Specific effects of alpha-D,L-aminoadipic acid on synaptic transmission in frog spinal cord

Electrophysiological properties of axons in mice lacking neurofilament subunit genes: disparity between conduction velocity and axon diameter in absence of NF-H

Neurofilament proteins (NFs) are made by co-polymerization of three intermediate filament proteins, NF-L, NF-M and NF-H and constitute the most abundant cytoskeletal element in large myelinated axons. NFs have a well-established role as intrinsic determinants of axon caliber with all the functional implications, but the role of each individual NF subunit is much less clear. The aim of our study was to examine functional properties of large myelinated axons with altered morphology from mice bearing a targeted disruption of each NF genes (NF-L -/-, NF-M-/- and NF-H -/- mice). Membrane properties, action potentials and single axon refractory period were measured in isolated sciatic nerves in vitro, using intra-axonal microelectrode recording in conjunction with current-clamp technique. Some results were obtained from whole nerves by sucrose-gap recording. The NF-knockout mice showed several deficits in physiological properties of low-threshold fibers. In keeping with smaller axon diameter, the conduction velocity was significantly decreased in NF-L -/- and NF-M -/- transgenic animals (control, 39.9+/-1.8 m/s, NF-M -/-; 23.5+/-1. 4 m/s, and NF-L-/-; 12.0+/-0.7 m/s, mean+/-S.E.M.; intra-axonal recording; similar ratios obtained by sucrose-gap recording; 22-26 degrees C). However, in spite of their preserved caliber, large myelinated axons in NF-H -/- mice also showed a significant decrease in conduction velocity (22.8+/-1.0 m/s, mean+/-S.E.M.). Although action potential amplitudes, duration and shape did not differ between control axons and transgenic animals, the refractory period was prolonged in NF-H -/- and NF-M -/- animals. Intracellular injections of 200 ms depolarizing and hyperpolarizing currents revealed outward and inward rectification in all animal groups. In comparison to control animals, NF-H -/- mice expressed a significant decrease in outward rectification. Potassium channel blockers (4AP and TEA) and cesium ions were able to block outward and inward rectification in all myelinated axons in qualitatively the same manner. These results suggest that NF-H may have a specific role in modulating ion channel functions in large myelinated fibers.

Excitatory amino acid receptors involved in primary afferent-evoked polysynaptic EPSPs of substantia gelatinosa neurons in the adult rat spinal cord slice

Intracellular recordings were made from substantia gelatinosa (SG) neurons in spinal cord slices to determine a subclass of excitatory amino acid receptors involved in polysynaptic excitatory postsynaptic potentials (EPSPs). In the majority of neurons, polysynaptic EPSPs evoked by A delta fiber were not affected by 2-amino-5-phosphonovaleric acid (APV), while all EPSPs including monosynaptic EPSPs were depressed by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). All spontaneous EPSPs were blocked by CNQX, while spontaneous EPSPs in a few SG neurons were attenuated by APV. These observations suggest that polysynaptic EPSPs evoked through A delta fibers are predominantly mediated by activation of the non-N-methyl-D-aspartate (non-NMDA) receptor subclass.

Dorsal root potentials in the isolated frog spinal cord: amino acid neurotransmitters and magnesium ions

Sucrose gap techniques recorded dorsal root potentials evoked by supramaximal dorsal root stimulation in in vitro, hemisected frog spinal cords. In 0 mM Mg2+ large (mean 13.0 mV), long lasting (mean 8.1 s) dorsal root potentials were recorded which consisted of two components: (1) an early component sensitive to picrotoxin, bicuculline, and low [Cl-]o and presumably produced by activation of GABAA receptors; and (2) a long-duration second component enhanced and lengthened by picrotoxin, bicuculline and low [Cl-]o and thought to result from increased interneuron discharges resulting from depression of GABA-mediated pre- and postsynaptic inhibition. Both the early and late components were reduced by over 90% in amplitude and duration by 20 mM Mg2+ or by kynurenate and bicuculline. The early component of the dorsal root potential may depend mainly upon activation of non-N-methyl-D-aspartate receptors. Thus, the N-methyl-D-aspartate antagonist D-(-)-2-amino-5- phosphonovalerate caused only a modest reduction in the amplitude of the early dorsal root potential component while the non N-methyl-D-aspartate antagonist 6-cyano-7-nitroquinoxaline-2,3-dione caused a much more substantial reduction. Exposure of the spinal cord to a "physiological" concentration of Mg2+ (1.0 mM) greatly reduced the duration and somewhat reduced the amplitude of the dorsal root potential. The reduction of dorsal root potentials by 1.0 mM Mg2+ appears to be caused by both pre- and postsynaptic factors.(ABSTRACT TRUNCATED AT 250 WORDS)

