Rett syndrome induced pluripotent stem cell-derived neurons reveal novel neurophysiological alterations.

Rett syndrome (RTT) is a neurodevelopmental autism spectrum disorder caused by mutations in the methyl-CpG-binding protein 2 (MECP2) gene. Here, we describe the first characterization and neuronal differentiation of induced pluripotent stem (iPS) cells derived from Mecp2-deficient mice. Fully reprogrammed wild-type (WT) and heterozygous female iPS cells express endogenous pluripotency markers, reactivate the X-chromosome and differentiate into the three germ layers. We directed iPS cells to produce glutamatergic neurons, which generated action potentials and formed functional excitatory synapses. iPS cell-derived neurons from heterozygous Mecp2(308) mice showed defects in the generation of evoked action potentials and glutamatergic synaptic transmission, as previously reported in brain slices. Further, we examined electrophysiology features not yet studied with the RTT iPS cell system and discovered that MeCP2-deficient neurons fired fewer action potentials, and displayed decreased action potential amplitude, diminished peak inward currents and higher input resistance relative to WT iPS-derived neurons. Deficiencies in action potential firing and inward currents suggest that disturbed Na(+) channel function may contribute to the dysfunctional RTT neuronal network. These phenotypes were additionally confirmed in neurons derived from independent WT and hemizygous mutant iPS cell lines, indicating that these reproducible deficits are attributable to MeCP2 deficiency. Taken together, these results demonstrate that neuronally differentiated MeCP2-deficient iPS cells recapitulate deficits observed previously in primary neurons, and these identified phenotypes further illustrate the requirement of MeCP2 in neuronal development and/or in the maintenance of normal function. By validating the use of iPS cells to delineate mechanisms underlying RTT pathogenesis, we identify deficiencies that can be targeted for in vitro translational screens.

Neuronal plasticity: increasing the gain in pain.

We describe those sensations that are unpleasant, intense, or distressing as painful. Pain is not homogeneous, however, and comprises three categories: physiological, inflammatory, and neuropathic pain. Multiple mechanisms contribute, each of which is subject to or an expression of neural plasticity-the capacity of neurons to change their function, chemical profile, or structure. Here, we develop a conceptual framework for the contribution of plasticity in primary sensory and dorsal horn neurons to the pathogenesis of pain, identifying distinct forms of plasticity, which we term activation, modulation, and modification, that by increasing gain, elicit pain hypersensitivity.

Regulation of kainate receptors by cAMP-dependent protein kinase and phosphatases.

In the mammalian central nervous system, receptors for excitatory amino acid neurotransmitters such as the alpha-amino-3-hydroxy-5-methyl-4- isoxazolepropionic acid (AMPA)-kainate receptor mediate a large fraction of excitatory transmission. Currents induced by activation of the AMPA-kainate receptor were potentiated by agents that specifically stimulate adenosine 3',5'-monophosphate (cAMP)-dependent protein kinase A (PKA) activity or were supported by intracellular application of the catalytic subunit of PKA by itself or in combination with cAMP. Furthermore, depression of these currents by a competitive inhibitor of PKA indicates that AMPA-kainate receptors are regulated by endogenous PKA. Endogenous protein phosphatases also regulate these receptors because an inhibitor of cellular phosphates enhanced kainate currents. Modulation of PKA and phosphatases may regulate the function of these receptors and thus contribute to synaptic plasticity in hippocampal neurons.

NMDA channel regulation by channel-associated protein tyrosine kinase Src.

The N-methyl-D-aspartate (NMDA) receptor mediates synaptic transmission and plasticity in the central nervous system (CNS) and is regulated by tyrosine phosphorylation. In membrane patches excised from mammalian central neurons, the endogenous tyrosine kinase Src was shown to regulate the activity of NMDA channels. The action of Src required a sequence [Src(40-58)] within the noncatalytic, unique domain of Src. In addition, Src coprecipitated with NMDA receptor proteins. Finally, endogenous Src regulated the function of NMDA receptors at synapses. Thus, NMDA receptor regulation by Src may be important in development, plasticity, and pathology in the CNS.

