Evidence for an ascending inhibitory histaminergic pathway to the cerebral cortex.

Previous observations from our laboratory indicate that metiamide is a specific histamine antagonist in rat cerebral cortex. In view of the recent finding that histamine levels and L-histidine decarboxylase (EC 4.1.1.22) activity in cerebral cortex decrease following disruption of the ipsilateral medial forebrain bundle (MFB), the present investigation was undertaken to examine whether iontophoretically applied metiamide antagonizes the inhibition of deep cerebral cortical neurones produced by stimulation of the MFB. In rats anaesthetized with a mixture of methoxyflurane, nitrous oxide and oxygen, stimulation of the ipsilateral MFB or the cortical surface with iontophoretically applied histamine depressed the firing of cortical neurones. Metiamide antagonized the histamine-induced depression and reduced the duration of inhibition produced by MFB stimulation. However, it did not alter the inhibition induced by the cortical surface stimulation. These results indicate that a histaminergic pathway ascending through the MFB may inhibit rat cerebral cortical neurones.     

Effect of conditioned-reflex bilateral avoidance learning on lipid components of the rat brain

The active avoidance training of rats resulted in a depletion of lipid peroxidation (LPO) products in cerebral cortex. LPO inhibition was also shown in cerebral cortex of "active control" group receiving +non-combined stimuli (the effect of short-term stress). LPO inhibition was more pronounced in rats staining a training criterion compared to rats which received combined stimuli but did not reach the criterion. In the active control group LPO inhibition was accompanied by total phospholipids accumulation and cholesterol depletion in cortical lipid extracts. Irrespective of attaining the criterion in all rats trained for active avoidance the accumulation of cholesterol was seen. Active avoidance training affected also the phospholipid composition of cerebral cortex.     

Ethanol selectively potentiates GABA-mediated inhibition of single feline cortical neurons

Ethanol (alcohol) released from micropipettes by electro-osmosis (up to 10 nA from 0.3 M in 165 mM NaCl solution) potentiated the inhibition of firing of single cortical neurons produced by iontophoretically-applied pulses of γ-aminobutyric acid (GABA), whereas it had no effect or a mild antagonistic effect on the inhibition produced by pulses of glycine, and had an antagonistic effect on the inhibition produced by pulses of serotonin or dopamine. The potentiation of iontophoretically-applied GABA was also obtained by intravenously-applied ethanol (0.2–2 mg/kg). Furthermore, ethanol applied by electro-osmosis or intravenously in the same doses potentiated the inhibition of firing of single cortical neurons evoked by electrical stimulation of the surface of the cerebral cortex, which is believed to be mediated by endogenous GABA. These findings may have implications for alcoholism, since GABAergic neurotransmission is involved in the mechanism of action of anxiolytic drugs and anxiety is involved in the etiology of alcoholism.     

High-Affinity Transport of γ-Aminobutyric Acid, Glycine, Taurine, L-Aspartic Acid, and L-Glutamic Acid in Synaptosomal (P2) Tissue: A Kinetic and Substrate Specificity Analysis

In a cortical P2 fraction, [14C]gamma-aminobutyric acid ([14C]GABA), [14C]glycine, [14C]taurine, and [14C]glutamic and [14C]aspartic acids are transported by four separate high-affinity transport systems with L-glutamic acid and L-aspartic acid transported by a common system. GABA transport in cortical synaptosomal tissue occurs by one high-affinity system, with no second, low-affinity, transport system detectable. Only one high-affinity system is observed for the transport of aspartic/glutamic acids; as with GABA transport, no low-affinity transport is detectable. In the uptake of taurine and glycine (cerebral cortex and pons-medulla-spinal cord) both high- and low-affinity transport processes could be detected. The high-affinity GABA and high-affinity taurine transport classes exhibit some overlap, with the GABA transport system being more specific and having a much higher Vmax value. High-affinity GABA transport exhibits no overlap with either the high-affinity glycine or the high-affinity aspartic/glutamic acid transport class, and in fact they demonstrate somewhat negative correlations in inhibition profiles. The inhibition profiles of high-affinity cortical glycine transport and those of high-affinity cortical taurine and aspartic/glutamic acid transport also show no significant positive relationship. The inhibition profiles of high-affinity glycine transport in the cerebral cortex and in the pons-medulla-spinal cord show a significant positive correlation with each other; however, high-affinity glycine uptake in the pons-medulla-spinal cord is more specific than that in the cerebral cortex. The inhibition profile of high-affinity taurine transport exhibits a nonsignificant negative correlation with that of the aspartic/glutamic acid transport class.     

Electroencephalographic study of iron-induced chronic focal cortical epilepsy in rat: propagation of cortical epileptic activity to substantia nigra and thalamus.

