Enhanced chemiluminescent assays for acetylcholine

Acetylcholine and choline chemiluminescent assays have limitations when these compounds are detected in small areas of mammalian nervous tissue. Use of 7-dimethyl-aminonaphthalene-1,2-dicarbonic acid hydrazide (7-DMAN), instead of luminol, gives a threefold increase in emitted light in the chemiluminescent assay for acetylcholine based on the coupled choline oxidase-peroxidase reaction. Addition of light enhancers, such as para-iodophenol or D-luciferin, to luminol or 7-DMAN further increased the light emission. Under these conditions the detection limit for acetylcholine was 650 femtomoles. This enhanced chemiluminescent assay should be convenient for the detection of in vivo and in vitro acetylcholine release from mammalian neurons.     

Sensitive detection of acetylcholine based on a novel boronate intramolecular charge transfer fluorescence probe

A highly sensitive and selective fluorescence method for the detection of acetylcholine (ACh) based on enzyme-generated hydrogen peroxide (H₂O₂) and a new boronate intramolecular charge transfer (ICT) fluorescence probe, 4-(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)-N-butyl-1,8-naphthalimide (BN), was developed. This strategy involves the reaction of ACh with acetylcholinesterase (AChE) to produce choline, which is further oxidized by choline oxidase (ChOx) to obtain betaine and H₂O₂. The enzyme-generated H₂O₂ reacts with BN and results in hydrolytic deprotection of BN to generate fluorescent product (4-hydroxyl-N-butyl-1,8-naphthalimide, ON). Two consecutive linear response ranges allow determining ACh in a wide concentration range with a low detection limit of 2.7 nM (signal/noise = 3). Compared with other fluorescent probes based on the mechanism of nonspecific oxidation, this reported boronate probe has the advantage of no interference from other biologically relevant reactive oxygen species (ROS) on the detection of ACh. This study provides a new method for the detection of ACh with high selectivity and sensitivity.     

Enhanced tolerance to light stress of transgenic Arabidopsis plants that express the codA gene for a bacterial choline oxidase

Arabidopsis thaliana was transformed with the codA gene from Arthrobacter globiformis. This gene encodes choline oxidase, an enzyme that converts choline to glycinebetaine. The photosynthetic activity, monitored in terms of chlorophyll fluorescence, of transformed plants was more tolerant to light stress than that of wild-type plants. This enhanced tolerance to light stress was caused by acceleration of the recovery of the photosystem II (PS II) complex from the photo-inactivated state. The transformed plants synthesized glycinebetaine, but no changes were detected in the relative levels of membrane lipids or in the relative levels of fatty acids in the various membrane lipids. Transformation with the codA gene increased levels of H₂O₂, a by-product of the reaction catalyzed by choline oxidase, by only 50% to 100% under stress or non-stress conditions. The activity of ascorbate peroxidase and, to a lesser extent, that of catalase in transformed plants were significantly higher than in the wild-type plants. These observations suggest that H₂O₂ produced by choline oxidase in the transformed plants might have stimulated the expression of H₂O₂ scavenging enzymes, with resultant maintenance of the level of H₂O₂ within a certain limited range. It appears that glycinebetaine produced in vivo, but not changes in membrane lipids or in the level of H₂O₂, protected the PS II complex in transformed plants from damage due to light stress.     

Rearrangement of intramembrane particles as a possible mechanism for the release of acetylcholine

