Effect of visual deprivation on evoked potentials in the visual cortex and superior colliculus in rabbits

Evoked potentials arising in the visual cortex and superior colliculus to stimulation of the collateral eye by single, paired, and repetitive flashes were recorded in rabbits reared in darkness or in normal illumination. The absence of significant change in the latent period and amplitudes of the first two components of the collicular responses and of the recovery cycle and response to repetitive stimulation in the light-deprived animals suggest that photic stimulation does not affect the normal functional development of the rabbit retinotectal system. However, functional deafferentation in the early postnatal period gives rise to serious disturbances of visual cortical function, as reflected in a marked decrease in amplitude of the primary response, lengthening of the recovery cycle, and narrowing of the range of rhythm-binding frequencies of flashes. These disturbances were reversible. The period of maximal sensitivity of the rabbit retinocortical system to visual deprivation begins at the end of the first month of postnatal life. The possible mechanisms lying at the basis of these functional disturbances in light-deprived animals are discussed.     

Sleep deprivation induces the unfolded protein response in mouse cerebral cortex

Little is known about the molecular mechanisms underlying sleep. We show the induction of key regulatory proteins in a cellular protective pathway, the unfolded protein response (UPR), following 6 h of induced wakefulness. Using C57/B6 male mice maintained on a 12:12 light/dark cycle, we examined, in cerebral cortex, the effect of different durations of prolonged wakefulness (0, 3, 6, 9 and 12 h) from the beginning of the lights-on inactivity period, on the protein expression of BiP/GRP78, a chaperone and classical UPR marker. BiP/GRP78 expression is increased with increasing durations of sleep deprivation (6, 9 and 12 h). There is no change in BiP/GRP78 levels in handling control experiments carried out during the lights-off period. PERK, the transmembrane kinase responsible for attenuating protein synthesis, which is negatively regulated by binding to BiP/GRP78, is activated by dissociation from BiP/GRP78 and by autophosphorylation. There is phosphorylation of the elongation initiation factor 2alpha and alteration in ribosomal function. These changes are first observed after 6 h of induced wakefulness. Thus, prolonging wakefulness beyond a certain duration induces the UPR indicating a physiological limit to wakefulness.     

Experimental alcoholism in rats: protein synthesis in subcellular fractions from cerebellum, cerebral cortex and liver after long term treatment

Abstract— The incorporation in vivo of [³H]leucine into protein from subcellular fractions was determined in rats chronically ingesting 15 per cent ethanol for 8 months. Mitochondrial, microsomal and cell sap fractions from cerebellum, cortex cerebri and liver were investigated. The results showed a minor over-all depression of protein synthesis in cerebellum and cortex cerebri and a slight stimulation of the incorporation of leucine into protein from liver subcellular fractions. If the animals were abstinent 24 h before injection of the isotope, the incorporation of labelled amino acids into protein was markedly increased in cerebellum and cerebral cortex but not in liver.     

Nuclear and cytoplasmic RNA in visual cortex neurons of adult rats following visual deprivation and photic stimulation

It has been shown by two-wavelength cytospectrophotometry of gallocyanin-chrome alum-stained sections that visual deprivation in adult rats kept in a complete darkness for 30 days resulted in an accumulation of cytoplasmic RNA by layer V neurons of the visual cerebral cortex and by the cells of the perineuronal neuroglia of this layer. The nuclear RNA content remained unchanged. Stimulation of intact rats with a flickering or constant light induced an increase in the cytoplasmic RNA in these neurons rather than in the nuclear RNA as well as in RNA in their glial satellite cells. Similar light stimulation of the deprived animals gave rise to a complete return of the neuronal RNA to normal with only a slight decrease in the deprivation-induced RNA accumulation by the neuroglial cells. Neither visual deprivation nor light stimulation affected the RNA content in the neurons and neuroglia of layer V of the motor cerebral cortex. Compartmentation of RNA metabolism within the neuronal-neuroglial unit is discussed.     

Effect of motor deprivation in early ontogeny on evoked potentials of the sensomotor and visual cortex in the rat

The influence of long-term (3 months) locomotor deprivation of rats in a month age, on the evoked potentials (EP) of the sensorimotor and the visual cortex was studied in conditions of presentation of single and paired stimuli. Changes were revealed in both cortical zones. An increase of peak latency of the initial positive EP phase in the sensorimotor cortex, and prolongation of the process of changes in excitability of neural elements, elicited by conditioning stimulus, was revealed both in the sensorimotor and the visual areas. The effect of deprivation on the dynamics of changes in neuronal systems excitability was greater in the visual evoked responses.     

