A biologically inert photolabile precursor of carbamoylcholine has been synthesized; it is photolyzed to carbamoylcholine, a well-characterized acetylcholine analogue, with a half-time of 40 microseconds at pH 7.0 and a quantum yield of 0.8. The compound, N-(alpha-carboxy-2-nitrobenzyl)carbamoylcholine, was synthesized from (2-nitrophenyl)glycine. The photolysis rates (of five compounds) and the biological activity (of two compounds) were determined, and both properties were found to depend on the nature of the substituents on the photolabile protecting group. Laser pulse photolysis at wavelengths between 308 and 355 nm was used to investigate the wavelength dependence, quantum yield, and rate of the photolysis reaction. Photolysis products were isolated by high-performance liquid chromatography and identified by chemical and spectroscopic analysis and by their ability to activate the nicotinic acetylcholine receptor. BC3H1 muscle cells containing those receptors and a cell-flow method were used in the biological assays. The approach described may be useful in the preparation and characterization of other photolabile precursors of neurotransmitters that contain amino groups. The importance of these rapidly photolyzed, inert precursors of neurotransmitters is in chemical kinetic investigations of the reactions involving diverse neuronal receptors; such studies have been hampered because the available techniques have an insufficient time resolution.
The integrated function of the nervous system depends on specific and rapid transmission of signals between its constituent cells. The nicotinic acetylcholine receptor is the best known of a group of membrane-bound proteins responsible for such transmission; for this process to occur, a specific neurotransmitter, in this case acetylcholine, must bind to the receptor, which then forms transmembrane channels through which cations pass. The resulting change in transmembrane voltage determines whether or not a signal is transmitted. The question of how fast this process takes place in any neurotransmitter receptor has remained one of the interesting and most challenging in the field. To answer it, many attempts have been made to evaluate the rate constant for the opening of the acetylcholine receptor channel, but in almost all these studies the rate was measured after the receptor-mediated reaction, which involves the open channel and many intermediate states, had reached a quasi equilibrium. This resulted in a plethora of reported values for the rate constant that differ by a factor of up to 50-fold, even when the measurements were made with the same type of cell. The new approach described here involves the use of single cells of a mammalian cell line (BC3H1), containing muscle-type acetylcholine receptors, and the rapid introduction of neurotransmitter to the cell surface. The rapid delivery was achieved by converting a previously synthesized photolabile precursor of carbamoylcholine to carbamoylcholine, a stable amino-group-containing analogue of acetylcholine, with a single laser pulse and an observed photolysis rate of 7300 s-1.(ABSTRACT TRUNCATED AT 250 WORDS)
Three photolabile precursors of glycine containing a photosensitive 2-nitrobenzyl moiety attached to the amino group have been synthesized. When exposed to ultraviolet radiation between 308 and 350 nm, the compounds photolyze to release glycine, an important inhibitory neurotransmitter in the central nervous system. The identification of glycine as a photolysis product was determined by two different methods: separation of the photolyzed sample by thin-layer chromatography followed by a reaction with ninhydrin, and recognition of derivatized glycine using the Waters pico-tag method in conjunction with high-performance liquid chromatography. The photolysis of these compounds at 22 degrees C has been investigated, and the rate of decay of a transient intermediate in the reaction, which is assumed to reflect product release, has been measured. For N-(alpha-carboxy-2-nitrobenzyl)glycine this decay rate was found to be 940 s-1 at pH 6.8 and 600 s-1 at pH 7.5. Additionally, this compound was found to exhibit biological activity upon photolysis; cultured mouse spinal cord cells containing neuronal glycine receptors were used to detect the glycine liberation. The approach adopted here is useful in demonstrating the utility of photolabile precursors of neurotransmitters that have the protecting group linked to the neurotransmitter through the amino group. The rapid photolysis of such compounds to release free neurotransmitter is valuable in gaining access to chemical kinetic studies of neurotransmitter receptors. Previously, such studies have been limited because the available methods for neurotransmitter delivery did not give a sufficiently high time resolution.
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