Hitoo Nishino

Pleiotrophin mRNA is highly expressed in neural stem (progenitor) cells of mouse ventral mesencephalon and the product promotes production of dopaminergic neurons from embryonic stem cell-derived nestin-positive cells

Neural stem cells are promising candidates for donor cells in neural transplantation. However, the mechanism by which neural stem cells differentiate into neurons is not well understood. In the present study, a serial analysis of gene expression (SAGE) was carried out to generate a gene file of neural stem (progenitor) cells from the mouse ventral mesencephalon. Among the 15,815 tags investigated, the mRNA of the housekeeping genes (elongation factor 1‐α, ATPase subunit 6, GAPDH, actin), laminin receptor 1, HSP 70, pleiotrophin, and nestin were highly expressed. Because pleiotrophin (PTN) exhibits mitogenic and trophic effects on neural development and exhibits trophic effects on survival of dopaminergic (DAergic) neurons, we investigated the role of PTN in neurogenesis, especially to DAergic neurons. Here, we show that PTN increased the production of tyrosine hydroxylase (TH)‐positive neurons from embryonic stem (ES) cell‐ derived nestin‐positive cells. The expression of Nurr1 mRNA was enhanced by PTN. L‐dopa in the culture medium was increased by PTN. This effect was as strong as with sonic hedgehog. Data suggest that PTN mRNA is highly expressed in neural stem (progenitor) cells of mouse ventral mesencephalon, and PTN promotes the production of DAergic neurons from ES cell‐ derived nestin‐positive cells.

Homeotic factor ATBF1 induces the cell cycle arrest associated with neuronal differentiation

The present study aimed to elucidate the function of AT motif-binding factor 1 (ATBF1) during neurogenesis in the developing brain and in primary cultures of neuroepithelial cells and cell lines (Neuro 2A and P19 cells). Here, we show that ATBF1 is expressed in the differentiating field in association with the neuronal differentiation markers β-tubulin and MAP2 in the day E14.5 embryo rat brain, suggesting that it promotes neuronal differentiation. In support of this, we show that ATBF1 suppresses nestin expression, a neural stem cell marker, and activates the promoter of Neurod1 gene, a marker for neuronal differentiation. Furthermore, we show that in Neuro 2A cells, overexpressed ATBF1 localizes predominantly in the nucleus and causes cell cycle arrest. In P19 cells, which formed embryonic bodies in the floating condition, ATBF1 is mainly cytoplasmic and has no effect on the cell cycle. However, the cell cycle was arrested when ATBF1 became nuclear after transfer of P19 cells onto adhesive surfaces or in isolated single cells. The nuclear localization of ATBF1 was suppressed by treatment with caffeine, an inhibitor of PI(3)K-related kinase activity of ataxa-telangiectasia mutated (ATM) gene product. The cytoplasmic localization of ATBF1 in floating/nonadherent cells is due to CRM1-dependent nuclear export of ATBF1. Moreover, in the embryonic brain ATBF1 was expressed in the cytoplasm of proliferating stem cells on the ventricular zone, where cells are present at high density and interact through cell-to-cell contact. Conversely, in the differentiating field, where cell density is low and extracellular matrix is dense, the cell-to-matrix interaction triggered nuclear localization of ATBF1, resulting in the cell cycle arrest. We propose that ATBF1 plays an important role in the nucleus by organizing the neuronal differentiation associated with the cell cycle arrest.

Melatonin suppresses cerebral edema caused by middle cerebral artery occlusion/reperfusion in rats assessed by magnetic resonance imaging

