Dantrolene enhances the protective effect of hypothermia on cerebral cortex neurons

Therapeutic hypothermia is the most promising non-pharmacological neuroprotective strategy against ischemic injury. However, shivering is the most common adverse reaction. Many studies have shown that dantrolene is neuroprotective in in vitro and in vivo ischemic injury models. In addition to its neuroprotective effect, dantrolene neutralizes the adverse reaction of hypothermia. Dantrolene may be an effective adjunctive therapy to enhance the neuroprotection of hypothermia in treating ischemic stroke. Cortical neurons isolated from rat fetuses were exposed to 90 minutes of oxygen-glucose deprivation followed by reoxygenation. Neurons were treated with 40 μM dantrolene, hypothermia(at 33°C), or the combination of both for 12 hours. Results revealed that the combination of dantrolene and hypothermia increased neuronal survival and the mitochondrial membrane potential, and reduced intracellular active oxygen cytoplasmic histone-associated DNA fragmentation, and apoptosis. Furthermore, improvements in cell morphology were observed. The combined treatment enhanced these responses compared with either treatment alone. These findings indicate that dantrolene may be used as an effective adjunctive therapy to enhance the neuroprotective effects of hypothermia in ischemic stroke.     

A potent protective role of lysophospholipids against global cerebral ischemia and glutamate excitotoxicity in neuronal cultures.

Lysophospholipids (LPLs) are important intermediates in the synthesis and degradation of membrane phospholipids. Here we show that certain LPLs, particularly lysophosphatidylcholine and lysophosphatidylinositol, prevent neuronal death both in an in vivo model of transient global ischemia and in an in vitro model of excitotoxicity using primary cultures of cerebellar granule cells exposed to high extracellular concentrations of glutamate (20-40 micromol/L). The intravenous injection of lysophosphatidylcholine or lysophosphatidylinositol at a concentration of 200 nmol/kg induced a survival of CA1 pyramidal neurons as high as approximately 95%, even when the treatment was started 30 minutes after 15-minute global ischemia. In contrast, lysophosphatidic acid induced no protection. This work also provides evidence that a pretreatment with lysophosphatidylcholine or lysophosphatidylinositol (200 nmol/kg) injected as long as 3 days before a severe 6-minute ischemia provided a potent tolerance against neurodegeneration. Neuroprotection was also observed in in vitro experiments with LPLs. Taken together, in vivo and in vitro data suggest a potential therapeutic use of LPLs as antiischemic compounds. The potential role of 2P-domain K+ channels as targets of LPLs in this potent neuroprotective effect is discussed.     

A unique subpopulation of Tbr1-expressing deep layer neurons in the developing cerebral cortex

Cells of the subplate (SP) and deep cortical plate (CP) are among the pioneer neurons of the developing cerebral cortex, an important group of early-born cells that impact cortical organization and function. Similarities between pioneer neurons in different cortical positions and heterogeneities in pioneer cells in the same cortical location, however, have made it difficult to appreciate the characteristics and functions of particular sets of these cells. Here, we provide a tool to illuminate a unique subset of SP and deep CP neurons: expression of a Tbrain-1 (Tbr1)-driven transgene. Transgene-expressing cells were consistently positive for neuronal but not glial markers, were born early in corticogenesis, representing just a subset of SP and deep CP neurons, were morphologically complex during the formation of the cortex, and were maintained into maturity. This analysis reveals a novel group of pioneer neurons and demonstrates unrecognized diversity within this cortical population. In the future, this information will help to uncover the roles of discrete pioneer populations in cortical development.     

A unique subpopulation of Tbr1-expressing deep layer neurons in the developing cerebral cortex

Cells of the subplate (SP) and deep cortical plate (CP) are among the pioneer neurons of the developing cerebral cortex, an important group of early-born cells that impact cortical organization and function. Similarities between pioneer neurons in different cortical positions and heterogeneities in pioneer cells in the same cortical location, however, have made it difficult to appreciate the characteristics and functions of particular sets of these cells. Here, we provide a tool to illuminate a unique subset of SP and deep CP neurons: expression of a Tbrain-1 (Tbr1)-driven transgene. Transgene-expressing cells were consistently positive for neuronal but not glial markers, were born early in corticogenesis, representing just a subset of SP and deep CP neurons, were morphologically complex during the formation of the cortex, and were maintained into maturity. This analysis reveals a novel group of pioneer neurons and demonstrates unrecognized diversity within this cortical population. In the future, this information will help to uncover the roles of discrete pioneer populations in cortical development.     