吡哆胺对糖尿病大鼠视皮质AGE-RAGE系统的影响

目的观察吡哆胺对糖尿病大鼠视皮质高级糖基化终末产物(AGE)及其受体(RAGE)表达的影响,探讨吡哆胺对视皮质的保护作用。方法健康SD大鼠随机分为正常对照组(NC组)、糖尿病未治疗组(DM组)、糖尿病吡哆胺治疗组(PM组)和氨基胍治疗对照组(AG组)各20只,用链脲佐菌素(STZ)建立糖尿病模型,PM组和AG组分别于造模成功后第二天开始予吡哆胺和氨基胍灌胃。各组于治疗4w和12w后取材,用酶联免疫吸附(ELISA)法定量检测大鼠视皮质中AGEs含量,荧光免疫组化及图像分析半定量检测各组视皮质RAGE的表达。结果糖尿病治疗组和未治疗组血糖无显著性差异。4w时各组AGEs含量无明显差异,12w时PM组视皮质中AGEs含量与AG组、NC组比较差异无统计学意义,与DM组相比显著降低,差异具有统计学意义(P0.05)。PM组视皮质中RAGE表达比DM组显著减少,差异具有统计学意义(P0.05),但高于NC组(P0.05)。结论糖尿病大鼠12w后视皮质中AGEs含量和RAGE的表达高于正常对照组,吡哆胺类似氨基胍可减少AGEs的堆积,还能抑制RAGE的表达,减轻AGEs-RAGE通路作用导致的组织损伤,对视皮质具有一定的保护作用。     

Effect of visual deprivation on neurotransmitter receptor development in the rat visual system

The effect of monocular deprivation (covering one eye on the 11th posnatal day) and rearing in darkness (the animals were born, developed, and killed with total exclusion of light) on development of -adrenergic, serotoninergic, muscarinic cholinergic, glutamatergic, and benzodiazepine receptors in primary visual structures (visual cortex, lateral geniculate body, superior colliculus, and retina) was investigated in rats. For quantitative analysis of neurotransmitter receptors, the technique of ligand binding was used. It was shown that monocular deprivation affects the development of -adrenergic, serotoninergic, and glutaminergic receptors mainly in the lateral geniculate body and retina, whereas rearing in darkness affects mainly the development of serotoninergic receptors in the superior colliculus. The development of receptors of the cholinergic neurotransmitter system is disturbed only temporarily by visual deprivation. Changes found in receptor development after visual deprivation indicate altered activity of different neurotransmitter systems in corresponding visual structures.P. Flechsig Brain Research Institute, Leipzig, East Germany. Karl Marx University, Leipzig, East Germany. Translated from Neirofiziologiya, Vol. 16, No. 5, pp. 691–701, September–October, 1984.     

Effect of chlorphentermine on hormone content and function of the adrenal cortex in rats.

Amphiphilic drugs like chlorphentermine induce a generalized lipid storage disease upon chronic application. The adrenal cortex is among the organs most heavily affected. We therefore determined the urinary corticosterone excretion during the treatment of rats with chlorphentermine and the corticosterone content of the adrenals and its blood level at the end of the treatment period. In addition, the responsiveness of adrenal cortex was tested by application of ACTH. During treatment, the corticosterone excretion declined considerably. Both the corticosterone content of the adrenals and the plasma level were found depressed at the end of a treatment period of 8 weeks. The ACTH evoked response was also diminished. The results indicate that the chlorphentermine-induced lipidosis is associated with a reduced corticosterone production of the adrenal cortex of rats. At present it cannot be decided whether the cortical insufficiency is causally related to lipidotic alterations of the cortical cells, or whether it is caused or additionally influenced by alteration at a higher level, e.g. hypothalamic centers or anterior pituitary.     

Representation of three-dimensional visual space in the cerebral cortex

This article reviews two issues relevant to the topic of how three-dimensional space is represented in the cerebral cortex. The first is the question of how individual neurons encode information that might contribute to stereoscopic estimation of visual depth. Particular attention is given to the current understanding of the neural representation of motion through three-dimensional space and to the complexities that arise in interpreting neuronal responses to this complex stimulus parameter. The second issue considered is the disorderlines that exists in the retinotopic mapping of the visual field in some cortical visual areas. Several extrastriate areas have been found to contain maps of the contralateral visual hemifield that are disorderly in the sense that the representation of various parts of the visual field are often misplaced or grossly over-or under-represented. It is suggested that this disorderlines may in some cases represent adaptations to facilitate certain types of visual functions.     