NMDA antagonists and potentiation of NMDA-induced motoneuron depolarizations in the isolated frog spinal cord

The action of N-methyl-D-aspartate (NMDA) antagonists on motoneurons was studied in the isolated, hemisected frog spinal cord using sucrose gap techniques. NMDA-evoked motoneuron depolarizations were depressed by application of APV, APH, kynurenate, Mg2+ ions, ketamine, and MK-801. Upon returning to normal Ringer's solution after exposure to all antagonists (except MK-801). NMDA responses were significantly potentiated. Kainate- and quisqualate-induced depolarizations were unchanged. The facilitation appeared to result, at least in part, from a direct action on motoneuron membranes since it persisted in the presence of tetrodotoxin which eliminated interneuronal firing. However, indirect actions involving interneurons also contributed to the potentiation because NMDA-evoked changes in K+ release were increased following exposure to NMDA antagonists and return to normal medium. Reduction of temperature (7 degrees C) which should reduce amino acid uptake did not affect results with APV. In addition, desensitization of NMDA responses was not altered by application of APV. The results indicate that NMDA antagonists have complex and long-lasting effects on the function of the NMDA receptor complex.

Further evidence in support of taurine as a mediator of synaptic transmission in the frog spinal cord

It has been reported that 6-aminomethyl-3-methyl-4H,1,2,4-benzothiadiazine-1, 1-dioxide (AMBD, TAG) is a specific blocker of taurine and beta-alanine responses in the central nervous system. We have re-examined the effect of AMBD on amino acid and synaptically evoked responses recorded from isolated hemisected frog spinal cords by means of the sucrose gap technique. When indirect responses were blocked by adding tetrodotoxin (0.2 microM) or manganese chloride (2 mM) to the normal Ringer solution, AMBD (0.01-0.5 mM) selectively antagonized taurine, beta-alanine, hypotaurine and kojic amine evoked depolarizations of primary afferents at their intramedullary part (dorsal root terminals, DRT) and on dorsal root ganglia (DRG), without significantly affecting responses to glutamate (on DRT), glycine (on DRT) or GABA (on DRT and DRG). Depolarizing responses to taurine and beta-alanine (1 mM) were depressed by up to 50% with 0.1 mM AMBD and often completely antagonized with 0.25 mM AMBD. In normal Ringer solution, AMBD selectively antagonized the dorsal root potential evoked by ventral root stimulation (VR-DRP, threshold at 0.02 mM AMBD, 90% block with 0.25 mM); other synaptic potentials increased in duration and/or amplitude, demonstrating a strong convulsant effect of AMBD. Thus, the depolarizing responses of taurine, beta-alanine and hypotaurine on primary afferents are pharmacologically indistinguishable from the VR-DRP. These results are in agreement with the proposal that taurine or a taurine-like substance (possibly beta-alanine or hypotaurine) is the mediator of VR-DRP in amphibian spinal cord.

Primary afferent depolarization in the rat spinal cord is mediated by pathways utilising NMDA and non-NMDA receptors

In the present experiments the dorsal root-evoked dorsal root potential (DR-DRP) has been measured in vitro from a mature rat sacrococcygeal preparation. The DR-DRP is an index of presynaptic inhibition since it represents the depolarization of primary afferent terminals by gamma-aminobutyric acid (GABA) released synaptically from interneurones. The present study shows that the synaptic excitation of the GABAergic interneurons contains a large component resistant to the selective N-methyl-D-aspartate (NMDA) receptor antagonists 2-amino-5-phosphonopentanoate (AP5) (100 microM) and 3((+)-2-carboxypiperazin-4-yl)propyl-1-phosphonate (CPP) 20-100 microM. This non-NMDA receptor mediated component reflected in the DR-DRP was depressed markedly by the non-selective excitatory amino acid receptor antagonists kynurenate (1-2 mM) and 6-cyano-2,3-dihydroxy-7-nitro-quinoxaline (CNQX) (10-20 microM). Because previous reports show non-cholinergic activation of Renshaw cells to be blocked by NMDA receptor antagonists the present observations suggest that pre- and postsynaptic inhibition in the spinal cord are mediated by different types of excitatory amino acid receptor.