Abstract: Melatonin, a pineal secretory product synthesized from tryptophan, has been found to be effective against neurotoxicity. The present study was aimed at demonstrating the effectiveness of melatonin in vivo in reducing ischemia‐induced cerebral edema using magnetic resonance imaging (MRI). Rats were subjected to middle cerebral artery (MCA) occlusion/reperfusion surgery. Melatonin was administered twice (6.0u2003mg/kg, p.o.) just prior to 1u2003hr of MCA occlusion and 1u2003day after the surgery. T2‐weighted multislice spin‐echo images were acquired 1u2003day after the surgery. In the saline‐treated control rats, increases in T2‐weighted signals (water content) were clearly observed in the striatum and in the cerebral cortex. In the melatonin‐treated group, total volume of edema was reduced by 51.6% compared with control group (Pu2003<u20030.01). The protective effect of melatonin against edema was more clearly observed in the cerebral cortex (reduced by 59.8%, Pu2003<u20030.01) than in the striatum (reduced by 34.2%, Pu2003<u20030.05). Edema volume in a coronal slice was the greatest at the level of the bregma. Suppression of cerebral edema by melatonin was more effective posterior than anterior to the bregma. Melatonin appeared to reduce the volume of the edematous sites rather than to shift the signal intensity distribution. The present MRI study clearly demonstrates the effectiveness of melatonin against cerebral edema formation in ischemic animals in vivo, especially in the cerebral cortex. Melatonin may be highly useful in preventing cortical dysfunctions such as motor, sensory, memory, and psychological impairments associated with ischemic stroke.

Environmental enrichment brings a beneficial effect on beam walking and enhances the migration of doublecortin-positive cells following striatal lesions in rats

Rats raised in an enriched environment (enriched rats) have been reported to show less motor dysfunction following brain lesions, but the neuronal correlates of this improvement have not been well clarified. The present study aimed to elucidate the effect of chemical brain lesions and environmental enrichment on motor function and lesion-induced neurogenesis. Three week-old, recently weaned rats were divided into two groups: one group was raised in an enriched environment and the other group was raised in a standard cage for 5 weeks. Striatal damage was induced at an age of 8 weeks by injection of the neuro-toxins 6-hydroxydopamine (6-OHDA) or quinolinic acid (QA) into the striatum, or by injection of 6-OHDA into the substantia nigra (SN), which depleted nigrostriatal dopaminergic innervation. Enriched rats showed better performance on beam walking compared with those raised in standard conditions, but both groups showed similar forelimb use asymmetry in a cylinder test. The number of bromodeoxyuridine-labeled proliferating cells in the subventricular zone was increased by a severe striatal lesion induced by QA injection 1 week after the lesion, but decreased by injection of 6-OHDA into the SN. Following induction of lesions by striatal injection of 6-OHDA or QA, the number of cells positive for doublecortin (DCX) was strongly increased in the striatum; however, there was no change in the number of DCX-positive cells following 6-OHDA injection into the SN. Environmental enrichment enhanced the increase of DCX-positive cells with migrating morphology in the dorsal striatum. In enriched rats, DCX-positive cells traversed the striatal parenchyma far from the corpus callosum and lateral ventricle. DCX-positive cells co-expressed an immature neuronal marker, polysialylated neural cell adhesion molecule, but were negative for a glial marker. These data suggest that environmental enrichment improves motor performance on beam walking and enhances neuronal migration toward a lesion area in the striatum.

Argyrophilic dark neurons represent various states of neuronal damage in brain insults: some come to die and others survive

Argyrophilic dark neurons (DNs) reflect the early histopathological state of neurons following various brain insults. We examined the fate of DNs, about to either die or recover, following two types (heavy and light damage) of brain insult. Wistar rats were injected ibotenic acid unilaterally into the hippocampal CA1 region (ibotenic acid [IA] injection) or were forced to swim (SWIM). Argyrophil III (DNs)-, activated caspase-3 immuno-, TUNEL- and hematoxylin-eosin (H-E)-staining and ultrastructural examinations were then performed. One to three hours after IA injection, typical DNs (argyrophilic both in somata and dendrites) with corkscrew-like dendrites were densely packed in the pyramidal cell layer of hippocampal CA1 around the injection site. After 12-24 h, DNs were argyrophilic only in the somata and proximal dendrites but absent in distal dendrites in the CA1 region. However, at this time typical DNs were found in remote areas. At 3 h, caspase-3 activation was detected at the injection site, which increased to a peak level after 12 h. Three to 7 days after injection, TUNEL positive cells were detected in the CA1 pyramidal cell layer. Immediately following SWIM, brown rather than dark neurons were detected in the various areas and most frequently in the CA1 pyramidal cell layer. No typical DNs were detected over the first 3 days. Some activation of caspase-3 was detected in a few CA3 pyramidal cells but no TUNEL-positive cells were detected. Ultrastructural examination revealed a diffuse distribution of aggregated silver particles in the dendrites and cytoplasm of pyramidal cells at the sites of IA injection. After SWIM, silver particles were detected mainly on mitochondria of affected cells. These data suggest that DNs provide a measure of neuronal damage: typically dark neurons with broad damage to the cytoskeleton of dendrites would die, while non-typical brown neurons, that may have a disturbance in mitochondria, predominantly survive.