Fibronectin-like immunoreactivity in the developing cerebral cortex

In the developing cerebral cortex of the mouse, binding of antibodies directed against the extracellular matrix glycoprotein fibronectin occurs with a distinct temporal and spatial pattern. On the 10th embryonic day (E10), when the wall of the telencephalic vesicle is made up of only the proliferating cells of the ventricular zone, antifibronectin (aFN) binding is restricted to the blood vessels and pia-arachnoid. Fibronectin-like immunoreactivity first appears in the neuropil as small points of immunofluorescence among the earliest postmitotic neurons that form the preplate (E11-12). A short time later (E12-13), aFN immunoreactivity becomes more diffuse but continues to be restricted to the preplate. As newly arriving neurons form the cortical plate within the preplate (E13-14), aFN binding is present in the marginal zone above the cortical plate and in the subplate below it. Both the marginal zone and the subplate contain early afferents and the cells that were previously part of the preplate. Binding of aFN is transient; by E18-19 it has diminished to the point where it is no longer detectable except in the blood vessels and pia-arachnoid. The transient appearance of fibronectin-like immunostaining in the zones that contain early cortical afferents suggests that fibronectin plays a role in forming the migratory pathway for the growth cones of these axons. In this role it may be acting in concert with other extracellular matrix components such as hyaluronectin, glycosaminoglycans, and laminin, which have been shown to have similar spatial distributions.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of cycloheximide on natural and X-ray-induced cell death in the developing cerebral cortex.

Naturally occurring cell death in the cerebral cortex and subcortical white matter is increased after X-irradiation, and this process is curbed with cycloheximide, an inhibitor of protein synthesis. However, cycloheximide alone increases cell death during development, and this effect is dose-dependent. This suggests that, in both normal and experimentally-induced cortical cell death during development, different proteins are activated or inhibited, depending on the agent, the time of its application, and the previous metabolic or functional state of the cell.     

In vivo studies on the protective role of minocycline against excitotoxicity caused by malonate or N-methyl-d-aspartate

Minocycline has been shown to exert neuroprotection against a wide variety of toxic insults both in vitro and in vivo. However, contradictory results have recently been reported. We now report that minocycline affords no protection against the neurotoxicity caused by malonate or N-methyl-d-aspartate (NMDA). Rats were treated with minocycline (45 mg/kg i.p. x 7) every 12 h. Thirty minutes after the second dose of minocycline, an intrastriatal stereotaxic injection of malonate (1.5 mumol) or NMDA (0.1 mumol) was administered. Seven days later, the rats were killed, and lesion volumes were quantified using two different methods [triphenyltetrazolium chloride (TTC) staining or cytochrome oxidase histochemistry]. Our results show that minocycline does not prevent the lesions caused by either malonate or by NMDA. On the contrary, the putative NMDA receptor antagonist, MK-801, blocked the toxicity caused by both toxins indicating that, although by different mechanisms, excitotoxicity is mediating neuronal death. We conclude that minocycline, at least under our experimental conditions, is not neuroprotective against excitotoxicity caused by either malonate or NMDA.     