1. A chemiluminescent procedure for measuring acetylcholine (ACh) has recently been described. The procedure is based on the hydrolysis of ACh by acetylcholinesterase and on the oxidation of choline to betaine and H2O2 by choline oxidase. The H2O2 generated reacts with luminol in presence of peroxidase to produce a light emission. This method is sensitive in the pmol/ml range. 2. On isolated synaptosomes from electric organ, it is possible to obtain an estimate of the cytoplasmic ACh compartment by measuring the light emission after a single freezing and thawing cycle. The vesicular pool which resists several freezing and thawing cycles is then estimated by opening the compartment with a detergent. Increasing the intensity of stimulation of synaptosomes with different agents depletes the ACh content down to the vesicular pool. 3. The release of ACh is not associated with any change in the number of synaptic vesicles as seen in cryofractured synaptosomes. The only ultrastructural change detected common to all stimulations was a decreased density of P face intramembrane particles smaller than 11 nm and an increased density of E face 8 to 18 nm particles. The very significant particle changes were more intense for the conditions releasing more ACh. It is suggested that these particles are involved in the release of ACh from the cytoplasm. An attempt to directly correlate the release of ACh with intramembrane particle changes is discussed.     

Targeting prokaryotic choline oxidase into chloroplasts enhance the potential of photosynthetic machinery of plants to withstand oxidative damage

Chloroplasts from plants of transgenic lines expressing prokaryotic choline oxidase gene (the codA_ps gene; GenBank accession number-AY589052) and wild-type of chickpea and Indian mustard were evaluated for their efficacy to withstand photoinhibitory damage, by exposing them to high light intensity (～1200 μmol m^?2 s^?1 photon flux density) at 10 and 25 °C. Western analysis confirmed presence of choline oxidase in chloroplasts of only transgenic lines. The loss in PS II activity in chloroplasts of wild-type exposed to high light intensity was significantly higher than that in chloroplasts of transgenic chickpea as well as Indian mustard. Although, chloroplasts of both wild-type and transgenic chickpea as well as Indian mustard were more sensitive to photoinhibitory damage at 10 than at 25 °C, the damage recorded in chloroplasts harboring choline oxidase was significantly lower than those of wild-type. High light promotes H₂O₂ production in chloroplasts more significantly at low temperature (10 °C) than at 25 °C. We compared low temperature accelerated photoinhibition of chloroplasts with that caused due to exogenously applied H₂O₂. Although exogenous H₂O₂ accelerated high light intensity induced loss in PS II activity of chloroplasts of wild-type, it caused only a little alteration in PS II activity of chloroplasts from transgenic lines of both chickpea and Indian mustard, demonstrating that the chloroplasts harboring choline oxidase are better equipped to resist photoinhibition. We hypothesize that H₂O₂ produced by choline oxidase as a byproduct during synthesis of glycinebetaine is responsible for building stronger antioxidant system in chloroplasts of transgenic lines compared to that of wild-type.     

Light generation with Fenton's reagent its relationship to granulocyte chemiluminescence

A simple chemical system consisting of FeSO₄ and H₂O₂ (Fenton's reagent) was shown to emit light (chemiluminescence). The addition of tryptophan to the reaction markedly enhanced light production. Very little chemiluminescence was observed when H₂O₂ was omitted from the reaction and when ferric, instead of ferrous, ions were used. Hydroxyl radical (OH^.) and singlet oxygen (¹Δ_gO₂) quenchers suppressed chemiluminescence of the FeSO₄ + tryptophan + H₂O₂ system; and, deuterium oxide (²H₂O) enhanced chemiluminescence of both FeSO₄ reactions. These observations suggest that a radical chain reaction involving both OH^. and ¹Δ_gO₂ is responsible for the chemiluminescent reactions. Six iron-containing proteins, some of which are located within granulocytes, all emitted light in the presence of H₂O₂. Since iron and H₂O₂ are present in metabolically stimulated granulocytes, it is likely that chemiluminescent reactions similar to the ones demonstrated in this study account for part of the chemiluminescence of activated granulocytes.     