Cortical epileptic focus was produced by an intracortical injection of FeCl3 in rat cerebral cortex using standard techniques. How after its onset in the cortical focus, the epileptiform activity evolved with time in the thalamus and substantia nigra has been determined. To study the propagation of the epileptiform activity, the local EEG and multiple unit action potentials were recorded from these structures simultaneously with the cortical epileptiform EEG. The results showed that in thalamus and substantia nigra epileptiform activity appeared simultaneously with that in the cortical focus. Intensity of epileptic activity in thalamus and substantia nigra on the whole increased in parallel with that in the cortical focus. The results suggest that the thalamic and nigral epileptiform activity may reinforce the cortical epileptiform activity.     

Sound-driven synaptic inhibition in primary visual cortex

Multimodal objects and events activate many sensory cortical areas simultaneously. This is possibly reflected in reciprocal modulations of neuronal activity, even at the level of primary cortical areas. However, the synaptic character of these interareal interactions, and their impact on synaptic and behavioral sensory responses are unclear. Here, we found that activation of auditory cortex by a noise burst drove local GABAergic inhibition on supragranular pyramids of the mouse primary visual cortex, via cortico-cortical connections. This inhibition was generated by sound-driven excitation of a limited number of cells in infragranular visual cortical neurons. Consequently, visually driven synaptic and spike responses were reduced upon bimodal stimulation. Also, acoustic stimulation suppressed conditioned behavioral responses to a dim flash, an effect that was prevented by acute blockade of GABAergic transmission in visual cortex. Thus, auditory cortex activation by salient stimuli degrades potentially distracting sensory processing in visual cortex by recruiting local, translaminar, inhibitory circuits.     

Evidence that glutaric acid reduces glutamate uptake by cerebral cortex of infant rats

The role of excitotoxicity in the cerebral damage of glutaryl-CoA dehydrogenase deficiency (GDD) is under intense debate. We therefore investigated the in vitro effect of glutaric (GA) and 3-hydroxyglutaric (3-OHGA) acids, which accumulate in GDD, on [(3)H]glutamate uptake by slices and synaptosomal preparations from cerebral cortex and striatum of rats aged 7, 15 and 30 days. Glutamate uptake was significantly decreased by high concentrations of GA in cortical slices of 7-day-old rats, but not in cerebral cortex from 15- and 30-day-old rats and in striatum from all studied ages. Furthermore, this effect was not due to cellular death and was prevented by N-acetylcysteine preadministration, suggesting the involvement of oxidative damage. In contrast, glutamate uptake by brain slices was not affected by 3-OHGA exposure. Immunoblot analysis revealed that GLAST transporters were more abundant in the cerebral cortex compared to the striatum of 7-day-old rats. Moreover, the simultaneous addition of GA and dihydrokainate (DHK), a specific inhibitor of GLT1, resulted in a significantly higher inhibition of [(3)H]glutamate uptake by cortical slices of 7-day-old rats than that induced by the sole presence of DHK. We also observed that both GA and 3-OHGA exposure did not alter the incorporation of glutamate into synaptosomal preparations from cerebral cortex and striatum of rats aged 7, 15 and 30 days. Finally, GA in vivo administration did not alter glutamate uptake into cortical slices from 7-day-old rats. Our findings may explain at least in part why cortical neurons are more vulnerable to damage at birth as evidenced by the frontotemporal cortical atrophy observed in newborns affected by GDD.     

C3G regulates the size of the cerebral cortex neural precursor population

The mechanisms regulating the size of the cerebral cortex are poorly understood. Here, we demonstrate that the Rap1 guanine nucleotide exchange factor, C3G (Grf2, Rapgef1), controls the size of the cerebral precursor population. Mice lacking C3G show overproliferation of the cortical neuroepithelium. C3G-deficient neuroepithelial cells accumulate nuclear beta-catenin and fail to exit the cell cycle in vivo. C3G mutant neural precursor cells fail to activate Rap1, exhibit activation of Akt/PKB, inhibition of the beta-catenin-degrading enzyme, Gsk3beta and accumulation of cytosolic and nuclear beta-catenin when exposed to growth factors, in vitro. Our results show that the size of the cortical neural precursor population is controlled by C3G-mediated inhibition of the Ras signalling pathway.     

