Masanori Ogata

Impaired acquisition of skilled behavior in rotarod task by moderate depletion of striatal dopamine in a pre-symptomatic stage model of Parkinson's disease

In view of recent findings that suggest that the nigrostriatal dopamine (DA) system plays a role in motor control and the acquisition of habits and skills, we hypothesized that the striatum-based function underlying the acquisition of skilled behaviors might be more vulnerable to dopamine depletion than the motor control. To test this hypothesis, we investigated whether impaired acquisition of skilled behaviors occurs in a pre-symptomatic stage model of Parkinsons disease (PD). By using the microdialysis method and the 6-OHDA-technique to destroy dopamine neurons, we confirmed that rats with unilateral partial lesions of the nigral dopamine cells by 6-OHDA are suitable for a pre-symptomatic stage model of Parkinsons disease. The rats in this model exhibited moderate disruption of striatal dopamine release function and relatively intact motor functions. In a rotarod test, the impaired acquisition of skilled behavior occurred in rats with bilateral partial lesions of the nigral dopamine cells by 6-OHDA. These rats displayed intact general motor functions, such as locomotor activity, adjusting steps, equilibrium function and muscle strength. Based on these results, we concluded that the striatum-based function underlying the acquisition of skilled behaviors or sensorimotor learning may be more vulnerable to dopamine depletion than the motor control.

Antisense knockdown of spinal-mGluR1 reduces the sustained phase of formalin-induced nociceptive responses

To examine the role of mGluR1 (a subunit of the group I metabotropic glutamate receptor) in the nociceptive responses of rats following a subcutaneous injection of formalin into the plantar surface of the hind paw, we delivered antisense oligonucleotides (ODNs) against mGluR1 into the rat lumbar spinal cord (L3-L5) intrathecally using an HVJ-liposome-mediated gene transfer method. Rats treated with a single injection of mGluR1 antisense ODNs into the intrathecal space of the lumbar spinal cord showed a marked reduction of the early-sustained phase of formalin-induced nociceptive responses, but not of their acute phase. The reduction of nociceptive behavioral responses became apparent at day 2 after the antisense treatment and lasted for 2 days. This corresponded to a long-lasting down-regulation (46%) of mGluR1 expression in the lumbar cord. This down-regulated mGluR1 was observed at day 2 and persisted until day 4 after the intrathecal infusion of mGluR1 antisense ODN. In contrast, rats treated with mGluR1 sense or mismatch ODNs showed none of these changes. These results suggest that mGluR1 may play a crucial role in the sustained nociception of formalin-induced behavioral responses.

Nigral injection of antisense oligonucleotides to synaptotagmin I using HVJ-liposome vectors causes disruption of dopamine release in the striatum and impaired skill learning.

To produce an animal model of a dopa-responsive motor disorder with depletion of dopamine (DA) release in the striatum by dysfunction of the transmitter release machinery of the nigrostriatal DA system, we performed an intra-nigral injection of an HVJ-liposome gene transfer vector containing antisense oligodeoxynucleotides (ODNs) against synaptotagmin I (SytI), a key regulator of Ca(2+)-dependent exocytosis and endocytosis in adult rats. A unilateral intra-nigral injection of HVJ-liposome vectors containing antisense ODNs against SytI (syt-AS) caused a moderate disruption of methamphetamine-induced release of DA in the treated side of the striatum, while the syt-AS treatment did not affect physiological release of DA in the treated striatum. A bilateral intra-nigral injection of HVJ-liposome vectors containing syt-AS induced an impairment of the striatal DA-mediated acquisition of skilled behavior in a rotarod task without any deficits in general motor functions, such as spontaneous locomotor activity, motor adjusting steps, equilibrium function, or muscle strength. These findings suggest that an intra-nigral treatment with HVJ-liposome vectors containing syt-AS may cause a long-lasting nigral knockdown of SytI which, in turn, leads to a moderate dysfunction of the DA release machinery in the terminals of the nigrostriatal DA system and a subsequent mild depletion of DA release in the striatum.