Disposable, enzymatically modified printed film carbon electrodes for use in the high-performance liquid chromatographic–electrochemical detection of glucose or hydrogen peroxide from immobilized enzyme reactors

Disposable screen-printed, film carbon electrodes (PFCE) were modified with cast-coated Osmium–polyvinylpyrridine-wired horse radish peroxidase gel polymer (Os-gel-HRP) to enable the detection of the reduction at 0 mV of hydrogen peroxide (H₂O₂) derived from a post-column immobilized enzyme reactor (IMER) containing acetylcholinesterase and choline oxidase. In another series of experiments PFCE were initially modified with cast-coated Os-gel-HRP and then treated with glucose oxidase in bovine serum albumin (BSA) and cross-linked with glutaraldehyde to form a bi-layer glucose–Os-gel-HRP PFCE. This bi-layer glucose–Os-gel-HRP PFCE generated a reduction current at 0 mV to H₂O₂ derived from the reaction of glucose oxidase and glucose in solution. These enzyme-modified PFCE were housed in a radial flow cell and coupled with cation-exchange liquid chromatographic methods to temporally separate substrates in solution for the determination of acetylcholine (ACh) and choline (Ch) in the first experimental series, or glucose in the second experimental series. These two disposable enzyme-modified PFCE exhibited linear current vs. substrate relations, were durable, being usable for approximately 40 determinations, and were sufficiently sensitive to be employed in biological sampling. Both assays utilized the same HPLC equipment. The limit of detection for ACh was 16 fmol/10 μl and that for glucose was 12 μmol/7.5 μl. ACh and Ch were measured from a microdialysate from the frontal cortex of a rat. Glucose in human urine was determined using the bi-layer glucose oxidase–Os-gel-HRP PFCE.     

Continuous Determination by a Chemiluminescent Method of Acetylcholine Release and Compartmentation in Torpedo Electric Organ Synaptosomes

Abstract: The detection of acetylcholine (ACh) with a chemiluminescent procedure enables one to follow continuously the release of transmitter from stimulated synaptosomes and to study the compartmentation of ACh in resting and active nerve terminals. A compartment of ACh liberated almost entirely by a single freezing and thawing could be directly measured and compared with a compartment of ACh resistant to several cycles of freezing and thawing but liberated by a detergent (60–70% of the total). It is the compartment liberated by freezing and thawing that is reduced when synaptosomes are stimulated. Up to half the total synaptosomal ACh content is readily releasable provided the calcium entry is maintained, or if a strong releasing agent such as the venom of Glycera convoluta is used. In addition, it is shown that synaptosomes contain only negligible amounts of choline, and that the proportion of the two ACh compartments is not influenced by changing extracellular calcium just before their determination.     

Application to Mammalian Tissues of the Chemiluminescent Method for Detecting Acetylcholine

Abstract: It is now possible to extend to mammalian tissues the chemilumi-nescent acetylcholine assay. Mammalian tissue extracts must be treated with oxidants (which is not necessary for electric organ extracts). The assay can then be performed as previously described (acetylcholinesterase hydrolyses acetylcholine; choline oxidase converts choline to betaine and H₂O₂, which gives off light in the presence of luminol and peroxidase). It is also shown that release experiments can be performed on mammalian tissue slices (mouse caudate nucleus) after the slice is washed in oxygenated saline solutions.     

Chemically shifted singlet oxygen spectrum

The estimated light emission spectrum was determined for a singlet oxygen (¹O₂)-producing system, NaOCl + H₂O₂, alone and in the presence of tryptophan and bovine serum albumin. Tryptophan and bovine serum albumin caused a decrease in the red emission of ¹O₂ and an increase in the amount of shorter wavelength light. This effect was due to chemiluminescence rather than fluorescence. Arachidonic acid caused a similar spectral shift, while guanosine demonstrated a late chemiluminescent reaction of predominantly short wavelength light in the presence of ¹O₂.     

