Structural alterations of spiny stellate cells in the somatosensory cortex in ephrin‐A5‐deficient mice

Previous studies demonstrated that in ephrin‐A5‐deficient mice corticothalamic arbors are reduced by more than 50% in layer 4 of the somatosensory cortex (S1), where ephrin‐A5 is normally expressed. Here we examined possible consequences of the reduced thalamic input on spiny stellate cells, the target neurons of thalamocortical afferents. Using ballistic delivery of particles coated with lipophilic dyes in fixed slices and confocal laser‐microscopy, we could quantitatively analyze the morphology of these neurons. Cells were examined in S1 at postnatal day 8 (P8), when thalamic afferents establish synaptic contacts and the dendrites of their target cells are covered with filopodia, and at P23, after synapse formation and replacement of filopodia by spines. Our results indicate that at P8 the dendrites of cells in mutant animals exhibit more filopodia and are more branched than dendrites of wildtype cells. In contrast, there is no difference in the extent of the dendritic tree between knockout and control animals. At P23, dendrites of neurons in ephrin‐A5‐deficient mice are still more branched, but possess fewer spines than wildtype cells. Thus, at early stages layer 4 neurons appear to compensate the reduced thalamic input by increasing dendritic branching and the density of filopodia. However, while at later stages the dendrites of layer 4 neurons in mutants are still more branched, their spine density is now lower than in wildtype cells. Taken together, these data demonstrate that the structure of spiny stellate cells is shaped by thalamic input and Eph receptor signaling. J. Comp. Neurol. 517:645–654, 2009. © 2009 Wiley‐Liss, Inc.     

Quantitative morphometry of electrophysiologically identified CA3b interneurons reveals robust local geometry and distinct cell classes

The morphological and electrophysiological diversity of inhibitory cells in hippocampal area CA3 may underlie specific computational roles and is not yet fully elucidated. In particular, interneurons with somata in strata radiatum (R) and lacunosum‐moleculare (L‐M) receive converging stimulation from the dentate gyrus and entorhinal cortex as well as within CA3. Although these cells express different forms of synaptic plasticity, their axonal trees and connectivity are still largely unknown. We investigated the branching and spatial patterns, plus the membrane and synaptic properties, of rat CA3b R and L‐M interneurons digitally reconstructed after intracellular labeling. We found considerable variability within but no difference between the two layers, and no correlation between morphological and biophysical properties. Nevertheless, two cell types were identified based on the number of dendritic bifurcations, with significantly different anatomical and electrophysiological features. Axons generally branched an order of magnitude more than dendrites. However, interneurons on both sides of the R/L‐M boundary revealed surprisingly modular axodendritic arborizations with consistently uniform local branch geometry. Both axons and dendrites followed a lamellar organization, and axons displayed a spatial preference toward the fissure. Moreover, only a small fraction of the axonal arbor extended to the outer portion of the invaded volume, and tended to return toward the proximal region. In contrast, dendritic trees demonstrated more limited but isotropic volume occupancy. These results suggest a role of predominantly local feedforward and lateral inhibitory control for both R and L‐M interneurons. Such a role may be essential to balance the extensive recurrent excitation of area CA3 underlying hippocampal autoassociative memory function. J. Comp. Neurol. 515:677–695, 2009. © 2009 Wiley‐Liss, Inc.     

Corticosterone reduces dendritic complexity in developing hippocampal CA1 neurons

Although prolonged stress and corticosteroid exposure induce morphological changes in the hippocampal CA3 area, the adult CA1 area is quite resistant to such changes. Here we addressed the question whether elevated corticosteroid hormone levels change dendritic complexity in young, developing CA1 cells. In organotypic cultures (prepared from P5 rats) that were 14–21 days cultured in vitro, two doses of corticosterone (30 and 100 nM) were tested. Dendritic morphology of CA1 neurons was established by imaging neurons filled with the fluorescent dye Alexa. Application of 100 nM corticosterone for 20 minutes induced atrophy of the apical dendritic tree 1–4 hours later. Fractal analysis showed that total neuronal complexity was reduced twofold when compared with vehicle‐treated neurons. Exposing organotypic slices to 30 nM corticosterone reduced apical length in a more delayed manner: only neurons examined more than 2 hours after exposure to corticosterone showed atrophy of the apical dendritic tree. Neither dose of corticosterone affected the length of basal dendrites or spine density. Corticosterone was ineffective in changing morphology of the apical dendrites when tested in the presence of the glucocorticoid receptor antagonist RU38486. These results suggest that high physiological levels of corticosterone, via activation of the glucocorticoid receptor, can, during the course of only a few hours, reduce the dendritic complexity of CA1 pyramidal neurons in young, developing hippocampal tissue. These findings suggest that it is relevant to maintain plasma corticosterone levels low during hippocampal development. © 2009 Wiley‐Liss, Inc.     