Control of astrocyte migration in the developing cerebral cortex

Development of the vertebrate central nervous system is characterized by significant long distance cell migration. While the radial migration of neuronal precursors to their final location is well established the migration of glial cells and their precursors is less well understood. To define the pathways of migration and dissect the cell and molecular mechanisms mediating such migration requires the development of appropriate models. Here we show that purified neonatal astrocytes injected into organotypic slice cultures of developing cerebral cortex migrate in defined patterns depending on where they are placed within the tissue. Injection into gray matter resulted in radially oriented migration either towards the pial or ventricular surface. By contrast injection into developing white matter resulted in largely longitudinal migration along developing axon tracts. While the cytoarchitecture of the tissue influenced the pattern of migration, the extent of migration appeared to be regulated primarily by the age of the host tissue. Homochronic injections performed prior to postnatal day 4 resulted in extensive migration while after day 7 migration was relatively limited. Heterochronic injections indicated that while astrocytes within the 1st postnatal week retained the capacity to migrate extensively, older tissue failed to support extensive migration of either young or old astrocytes. These data suggest the existence of distinct migrational cues in the CNS and that environmental, not cell intrinsic properties primarily regulate astrocyte migration through the developing cortex.     

The protective effect of fish n-3 fatty acids on cerebral ischemia in rat prefrontal cortex

This study presents neuroprotective effects of fish n-3 EFA on the prefrontal cortex after cerebral ischemia and reperfusion. Eighteen rats divided into three groups. Group A rats were used as control. Cerebral ischemia and reperfusion was produced in rats either on a standard diet (Group B) or a standard diet plus fish n-3 EFA for 14 days (Group C). The malondialdehyde (MDA) levels and activities of superoxide dismutase (SOD) and catalase (CAT) were measured and the number of apoptotic neurons was counted. The levels of MDA and activities of SOD increased in Group B rats as compared to Group A rats, and decreased in Group C rats as compared to Group B rats. The activities of CAT increased in Group C as compared to Group B rats. The number of apoptotic neurons in the prefrontal cortex was lower in Group C as compared to Group B rats.     

Morphological heterogeneity of layer VI neurons in mouse barrel cortex

Understanding the basic neuronal building blocks of the neocortex is a necessary first step toward comprehending the composition of cortical circuits. Neocortical layer VI is the most morphologically diverse layer and plays a pivotal role in gating information to the cortex via its feedback connection to the thalamus and other ipsilateral and callosal corticocortical connections. The heterogeneity of function within this layer is presumably linked to its varied morphological composition. However, so far, very few studies have attempted to define cell classes in this layer using unbiased quantitative methodologies. Utilizing the Golgi staining technique along with the Neurolucida software, we recontructed 222 cortical neurons from layer VI of mouse barrel cortex. Morphological analyses were performed by quantifying somatic and dendritic parameters, and, by using principal component and cluster analyses, we quantitatively categorized neurons into six distinct morphological groups. Additional systematic replication on a separate population of neurons yielded similar results, demonstrating the consistency and reliability of our categorization methodology. Subsequent post hoc analyses of dendritic parameters supported our neuronal classification scheme. Characterizing neuronal elements with unbiased quantitative techniques provides a framework for better understanding structure–function relationships within neocortical circuits in general. J. Comp. Neurol. 512:726–746, 2009. © 2008 Wiley‐Liss, Inc.     

Sublaminar organization within layer VI of the striate cortex in Galago.

In this study we examined the organization of projections from the striate cortex to the dorsal lateral geniculate (GL) and pulvinar (PUL) nuclei in the prosimian Galago by using retrograde transport methods. Injections of wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) into the PUL labeled two bands of cells in the striate cortex: the first consisted of large pyramidal cells in the upper half of layer V; the second consisted of small and medium-size pyramidal cells located in the deepest part of layer VI. The location of cells within layer VI coincided with a clear cytoarchitectonic sublayer, VIb, which contains fewer and paler staining cells than VIa. Injections of WGA-HRP involving all layers of the GL produced an uninterrupted band of pyramidal cells distributed throughout layer VI (a and b), including the region labeled after injections into the PUL. Thus as a first approximation, layer VI can be divided into an upper tier (VIa) that projects only to the GL and a lower tier (VIb) that projects to both the GL and PUL. Injections of WGA-HRP that were restricted to one or a few GL layers revealed a further refinement of the subdivisions within layer VI. Injections into the parvicellular and intercalated (or koniocellular) layers of the GL labeled neurons predominantly in the upper half of layer VIa, whereas injections restricted to the magnocellular layers labeled neurons in the lower half of layer VIa and in layer VIb. In order to determine whether individual neurons in layer VIb send axon collaterals to both the GL and PUL, we injected WGA-HRP into one nucleus and fluorescent rhodamine latex beads into the other. In three experiments, we found only one double-labeled cell. In sum, the results provide evidence that layer VI is divided into at least three sublayers: upper VIa, which projects to the intercalated and parvicellular GL layers; lower VIa, which projects to the magnocellular GL layers; and VIb, which sends separate projections to the magnocellular layers of the GL and to the PUL. The segregation observed is sufficiently discrete to propose the existence of multiple, descending pathways from layer VI of the striate cortex that complement those ascending from the GL and PUL.     