Src activation in the induction of long-term potentiation in CA1 hippocampal neurons.

Long-term potentiation (LTP) is an activity-dependent strengthening of synaptic efficacy that is considered to be a model of learning and memory. Protein tyrosine phosphorylation is necessary to induce LTP. Here, induction of LTP in CA1 pyramidal cells of rats was prevented by blocking the tyrosine kinase Src, and Src activity was increased by stimulation producing LTP. Directly activating Src in the postsynaptic neuron enhanced excitatory synaptic responses, occluding LTP. Src-induced enhancement of alpha-amino-3-hydroxy-5-methylisoxazolepropionic acid (AMPA) receptor-mediated synaptic responses required raised intracellular Ca2+ and N-methyl-D-aspartate (NMDA) receptors. Thus, Src activation is necessary and sufficient for inducing LTP and may function by up-regulating NMDA receptors.

Regulation of neuregulin signaling by PSD-95 interacting with ErbB4 at CNS synapses.

Neuregulins (NRGs) and their receptors, the ErbB protein tyrosine kinases, are essential for neuronal development, but their functions in the adult CNS are unknown. We report that ErbB4 is enriched in the postsynaptic density (PSD) and associates with PSD-95. Heterologous expression of PSD-95 enhanced NRG activation of ErbB4 and MAP kinase. Conversely, inhibiting expression of PSD-95 in neurons attenuated NRG-mediated activation of MAP kinase. PSD-95 formed a ternary complex with two molecules of ErbB4, suggesting that PSD-95 facilitates ErbB4 dimerization. Finally, NRG suppressed induction of long-term potentiation in the hippocampal CA1 region without affecting basal synaptic transmission. Thus, NRG signaling may be synaptic and regulated by PSD-95. A role of NRG signaling in the adult CNS may be modulation of synaptic plasticity.

CAKbeta/Pyk2 kinase is a signaling link for induction of long-term potentiation in CA1 hippocampus.

Long-term potentiation (LTP) is an activity-dependent enhancement of synaptic efficacy, considered a model of learning and memory. The biochemical cascade producing LTP requires activation of Src, which upregulates the function of NMDA receptors (NMDARs), but how Src becomes activated is unknown. Here, we show that the focal adhesion kinase CAKbeta/Pyk2 upregulated NMDAR function by activating Src in CA1 hippocampal neurons. Induction of LTP was prevented by blocking CAKbeta/Pyk2, and administering CAKbeta/Pyk2 intracellularly mimicked and occluded LTP. Tyrosine phosphorylation of CAKbeta/Pyk2 and its association with Src was increased by stimulation that produced LTP. Finally, CAKbeta/Pyk2-stimulated enhancement of synaptic AMPA responses was prevented by blocking NMDARS, chelating intracellular Ca(2+), or blocking Src. Thus, activating CAKbeta/Pyk2 is required for inducing LTP and may depend upon downstream activation of Src to upregulate NMDA receptors.

LTP gets culture.

In a recent breakthrough, a methodology has been developed for studying persistent enhancement of excitatory synaptic transmission in primary cultures of hippocampus. Results from the use of this method have already pointed to a previously unsuspected differential role for synaptic versus extrasynaptic NMDA receptors in lasting synaptic potentiation.

NMDA receptor regulation by Src kinase signalling in excitatory synaptic transmission and plasticity.

Regulation of postsynaptic glutamate receptors is one of the main mechanisms for altering synaptic efficacy in the central nervous system. Recent studies have given insight into the upregulation of the NMDA receptor by Src family tyrosine kinases, which bind to scaffolding proteins in the NMDA receptor complex. Src acts as a common step in signalling cascades that link G-protein-coupled receptors with protein kinase C via the intermediary cell-adhesion kinase beta. This signalling to NMDA receptors is required for long-term potentiation in the CA1 region of the hippocampus.

P2Y(1) purinoceptor-mediated Ca(2+) signaling and Ca(2+) wave propagation in dorsal spinal cord astrocytes.

