Synthesis, photochemistry, and biological activity of a caged photolabile acetylcholine receptor ligand

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.     

A new photolabile precursor of glycine with improved properties: A tool for chemical kinetic investigations of the glycine receptor

The synthesis and characterization of a new photolabile precursor of glycine (caged glycine) is described. The alpha-carboxyl group of glycine is covalently coupled to the alpha-carboxy-2-nitrobenzyl (alphaCNB) protecting group. Photolysis of the caged glycine with UV light produces free glycine. At 308 nm, the compound photolyzes with a quantum yield of 0.38. The absorption spectrum and the pH dependence of a transient absorption produced after laser-flash illumination are typical for aci-nitro intermediates of alphaCNB-protected compounds. The time constant for the major component of the aci-nitro intermediate decay ( approximately 84% of the total aci-nitro absorbance) was determined to be 7 micros at physiological pH. A minor component ( approximately 16%) decays with a rate constant of 170 micros. The compound does not activate or inhibit the alpha(1)-homomeric glycine receptor transiently expressed in HEK293 cells. After photolysis with a 10 ns pulse of 325 nm laser light, the glycine released from the caged compound activates glycine-mediated whole-cell currents in the same cells. The rise of these currents can be measured in a time-resolved fashion and occurs on a millisecond to sub-millisecond time scale. It can be described with a single-exponential function over >85% of the total current. The rate constant of the current rise is about 2 orders of magnitude slower than the rate constant of caged glycine photolysis. Thermal hydrolysis of the alphaCNB-caged glycine takes place with a half-life of 15.6 h at physiological pH. The new caged glycine is the first in a series of photoprotected glycine derivatives that has the required properties for use with chemical kinetic methods for investigation of glycine-activated cell surface receptors. Photolysis is rapid and efficient with respect to the receptor reactions to be studied; hydrolysis in aqueous solution is sufficiently slow, and the compound is biologically inert. It will, therefore, be a useful tool for investigation of the processes leading to channel opening of glycine receptor channels and the effects of mutations of the glycine receptor and of inhibitors on these processes.     

Decarboxylation is a significant reaction pathway for photolabile calcium chelators and related compounds.

Photolysis of amino acids that bear a 2-nitrobenzyl protecting group on the amino nitrogen involves a normal 2-nitrobenzyl-type photocleavage to release the amino acid but also a second mechanistic pathway, that appears to be initiated by single electron transfer from the amino group to the excited state of the nitroaromatic. The end result of this pathway is photodecarboxylation. Quantitative experiments suggest that this latter pathway can contribute between 10 and 80% of the total reaction flux in different compounds. It appears that the aminium radical, the first product of the single electron transfer, can be intercepted by certain amino acids, resulting in a transfer of decarboxylation to this "sacrificial" amino acid. Possible implications for precise details of calcium release from photolabile derivatives of EDTA and EGTA are discussed.     

Photolabile precursors of inositol phosphates. Preparation and properties of 1-(2-nitrophenyl)ethyl esters of myo-inositol 1,4,5-trisphosphate

1-(2-Nitrophenyl)ethyl esters of D-myo-inositol 1,4,5-trisphosphate (InsP3) have been synthesized and shown to have suitable properties for use as photolabile precursors of InsP3. Synthesis was accomplished by treatment of InsP3 with 1-(2-nitrophenyl)diazoethane in a CHCl3/water mixture. This resulted in esterification of each of the three phosphate residues in InsP3, the 1-phosphate being more reactive than the 4- or 5-phosphate. Singly esterified P-1, P-4, and P-5 esters, termed P-1, P-4, and P-5 caged InsP3, were isolated from the reaction mixture by anion-exchange HPLC and characterized by 500-MHz 1H NMR spectroscopy. Each of these caged InsP3 esters exists as a pair of diastereoisomers and was identified by examining the effects of pH and nitrophenyl ring current shielding on the chemical shifts of nonexchangeable inositol protons. 1H NMR spectra of InsP3 were analyzed for comparison. On photolysis the compounds released InsP3 with rate constants of 175 (P-1), 225 (P-4), and 280 s-1 (P-5) as determined by monitoring the aci-nitro decay reaction at pH 7.1, 0.2 M ionic strength, 21 degrees C. Quantum yields determined by steady-state near-UV photolysis were 0.65 +/- 0.08 for each compound. P-4 and P-5 caged InsP3 were the most promising biologically inactive InsP3 precursors since at concentrations up to 50 microM they did not release Ca2+ from smooth muscle sarcoplasmic reticulum (SR) and were not metabolized by vascular smooth muscle InsP3 5-phosphatase or bovine brain InsP3 3-kinase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis and photochemistry of a photolabile precursor of N-methyl-D-aspartate (NMDA) that is photolyzed in the microsecond time region and is suitable for chemical kinetic investigations of the NMDA receptor.

