Tomomitsu Miyoshi

Specific deficit of the ON response in visual transmission by targeted disruption of the mGIuR6 gene

Taking advantage of the restricted expression of metabotropic glutamate receptor subtype 6 (mGluR6) in retinal ON bipolar cells, we generated knockout mice lacking mGluR6 expression. The homozygous mutant mice showed a loss of ON responses but unchanged OFF responses to light. The mutant mice displayed no obvious changes in retinal cell organization nor in the projection of optic fibers to the brain. Furthermore, the mGluR6-deficient mice showed visual behavioral responses to light stimulation as examined by shuttle box avoidance behavior experiments using light exposure as a conditioned stimulus. The results demonstrate that mGluR6 is essential in synaptic transmission to the ON bipolar cell and that the OFF response provides an important means for transmitting visual information.

Pikachurin, a dystroglycan ligand, is essential for photoreceptor ribbon synapse formation

Exquisitely precise synapse formation is crucial for the mammalian CNS to function correctly. Retinal photoreceptors transfer information to bipolar and horizontal cells at a specialized synapse, the ribbon synapse. We identified pikachurin, an extracellular matrix–like retinal protein, and observed that it localized to the synaptic cleft in the photoreceptor ribbon synapse. Pikachurin null-mutant mice showed improper apposition of the bipolar cell dendritic tips to the photoreceptor ribbon synapses, resulting in alterations in synaptic signal transmission and visual function. Pikachurin colocalized with both dystrophin and dystroglycan at the ribbon synapses. Furthermore, we observed direct biochemical interactions between pikachurin and dystroglycan. Together, our results identify pikachurin as a dystroglycan-interacting protein and demonstrate that it has an essential role in the precise interactions between the photoreceptor ribbon synapse and the bipolar dendrites. This may also advance our understanding of the molecular mechanisms underlying the retinal electrophysiological abnormalities observed in muscular dystrophy patients.

Electrical stimulation enhances the survival of axotomized retinal ganglion cells in vivo.

In view of recent reports on the survival promotion of damaged spiral ganglion cells and motoneurons by electrical stimulation, we hypothesized that an electrical stimulation of the cut optic nerve (ON) may promote the survival of axotomized retinal ganglion cells (RGCs) in vivo. To test this hypothesis, we examined 1 week after ON transection the RGC densities in the retinas with or without electrical stimulation. The densities of surviving RGCs in the retinas with the electrical stimulation increased as compared with those without the electrical stimulation. We concluded that electrical stimulation of the ON enhances the survival of axotomized RGCs in vivo, probably due to electrical activation of their soma.

Axonal regeneration induced by repetitive electrical stimulation of crushed optic nerve in adult rats

PurposeTo investigate whether electrical stimulation promoted axonal regeneration of retinal ganglion cells (RGCs) after optic nerve (ON) crush in adult rats.MethodsTranscorneal electrical stimulation (TES), which stimulates the retina with current from a corneal contact lens electrode, was used to stimulate the eye. TES was applied for 1 h immediately after ON crush. Axonal regeneration was determined by anterograde labeling of RGC axons. To examine whether the axonal regeneration was mediated by insulin-like growth factor 1 (IGF-1) receptors, an IGF-1 receptor antagonist, JB3, was injected intraperitoneally before each TES application. Immunostaining for IGF-1 was performed to examine the effects of TES. To test the survival-promoting effects of TES applied daily, the mean density of retrogradely labeled RGCs was determined on day 12 after ON crush.ResultsCompared with sham stimulation, the mean number of regenerating axons significantly increased at 250 μm distal from the lesion and increased IGF-1 immunoreactivity was observed in retinas treated daily with TES. Preinjection of an IGF-1 receptor antagonist significantly blocked axonal regeneration by TES applied daily. TES applied daily also markedly enhanced the survival of RGCs 12 days after ON crush.ConclusionTES applied daily promotes both axonal regeneration and survival of RGCs after ON crush.

Optimal parameters of transcorneal electrical stimulation (TES) to be neuroprotective of axotomized RGCs in adult rats

We previously showed that transcorneal electrical stimulation (TES) promoted the survival of axotomized retinal ganglion cells (RGCs) of rats. However the relationship between the parameters of TES and the neuroprotective effect of TES on axotomized RGCs was unclear. In the present study, we determined whether the neuroprotective effect of TES is affected by the parameters of TES. Adult male Wistar rats received TES just after transection of the left optic nerve (ON). The pulse duration, current intensity, frequency, waveform, and numbers of sessions of the TES were changed systematically. The alterations of the retina were examined histologically seven days or fourteen days after the ON transection. The optimal neuroprotective parameters were pulse duration of 1 and 2 ms/phase (P < 0.001, each), current intensity of 100 and 200 muA (P < 0.05, each), and stimulation frequency of 1, 5, and 20 Hz (P < 0.001, respectively). More than 30 min of TES was necessary to have a neuroprotective effect (P < 0.001). Symmetric pulses without an inter-pulse interval were most effective (P < 0.001). Repeated TES was more neuroprotective than a single TES at 14 days after ON transection (P < 0.001). Our results indicate that there is a range of optimal neuroprotective parameters of TES for axotomized RGCs of rats. These values will provide a guideline for the use of TES in patients with different retinal and optic nerve diseases.