ATP is known to act as an extracellular messenger mediating the propagation of Ca(2+) waves in astrocyte networks. ATP mediates Ca(2+) waves by activating P2Y purinoceptors, which mobilize intracellular Ca(2+) in astrocytes. A number of P2Y purinoceptor subtypes have been discovered, but it is not known which P2Y subtypes participate in transmitting astrocyte Ca(2+) waves. Here, we show that ATP analogs that are selective agonists for the P2Y(1) subtype of purinoceptor caused release of intracellular Ca(2+) in astrocytes from the dorsal spinal cord. The Ca(2+) responses were blocked by adenosine-3'-phospho-5'-phosphosulfate, an antagonist known to selectively inhibit P2Y(1) but not other P2Y purinoceptor subtypes. Also, we show that P2Y(1) mRNA is expressed in dorsal spinal cord astrocytes. Furthermore, expression of P2Y(1) in an astrocytoma cell line lacking endogenous purinoceptors was sufficient to permit propagation of intercellular Ca(2+) waves. Finally, Ca(2+) wave propagation in dorsal spinal cord astrocytes was suppressed by pharmacologically blocking P2Y(1) purinoceptors. Together, these results indicate that dorsal spinal astrocytes express functional P2Y(1) purinoceptors, which participate in the transmission of Ca(2+) waves. Ca(2+) waves in astrocytes have been implicated as a major signaling pathway coordinating glial and neuronal activity; therefore, P2Y(1) purinoceptors may represent an important link in cell-cell signaling in the CNS.

Src potentiation of NMDA receptors in hippocampal and spinal neurons is not mediated by reducing zinc inhibition.

The protein-tyrosine kinase Src is known to potentiate the function of NMDA receptors, which is necessary for the induction of long-term potentiation in the hippocampus. With recombinant receptors composed of NR1-1a/NR2A or NR1-1a/2B subunits, Src reduces voltage-independent inhibition by the divalent cation Zn2+. Thereby the function of recombinant NMDA receptors is potentiated by Src only when the Zn2+ level is sufficient to cause tonic inhibition. Here we investigated whether the Src-induced potentiation of NMDA receptor function in neurons is caused by reducing voltage-independent Zn2+ inhibition. Whereas chelating extracellular Zn2+ blocked the Src-induced potentiation of NR1-1a/2A receptors, we found that Zn2+ chelation did not affect the potentiation of NMDA receptor (NMDAR) currents by Src applied into hippocampal CA1 or CA3 neurons. Moreover, Src did not alter the Zn2+ concentration-inhibition relationship for NMDAR currents in CA1 or CA3 neurons. Also, chelating extracellular Zn2+ did not prevent the upregulation of NMDA single-channel activity by endogenous Src in membrane patches from spinal dorsal horn neurons. Taking these results together we conclude that Src-induced potentiation of NMDAR currents is not mediated by reducing Zn2+ inhibition in hippocampal and dorsal horn neurons.

Pharmacologic rescue of motor and sensory function by the neuroprotective compound P7C3 following neonatal nerve injury.

Nerve injuries cause pain, paralysis and numbness that can lead to major disability, and newborns often sustain nerve injuries during delivery that result in lifelong impairment. Without a pharmacologic agent to enhance functional recovery from these injuries, clinicians rely solely on surgery and rehabilitation to treat patients. Unfortunately, patient outcomes remain poor despite application of the most advanced microsurgical and rehabilitative techniques. We hypothesized that the detrimental effects of traumatic neonatal nerve injury could be mitigated with pharmacologic neuroprotection, and tested whether the novel neuroprotective agent P7C3 would block peripheral neuron cell death and enhance functional recovery in a rat neonatal nerve injury model. Administration of P7C3 after sciatic nerve crush injury doubled motor and sensory neuron survival, and also promoted axon regeneration in a dose-dependent manner. Treatment with P7C3 also enhanced behavioral and muscle functional recovery, and reversed pathological mobilization of spinal microglia after injury. Our findings suggest that the P7C3 family of neuroprotective compounds may provide a basis for the development of a new neuroprotective drug to enhance recovery following peripheral nerve injury.