The amino acid L-glutamate is a major neurotransmitter at excitatory synapses within the central nervous system. Neuronal responses to glutamate are mediated by at least three receptor types, one of which is the NMDA subtype, named for its specific ligand N-methyl-D-aspartic acid. Neurotransmitter receptors are transmembrane proteins that can form ion channels upon binding a specific ligand and are involved in many physiological activities of the brain and in some neurological disorders. Elucidating the mechanisms of the formation of transmembrane receptor-channels and of receptor regulation and inhibition is necessary for understanding nervous system function and for designing potential therapeutic agents. This has been hampered by the lack of rapid reaction techniques suitable for investigating protein-mediated reactions on cell surfaces. Recently a laser-pulse photolysis technique was developed to study the chemical reactions of channel-forming receptor proteins in the microsecond-to-millisecond time region. To apply the technique to NMDA1 receptors a photolabile NMDA precursor (beta-DNB NMDA) was synthesized. In this precursor the side chain carboxylate was protected as a photosensitive 2,2'-dinitrobenzhydryl ester. Photolysis with 308 nm laser light generated free NMDA with a time constant of 4.2 +/- 0.1 microseconds at pH 7 and a photolysis quantum yield of 0.18 +/- 0.05. In rat hippocampal neurons the beta-DNB NMDA (250 microM) neither activated endogenously expressed receptors nor potentiated or inhibited the NMDA response. Equilibration of hippocampal neurons in the whole-cell current recording mode with 250 microM caged precursor followed by a pulse of 333 nm laser light resulted in a rapid current rise with a rate constant of 100 s-1 due to opening of NMDA-activated receptor-channels. The caged NMDA precursor described here now makes it possible to investigate the mechanism of NMDA receptors in the micro- to millisecond time region.     

A protecting group for carboxylic acids that can be photolyzed by visible light

We report on a photolabile protecting (caging) group that is new for carboxylic acids. Unlike previously used caging groups for carboxylic acids, it can be photolyzed rapidly and efficiently in the visible wavelength region. The caging group 7-N,N-diethyl aminocoumarin (DECM) was used to cage the gamma-carboxyl group of glutamic acid, which is also a neurotransmitter. The caged compound has a major absorption band with a maximum at 390 nm (epsilon(390) = 13651 M(-)(1) cm(-)(1)). Experiments are performed at 400 nm (epsilon(400) = 12232 M(-)(1) cm(-)(1)) and longer wavelengths. DECM-caged glutamate is water soluble and stable at pH 7.4 and 22 degrees C. It photolyzes rapidly in aqueous solution to release glutamic acid within 3 micros with a quantum yield of 0.11 +/- 0.008 in the visible region. In whole-cell current-recording experiments, using HEK-293 cells expressing glutamate receptors and visible light for photolysis, DECM-caged glutamate and its photolytic byproducts were found to be biologically inert. Neurotransmitter receptors that are activated by various carboxyl-group-containing compounds play a central role in signal transmission between approximately 10(12) neurons of the nervous system. Caged neurotransmitters have become an essential tool in transient kinetic investigations of the mechanism of action of neurotransmitter receptors. Previously uncaging the compounds suitable for transient kinetic investigations required ultraviolet light and expensive lasers, and, therefore, special precautions. The availability of caged neurotransmitters suitable for transient kinetic investigations that can be photolyzed by visible light allows the use of simple-to-use, readily available inexpensive light sources, thereby opening up this important field to an increasing number of investigators.     