Improvement in Regional CBF by L-Serine Contributes to Its Neuroprotective Effect in Rats after Focal Cerebral Ischemia

To investigate the mechanisms underlying the neuroprotective effect of L-serine, permanent focal cerebral ischemia was induced by occlusion of the middle cerebral artery while monitoring cerebral blood flow (CBF). Rats were divided into control and L-serine-treated groups after middle cerebral artery occlusion. The neurological deficit score and brain infarct volume were assessed. Nissl staining was used to quantify the cortical injury. L-serine and D-serine levels in the ischemic cortex were analyzed with high performance liquid chromatography. We found that L-serine treatment: 1) reduced the neurological deficit score, infarct volume and cortical neuron loss in a dose-dependent manner; 2) improved CBF in the cortex, and this effect was inhibited in the presence of apamin plus charybdotoxin while the alleviation of both neurological deficit score and infarct volume was blocked; and 3) increased the amount of L-serine and D-serine in the cortex, and inhibition of the conversion of L-serine into D-serine by aminooxyacetic acid did not affect the reduction of neurological deficit score and infarct volume by L-serine. In conclusion, improvement in regional CBF by L-serine may contribute to its neuroprotective effect on the ischemic brain, potentially through vasodilation which is mediated by the small- and intermediate-conductance Ca²⁺-activated K⁺ channels on the cerebral blood vessel endothelium.     

Mechanisms for recovery of motor function following cortical damage

Recent studies of focal injury to the cerebral cortex have demonstrated that the remaining, intact tissue undergoes structural and functional changes that could play a substantial role in neurological recovery. New information regarding the molecular and cellular environment in the adjacent, intact tissue has suggested that waves of growth promotion and inhibition modulate the self-repair processes of the brain. Furthermore, recent studies have documented widespread neurophysiological and neuroanatomical changes in regions remote from a focal cortical injury, suggesting that entire cortical networks participate in the recovery process.     

An immunohistochemical localization of neuropeptide Y (NPY) in its amidated form in human frontal cortex

The distribution of neuropeptide Y (NPY)-immunoreactive neurons was studied in human frontal cerebral cortex from surgical biopsy specimens by immunohistochemical techniques. NPY-containing neurons were identified in all cortical sublayers except sublayer I. The stained neurons were of the multipolar, bitufted, round or triangular form with dendritic and axonal processes. The immunoreactive neurons were considered to be cortical interneurons, due to their nonpyramidal form, and since their processes could be followed intracortically particularly in direction to superficial cortical layers. The NPY precursor molecule is processed to NPY by a dibasic cleavage, and NPY is further enzymatically amidated before release and receptor activation can be achieved. Antisera raised against Cys-NPY(32-36)amide recognize amidated NPY not cross-reacting with nonamidated NPY. These antisera and immunohistochemistry revealed the presence of a population of NPYamide-immunoreactive cells morphologically indistinguishable from the NPY-immunoreactive cells in the human frontal cortex. By comparing the number of immunoreactive cells in adjacent sections, it appears that the number of NPY-immunoreactive cells was higher than those immunoreactive to NPYamide. Also, the density of NPY fibers was much higher compared with the number stained with NPYamide antiserum. The present immunohistochemical study indicates that NPY in its amidated form is contained in a subpopulation of human cortical NPY-immunoreactive neurons and may participate as an active neurotransmitter/modulator within the human cerebral cortex.     

Brain oscillations,medium spiny neurons,and dopamine

1. The striatum is part of a multisynaptic loop involved in translating higher order cognitive activity into action. The main striatal computational unit is the medium spiny neuron, which integrates inputs arriving from widely distributed cortical neurons and provides the sole striatal output.2. The membrane potential of medium spiny neurons' displays shifts between a very negative resting state (down state) and depolarizing plateaus (up states) which are driven by the excitatory cortical inputs.3. Because striatal spiny neurons fire action potentials only during the up state, these plateau depolarizations are perceived as enabling events that allow information processing through cerebral cortex – basal ganglia circuits. In vivo intracellular recording techniques allow to investigate simultaneously the subthreshold behavior of the medium spiny neuron membrane potential (which is a reading of distributed patterns of cortical activity) and medium spiny neuron firing (which is an index of striatal output).4. Recent studies combining intracellular recordings of striatal neurons with field potential recordings of the cerebral cortex illustrate how the analysis of the input–output transformations performed by medium spiny neurons may help to unveil some aspects of information processing in cerebral cortex – basal ganglia circuits, and to understand the origin of the clinical manifestations of Parkinson's disease and other neurologic and neuropsychiatric disorders that result from alterations in dopamine-dependent information processing in the cerebral cortex – basal ganglia circuits.     

Change in the Cortical Complexity of Spinocerebellar Ataxia Type 3 Appears Earlier than Clinical Symptoms