Differential responses of nociceptive vs. non-nociceptive spinal dorsal horn neurones to cutaneously applied vibration in the cat.

Extracellular single-unit recordings were made from dorsal horn neurones in the lumbar spinal cord of cats which were anaesthetized or were anaemically decerebrated. Each neurone was classified functionally as wide dynamic range (WDR), non-nociceptive, nociceptive specific or proprioceptive. Vibration was then applied to the hind limb using a feedback-controlled mechanical stimulator. WDR neurones had 3 distinct types of response to vibration (80 Hz: 0.3-1.0 mm): excitation, depression and a biphasic response consisting of excitation followed by depression. The type of response depended upon the location of the stimulator probe. With the stimulator probe placed inside that part of the receptive field from which low intensity, non-vibrational cutaneous stimuli elicited excitation, 35 neurones were excited by the vibratory stimulation, none was depressed and 4 showed the biphasic response. On the other hand, when the probe was positioned outside the receptive field for low intensity stimuli, 7 WDR neurones were excited, 164 showed depression or the biphasic response and 7 were unaffected. On-going activity and activity evoked by iontophoretic application of glutamate were decreased during the depressant response and during the depressant phase of the biphasic response. In terms of non-nociceptive neurones, all (n = 30) were excited by vibration; depressant or biphasic responses were not observed. Excitation was elicited by placing the probe either inside or outside the receptive field for non-vibrational stimuli. All nociceptive specific neurones (n = 3) were depressed by vibration regardless of the position of the stimulus. All proprioceptive neurones (n = 12) were excited by vibration. The predominantly depressant effect of vibration on nociceptive neurones vs. the predominantly excitatory effect on non-nociceptive neurones prompts us to suggest that the increase in pain threshold and the clinical analgesia elicited by vibration may be mediated at the spinal level by a decrease in the rate of firing of nociceptive neurones and/or by excitation of non-nociceptive neurones.

Evidence that adenosine mediates the depression of spinal dorsal horn neurons induced by peripheral vibration in the cat.

Nociceptive neurons in the dorsal horn of the cat spinal cord are depressed by vibration applied to the ipsilateral hind limb. The present study investigated the pharmacological properties of this depression because of the possibility that it represents the neural basis at the spinal level for the analgesic effects of vibration in humans. Experiments were done in cats anesthetized with sodium pentobarbital and acutely spinalized at the first lumbar level. Extracellular recordings were made from nociceptive neurons in the lower lumbar segments. The depression of these neurons induced by vibration to the hindlimb was attenuated by administration of the P1-purinergic (adenosine) receptor antagonist, caffeine (20-60 mg/kg i.v.); the maximum attenuation was 100%. Effects of caffeine began within 2 min after the start of injection (1-3 min injection period), were greatest in the 10 min period after the end of injection and lasted for up to 2 hr. Importantly, another P1-purinergic receptor antagonist, which does not cross the blood-brain barrier, 8-sulphophenyltheophylline (8-16 mg/kg), had no effect on the depression when given intravenously (n = 5); however, when administered by iontophoresis 8-sulphophenyltheophylline blocked the depression in 2 of 6 units. Dipyridamole (1.0-2.0 mg/kg i.v.), an inhibitor of adenosine uptake, potentiated the depression in 2 of 5 cases. These results prompt us to suggest that depression induced by vibration may be mediated by adenosine via the activation of P1-purinergic receptors. On the other hand, the GABAA antagonist, bicuculline, failed to attenuate vibration-induced depression when administered either intravenously (0.2-0.4 mg/kg; n = 5) or by iontophoresis (n = 10) and the glycine antagonist, strychnine (0.2-0.6 mg/kg; n = 3) and the opiate antagonist, naloxone (0.1-0.4 mg/kg; n = 4) were similarly ineffective. These findings suggest that vibration-induced depression of these units occurs without involvement of bicuculline-sensitive GABA receptors, strychnine-sensitive glycine receptors and naloxone-sensitive opiate receptors. In view of the fact that vibration-induced depression is evoked synaptically, this study is the first to demonstrate in the central nervous system a synaptic response which is mediated by adenosine. In addition, we suggest that the analgesic effects of vibration in humans may be mediated at the spinal level by activation of P1-purinergic receptors.