Coumarin-caged glycine that can be photolyzed within 3 microseconds by visible light

The synthesis and characterization of a new photolabile precursor of glycine (coumarin-caged glycine) are reported. The new compound is suitable for rapid chemical kinetic investigations of the membrane-bound neurotransmitter receptor activated by glycine. Unlike previously used caging groups for glycine, this precursor can be photolyzed rapidly and efficiently in the visible wavelength region. This allows the use of a relatively inexpensive light source. The alpha-carboxyl group of glycine was covalently coupled to the 7-(diethylamino)coumarin (DECM) caging group. The caged compound has a major absorption band with a maximum at 390 nm (epsilon390 = 13,900 M-1 cm-1). Photolysis was performed at wavelengths of >or=400 nm (epsilon400 = 12,400 M-1 cm-1). Under physiological conditions, DECM-caged glycine is water soluble and stable. In the visible wavelength region, it photolyzes rapidly to release glycine with a half-life of approximately 2.5 micrometers and a quantum yield of 0.12 +/- 0.01. The experimental results demonstrated that neither DECM-caged glycine nor its byproduct inhibits or activates human alpha1 glycine receptors expressed on the surface of HEK 293 cells.     

Studies of decarboxylation in photolysis of alpha-carboxy-2-nitrobenzyl (CNB) caged compounds

Photolysis of alpha-carboxy-2-nitrobenzyl (CNB) caged compounds, studied here by time-resolved IR and UV spectroscopy, involves at least two pathways. In one, a conventional 2-nitrobenzyl type rearrangement takes place to release the photoprotected species via rapid decay of an aci-nitro intermediate. The alpha-carboxylate moiety of the CNB group is retained and the final by-product from this pathway is 2-nitrosophenylglyoxylate. Direct measurements of product formation confirmed that release via this pathway is faster for CNB-caged compounds than for related caged compounds without an alpha-carboxylate substituent and a rationale for the faster release rate is proposed. In a second pathway, photodecarboxylation of the starting material occurs: this pathway leads only to a slow, minor release of the photoprotected species. The extent to which the latter pathway contributes is affected by the nature of buffer salts in the irradiated solution. It was more prominent in an amine-based buffer (MOPS) than in phosphate buffer.     

Proton concentration jumps and generation of transmembrane pH-gradients by photolysis of 4-formyl-6-methoxy-3-nitrophenoxyacetic acid

Proton concentration gradients across membranes are important for many biological energy transducing processes. The kinetics of proton dependent processes can be studied by pH-jump methods in which protons are photochemically released. In the following we describe the synthesis and the properties of photolabile 4-formyl-6-methoxy-3-nitrophenoxyacetic acid, a 'caged proton'. The synthesis is based on vanillin, which is alkylated with chloroacetic acid to give a carboxylic acid (pK = 2.72). In a second step a nitro group ortho to the formyl group is introduced. Photochemical proton release occurs by a reaction mechanism analogous to the well known photochemical formation of 2-nitrosobenzoic acid from 2-nitrobenzaldehyde. The pK values of the photoproduct are 0.75 and 2.76, respectively, thus allowing the use of the compound in a wide pH-range. The quantum yield is 0.18, lower than in the case of the 2-nitrobenzaldehyde/2-nitrosobenzoic acid system (phi = 0.5). The release of the proton in a flash photolysis experiment occurs within less than 1 microseconds. The spectrum of photolabile compound has absorption maxima at 263 nm and 345 nm, respectively. Its permeability across a lipid bilayer membrane is very low (permeability coefficient Pd approximately equal to 10(-9) cm.s-1 at pH 8) so that transmembrane proton concentration gradients can be generated.     

Rate of release of Ca2+ following laser photolysis of the DM-nitrophen-Ca2+ complex.