Differential sensitivity of dorsal and ventral root activity to magnesium and 2-amino-5-phosphonovalerate (APV) in an isolated mammalian spinal cord preparation

Spontaneous activity emerging from the isolated hamster spinal cord simultaneously along the ventral and dorsal lumbar roots was shown by inter-spike interval analysis to have different firing patterns. Ventral root firing was reduced in solutions containing 1 mM magnesium or sub-micromolar concentrations of 2-amino-5-phosphonovalerate (APV), whereas the activity in the dorsal roots was unchanged. Differences in sensitivity to magnesium and APV were also shown on the evoked ventral and dorsal root reflexes, with the dorsal root reflex being unaffected, and the ventral root reflex exhibiting a long latency component that was sensitive to magnesium and APV. These results indicate that NMDA receptors are involved in the generation of part of the ventral root responses in the spinal cord, but not in the generation of the dorsal root reflex and spontaneous dorsal root activity.

After-hyperpolarizations produced in frog motoneurons by excitatory amino acid analogues

After-hyperpolarizations (AHPs) produced in frog motoneurons by applications of the excitatory amino acid analogues quisqualate (QUIS), N-methyl-D-aspartate (NMDA), and kainate (KA) were studied in the isolated hemisected frog spinal cord using sucrose gap techniques. AHPs were present following 98% of QUIS-induced depolarizations, but were seen in only 35% and 15% of NMDA- and KA-evoked responses respectively. AHPs produced by QUIS are produced both by direct effects of QUIS on motoneuron membranes and by indirect effects mediated through a synaptic process involving interneurons. Thus, application of Mg2+, Mn2+, or tetrodotoxin (TTX) in concentrations sufficient to block synaptic transmission and interneuronal firing, reduced, but did not abolish the AHPs produced by QUIS. In contrast, NMDA- and KA-AHPs appear to be entirely mediated by indirect means as block of synaptic transmission and interneuronal firing eliminated AHPs produced by these substances. Exposure of the cord to Mn2+ after addition of TTX did not affect the size of QUIS-AHPs. In the presence of TTX, QUIS-AHPs were reduced or completely blocked by addition of dinitrophenol (DNP) and sodium cyanide, by dihydro-ouabain, by removal of K+ from the superfusate, by cooling, and by replacement of 50% of the external Na+ with Li+. The results suggest that the QUIS-AHPs are largely the result of the direct effect of the excitatory amino acid agonist on motoneuron membranes and is caused by activation of an electrogenic Na+ pump. AHPs following depolarizations evoked by NMDA and KA are presumably the result of indirect actions of these latter analogues on interneurons.

Descending and segmental spinal pathways differently regulate contractions of antagonistic muscles of frogs in vitro

A comparison of fibres descending through the ventral column and segmental afferent fibres was carried out using an isolated frog spinal cord-nerve-muscle preparation with a pair of antagonistic muscles. The m. tibialis anterior (TIB) was contracted with stimulation of the ventral column much stronger than with that of the dorsal root (DR). Contraction of the m. gastrocnemius (GAS) was selectively induced with DR stimulation. These results suggest that the descending fibres and segmental afferent fibres preferentially regulate contractions of the flexor (the TIB) and the extensor (the GAS), respectively. Effects of alpha-aminoadipate, methysergide and LSD were also examined.

The effect of D-alpha-aminoadipate on excitatory amino acid responses recorded intracellularly from motoneurones of the frog spinal cord

The excitatory responses to amino acids were recorded intracellularly from motoneurones in the isolated frog spinal cord and the effect of the antagonist D-alpha-aminoadipate examined. An unusual profile of antagonism was obtained in that with 50-100 microM D-alpha-aminoadipate the depolarization to quisqualate was unaffected (or slightly potentiated) while those to L-glutamate, L-aspartate and N-methyl-D-aspartate were all considerably attenuated. D-alpha-aminoadipate did not influence passive membrane properties although a small hyperpolarization was sometimes evident. Dorsal root evoked excitations of motoneurones, particularly those using low strength stimulation, were also susceptible to antagonism by D-alpha-aminoadipate. These data suggest a separate neuroeffector/receptor mechanism for quisqualate compared to L-glutamate, L-aspartate and N-methyl-D-aspartate.