Tachykinins enhance the depression of spinal nociceptive neurons caused by cutaneously applied vibration in the cat.

The present investigation was prompted by previous studies in our laboratory which have indicated that tachykinins enhance depressant effects of purines and that the purine adenosine mediates a vibration-induced depression of nociceptive dorsal horn neurons. Extracellular recordings were made from single nociceptive neurons in the lower lumbar segments of anaesthetized cats. Vibration (80 Hz; 2.5-3.5 s every 20-25 s) was applied to the hindlimb using a feedback-controlled mechanical stimulator. The tachykinins physalaemin, substance P and neurokinin A were administered by iontophoresis. Physalaemin was tested on vibration-induced responses of 29 neurons; each neuron was excited by this tachykinin. To control for possible changes in the response to vibration caused by the excitation per se, statistical comparisons were made of the vibration-induced responses during excitation by tachykinins and during excitation by glutamate. In 16 cases the magnitude of the vibration-induced depression was significantly greater during the excitation caused by physalaemin. With the remaining neurons the response to vibration failed to differ during the excitation by physalaemin compared with the excitation by glutamate. In four of the 16 cases subthreshold applications of vibration caused depression after administration of physalaemin. The P1-purinergic (adenosine) antagonist, caffeine, was administered in three cases where vibration caused depression only with application of physalaemin. In each of these cases the depression was reversibly blocked by caffeine (10 or 40 mg kg-1 i.v.). The magnitude of vibration-induced depression was significantly increased during excitation by neurokinin A (5/14 neurons) or by substance P (1/9 neurons). From the results of the present study we suggest that tachykinins enhance the vibration-induced depression. This enhancement may be due to enhanced depression by adenosine.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of adenosine 5'-monophosphate and adenosine 5'-triphosphate on functionally identified units in the cat spinal dorsal horn. Evidence for a differential effect of adenosine 5'-triphosphate on nociceptive vs non-nociceptive units.

A study was done of the effects of iontophoretic application of adenosine 5'-monophosphate (AMP) and adenosine 5'-triphosphate (ATP) on functionally identified neurones in the spinal dorsal horn of the cat. AMP depressed nearly two-thirds of the 32 neurones tested regardless of functional type; the remainder were unaffected. ATP, on the other hand, had three types of effect: depression, excitation and a biphasic effect which consisted of excitation followed by depression. A significant difference was found when a comparison was made of the frequency of occurrence of each of these three types of effect in the samples of non-nociceptive (n = 18) and of wide dynamic range neurones (n = 42): of non-nociceptive neurones 61% were excited, 11% were depressed, 6% had a biphasic response and 22% were unaffected; of wide dynamic range neurones 45% had a biphasic response, 19% were depressed, 14% were excited and 21% were unaffected (chi 2 = 16.2, P less than 0.005). The depressant effects of both AMP and ATP and the depressant phase of the biphasic effect of ATP seem to be mediated through activation of P1-purinergic receptors because these effects were blocked by theophylline, a P1-purinergic antagonist [Burnstock (1978) In Cell Membrane Receptors for Drugs and Hormones: A Multidisciplinary Approach, pp. 107-118]. Thus the biphasic effect appears to consist of excitatory and depressant responses in the same neurone. The differential effects of ATP on non-nociceptive vs wide dynamic-range neurones are similar to the differential effects on these neurones observed during activation of low-threshold primary afferents. This similarity, together with evidence that ATP can be released from primary afferent neurones [Holton and Holton (1954) J. Physiol., Lond. 126, 124-140; Holton (1959) J. Physiol., Lond. 145, 494-504], prompts us to suggest that ATP may be a chemical mediator of effects of low-threshold primary afferent inputs in the spinal dorsal horn.

Purine-induced depression of dorsal horn neurons in the cat spinal cord: enhancement by tachykinins.