The determination of the rate of release of Ca2+ by pulsed photolysis of the photolabile chelator DM-nitrophen is important for its use in time-resolved physiological studies: the rate of substrate or effector release should be faster than the processes they initiate. Flash photolysis of DM-nitrophen using a 50-ns pulse from a frequency-doubled ruby laser (with emission at 347 nm having energy of ca. 10-20 mJ) yields short-lived photochromic or aci-nitro intermediates. At pH 6.9, double-exponential decay of a photochromic intermediate was observed for DM-nitrophen itself and its Ca2+ complex (tau 1/2 values of 24 and 570 microseconds, and 32 and 220 microseconds respectively), while only monoexponential decay of the DM-nitrophen-Mg2+ complex was detected (tau 1/2 = 31 microseconds). Only the photochemistry of DM-nitrophen-Ca2+ was found to be pH sensitive (monoexponential decay, tau 1/2 approximately 115 microseconds at pH 7.9 and 8.9). Use of the Ca(2+)-sensitive metallochromic dye antipyrylazo III in conjunction with pulsed photolysis of DM-nitrophen-Ca2+ enabled an upper limit of the half-time of release of Ca2+ to be established of ca. 180 microseconds (the rate of association of Ca2+ with the dye was probably rate determining). The rate of Ca2+ photorelease may, however, be faster than this. Thus, the DM-nitrophen-Ca2+ complex releases Ca2+ on photolysis sufficiently rapidly for the study of many Ca(2+)-dependent physiological processes with improved kinetic resolution over conventional mixing methods.     

Rapid chemical reaction techniques developed for use in investigations of membrane-bound proteins (neurotransmitter receptors)

New techniques for investigating chemical reactions on cell surfaces in the microsecond-to-millisecond time region are described. Reactions mediated by membrane-bound neurotransmitter receptors that control signal transmission between 10¹² cells of the nervous system are taken as an example. Cells with receptors on their plasma membrane are equilibrated with photolabile, biologically inactive precursors of the neurotransmitters. Photolysis of these compounds releases free neurotransmitter that interacts with the receptors, leading to the transient opening of transmembrane receptor-formed channels that are permeant to small inorganic ions. The current thus induced can be measured. The technique can be used to measure the elementary steps of the receptor-mediated reactions. To illustrate the approach it was shown that an understanding of the mechanism of inhibition of the nicotinic acetylcholine receptor by the drug cocaine was obtained and led to the first proof that compounds exist that alleviate the inhibition.     

Flash photolytic release of alcohols from photolabile carbamates or carbonates is rate-limited by decarboxylation of the photoproduct.

Flash photolysis of a 7-nitroindolinyl carbamate derivative in neutral aqueous solution rapidly generated a monoalkyl carbonate salt. The rate constant for subsequent decarboxylation of this salt [mono(2-phosphoryloxyethyl) carbonate], determined by rapid scan IR difference spectroscopy, was 0.4 s(-1) at pH 7.0, 20 degrees C. This rate reflects release of the product alcohol upon photolysis of the parent compound. In general, alcohols protected as photolabile carbamate (or carbonate) derivatives will therefore be released too slowly for studies of the kinetics of millisecond time scale biological processes.     

Photolabile protecting groups for an acetylcholine receptor ligand. Synthesis and photochemistry of a new class of o-nitrobenzyl derivatives and their effects on receptor function

Two compounds have been synthesized that feature a photosensitive o-nitrobenzyl moiety attached directly to the carbamate nitrogen of carbamoylcholine. The well-characterized acetylcholine analogue, carbamoylcholine, was released from these derivatives in response to laser light pulses at wavelengths between 300 and 355 nm. Photolysis products were isolated by high-performance liquid chromatography and identified by chemical and spectroscopic analysis. The yield of carbamoylcholine molecules per photon absorbed was 0.25. A short-lived photochromic intermediate in the photolysis reaction was detected by laser flash photolysis. A single laser flash induced an instantaneous increase in absorbance at 406 nm, followed by a first-order decay to products, with a half-time of 0.07 ms for one of the compounds [N-[1-(2-nitrophenyl)ethyl]carbamoylcholine iodide] in aqueous buffers at pH 7 and 23 degrees C. Decay rates and quantum yields depended on the nature of the substituent on the protecting group. Evidence is presented in support of the conclusion that the transient species is an aci-nitro intermediate that decays directly to carbamoylcholine and therefore determines its rate of release. The photosensitive carbamoylcholine derivatives activated the nicotinic acetylcholine receptor only after photolysis, as determined by 86Rb+ flux measurements with membrane vesicles prepared from Torpedo californica and Electrophorus electricus. Before photolysis, the compounds interacted weakly with the acetylcholine-binding sites as shown by competitive inhibition of acetylcholine-stimulated flux at high concentrations. The compounds did not induce receptor desensitization at a significant rate. The new compounds afford several major advantages over other photoactivatable acetylcholine analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

How fast does an acetylcholine receptor channel open? Laser-pulse photolysis of an inactive precursor of carbamoylcholine in the microsecond time region with BC3H1 cells.