Functional recovery of vision in regenerated optic nerve fibers

Retinal ganglion cells (RGCs) of adult mammals normally suffer from retrograde cell death after optic nerve section. However, with transplantation of a segment of peripheral nerve (PN), their axons can regenerate and regrow through the graft. When properly guided, the regenerated axons make functional synapses with the target cells in the superior colliculus. Two months after PN graft we studied the number and morphology of RGCs with regenerated axons in adult cats. Number of regenerated RGCs was a few percent of the total population and, among various RGC types, alpha cells revealed the greatest ability for axonal regeneration and ON-center RGCs tended to regenerate better than OFF-center cells. While dendritic field dimension of RGCs with regenerated axons was mostly preserved, their regenerated axons were thinner than normal optic axons and mostly unmyelinated. The RGCs with regenerated axons revealed normal physiological properties in response to visual stimuli, and were classifiable into Y, X or W cells. In accordance with morphological results, Y cells (morphological alpha cells) were most frequently sampled. In hamsters and rats it has been shown that the animals with reconstructed retinocollicular pathway by the PN graft reveal behavioral recovery of visual function. However, in the cat, trials are still in progress to reconstruct the retinogeniculate pathway. The present status of researches on optic nerve regeneration of adult mammals using the PN graft is reviewed, and some future directions discussed.

Random bin for analyzing neuron spike trains

When analyzing neuron spike trains, it is always the problem of how to set the time bin. Bin width affects much to analyzed results of such as periodicity of the spike trains. Many approaches have been proposed to determine the bin setting. However, these bins are fixed through the analysis. In this paper, we propose a randomizing method of bin width and location instead of conventional fixed bin setting. This technique is applied to analyzing periodicity of interspike interval train. Also the sensitivity of the method is presented.

Cilostazol promotes survival of axotomized retinal ganglion cells in adult rats

Cilostazol (CLZ), a selective inhibitor of cyclic nucleotide phosphodiesterase 3, has been shown to reduce neuronal cell death after a transient cerebral infarction. The mechanism for this reduction was suggested to be an elevation of intracellular cAMP or an inhibition of tumor necrosis factor alpha. Optic nerve injury leads to retinal ganglion cell (RGC) death possibly from a deprivation of neurotrophic factors and/or the down-regulation of intracellular cAMP. The purpose of this study was to determine if CLZ can rescue RGCs after optic nerve transection by inhibiting cyclic nucleotide phosphodiesterase 3. To examine this, the mean densities of surviving RGCs after optic nerve transection were determined in retinas that received an intravitreal injection of CLZ and in retinas that received vehicle. Our results showed that the density of surviving RGCs in the retina with intravitreal CLZ were significantly higher than that with vehicle injection on day 7. The CLZ was effective in promoting the survival at more than 0.05% concentration. The neuroprotective effects induced by 0.05% CLZ could be observed even 14 days after optic nerve transection. Furthermore, combined application of protein kinase A (PKA) inhibitor, KT5720 (10 microM) and 0.05% CLZ significantly decreased the density of surviving RGCs compared to that with only 0.05% CLZ. Based on these data, we concluded that CLZ enhances the survival of axotomized RGC in vivo, possibly depending on the activation of PKA pathway.

Receptive-field properties of adult cat’s retinal ganglion cells with regenerated axons

Abstract Receptive-field properties of retinal ganglion cells (RGCs) that had regenerated their axons were studied by recording single-unit activity from strands teased from peripheral nerve (PN) grafts apposed to the cut optic nerve in adult cats. Of the 286 visually responsive units recorded from PN grafts in 20 cats, 49.7% were classified, according to their receptive-field properties, as Y-cells, 39.5% as X-cells, 6.6% as W-cells, and 4.2% were unclassified. The predominant representation of Y-cells is consistent with a corresponding morphological study (Watanabe et al. 1993a), which identified α-cells as the RGC type with the largest proportion of regenerating axons. Among the X-cells, we only found ON-center types, whereas both ON-center and OFF-center Y-cells were found. As in intact retinas, the receptive-field center sizes of Y-cells and W-cells were larger than those of X-cells at corresponding displacements from the area centralis. Within the 10° surrounding the area centralis, the receptive fields of X-cells with regenerated axons were larger than those in intact retinas, suggesting that some rearrangement of retinal circuitry occurred as a consequence of degeneration and regeneration. Receptive-field center responses of Y-, X-, and W-type units with regenerated axons were similar to those found in intact retinas, but the level of spontaneous activity of Y- and X-type units was, in general, less than that of intact RGCs. Receptive-field surrounds were weak or not detected in more than half of the visually responsive RGCs with regenerated axons.

Detection of M-sequences from spike sequence in neuronal networks

In circuit theory, it is well known that a linear feedback shift register (LFSR) circuit generates pseudorandom bit sequences (PRBS), including an M-sequence with the maximum period of length. In this study, we tried to detect M-sequences known as a pseudorandom sequence generated by the LFSR circuit from time series patterns of stimulated action potentials. Stimulated action potentials were recorded from dissociated cultures of hippocampal neurons grown on a multielectrode array. We could find several M-sequences from a 3-stage LFSR circuit (M3). These results show the possibility of assembling LFSR circuits or its equivalent ones in a neuronal network. However, since the M3 pattern was composed of only four spike intervals, the possibility of an accidental detection was not zero. Then, we detected M-sequences from random spike sequences which were not generated from an LFSR circuit and compare the result with the number of M-sequences from the originally observed raster data. As a result, a significant difference was confirmed: a greater number of “0–1” reversed the 3-stage M-sequences occurred than would have accidentally be detected. This result suggests that some LFSR equivalent circuits are assembled in neuronal networks.