The actions of 'selective' excitatory amino acid antagonists on the crustacean neuromuscular junction

Intracellular recordings of neurally evoked excitatory junction potentials were made from the hermit crab neuromuscular junction and the effects of a series of putative antagonists, including the phosphonic amino acids, were examined for their effectiveness. The most potent antagonists were (+/-)2-amino-5-phosphonohexanoic acid and (+/-) 2-amino-5-phosphonovaleric acid while glutamate diethyl ester, DL-alpha-aminoadipate, 2-amino-7-phosphonoheptanoic acid and gamma-D-glutamylglycine were less effective. None of the compounds produced a change in membrane input resistance, but pyridine-2,5-dicarboxylic acid depolarized the muscle membrane and this probably accounted for its apparent antagonist properties. All the compounds readily and reversibly, but not competitively, antagonized the ionophoretic L-glutamate-induced depolarization. Since none of the compounds was capable of producing complete antagonism it is concluded that a more potent and competitive antagonist is required.

Spontaneous dorsal root potentials arise from interneuronal activity in the isolated frog spinal cord

Spontaneous dorsal root potentials (sDRPs) were recorded from the dorsal roots of the isolated frog spinal cord using sucrose gap techniques. sDRPs were always negative (depolarizing) in sign and ranged in size from about 100 microV to 6.0 mV. The largest sDRPs were 25-40% of the amplitude of DRPs evoked by stimulation of adjacent dorsal roots. Hypoxia or accumulation of extracellular K+ ions did not appear responsible for the generation of this spontaneous activity since exposing the cord to unoxygenated Ringer's solution decreased sDRPs and K+-sensitive microelectrodes indicated that only small changes in extracellular K+ (approximately 0.15 mM) were produced coincidently with the largest sDRPs. Chemically-mediated synaptic transmission was found to be necessary for the production of sDRPs because the addition of Mn2+ or Mg2+ ions or tetrodotoxin to the Ringer's solution or reduction of its Na+ concentration blocked sDRPs, whereas application of 4-aminopyridine enhanced them. It did not seem that a direct action of GABA on afferent fiber terminals was responsible for the generation of spontaneous potentials since an increase in sDRPs was seen after: application of the GABA antagonists, bicuculline and picrotoxin; exposure to the glutamic acid decarboxylase inhibitor, semicarbazide (which significantly reduced the concentration of GABA in the cord); and lowering of the external Cl- concentration. Similarly taurine is probably not significant since the taurine antagonist, TAG, increased the amount of spontaneous activity. On the other hand, (--)-baclofen, which is thought to reduce excitatory amino acid release, D,L-alpha-aminoadipic acid, alpha, epsilon-diaminopimelic acid, and 2-amino-4-phosphonobutyric acid, which are believed to be selective postsynaptic excitatory amino acid antagonists, and [D-Pro2-D-Phe7-D-Trp9]-substance P, a postsynaptic blocker of the action of substance P, markedly and reversibly reduced sDRPs. Experiments were performed on isolated cords without supraspinal or afferent input; therefore sDRPs must be generated by intraspinal structures. It would seem that interneurons are responsible because addition of mephenesin or pentobarbital--compounds which inhibit polysynaptic reflex transmission involving interneurons--reduced the production of sDRPs. sDRPs may result from the action of excitatory transmitters such as L-glutamate, L-aspartate, or substance P released by interneuronal firing in the spinal cord. Moreover, because sDRPs were increased by application of yohimbine, corynanthine and propanolol and reduced by haloperidol, such interneurons may be under descending control of adrenergic and dopaminergic fibers.