Antisense in vivo knockdown of synaptotagmin I and synapsin I by HVJ-liposome mediated gene transfer modulates ischemic injury of hippocampus in opposing ways.

Neurotransmitter release during and after ischemic event is thought to be involved in excitotoxicity as a pathogenesis for the ischemic brain damage, which is mediated by excessive activation of glutamate receptors and attendant calcium overload. To ascertain the role of transmitter release from nerve terminals in promoting the ischemic neurodegeneration, we delivered antisense oligodeoxynucleotides (ODNs) to synaptotagmin I or synapsin I into the rat brain by using HVJ-liposome gene transfer technique. The antisense ODNs were injected into the lateralventricle in rats 4 days prior to transient forebrain ischemia of 20 min. With a single antisense treatment, long-lasting downregulation of the transmitter release relating protein levels at overall synaptic terminals was achieved. The antisense in vivo knockdown of synaptotagmin I prevented almost completely the ischemic damage of hippocampal CA1 neurons, while the in vivo knockdown of synapsin I markedly promoted the ischemic damage of CA1 pyramidal neurons and extended the injury to relatively resistant CA2/CA3 region. The modulation of ischemic hippocampal damage by the in vivo knockdown of synaptotagmin I or synapsin I suggests that transmitter release from terminals plays an important role in the evolution of ischemic brain damage and therefore the transmitter release strategy by the use of antisense ODNs-HVJ-liposome complex is reliable for neuroprotective therapies.

Activation of the NMDA receptor involved in the alleviating after-effect of repeated stimulation of the subthalamic nucleus on motor deficits in hemiparkinsonian rats.

To test the hypothesis that the cellular mechanism whereby chronic deep brain stimulation of the subthalamic nucleus (STN-DBS) induces the improvement of motor deficits lasting after stimulation in the hemiparkinsonian (hemi-PD) rat involves the NMDA receptor-dependent processes in neurons receiving afferents from the STN, we examined whether the NMDA receptor antagonist prevents the alleviating after-effect of repeated STN-DBS on motor deficits in hemi-PD. The cylinder test was performed before and after repeated STN-DBS over 3 days in hemi-PD that received a unilateral injection of 6-OHDA into the medial forebrain bundle 3 weeks prior to STN-DBS experiments. No significant improvement in the reduced frequency of forelimb use and forelimb-use asymmetry was seen in the cylinder test after the single STN-DBS, while, when the STN-DBS was applied three times at intervals of 24 h, the improvement became apparent and significant only in the reduced frequency of forelimb use (akinesia) after termination of the stimulation, suggesting the alleviating after-effect of chronic stimulation. Then, the effects of intraperitoneal administration of the non-competitive NMDA receptor antagonist MK-801 and the competitive NMDA receptor antagonist CPP on the alleviating after-effect of the STN-DBS were examined in cylinder tests performed before and after repeated STN-DBS for 3 days in hemi-PD. Both MK-801 (0.1 mg/kg) and CPP (0.5 mg/kg) completely prevented the improvement of the akinetic motor deficit after repeated STN-DBS. These results support the hypothesis that activation of the NMDA receptor and subsequent cellular processes in neurons receiving the afferents from the STN may involve in the mechanism underlying the alleviating after-effect of chronic STN-DBS on the akinetic motor deficit in hemi-PD.

LATE PHASE OF LONG-TERM POTENTIATION INDUCED BY CO-APPLICATION OF N-METHYL-D-ASPARTIC ACID AND THE ANTAGONIST OF NR2B-CONTAINING N-METHYL-D-ASPARTIC ACID RECEPTORS IN RAT HIPPOCAMPUS