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)     

Subcellular distribution of enzymes of transmethylation and transsulphuration in rat brain.

—Certain of the sulphur containing amino acids have been associated with synaptic transmission in the central nervous system. The enzymes involved in the synthesis of these putative neurotransmitter or modulator compounds have a different subcellular distribution in rat brain from those enzymes that catalyse the synthesis of other compounds in this pathway. Methionine adenosyltransferase and 5-methyltetrahydrofolate-homocysteine methyltransferase catalyse reactions that maintain the methylation functions of the pathway and are found in soluble fractions. Cystathionine β-synthase, cystathionase, cysteine dioxygenase and cysteine sulphinic acid decarboxylase catalyse the synthesis of those sulphur-containing amino acids implicated in neurotransmitter functions and these enzymes have both paniculate and soluble components. Serine hydroxymethyltransferase, which also has a particulate fraction in brain, is responsible for the synthesis of the neurotransmitter glycine, in addition to its role in the methionine-related metabolism of folate.     

Depolarization-Induced Release of Amino Acids From the Vestibular Nuclear Complex

There is evidence from immunohistochemistry, quantitative microchemistry, and pharmacology for several amino acids as neurotransmitters in the vestibular nuclear complex (VNC), including glutamate, γ-aminobutyrate (GABA), and glycine. However, evidence from measurements of release has been limited. The purpose of this study was to measure depolarization-stimulated calcium-dependent release of amino acids from the VNC in brain slices. Coronal slices containing predominantly the VNC were prepared from rats and perfused with artificial cerebrospinal fluid (ACSF) in an interface chamber. Fluid was collected from the chamber just downstream from the VNC using a microsiphon. Depolarization was induced by 50 mM potassium in either control calcium and magnesium concentrations or reduced calcium and elevated magnesium. Amino acid concentrations in effluent fluid were measured by high performance liquid chromatography. Glutamate release increased fivefold during depolarization in control calcium concentration and twofold in low calcium/high magnesium. These same ratios were 6 and 1.5 for GABA, 2 and 1.3 for glycine, and 2 and 1.5 for aspartate. Differences between release in control and low calcium/high magnesium ACSF were statistically significant for glutamate, GABA, and glycine. Glutamine release decreased during and after depolarization, and taurine release slowly increased. No evidence for calcium-dependent release was found for serine, glutamine, alanine, threonine, arginine, taurine, or tyrosine. Our results support glutamate and GABA as major neurotransmitters in the VNC. They also support glycine as a neurotransmitter and some function for taurine.     

3'-Arylazido-8-azido ATP--a cross-linking photoaffinity label for ATP binding proteins

The synthesis of 3′-O-{3-[N-(4-azido-2-nitrophenyl) amino] propionyl} 8-azido-adenosine 5′-triphosphate—a 3′-arylazido-8-azido ATP—is described. The ATP derivative is characterized by thin layer chromatography, infrared spectroscopy, and optical spectroscopy. Its photolysis upon irradiation with uv light and its stability in dependence on pH are tested. Its two photolabile azido groups allow the use of this ATP analog as a photoaffinity label for cross-linking the subunits of ATP binding proteins.     

Laser photolysis of caged calcium: rates of calcium release by nitrophenyl-EGTA and DM-nitrophen.