The dissociative anaesthetics, ketamine and phencyclidine, selectively reduce excitation of central mammalian neurones by N-methyl-aspartate

The interaction of two dissociative anaesthetics, ketamine and phencyclidine, with the responses of spinal neurones to the electrophoretic administration of amino acids and acetylcholine was studied in decerebrate or pentobarbitone-anaesthetized cats and rats. Both ketamine and phencyclidine selectively blocked excitation by N-methyl-aspartate (NMA) with little effect on excitation by quisqualate and kainate. Ketamine reduced responses to L-aspartate somewhat more than those of L-glutamate; the sensitivity of responses to these two putative transmitters was between that to NMA on one hand and that to quisqualate or kainate on the other. On Renshaw cells, ketamine and phencyclidine reduced responses to acetylcholine less than those to NMA but more than those to quisqualate or kainate. Dorsal root-evoked synaptic excitation of Renshaw cells was reduced to a greater extent than that following ventral root excitation. Intravenous ketamine, 2.5-20 mg/kg, and phencyclidine, 0.2-0.5 mg/kg, also selectively blocked excitation of neurones by NMA. Ketamine showed no consistent or selective effect on inhibition of spinal neurones by electrophoretically administered glycine or gamma-aminobutyricacid (GABA). The results suggest that reduction of synaptic excitation mediated via NMA receptors contributes to the anaesthetic/analgesic properties of these two dissociative anaesthetics.

The role of the electrogenic sodium pump in the glutamate afterhyperpolarization of frog spinal cord

Drug responses of isolated hemisected frog spinal cords were examined by means of the sucrose-gap technique. The glutamate-induced depolarizations (glu-d) of motoneurones (recorded from ventral roots), and primary afferents (recorded from dorsal roots), were followed by an afterhyperpolarization (glu-a.h.). The depolarization induced by DL-homocysteic acid (DLH) was only occasionally followed by an afterhyperpolarization (DLH-a.h.). The glu-a.h. on both roots persisted in the presence of tetrodotoxin (TTX, 0.1-1 microM), or Ringer solution containing 10 mM-Mg2+; 0.1 mM-Ca2+ or 2 mM-Mn2+; 0.2 mM-Ca2+. This indicated that the response was neither due to the release of endogenous neurally active substances nor to the activation of a Ca2+-sensitive K+ conductance. The glu-a.h. was reduced or blocked by K+-free Ringer solution, 3-acetylstrophanthin (3-Ac-Str; 1 microM) or Li+ ions, and was therefore attributed to the activity of the electrogenic Na+ pump. The duration of depolarization induced by glu or DLH was increased in the presence of K+-free Ringer solution, 1 microM 3-Ac-Str or Li ions. It is therefore suggested that the electrogenic Na+ pump may play a role in limiting the duration of depolarization induced by the action of excitatory amino acids. The re-admission of K+ ions to preparations which had been incubated in K+-free Ringer solution produced a transient hyperpolarization (K-a.h.) of the membrane potential of ventral roots which is also attributable to the activation of the electrogenic Na+ pump. Both the K-a.h. and the glu-a.h. were enhanced in Ca2+-free Ringer solution. It is therefore suggested that the Ca2+ ions may modulate the activity of the electrogenic pump in central nervous tissue.

The use of low concentrations of divalent cations to demonstrate a role for N-methyl-D-aspartate receptors in synaptic transmission in amphibian spinal cord

1 Synaptic potentials and the responses of frog spinal cord to various acidic amino acids were examined by means of the sucrose gap recording technique. 2 Divalent cations (50-250 microM) specifically antagonized responses evoked at N-methyl-D-aspartate (NMDA) receptors by N-methyl D,L aspartic acid (NMDLA). The rank order of potency was Ni2+ greater than Co2+ greater than Mg2+ greater than Mn2+. Responses to glutamate and aspartate were relatively insensitive to these concentrations of divalent cations. 3 The rank order of potency for divalent ions (1 mM) for antagonism of synaptic transmission in bullfrog sympathetic ganglia was Mn2+ greater than Co2+ greater than Ni2+ greater than Mg2+. Thus synaptic transmission in ganglia was especially sensitive to Mn2+ whereas NMDLA responses were especially sensitive to Co2+ and Mg2+. 4 It was possible to depress selectively the dorsal root-dorsal root potential (DR-DRP) and dorsal root-ventral root potential (DR-VRP) of frog spinal cord using low doses of Co2+ or Mg2+ which did not affect VR-DRP (ventral root-dorsal root potential). It was not possible to produce this selective depression of DR-DRP and DR-VRP with Mn2+, as this cation non-selectively depressed all responses. 5 These results suggest that: (i) divalent cations do not antagonize NMDLA responses by blocking Ca2+ channels which may mediate the response; (ii) postsynaptic NMDA receptors are activated by a neurotransmitter involved in the DR-DRP and DR-VRP pathways but not by any neurotransmitters involved in the VR-DRP pathway; (iii) the neurotransmitter activating NMDA receptors in amphibian spinal cord may be an aspartate-like substance rather than aspartate itself or glutamate.