Bicommissural neurones in the cerebral cortex of developing hamsters.

The trajectory, developmental time course, and origin of callosal fibres that recross through the anterior commissure were studied in developing hamsters, using carbocyanines in fixed brains on different ages. The bicommissural fibres were found in hamsters from E15 through P7, but disappeared after P7. By double labelling it was found that the neurones of origin of these bicommissural fibres were located in the lateral cortex within the region where the callosal zone of origin overlaps that of the anterior commissure. From these experiments, it was concluded that the axons of a group of cells in the lateral cortex of developing rodents are branched and grow transiently through both the callosum and the anterior commissure.     

Antiapoptotic effect of taurine against NMDA-induced retinal excitotoxicity in rats

ObjectiveN-methyl-D-aspartate (NMDA) excitotoxicity has been proposed to mediate apoptosis of retinal ganglion cells (RGCs) in glaucoma. Taurine (TAU) has been shown to have neuroprotective properties, thus we examined anti-apoptotic effect of TAU against retinal damage after NMDA exposure.MethodologySprague-Dawley rats were divided into 5 groups of 33 each. Group 1 was administered intravitreally with PBS and group 2 was similarly injected with NMDA (160 nmol). Groups 3, 4 and 5 were injected with TAU (320 nmol) 24 hours before (pre-treatment), in combination (co-treatment) and 24 hours after (post-treatment) NMDA exposure respectively. Seven days after injection, rats were sacrificed; eyes were enucleated, fixed and processed for morphometric analysis, TUNEL and caspase-3 staining. Optic nerve morphology assessment was done using toluidine blue staining. The estimation of BDNF, pro/anti-apoptotic factors (Bax/Bcl-2) and caspase-3 activity in retina was done using ELISA technique.ResultsSevere degenerative changes were observed in retinae after intravitreal NMDA exposure. The retinal morphology in the TAU pre-treated group appeared more similar to the control retinae and demonstrated a higher number of nuclei than the NMDA group both per 100 μm length (by 1.5-fold, p < 0.001) and per 100 μm² area (by 1.41-fold, p < 0.05) of the GCL. After NMDA exposure, visible axonal swelling was observed in optic nerve sections. In comparison with the changes observed in the NMDA treated group, the TAU treated group showed fewer prominent changes; axonal swelling was less frequent and less marked. Additionally, no marked glial cell changes were observed in the TAU-pretreated group. All TAU treated groups, particularly the pre-treated group, showed a significant decrease in the NMDA-induced optic nerve damage, with a 50% reduction (p < 0.001) in the mean grading compared to NMDA group. For the same, there was 25% decrease in co- and post-treatment groups, as compared with the NMDA group. Pre-treatment with TAU abolished apoptotic response to NMDA as indicated by decrease in the number of TUNEL- and caspase-3-positive cells. TAU pre-treatment also increased the Bcl-2 level (by 2.80-fold, p < 0.001) and decreased the level of Bax (by 34%, p < 0.01), and activity of caspase-3 (by 36%, p < 0.001) compared to NMDA group.In conclusionour study revealed that pre-treatment with TAU prevents NMDA-induced retinal cell apoptosis more effectively than co- and post-treatment with TAU.     

