microseconds and with a product quantum yield of 0.2. The compound is hydrolyzed in water with a time constant tau of 6.1 min at pH 7.1 and 3 hr at pH 4.0. Mouse cerebral cortical neurons containing glycine receptors were used in biological assays. A cell-flow device, in which solutions of caged glycine at pH 4.0 were mixed with buffer to give a final pH of 7.1, was used to equilibrate the compound with receptors on the cell surface. Neither the caged compound nor the 2-methoxy-5-nitrophenol photolysis product affected the glycine receptors or modified their response to glycine. When cells equilibrated with caged glycine are irradiated by a laser pulse at 337 nm, glycine receptor channels are opened, as detected in whole-cell current recordings. The approach described may be used in the synthesis and characterization of photolabile precursors of neurotransmitters and other compounds that contain carboxyl groups and for kinetic investigations of neurotransmitter receptors in central nervous system cells in the microsecond time domain.

Structural relationships of pancreatic nitrosamine carcinogens.

N.m.r. spectroscopy demonstrates that N-nitroso(2-hydroxypropyl)(2-oxopropyl)amine (HPOP) exists as a mixture of four isomers, A, B, C and D, the equilibrium ratios of which are 57:8:16:19, respectively, at 25 degrees C. Two of these isomers, A and B, are rotomers of the open chain conformer, while the other two, C and D, are rotomers of the ring tautomer of HPOP and are derived from A and B, respectively, via an intramolecular cyclization reaction. A syn orientation of the nitroso and carbonyl groups favors an open chain configuration (isomer A), while an anti orientation favors cyclization of the molecule (isomer D). Two forms of HPOP (I and II) which are mixtures of isomers A and C, and D and B, respectively were separated chromatographically. These two forms interconvert to each other. The first rate order constants for the interconversion reactions were determined to be 4.7 X 10(-3) and 12.8 X 10(-3)/min, respectively. During these reactions isomers A and D interconvert via the intermediate formation of isomer C. This suggests that rotomerization of C and D is thermodynamically more favorable than rotomerization of their open-chain tautomers A and B, and suggests an intramolecular interaction between the carbonyl and nitroso groups. Isomers A and D are formed during the metabolism of N-nitrosobis(2-oxopropyl)amine (BOP) and cis N-nitroso-2,6-dimethylmorpholine (NNDM), respectively, by hamster liver microsomes and NADH or NADPH. The stereo-specificity of reduction of BOP and the hydroxylation of cis NNDM results in the formation of two slowly interconvertible isomers of HPOP. This, in combination with a possible different metabolic fate of the cyclic and open tautomers of this compound, may have a significant impact on the mechanism of activation of pancreatropic nitrosamines which share HPOP as a common metabolite.