Alterations in dendritic morphology of the prefrontal cortical and striatum neurons in the unilateral 6-OHDA-rat model of Parkinson's disease

We have studied the morphological changes of the dendrites of the pyramidal neurons of the prefrontal cortex (PFC) and the medium spiny neurons of the caudate-putamen (CPu) and nucleus accumbens (NAcc) induced by the injection of 6-hydroxydopamine (6-OHDA) into the substantia nigra pars compacta (SNc). The unilateral 6-OHDA-induced lesion of the SNc was made in Wistar rats to produce the Parkinson model lesion. Two weeks after the injection, the testing of rotational behavior caused by amphetamine injection was done to assess the animals with lesions. Four weeks after the 6-OHDA injection, the morphology of the pyramidal cells of Layer 5 of the PFC and the medium spiny neurons of the CPu and NAcc were quantified by modified Golgi-Cox staining. The results showed that the length of dendrites, the branching, and the density of dendritic spines on the medium spiny neurons of the same side of the caudate-putamen lesion were significantly decreased in rats with the unilateral 6-OHDA-induced lesion of the SNc. The pyramidal neurons of the PFC and medium spiny neurons of the NAcc showed a decrease in the density of dendritic spines without significant changes in dendritic length or arborization. Our data suggest that the SNc lesion with the 6-OHDA, Hemiparkinsonism animal model may lead to altered neuronal plasticity in the CPu, NAcc, and PFC that may have participated in the emergence of the behavioral changes observed in these animals.     

Methamphetamine-induced structural plasticity in the dorsal striatum

Repeated exposure to psychostimulant drugs produces long-lasting changes in dendritic structure, presumably reflecting a reorganization in patterns of synaptic connectivity, in brain regions that mediate the psychomotor activating and incentive motivational effects of these drugs, including the nucleus accumbens and prefrontal cortex. However, repeated exposure to psychostimulant drugs also facilitates a transition in the control of some behaviors from action-outcome associations to behavior controlled by stimulus-response (S-R) habits. This latter effect is thought to be due to increasing engagement and control over behavior by the dorsolateral (but not dorsomedial) striatum. We hypothesized therefore that repeated exposure to methamphetamine would differentially alter the density of dendritic spines on medium spiny neurons (MSNs) in the dorsolateral vs. dorsomedial striatum. Rats were treated with repeated injections of methamphetamine, and 3 months later dendrites were visualized using Sindbis virus-mediated green fluorescent protein (GFP) expression in vivo. We report that prior exposure to methamphetamine produced a significant increase in mushroom and thin spines on MSNs in the dorsolateral striatum, but a significant decrease in mushroom spines in the dorsomedial striatum. This may be due to changes in the glutamatergic innervation of these two subregions of the dorsal striatum. Thus, we speculate that exposure to psychostimulant drugs may facilitate the development of S-R habits because this reorganizes patterns of synaptic connectivity in the dorsal striatum in a way that increases control over behavior by the dorsolateral striatum.     