The neurokinins, physalaemin, substance P, neurokinin A and bradykinin, were tested on the responses of single spinal neurons to the purines, adenosine 5'-triphosphate (ATP) and adenosine 5'-monophosphate and to GABA. Experiments were done on anaesthetized cats, recording extracellularly from functionally identified sensory neurons in the lumbar dorsal horn. All compounds were administered by iontophoresis. Neurokinins caused a slow, prolonged excitation which outlasted the period of application. Physalaemin was tested on responses to ATP in 24 units. In each case application of ATP caused either depression, excitation or a biphasic response when the application was not pre-conditioned by ejection of physalaemin. For 11 units, with ATP applications subthreshold to alter the on-going firing rate, such applications caused depression when they were preceded by administration of physalaemin. Three units were tested with ATP applications which caused the excitatory response; when the applications of ATP were preceded by ejection of physalaemin, there was then a depressant component in the response. In these 14 cases, the magnitude of the depression or of the depressant component of the response, was measured using currents which failed to produce depression in the absence of physalaemin ejection; the mean magnitude of this depression was 34.7 +/- 1.6% (+/- S.E.M.). With the 10 remaining units, responses to ATP were unaffected by application of physalaemin. The early components of the biphasic and excitatory responses were unaffected by physalaemin and hence it appeared to have a differential effect, enhancing only the depressant effects of ATP. The enhancement of depression was reversible, lasting up to 30 min following a single ejection. Neither control current nor glutamate mimicked the effect of physalaemin in the responses to application of ATP. The depressant response to adenosine 5'-monophosphate was also enhanced by physalaemin: ejections of adenosine 5'-monophosphate subthreshold to affect the on-going firing rate caused depression after physalaemin application in 3 of 8 units (average depression: 35.0 +/- 3.3%). On the other hand, depression induced by GABA was unaffected by physalaemin in every case (n = 8); in 4 of these cases GABA was tested on units for which purine-induced depression was enhanced by physalaemin. Thus, physalaemin preferentially affected depressant responses to ATP and to adenosine 5'-monophosphate.(ABSTRACT TRUNCATED AT 400 WORDS)

Responses of functionally identified neurones in the dorsal horn of the cat spinal cord to substance P, neurokinin A and physalaemin.

The mammalian tachykinins, substance P and neurokinin A, and the non-mammalian tachykinin, physalaemin, were tested on functionally identified dorsal horn neurones in vivo. The experiments were done on cats which were anaesthetized with sodium pentobarbital or were anaemically decerebrated. Extracellular single-unit recordings were made in the lumbar spinal cord and the tachykinins were applied by iontophoresis. Each neurone was classified functionally as wide dynamic range, non-nociceptive, nociceptive specific or proprioceptive. The response to tachykinin application was determined for each neurone. Application of each of the tachykinins evoked a characteristic excitatory response which was delayed in onset, slow in developing and prolonged: physalaemin excited 99/131 neurones tested, neurokinin A excited 45/63 neurones and substance P excited 32/49 neurones. With two neurones physalaemin evoked a depression of the rate of firing, which may have been caused indirectly by excitation of a neighbouring neurone. Such depression was not elicited by either substance P or by neurokinin A. Physalaemin had a preferential excitatory effect on nociceptive neurones evoking excitation of 76/94 nociceptive neurones compared with 12/23 non-nociceptive neurones (chi 2 = 7.9, 1 d.f., P = 0.005). Substance P also caused a preferential excitation, with 30/40 nociceptive neurones being excited while all of the non-nociceptive neurones (n = 7) were unaffected (chi 2 = 11.5, 1 d.f., P = 0.0007). In contrast, neurokinin A failed to have a preferential effect; 32/46 nociceptive and 9/10 non-nociceptive neurones were excited (chi 2 = 1.0, 1 d.f., P = 0.40). Comparing the proportions of nociceptive neurones excited by the different tachykinins indicated that this type of neurone was not differently sensitive to any of the three peptides (chi 2 = 3.2, 2 d.f., P = 0.20). On the other hand, non-nociceptive neurones were preferentially excited by neurokinin A and physalaemin compared with substance P (chi 2 = 13.4, 2 d.f., P = 0.001). With regard to the endogenous tachykinins the results of this study may be interpreted in the following ways. The differential excitatory effect of substance P on nociceptive neurones supports the proposed role for this peptide in the transmission specifically of nociceptive inputs at the first afferent synapse. On the other hand, as neurokinin A excited non-nociceptive as well as nociceptive neurones, there may be a functional role for neurokinin A distinct from that of substance P.