Oxygen-18 and deuterium labeling studies of choline oxidation by spinach and sugar beet

Chenopods synthesize betaine by a two-step oxidation of choline: choline → betaine aldehyde → betaine. The pathway is chloroplastic; the first step has been shown in isolated spinach (Spinacia oleracea L.) chloroplasts to be O₂- and light-dependent, the role of light being to provide reducing power (P Weigel, EA Weretilnyk, AD Hanson 1988 Plant Physiol 86: 54-60). Here, we report use of in vivo¹⁸O- and ²H-labeling in conjunction with fast atom bombardment mass spectrometry to test for two hypothetical choline-oxidizing reactions that would explain the observed requirements for O₂ and reductant: a desaturase or an oxygenase. Simple syntheses for ²H₃-choline, ²H₃, ¹⁸O-choline, and ²H₃, ¹⁸O-betaine are given. A desaturase mechanism was sought by giving choline deuterated at the 2-carbon, or choline unlabeled at this position together with ²H₂O and by analyzing newly synthesized betaine. About 15% of the ²H at C-2 was lost during oxidation of choline to betaine, and about 10% of the betaine made in the presence of 50% ²H₂O was monodeuterated. These small effects are more consistent with chemical exchange than with a desaturase, because 10 to 15% losses of ²H from the C-2 position also occurred if choline was converted to betaine by a purified bacterial choline oxidase. To test for an oxygenase, the incorporation of ¹⁸O from ¹⁸O₂ into newly synthesized betaine was compared with that from ¹⁸O-labeled choline, in light and darkness. Incorporation of ¹⁸O from ¹⁸O-choline was readily detectable and varied from about 15 to 50% of the theoretical maximum value; the ¹⁸O losses were attributable to exchange of the intermediate betaine aldehyde with water. In darkness, incorporation of ¹⁸O from ¹⁸O₂ approached that from ¹⁸O-choline, but in the light was severalfold lower, presumably due to isotopic dilution by photosynthetic ¹⁶O₂. These data indicate that the chloroplast choline-oxidizing enzyme is an oxygenase.     

Role of LytF and AtlS in eDNA Release by Streptococcus gordonii

Extracellular DNA (eDNA) is an important component of the biofilm matrix produced by many bacteria. In general, the release of eDNA is associated with the activity of muralytic enzymes leading to obvious cell lysis. In the Gram-positive oral commensal Streptococcus gordonii, eDNA release is dependent on pyruvate oxidase generated hydrogen peroxide (H₂O₂). Addition of H₂O₂ to cells grown under conditions non-permissive for H₂O₂ production causes eDNA release. Furthermore, eDNA release is maximal under aerobic growth conditions known to induce pyruvate oxidase gene expression and H₂O₂ production. Obvious cell lysis, however, does not occur. Two enzymes have been recently associated with eDNA release in S. gordonii. The autolysin AtlS and the competence regulated murein hydrolase LytF. In the present report, we investigated the role of both proteins in the H₂O₂ dependent eDNA release process. Single and double mutants in the respective genes for LytF and AtlS released less eDNA under normal growth conditions, but the AtlS mutant was still inducible for eDNA release by external H₂O₂. Moreover, we showed that the AtlS mutation interfered with the ability of S. gordonii to produce eDNA release inducing amounts of H₂O₂. Our data support a role of LytF in the H₂O₂ eDNA dependent release of S. gordonii as part of the competence stress pathway responding to oxidative stress.     

Rapid Respiratory Changes Due to Red Light or Acetylcholine during the Early Events of Phytochrome-mediated Photomorphogenesis

Two millimeter long secondary root tips of etiolated mung bean (Phaseolus aureus) plants were given 4 minute consecutive treatments of darkness, red light, far red light, and acetylcholine during darkness. We studied the effects of these treatments on exogenous (H⁺) changes, ATP utilization, O₂ uptake, P₁ levels, and ATPase activity. Red light and acetylcholine increased the level of P₁, O₂ uptake, and exogenous H⁺, but decreased ATP concentrations. Darkness and far red light caused the amount of ATP to increase and decreased the O₂ uptake and P₁ level. O₂ uptake of both excised root tips and isolated mitochondria was promoted by acetylcholine levels of the same order of magnitude that promoted the other photomimetic phenomena. ADP-O ratios indicated that acetylcholine did not cause an appreciable decrease in ATP synthesis. The total ATPase activity remained constant throughout all treatments. Ouabain caused no adhesion to negatively charged glass in the dark, while the inhibitors valinomycin, atractyloside, digitoxin, gramicidin, and oligomycin caused immediate adhesion. All of the inhibitors prevented release from the glass. In red light ouabain increased adhesion, whereas the other inhibitors caused caused immediate and complete adhesion.     