Activation of N-methyl-d-aspartic acid (NMDA) glutamate receptors (NMDARs) is required for long-term potentiation (LTP) of excitatory synaptic transmission at hippocampal CA1 synapses, the proposed cellular mechanisms of learning and memory. We demonstrate here that a brief bath co-application of a low concentration of NMDA, an agonist of NMDARs, and the selective antagonist of NR2B-containing NMDARs, (alpha R, beta S)-alpha-(4-hydroxyphenyl)-beta-methyl-4-(phenylmethyl)-1-piperidinepropanol (Ro25-6981), to hippocampal slices from young adult rats produced a slowly developing LTP persisting at least for 6 h following a transient depression of synaptic transmission in CA1 synapses. The LTP was likely to occur at postsynaptic site and was initiated by activation of NMDARs, and its development was mediated by cAMP-dependent protein kinase (PKA) activation and protein synthesis. This chemically induced LTP and the tetanus-induced late phase of LTP (L-LTP) were mutually occluding, suggesting a common expression mechanism. Thus, we have demonstrated that a brief bath co-application of NMDA with Ro25-6981 to a slice offers an alternative to electrical stimulation as a stimulation method to induce L-LTP. The chemically induced LTP did not require the low-frequency test stimulation typically used to monitor the strength of synapses during and after drug application. Thus, the LTP may occur at a large fraction of synapses in the slice and not to be confined to a small fraction of the synapses where electrical stimulation can reach and induce LTP. Therefore, this chemically induced LTP may be useful for assessing the biochemical and morphological correlates and the molecular aspects of the expression mechanism for L-LTP that has been proven to correlate to hippocampal long-term memory.

The NR2B antagonist, ifenprodil, corrects the l-DOPA-induced deficit of bilateral movement and reduces c-Fos expression in the subthalamic nucleus of hemiparkinsonian rats

The use of NR2B antagonists in Parkinsonism is still controversial. To examine their anti-parkinsonian effects, the NR2B antagonist, ifenprodil, and L-DOPA were administered together and separately in hemiparkinsonian rats (hemi-PD) that were subjected to a cylinder test. Recovery from hypoactivity was achieved by single administration of 3-7 mg/kg of L-DOPA; however, improvement in the deficit of bilateral forelimb use was not observed. When administered alone, ifenprodil had no anti-parkinsonian effects; however, combined administration of ifenprodil and 7 mg/kg of L-DOPA significantly reversed the deficit of bilateral forelimb use without adversely affecting the L-DOPA-induced improvement in motor activity. Next, in order to identify the brain area influenced by L-DOPA and ifenprodil, quantitative analysis of L-DOPA-induced c-Fos immunoreactivity was performed in various brain areas of hemi-PD following administration of L-dopa with and without ifenprodil. Among brain areas with robust c-Fos expression within the motor loop circuit in dopamine-depleted hemispheres, co-administered ifenprodil markedly attenuated L-DOPA-induced c-Fos expression in only the subthalamic nucleus (STN), suggesting that the STN is the primary target for the anti-parkinsonian action of NR2B antagonists.

Characterization of nociceptive response to chemical, mechanical, and thermal stimuli in adolescent rats with neonatal dopamine depletion.

Rats with dopamine depletion caused by 6-hydroxydopamine (6-OHDA) treatment during adulthood and the neonatal period exhibit akinetic motor activity and spontaneous motor hyperactivity during adolescence, respectively, indicating that the behavioral effects of dopamine depletion depend on the period of lesion development. Dopamine depletion during adulthood induces hyperalgesic response to mechanical, thermal, and/or chemical stimuli, whereas the effects of neonatal dopamine depletion on nociceptive response in adolescent rats are yet to be examined. The latter aspect was addressed in this study, and behavioral responses were examined using von-Frey, tail flick, and formalin tests. The formalin test revealed that rats with neonatal dopamine depletion exhibited a significant increase in nociceptive response during interphase (6-15min post formalin injection) and phase 2 (16-75min post formalin injection). This increase in nociceptive response to the formalin injection was not reversed by pretreatment with methamphetamine, which ameliorates motor hyperactivity observed in adolescent rats with neonatal 6-OHDA treatment. The von-Frey filament and tail flick tests failed to reveal significant differences in withdrawal thresholds between neonatal 6-OHDA-treated and vehicle-treated rats. The spinal neuronal response to the formalin injection into the rat hind paw was also examined through immunohistochemical analysis of c-Fos protein. Significantly increased numbers of c-Fos-immunoreactive cells were observed in laminae I-II and V-VI of the ipsilateral spinal cord to the site of the formalin injection in rats with neonatal dopamine depletion compared with vehicle-treated rats. These results suggest that the dopaminergic neural system plays a crucial role in the development of a neural network for tonic pain, including the spinal neural circuit for nociceptive transmission, and that the mechanism underlying hyperalgesia to tonic pain is not always consistent with that of spontaneous motor hyperactivity induced by neonatal dopamine depletion.