P2Y and P2U receptors differentially release intracellular Ca2+ via the phospholipase c/inositol 1,4,5-triphosphate pathway in astrocytes from the dorsal spinal cord.

In astrocytes, raising intracellular Ca2+ concentration is a principal mechanism for transducing extracellular signals following activation of cell-surface receptors. Receptors that may be activated by purine nucleotides, P2 receptors, are known to be expressed by astrocytes from dorsal spinal cord; these astrocytes express two distinct subtypes of P2 receptor, P2Y and P2U. A main goal of the present study was to determine the intracellular signalling pathways mediating the Ca2+ responses produced by stimulating these receptors. Experiments were done using cultured astrocytes from rat dorsal spinal cord. Ca2+ responses were evoked by 2-methylthio-ATP or UTP, nucleotides previously shown to selectively activate P2Y and P2U receptors, respectively, in these cells. P2Y- and P2U-evoked Ca2+ responses were found not to depend upon extracellular Ca2+ and were blocked by thapsigargin, a Ca2+-ATPase inhibitor known to deplete inositol 1,4,5-triphosphate-sensitive Ca2+ stores. Intracellular application of the inositol 1,4,5-triphosphate-sensitive receptor antagonist, heparin, or of the G-protein inhibitor guanosine 5'-O-(2-thiodiphosphate), blocked the P2Y- and P2U-evoked Ca2+ responses. Moreover, the responses were prevented by the phospholipase C inhibitor, U-73122, but were unaffected by the inactive analogue, U-73343. These results indicate that P2Y and P2U receptors on dorsal spinal astrocytes are linked via G-protein coupling to release of intracellular Ca2+ via the phospholipase C/inositol 1,4,5-triphosphate pathway. When we assessed the releasable pools of intracellular Ca2+, by repeated agonist applications in zero extracellular Ca2+, we found that the pool accessed by activating P2U receptors was only a subpool of that accessed by activating P2Y receptors. This implies that there are separable inositol 1,4,5-triphosphate-releasable pools of Ca2+ in dorsal spinal astrocytes and that these may be differentially released by activating distinct metabotropic P2 receptors. This differential release of Ca2+ may be important for physiological as well as pathophysiological events occurring within the spinal cord.

Reduction of tyrosine kinase activity and protein tyrosine dephosphorylation by anoxic stimulation in vitro.

Tyrosine-specific protein phosphorylation has been recently implicated in mediating pathological changes associated with cerebral ischemia. In the present study, acute hypoxia/ischemia (anoxia) was simulated in vitro by incubating rat hippocampal slices in glucose-free artificial cerebrospinal fluid saturated with 95% N2/5% CO2. A marked decrease in the level of tyrosine phosphorylation of many protein bands compared with the control was observed. Immunoprecipitation and western blot confirmed that the NR2A/2B subunits of the N-methyl-D-aspartate receptors are among the dephosphorylated proteins. Maximal dephosphorylation of bands corresponding to NR2A/2B was reached after 10 min, and no recovery was observed even after 1 h in normal, oxygenated artificial cerebrospinal fluid. The effect was partially blocked by dephostatin, a membrane-permeable inhibitor of protein tyrosine phosphatases, but was not affected by the presence of glutamate receptor antagonists, or by removing extracellular Ca2+ or chelating intracellular Ca2+. Enzyme assay showed that anoxic stimulation resulted in a selective reduction in protein tyrosine kinase activity without affecting protein tyrosine phosphatase activity. Thus the present work suggests that anoxic stimulation produces a selective inhibition of protein tyrosine kinase activity leading to tyrosine-dephosphorylation of several proteins including the N-methyl-D-aspartate receptors. The underlying mechanism may involve a novel signal transduction pathway, which may protect neurons from degeneration during ischemic stress.