Nitrophenyl-EGTA and DM-nitrophen are Ca2+ cages that release Ca2+ when cleaved upon illumination with near-ultraviolet light. Laser photolysis of nitrophenyl-EGTA produced transient intermediates that decayed biexponentially with rates of 500,000 s-1 and 100,000 s-1 in the presence of saturating Ca2+ and 290,000 s-1 and 68,000 s-1 in the absence of Ca2+ at pH 7.2 and 25 degrees C. Laser photolysis of nitrophenyl-EGTA in the presence of Ca2+ and the Ca2+ indicator Ca-orange-5N produced a monotonic increase in the indicator fluorescence, which had a rate of 68,000 s-1 at pH 7.2 and 25 degrees C. Irradiation of DM-nitrophen produced similar results with somewhat slower kinetics. The transient intermediates decayed with rates of 80,000 s-1 and 11,000 s-1 in the presence of Ca2+ and 59,000 s-1 and 3,600 s-1 in the absence of Ca2+ at pH 7.2 and 25 degrees C. The rate of increase in Ca(2+)-indicator fluorescence produced upon photolysis of the DM-nitrophen: Ca2+ complex was 38,000 s-1 at pH 7.2 and 25 degrees C. In contrast, pulses in Ca2+ concentration were generated when the chelator concentrations were more than the total Ca2+ concentration. Photoreleased Ca2+ concentration stabilized under these circumstances to a steady state within 1-2 ms.     

Excitatory signaling in bacterial probed by caged chemoeffectors.

Chemotactic excitation responses to caged ligand photorelease of rapidly swimming bacteria that reverse (Vibrio alginolyticus) or tumble (Escherichia coli and Salmonella typhimurium) have been measured by computer. Mutants were used to assess the effects of abnormal motility behavior upon signal processing times and test feasibility of kinetic analyses of the signaling pathway in intact bacteria. N-1-(2-Nitrophenyl)ethoxycarbonyl-L-serine and 2-hydroxyphenyl 1-(2-nitrophenyl) ethyl phosphate were synthesized. These compounds are a 'caged' serine and a 'caged' proton and on flash photolysis release serine and protons and attractant and repellent ligands, respectively, for Tsr, the serine receptor. The product quantum yield for serine was 0.65 (+/- 0.05) and the rate of serine release was proportional to [H+] near-neutrality with a rate constant of 17 s-1 at pH 7.0 and 21 degrees C. The product quantum yield for protons was calculated to be 0.095 on 308-nm irradiation but 0.29 (+/- 0.02) on 300-350-nm irradiation, with proton release occurring at > 10(5) s-1. The pH jumps produced were estimated using pH indicators, the pH-dependent decay of the chromophoric aci-nitro intermediate and bioassays. Receptor deletion mutants did not respond to photorelease of the caged ligands. Population responses occurred without measurable latency. Response times increased with decreased stimulus strength. Physiological or genetic perturbation of motor rotation bias leading to increased tumbling reduced response sensitivity but did not affect response times. Exceptions were found. A CheR-CheB mutant strain had normal motility, but reduced response. A CheZ mutant had tumbly motility, reduced sensitivity, and increased response time to attractant, but a normal repellent response. These observations are consistent with current ideas that motor interactions with a single parameter, namely phosphorylated CheY protein, dictate motor response to both attractant and repellent stimuli. Inverse motility motor mutants with extreme rotation bias exhibited the greatest reduction in response sensitivity but, nevertheless, had normal attractant response times. This implies that control of CheY phosphate concentration rather than motor reactions limits responses to attractants.     

D-Serine as a putative glial neurotransmitter

Abundant recent evidence favors a neurotransmitter/neuromodulator role for D-serine. D-serine is synthesized from L-serine by serine racemase in astrocytic glia that ensheath synapses, especially in regions of the brain that are enriched in NMDA-glutamate receptors. D-serine is more potent than glycine at activating the 'glycine' site of these receptors. Moreover, selective degradation of D-serine but not glycine by D-amino acid oxidase markedly reduces NMDA neurotransmission. D-serine appears to be released physiologically in response to activation by glutamate of AMPA-glutamate receptors on D-serine-containing glia. This causes glutamate-receptor-interacting protein, which binds serine racemase, to stimulate enzyme activity and D-serine release. Thus, glutamate triggers the release of D-serine so that the two amino acids can act together on postsynaptic NMDA receptors. D-serine also plays a role in neural development, being released from Bergmann glia to chemokinetically enhance the migration of granule cell cerebellar neurons from the external to the internal granular layer.