Patients with spinocerebellar ataxia type 3 (SCA3) have exhibited cerebral cortical involvement and various mental deficits in previous studies. Clinically, conventional measurements, such as the Mini-Mental State Examination (MMSE) and electroencephalography (EEG), are insensitive to cerebral cortical involvement and mental deficits associated with SCA3, particularly at the early stage of the disease. We applied a three-dimensional fractal dimension (3D-FD) method, which can be used to quantify the shape complexity of cortical folding, in assessing cortical degeneration. We evaluated 48 genetically confirmed SCA3 patients by employing clinical scales and magnetic resonance imaging and using 50 healthy participants as a control group. According to the Scale for the Assessment and Rating of Ataxia (SARA), the SCA3 patients were diagnosed with cortical dysfunction in the cerebellar cortex; however, no significant difference in the cerebral cortex was observed according to the patients’ MMSE ratings. Using the 3D-FD method, we determined that cortical involvement was more extensive than involvement of traditional olivopontocerebellar regions and the corticocerebellar system. Moreover, the significant correlation between decreased 3D-FD values and disease duration may indicate atrophy of the cerebellar cortex and cerebral cortex in SCA3 patients. The change of the cerebral complexity in the SCA3 patients can be detected throughout the disease duration, especially it becomes substantial at the late stage of the disease. Furthermore, we determined that atrophy of the cerebral cortex may occur earlier than changes in MMSE scores and EEG signals.     

Stimulation of the basal nucleus of Meynert in senile dementia of Alzheimer's type. A preliminary report

The basal nuclei of Meynert are the principal sources of cholinergic innervation of the cerebral cortex. It has been hypothesized that the depressed cortical glucose metabolic activity in senile dementia of Alzheimer's type (SDAT) may result primarily from diminished activity and loss of these cells. The present study was designed to test the hypothesis that electrical stimulation of the basal nuclei would bring about clinical improvement and increase cortical glucose metabolic activity in SDAT. An electrode was implanted in September 1984 into the left basal nucleus of a 74-year-old man with SDAT. Repetitive cycles of stimulation for 9 months since have had no definite effect clinically but a follow-up positron emission tomography scan shows that cortical glucose metabolic activity was preserved in the ipsilateral temporal and parietal lobes while it declined elsewhere in the cortex.     

The disinhibitory influence of the activating system when artificially excited from different points in the brain]

EEG activation can be produced by electrical stimulation of some cortical points with the same threshold current strength as by the midbrain RF and thalamic CM stimulation. Near-threshold stimulation of all these points acting simultaneously with inhibitory conditioned signals does not disturb the effector inhibition but displays an EEG difference between negative signals: the fine differentiation sound evokes considerable EEG desynchronization, while the rough one does not change the background rhythms. The same stimulation combined with a positive signal which has been made ineffective by successive inhibition or extinction, reestablishes the intensive EEG activation in response to this signal and the effector conditioned reflex. Therefore a mode-rate additional stimulation of the activating points in the cortex, RF and CM has a disinhibitory influence. When initiated in the cortex this influence may be transmitted from the cortical point to other parts of the brain along transcortical and corticofugal connections.     

Cholinergic regulation of the activity of somatosensory cortex neurons during early postnatal ontogeny of the cat

In 11-14 days kittens, about 20% of neurones in the somatosensory cortical zone react to stimulation of subpallidal region which is a source of cholinergic projections to the cerebral cortex. The effect of subpallidal region stimulation is reproduced in case of microiontophoretic acetylcholine application and blocked by atropine what points to its cholinergic nature. Cholinergic stimulation causes inhibition of the background and evoked activities of the cortical neurones while, as it is known, in adult cats, acetylcholine mainly stimulates a reaction of activation. It is postulated that in kittens at the end of the second week of postnatal development, cholinergic innervation of the cortex significantly differs from the definitive one by its quantitative and functional parameters.     

CHANGES IN THE NEURONAL PROTEIN LABELLING INDUCED BY POTASSIUM IONS IN VIVO(SPREADING DEPRESSION)

Abstract— Inhibition of incorporation of labelled leucine into the protein of the cerebral cortex induced by potassium ions in vivo (spreading depression) was analysed in isolated neuronal perikarya and compared with that in the whole cortex. Partition of proteins and amino acids and their radioactivities between tissue (cells) and incubation and disintegration media were checked at various steps of the separation procedure. The effect of potassium ions elicited in vivo persisted through all the steps of separation through to the neuronal perikarya pellets. The inhibition of amino acid incorporation was found to be less pronounced in perikarya than in the whole cortex. The validity of the separation method for the study of metabolic changes induced in vivo and possible participation of the glial cells in cerebral cortical responses to enhanced extracellular potassium are discussed.     

Emerging roles of neural stem cells in cerebral cortex development and evolution

Expansion and folding of the cerebral cortex are landmark features of mammalian brain evolution, which are recapitulated during embryonic development. Neural stem cells and their derived germinal cells are coordinated during cerebral cortex development to produce the appropriate amounts and types of neurons. This process is further complicated in gyrencephalic species, where newborn neurons must disperse in the tangential axis to expand the cerebral cortex in surface area. Here, we review advances that have been made over the last decade in understanding the nature and diversity of telencephalic neural stem cells and their roles in cortical development, and we discuss recent progress on how newly identified types of cortical progenitor cell populations may have evolved to drive the expansion and folding of the mammalian cerebral cortex.