RNA concentration in neuron-neuroglia systems of the retina and visual zones of the cerebral cortex during light deprivation and light stimulation]

A two-wave-length cytophotometry of the gallocyanin-chromium alum-stained preparations showed that in adult rats kept for 30 days in complete darkness there was a decrease in the RNA content in the perineuronal neuroglia of the retinal ganglion cell layer only, with no changes in the corresponding neurons. No changes were found in the neurons and in the perineuronal glia of the layer II---III of the visual cerebral cortex. After the end of light deprivation a 2-hour stimulation with a constant or flickering light did not influence the RNA content in the neurons of both regions of the visual analyzer studied, whereas in control rats this stimulation induced a marked increase in the RNA content in these neurons. Qualitative changes in the metabolism of the cellular RNA in the nervous system of adult animals under the effect of light deprivation are emphasized. Differences in the biochemical peculiarities of various neuron-neuroglia systems, depending on their localization in the visual analyzer, are discussed.     

Biochemical differences in the reactions of visual cortex neurons to deprivation]

Early visual deprivation was interferometrically shown to entail changes in the concentration and contents of the protein substance with simultaneous changes of the neurons size. The changes are statistically significant in the lamina V and not in the laminasIII and IV. The changes in each lamina are associated with definite group of the neurons the development of which is, probably, determined by visual stimuli.     

Phospholipid and malondialdehyde content in the cerebral cortex of rats with incomplete ischemia and in the postischemic period

During severe incomplete brain ischemia caused by combined bilateral ligation of the general carotid arteries and blood pressure reduction to 50 Hg by blood withdrawal from the femoral artery, the cortex of cerebral hemispheres demonstrates, by the 60th minute of ischemia, a 15.4%-lowering of the content of total phospholipids (PL) and a 33.3%-increase in the content of malonyl dialdehyde (MDA). By the 30th minute of the postischemic period the content of total PL remains decreased, the content of monophosphoinositides (MPI) rises by 110.2%, whereas the content of MDA remains high. By the 60th minute of postischemia the content of total PL and MDA returns to the initial levels. However the content of MDA remains high as before.     

Cell division in the cerebral cortex of adult rats after photothrombotic ring stroke

Neurogenesis has been shown to occur in the cerebral cortex in adult rats after ischemic stroke. The origin of the newborn neurons is largely unknown. This study aimed to explore cell division in the poststroke penumbral cortex. Adult male Wistar rats were subjected to photothrombotic ring stroke. After repeated delivery of the DNA duplication marker BrdU, the animals were sacrificed at various times poststroke. BrdU was detected by immunohistochemistry/immunofluorescence labeling, as was the M-phase marker Phos H3 and the spindle components α-tubulin/γ-tubulin. DNA damage was examined by TUNEL staining. Cell type was ascertained by double immunolabeling with the neuronal markers Map-2ab/β-tubulin III and NeuN/Hu or the astrocyte marker GFAP. From 16h poststroke, BrdU-immunolabeled cells appeared in the penumbral cortex. From 24h, Phos H3 was colocalized with BrdU in the nuclei. Mitotic spindles immunolabeled by α-tubulin/γ-tubulin appeared inside the cortical cells containing BrdU-immunopositive nuclei. Unexpectedly, the markers of neuronal differentiation, Map-2ab/β-tubulin III/NeuN/Hu, were expressed in the Phos H3-immunolabeled cells, and NeuN was detected in some cells containing spindles. This study suggests that in response to a sublethal ischemic insult, endogenous cells with neuronal immunolabeling may duplicate their nuclear DNA and commit cell mitosis to generate daughter neurons in the penumbral cortex in adult rats.     

Cytoskeletal-associated protein kinase and phosphatase activities from cerebral cortex of young rats

We describe the phosphorylation system associated with the Triton-insoluble cytoskeletal fraction that phosphorylates in vitro the 150 kDa neurofilament subunit (NF-M) and alpha and beta tubulin from cerebral cortex of rats. The protein kinase activities were determined in the presence of 20 M cyclic AMP (cAMP), 1 mM calcium and 1 M calmodulin (Ca²⁺/calmodulin) or 1 mM calcium, 0.2 mM phosphatidylserine and 0.5 M phorbol 12,13-dibutyrate (Ca²⁺/PS/PDBu). Phosphorylation of these cytoskeletal proteins increased approximately 35% and 65% in the presence of cAMP and Ca²⁺/calmodulin, respectively, but was unaffected in the presence of Ca²⁺/PS/PDBu. Basal phosphorylation of these proteins studied increased approximately 35% and 72% in the presence of 0.5 M okadaic acid and 0.01 M microcystin-LR, respectively, suggesting the presence of phosphatase type 1. Results suggest that at least two protein kinases and one protein phosphatase are associated with the Triton-insoluble cytoskeletal fraction from cerebral cortex of rats.