The mechanism of the activity-dependent luminescence of xanthine oxidase.

The weak luminescence that accompanies the aerobic xanthine oxidase reaction is inhibited by superoxide dismutase, by catalase, and by scavengers of hydroxyl radicals. It is also entirely dependent upon the presence of carbonate. It thus appears that the O₂ and H₂O₂ produced during the aerobic action of xanthine oxidase interact to generate OH which, in turn, reacts with carbonate to yield the carbonate radical (CO₃^?). The species that is directly responsible for light emission appears to be produced by a dimerization of carbonate radicals, since the light intensity was a function of the square of the carbonate concentration. The data provide no reason to suppose that the light-emitting species is singlet oxygen.     

Impaired Synthesis of Acetylcholine by Mild Hypoxic Hypoxia or Nitrous Oxide

The effect of mild hypoxic hypoxia on brain metabolism and acetylcholine synthesis was studied in awake, restrained rats. Since many studies of hypoxia are done with animals anesthetized with nitrous oxide (N₂O), the effects of N²O were evaluated. N²O (70%) increased the cerebral cortical blood flow by 33% and the cortical metabolic rate of oxygen by 26%. In addition, the synthesis of acetylcholine in N²O-anesthetized animals, measured with [U-¹⁴C]glucose and [1-²H₂,2-²H₂]choline, decreased by 45 and 53%, respectively. Consequently, mild hypoxia was studied in unanesthetized rats. Control rats breathing 30% O₂ (partial pressure of oxygen, Pao₂= 120 mm Hg) were compared with rats exposed to 15% O₂ (Pao₂= 57 mm Hg) or 10% O₂ (Pao₂= 42 mm Hg). The synthesis of acetylcholine, measured with [U-¹⁴C]glucose, was decreased by 35 and 54% with 15% O₂ and 10% O₂ respectively; acetylcholine synthesis, measured with [1-²H₂,2-²H₂]choline, was decreased by 50 and 68% with 15% O₂ and 10% O₂ respectively. Animals breathing either 15% or 10% O₂ had normal cerebral metabolic rates of oxygen but had increased brain lactates and increased cortical blood flows compared with animals breathing 30% O₂. These results show that even mild hypoxic hypoxia impairs acetylcholine synthesis, which in turn may account for the early symptoms of brain dysfunction associated with hypoxia.     

Possible Effect of Activation of α7-Nicotinic Acetylcholine Receptors in the Mitochondrial Membrane on the Development of Apoptosis

Using flow cytometry and sandwich-immunoenzyme assay, we showed that nicotinic acetylcholine receptors with a subunit α7 (nAChRs α7) expressed in the outer mitochondrial membrane are involved in the control of mitochondria-dependent apoptosis. Pre-incubation of the mitochondria with an nAChRs α7 agonist, choline, decreased dissipation of the membrane potential of these organelles induced by the action of 0.5 mM hydrogen peroxide (H₂O₂) but did not influence the analogous effect of a high Ca²⁺ concentration (90 μM). Agonists of nAChRs α7 (choline, acetylcholine, and PNU 282987), or an inhibitor of voltage-dependent anion channels, DIDS, prevented the release of cytochrome c from the intermembrane mitochondrial space under the action of H₂O₂. In contrast, an antagonist of nAChRs α7, methyllycaconitine, promoted the release of cytochrome c and prevented the effects of agonists. The obtained data confirm the active involvement of nAChRs α7 and voltage-dependent anion channels in the process of formation of mitochondrial pores. In this case, agonists of mitochondrial nAChRs α7 subunits exert an antiapoptotic effect, while antagonists of mitochondrial nAChRs α7 subunits manifest a proapoptotic action.     