Effect of urethane on synaptic and amino acid-induced excitation in isolated spinal cord preparations

Urethane (50 mM) produced a non-selective antagonism of depolarizations evoked by excitant amino acids or carbachol recorded from ventral roots of isolated spinal cord preparations of the frog or immature rat. Depolarizing responses to substance P or eledoisin-related-peptide were either unaffected or potentiated by this concentration of urethane. The threshold level for depression of dorsal to ventral root transmission was 10 mM urethane and transmission was completely blocked at 70-100 mM urethane. It is suggested that post-junctional blockade of the actions of excitant amino acids may be important in the anaesthetic action of urethane.

Characterization of [L-3H]aspartate binding to chick retinal subcellular fractions

Binding of [L-3H]aspartate to synaptic receptors was examined in membranes from whole chick retina and subcellular fractions enriched with photoreceptor terminals (P1) or terminals from the inner plexiform layer (P2), Na+-independent, stereospecific, high affinity binding was concentrated in the P1 fraction (Kb = 40 nM). P2 fraction also showed a high affinity binding system (KB = 11.8 nM) with lower capacity than in the P1 fraction. Comparative studies with [L-3H]-aspartate, [L-3H]-glutamate and [H3]-kainate showed that L-aspartate and L-glutamate are the most potent inhibitors of the binding of the three ligands. Aspartate and glutamate binding were effectively displaced by N-methyl-DL-aspartate and alpha-amino adipate, whereas only [3H]-glutamate binding was significantly inhibited by glutamate-diethyl-ester. Kainic acid exhibited negligible affinity for aspartate and glutamate binding sites. Results indicate the presence of different receptors for glutamate and aspartate in both plexiform layers of the retina.

High affinity binding of L-glutamate to chick retinal membranes

Binding of L-[3H]glutamate to membranes from whole chick retina and from subcellular fractions enriched with photoreceptor terminals (P1), or terminals from the inner plexiform layer (P2) was studied. Na+-dependent and Na+-independent binding to these membranes was demonstrated. Na+-independent binding was stereospecific. Kinetic analysis of the binding process indicated a single high-affinity system (KB = 0.55 micro M) with a capacity of approximately 20 pmoles/mg protein in all the membrane fractions. [3H]Glutamate binding to P1 and P2 fractions was effectively displaced by several structural analogues of glutamate. Glutamate diethyl-ester appreciably displaced binding, whereas kainic acid did not displace bound glutamate. Data indicate the binding of [3H]glutamate to physiologically relevant receptors in the chick retina.

Convulsant and possible anticholinergic actions of dendrotoxin in the amphibian spinal cord

1 Dendrotoxin (DTOX)6, 6a and 5,6-1, fractions of the venom isolated from the green mamba (Dendroaspis viridis) promoted both spontaneous and stimulus-coupled rhythmic activity and antagonized the cholinergically mediated ventral root-dorsal root potential (VR-DRP) of frog spinal cord. The different time course and reversibility of these two effects indicates that the toxin has two entirely separate sites of action on the frog spinal cord. 2 Since DTOX 6 neither blocked nor enhanced responses of ventral and dorsal roots to glutamate, gamma-aminobutyric acid (GABA), beta-alanine, glycine or aspartate, it is unlikely that its convulsant action resulted from an alteration of the postsynaptic actions of inhibitory or excitatory amino acids. 3 An alteration in the threshold for action potential generation could perhaps contribute to the convulsant action of DTOX 6, although other mechanisms such as blockade of the release of unspecified inhibitory substances cannot be excluded. 4 In addition to the lack of effect on amino acid responses, DTOX failed to block the polysynaptic DR-VRP or DR-DRP pathways, which are mediated at least in part by amino acid neurotransmitters. Although this would be consistent with a specific action of DTOX at the cholinergic synapse of the VR-DRP pathway, this site of action has not yet been demonstrated unequivocally. Other possible mechanisms whereby DTOX could block VR-DRP are discussed.