Distinct nonuniform cable properties optimize rapid and efficient activation of fast-spiking GABAergic interneurons

Fast-spiking, parvalbumin-expressing basket cells (BCs) play a key role in feedforward and feedback inhibition in the hippocampus. However, the dendritic mechanisms underlying rapid interneuron recruitment have remained unclear. To quantitatively address this question, we developed detailed passive cable models of BCs in the dentate gyrus based on dual somatic or somatodendritic recordings and complete morphologic reconstructions. Both specific membrane capacitance and axial resistivity were comparable to those of pyramidal neurons, but the average somatodendritic specific membrane resistance (R_m) was substantially lower in BCs. Furthermore, R_m was markedly nonuniform, being lowest in soma and proximal dendrites, intermediate in distal dendrites, and highest in the axon. Thus, the somatodendritic gradient of R_m was the reverse of that in pyramidal neurons. Further computational analysis revealed that these unique cable properties accelerate the time course of synaptic potentials at the soma in response to fast inputs, while boosting the efficacy of slow distal inputs. These properties will facilitate both rapid phasic and efficient tonic activation of BCs in hippocampal microcircuits.     

UVB照射对PIG1细胞增殖活性的影响

目的：探讨UVB照射对正常人黑素细胞PIG1细胞形态及增殖活性的影响。方法：取对数生长期的PIG1细胞,分别以50、100、200、300、400、500、600和700mJ/cm2剂量的UVB照射后继续培养0h、24h和48h,在倒置显微镜下观察其形态学变化,用MTT法检测UVB照射对细胞增殖活性的影响。结果：在50～200 mJ/cm2的UVB辐射下,随辐射剂量的增大,PIG1细胞的增殖活性逐渐增加,倒置相差显微镜从形态学上证实了一定剂量的UVB照射可以促进细胞增殖。结论：一定剂量的UVB照射有刺激PIG1细胞增殖及树突生长的作用。     

Anisotropic crystalline microstructures in dendritic arborizations of dried mid-cycle cervical mucus: surface morphology and crystallographic study.

Studies using scanning electron microscopic techniques permitted characterization of the nature and structure of the anisotropic elements present in dried preparations of mid-cycle cervical mucus. Sodium and potassium sulphates were located in the dehydrated matrix either isolated or bound to the dendrites. Depending on crystallization conditions, they appeared as well-formed individual crystals or as spherulites.     

Bistratified amacrine cells in the retina of the tammar wallaby — Macropus eugenii

Summary Cajal (1911) noted that bistratified amacrine cells were common in non mammalian species and extremely rare in the mammalian retina. An examination of the marsupial retina of the tammar wallaby, stained with a modified Golgi procedure, revealed that a particular type of bistratified amacrine was frequently impregnated with the silver stain. Flat mount and transverse sections showed that the morphology of this cell did not correspond with any of the species-dependent bistratified amacrines reproduced in Cajal's drawings. Instead, the cell appeared to be almost identical to the AII or rod amacrine that has been observed in a number of mammalian retinas. The relative frequency with which the cell appears in our material, and its confirmed rod input in other species, are both consistent with the grazing habits of the tammar wallaby which is a crepuscular animal that does most of its feeding at dusk and after dark.     

In vivo two‐photon imaging of structural dynamics in the spinal dorsal horn in an inflammatory pain model

Two‐photon microscopy imaging has recently been applied to the brain to clarify functional and structural synaptic plasticity in adult neural circuits. Whereas the pain system in the spinal cord is phylogenetically primitive and easily exhibits behavioral changes such as hyperalgesia in response to inflammation, the structural dynamics of dendrites has not been analysed in the spinal cord mainly due to tissue movements associated with breathing and heart beats. Here we present experimental procedures to prepare the spinal cord sufficiently to follow morphological changes of neuronal processes in vivo by using two‐photon microscopy and transgenic mice expressing fluorescent protein specific to the nervous system. Structural changes such as the formation of spine‐like structures and swelling of dendrites were observed in the spinal dorsal horn within 30 min after the multiple‐site injections of complete Freund's adjuvant (a chemical irritant) to a leg, and these changes continued for 5 h. Both AMPA and N‐methyl‐D‐aspartate receptor antagonists, and gabapentin, a presynaptic Ca²⁺ channel blocker, completely suppressed the inflammation‐induced structural changes in the dendrites in the spinal dorsal horn. The present study first demonstrated by in vivo two‐photon microscopy imaging that structural synaptic plasticity occurred in the spinal dorsal horn immediately after the injection of complete Freund's adjuvant and may be involved in inflammatory pain. Furthermore, acute inflammation‐associated structural changes in the spinal dorsal horn were shown to be mediated by glutamate receptor activation.