Neurons in layer I of the developing occipital cortex of the rat

This paper describes the neurons in layer I of the rat occipital cortex, and traces postnatal changes in the numbers and morphology of the different cell types therein. Golgi-Cox and Nissl material from adults and from 0.5, 2, 4, 6, 8, 10, 11,12, 13, 14, 15, 16, 18, 20, 24, 28 and 35 day-old rats, was utilized. Horizontal, vertical and classical non-pyramidal cells and cells without axons were recognized. Horizontal cells included foetal horizontal cells (Retzius-Cajal cells) and persisting horizontal cells. The former were fully differentiated and numerous at birth and were bipolar, with dendrite and axon extending from opposite poles, and fine ascending (verticle) branches. Some such cells possessed two axons. Almost all degenerated and disappeared over the first two to three postnatal weeks. An analogy with Rohon-Beard cells is drawn and it is suggested that these cells receive an early input which is subsquently withdrawn and/or concentrated cells receive an early input which is subsequently withdrawn and/or concentrated on cells in deeper layers. There is no evidence of transformation of foetal to persisting horizontal cells, which are not numerous and most commonly give rise to two dendrites from opposite perikaryal poles. Vertical cells, with spinous dendrites and descending axons, differentiate and reach adult numbers by the end of the first postnatal week. Classical non-pyramidal cells include spinous and spine-free varieties, resemble those in deeper layer, and are mature by the end of the third postnatal week. In the upper stratum of layer I are small number of cells without axons.     

The effect of prenatal X-irradiation on the developing cerebral cortex of rats. II: A quantitative assessment of glial cells in the somatosensory cortex

The developing central nervous system is known to be highly vulnerable to X-irradiation. Although glial cells are involved in various brain functions, knowledge on the effects of X-irradiation on glial cells is limited. Therefore, the purpose of the present study was to evaluate the effects of prenatal X-irradiation on glial cells. Pregnant Wistar rats were exposed to X-irradiation at a dose of 1.0 Gy on day 15 of gestation. Their offspring were examined at 7 weeks of age. The forebrain weight of X-irradiated rats was significantly lower than that of the age-matched controls. Histological quantification with stereology of the somatosensory cortex (SC) revealed no significant difference in the numerical density of glial cells between the X-irradiated and control rats. However, the glial cells in the X-irradiated animals had significantly larger nuclear size. We had previously reported that a similar X-irradiation paradigm resulted in no significant change in the numerical density of neurons in the SC. According to the results of the present study, there were no significant differences in the glial cell-to-neuron ratios between the X-irradiated and control animals. Taken together, it is speculated that prenatal X-irradiation has an equal effects on the numerical densities of glial cells and neurons.     

Cytoplasmic basophilia in the nerve cells of the cerebral cortex. VI. The human temporal cortex

An attempt is made to evaluate the metabolic functional pattern in the nerve cells of a human temporal lobe by determining the cytoplasmic basophilia. Following gallocyanin staining (RNA staining), the extinction is measured at two points in each cell by means of a cytophotometer at 570 nm. The section thickness is determined, and measurements are made only on those cells which are known with certainty to be cut in both section surfaces. A total of 2000 cells is measured, distributed throughout five sites over the temporal lobe. In each layer, mean extinction values are found which do not deviate significantly from each other in the regions measured. The results are compared with previous findings from the frontal lobe of the same brain, and the conclusion is reached that the distribution of chromophobic, chromophilic and chromoneutral cells must be taken as expressing the fact that a majority of cells are in moderate activity, and that two small groups are in a somewhat greater metabolic activity. The distribution pattern is the same in different regions of the isocortex, possibly a result of the intimate communications characteristic of the cerebral cortex.     

VEGF对缺血脑组织微血管再生作用的实验研究

目的 本文讨论外源性VEGF对兔局灶脑缺血后缺血脑组织血管再生的作用。方法缺血后1hVEGF(165)右侧侧脑室注射(0.5μg／kg体重)，CD34免疫组化测脑组织微血管密度(MVD)，脑组织含水率评价脑水肿情况。结果 缺血5d后，VEGF组MVD明显高于对照组，脑组织含水率则对照组高于VEGF组。结论 VEGF可能有直接的促进缺血脑组织血管再生作用。