Oral administration of metal chelator ameliorates motor dysfunction after a small hemorrhage near the internal capsule in rat

Cerebral hemorrhage leads to local production of free iron, radicals, cytokines, etc. To investigate whether a decrease of iron‐mediated radical production influences functional recovery after intracerebral hemorrhage (ICH), a modified ICH rat model with a small hemorrhage near the internal capsule (IC) accompanied with relatively severe motor dysfunction was first developed. Then clioquinol (CQ), an iron chelator that reduces hydroxyl radical production, was orally administrated. Injection of different doses of Type IV collagenase (1.4 μl 1–200 U/ml) into the left striatum near the IC in Wistar rats showed that injection of 7.5 U/ml collagenase resulted in a small hemorrhoidal lesion near the IC with relatively severe motor dysfunction (IC model). Retrograde labeling of neurons in the sensory‐motor cortex and axons in the corticospinal tract using Fluoro‐gold (FG) injection into the spinal cord (C3–C4) showed that few labeled neurons in the sensory‐motor cortex were detected in the IC model, FG‐labeled axons disappeared, and FG‐including ED‐1‐positive cells appeared within 24 hr in the IC. Assessments of behavior and histologic analysis after oral administration of CQ in the IC model indicated that oral administration of CQ prevented a decrease of FG‐labeled neurons, and resulted in better motor‐function recovery. CQ inhibited hydrogen peroxide‐induced cell toxicity in oligodendrocytes in vitro, but not in neurons. Our data suggests that CQ ameliorated motor dysfunction after a small hemorrhage near the IC by a mechanism that is related to reduction of chain‐reactive hydroxyl radical production in oligodendrocytes.

6-Hydroxydopamine-induced lesions in a rat model of hemi-Parkinson's disease monitored by magnetic resonance imaging

Injection with 6-hydroxydopamine (6-OHDA) into the nigrostriatal pathway results in loss of nigrostriatal dopaminergic neurons, which has been used widely as an animal model of Parkinsons disease. In the present study, location and extent of lesions 1 day after 6-OHDA injections (2, 4, 8, or 16 microg as a free base) in the substantia nigra (SN) were evaluated in rats by T(2)-weighted magnetic resonance imaging (MRI). The changes in MRI were also compared to immunohistochemical and behavioral changes. Hyperintense area in MRI was found at the region corresponding to 6-OHDA injection in a dose-dependent manner and was accompanied by a loss of tyrosine hydroxylase (TH)-positive cells. The shape of hyperintense area in the SN appeared to be composed of two components (i.e., circular and longitudinal regions). Administration of a larger dose of 6-OHDA (8-16 microg) was accompanied by an increase in hyperintense area and loss of TH-positive cells beyond the SN. The hyperintense area was observed on the first and third days after 6-OHDA injection, but the size and intensity declined to near normal levels on the ninth day. Rotational behavior induced by methamphetamine reached maximal levels at 4 microg 6-OHDA, and the behavior was maintained with doses up to 16 microg of 6-OHDA. Intrastriatal injection with 6-OHDA was less effective. These results suggest that MRI provides highly valuable information for verifying the size and location of intended lesions as well as for determining the optimal dose of neurotoxins in individual animals.

Melatonin-secreting pineal gland: a novel tissue source for neural transplantation therapy in stroke.