Effect of rovatirelin, a novel thyrotropin-releasing hormone analog, on the central noradrenergic system

Rovatirelin ([1-[-[(4S,5S)-(5-methyl-2-oxo oxazolidin-4-yl) carbonyl]-3-(thiazol-4-yl)-l-alanyl]-(2R)-2-methylpyrrolidine) is a novel synthetic agent that mimics the actions of thyrotropin-releasing hormone (TRH). The aim of this study was to investigate the electrophysiological and pharmacological effects of rovatirelin on the central noradrenergic system and to compare the results with those of another TRH mimetic agent, taltirelin, which is approved for the treatment of spinocerebellar degeneration (SCD) in Japan. Rovatirelin binds to the human TRH receptor with higher affinity (Ki=702nM) than taltirelin (Ki=3877nM). Rovatirelin increased the spontaneous firing of action potentials in the acutely isolated noradrenergic neurons of rat locus coeruleus (LC). The facilitatory action of rovatirelin on the firing rate in the LC neurons was inhibited by the TRH receptor antagonist, chlordiazepoxide. Reduction of the extracellular pH increased the spontaneous firing of LC neurons and rovatirelin failed to increase the firing frequency further, indicating an involvement of acid-sensitive K+ channels in the rovatirelin action. In in vivo studies, oral administration of rovatirelin increased both c-Fos expression in the LC and extracellular levels of noradrenaline (NA) in the medial prefrontal cortex (mPFC) of rats. Furthermore, rovatirelin increased locomotor activity. The increase in NA level and locomotor activity by rovatirelin was more potent and longer acting than those by taltirelin. These results indicate that rovatirelin exerts a central nervous system (CNS)-mediated action through the central noradrenergic system, which is more potent than taltirelin. Thus, rovatirelin may have an orally effective therapeutic potential in patients with SCD.

Muscarinic receptor-mediated excitation of rat intracardiac ganglion neurons

Modulation of the membrane excitability of rat parasympathetic intracardiac ganglion neurons by muscarinic receptors was studied using an amphotericin B-perforated patch-clamp recording configuration. Activation of muscarinic receptors by oxotremorine-M (OxoM) depolarized the membrane, accompanied by repetitive action potentials. OxoM evoked inward currents under voltage-clamp conditions at a holding potential of -60 mV. Removal of extracellular Ca(2+) markedly increased the OxoM-induced current (IOxoM). The inward IOxoM in the absence of extracellular Ca(2+) was fully inhibited by removal of extracellular Na(+), indicating the involvement of non-selective cation channels. The IOxoM was inhibited by organic cation channel antagonists including SKF-96365 and ML-204. The IOxoM was antagonized by muscarinic receptor antagonists with the following potency: 4-DAMP > pirenzepine = darifenacin > methoctramine. Muscarinic toxin 7 (MT-7), a highly selective inhibitor for M1 receptor, produced partial inhibition of the IOxoM. In the presence of MT-7, concentration-inhibition curve of the M3-preferring antagonist darifenacin was shifted to the left. These results suggest the contribution of M1 and M3 receptors to the OxoM response. The IOxoM was inhibited by U-73122, a phospholipase C inhibitor. The membrane-permeable IP3 receptor blocker xestospongin C also inhibited the IOxoM. Furthermore, pretreatment with thapsigargin and BAPTA-AM inhibited the IOxoM, while KN-62, a blocker of Ca(2+)/calmodulin-dependent protein kinase II, had no effect. These results suggest that the activation mechanism involves a PLC pathway, release of Ca(2+) from intracellular Ca(2+) stores and calmodulin. The cation channels activated by muscarinic receptors may play an important role in neuronal membrane depolarization in rat intracardiac ganglion neurons.