Spontaneous Release of Acetylcholine from TorpedoSynaptosomes: Effect of Cetiedil and Its Analogue MR 16728

Abstract: The effects of cetiedil and its analogue MR16728 were examined on spontaneous acetylcholine release measured with a chemiluminescent assay using choline oxidase in a synaptosomal suspension obtained from Torpedo marmorata electric organ. Evoked acetylcholine release is inhibited by cetiedil, whereas this drug enhances spontaneous extracellular Ca²⁺-independent acetylcholine release (up to 340%). This effect was examined as a function of cetiedil concentration and incubation time. On the other hand, the analogue MR16728, which enhances A23187-evoked acetylcholine release, also enhances spontaneous Ca²⁺-independent acetylcholine release. Cetiedil and MR16728 effects on spontaneous acetylcholine release were also examined in the presence of Ca²⁺. Addition of Ca²⁺ enhanced spontaneous acetylcholine release by 75%, and cetiedil and MR16728 stimulation was maintained but with different levels of enhancement. Thus, these results show that the processes responsible for evoked and spontaneous acetylcholine release are sensitive but in different ways to drugs of the cetiedil family.     

Visualization of the parietal mass transfer by using immobilized peroxidase

A new method is developed for direct visualization of the local mass transfer at solid liquid interfaces involving the chemiluminescent oxidation of luminol by H₂O₂ catalyzed by immobilized peroxidase. At low concentration of H₂O₂ (C < 5 × 10⁻⁵ M) this reaction is controlled by diffusion and it is possible to characterize the diffusion convection of H₂O₂ at each point of the tube as a function of the local hydrodynamic properties. These properties are characterized by pulsed Doppler ultrasound velocimetry.

1) The rate of light emission depends on Re^1/3 for the laminar case and decreases when going downstream in accordance with the known theories of diffusion convection along tubes.

2) Downstream to a stenosis, a maximum of light appears which depends on the input Reynolds number in a manner similar to the reattachment point of the flow. This constitutes the first experimental confirmation of calculations on diffusion convection downstream to stenoses.

These first experiments show the capacity of the method to detect the local properties of the parietal mass transfer phenomenon as a function of the geometry of the wall and the hydrodynamic properties of the flow ^(*).     

The action of black widow spider venom on cholinergic mechanisms in synaptosomal preparations of rat brain cortices

The neurochemical activity of black widow spider venom (BWSV) was investigated using a synaptosomal preparation (P₂) of rat cerebral cortices. In a P₂ preparation pre-incubated with [3H]-choline in order to label acetylcholine (ACh), BWSV caused a marked release of radioactive ACh which was calcium independent. The onset of the action of BWSV was very rapid, i.e. in a 20 sec incubation it caused a release of the transmitter. BWSV was also shown to be a potent inhibitor of the high affinity uptake system for choline, producing about 50% inhibition at a concentration of 3.75 μg protein/m1. These findings explain in the observed electrophysiological effects of the venom.     

Binding of a Glycera convoluta neurotoxin to cholinergic nerve terminal plasma membranes

The crude extract of venom glands of the polychaete annelid Glycera convoluta triggers a large Ca2+-dependent acetylcholine release from both frog motor nerve terminals and Torpedo electric organ synaptosomes. This extract was partially purified by Concanavalin A affinity chromatography. The biological activity was correlated in both preparations to a 300,000-dalton band, as shown by gel electrophoresis. This confirmed previous determinations obtained with chromatographic methods. This glycoprotein binds to presynaptic but not postsynaptic plasma membranes isolated from Torpedo electric organ. Pretreatment of intact synaptosomes by pronase abolished both the binding and the venom- induced acetylcholine release without impairing the high K+-induced acetylcholine release. Pretreatment of nerve terminal membranes by Concanavalin A similarly prevented the binding and the biological response. Binding to Torpedo membranes was still observed in the presence of EGTA. An antiserum directed to venom glycoproteins inhibited the neurotoxin so we could directly follow its binding to the presynaptic membrane. Glycera convoluta neurotoxin has to bind to a ectocellularly oriented protein of the presynaptic terminal to induce transmitter release.