Chronic systemic melatonin treatment attenuates abnormalities produced by occlusion of middle cerebral artery (MCA) in adult rats. Because the pineal gland secretes high levels of melatonin, we examined in the present study whether transplantation of pineal gland exerted similar protective effects in MCA-occluded adult rats. Animals underwent same-day MCA occlusion and either intrastriatal transplantation of pineal gland (harvested from 2-month-old rats) or vehicle infusion. Behavioral tests (from day of surgery to 3 days posttransplantation) revealed that transplanted stroke rats displayed significantly less motor asymmetrical behaviors than vehicle-infused stroke rats. Histological analysis at 3 days posttransplantation revealed that transplanted stroke rats had significantly smaller cerebral infarction than vehicle-infused rats. Additional experiments showed that pinealectomy affected transplantation outcome, in that transplantation of pineal gland only protected against stroke-induced deficits in stroke animals with intact pineal gland, but not in pinealectomized stroke rats. Interestingly, nonpinealectomized vehicle-infused stroke rats, as well as pinealectomized transplanted stroke rats, had significantly lower melatonin levels in the cerebrospinal fluid than nonpinealectomized transplanted stroke rats. We conclude that intracerebral transplantation of pineal gland, in the presence of host intact pineal gland, protected against stroke, possibly through secretion of melatonin.

Signal transmission from the suprachiasmatic nucleus to the pineal gland via the paraventricular nucleus: analysed from arg-vasopressin peptide, rPer2 mRNA and AVP mRNA changes and pineal AA-NAT mRNA after the melatonin injection during light and dark periods.

Arg-vasopressin (AVP) containing neurons are one of the output paths from the suprachiasmatic nucleus (SCN), the center of the biological clock. AVP mRNA transcription is controlled by a negative feedback loop of clock genes. Circadian rhythm of melatonin release from the pineal gland is regulated by the SCN via the paraventricular nucleus (PVN). To clarify the transduction system of circadian signals from the SCN to the pineal gland, we determined the effects of melatonin injection (1 mg/kg, i.p.) during light and dark periods on Per2 and AVP mRNAs in the SCN and PVN, in addition to arylalkylamine N-acetyltransferase (AA-NAT) and inducible cAMP early repressor (ICER) mRNAs in the pineal gland of rats using RT-PCR. AVP peptide contents were also measured in the SCN and PVN. AVP content in the SCN decreased during the light period, while no changes were observed in the PVN. In the SCN, Per2 mRNA increased during both light and dark periods. In the PVN, Per2 decreased during the light period and increased during the dark period at 180 min after melatonin injection. In the pineal gland, Per2 mRNA increased between 60 and 180 min after the melatonin injection during the light period, while it did not significantly change during the dark period. The AA-NAT mRNA varied similar to the Per2 mRNA changes. These results might suggest that the different responses to melatonin in the pineal gland during the light and dark periods was originated in the changes of Per2 in the PVN via SCN.

Neurodegeneration of substantia nigra accompanied with macrophage/microglia infiltration after intrastriatal hemorrhage.

Intrastriatal hemorrhage in rats causes neurodegenaration of the substantia nigra (SN) followed by the appearance of ED1(+) cells (macrophage/microglia). ED1(+) cells were observed for at least 8 weeks after hemorrhage. Phosphorylation of p38 mitogen-activated protein kinase (MAPK) was shown in ED1(+) cells with the expression of both brain-derived neurotrophic factor (BDNF) mRNA and BDNF, suggesting that activated-p38 MAPK(+)/ED1(+) cells would produce BDNF and may exhibit trophic effect on the degenerating neurons in the SN. However, in ELISA, BDNF protein decreased significantly in ipsilateral SN at 7 days after hemorrhage, which may be due to a dramatic decrease of BDNF immunoreactive neurons in pars compacta. Data suggest that activation of p38 MAPK in ED1(+) cells infiltrating in ipsilateral SN after hemorrhage may produce BDNF, but that the amount of BDNF produced from ED1(+) cells is insufficient for the rescue of degenerating neurons.