The effect of electrical stimulation on the incorporation of l-[U-14C]valine into the protein of chopped tissue from guinea-pig cerebral cortex

1. Chopped tissue from guinea-pig cerebral cortex carried out an energy-dependent incorporation of [(14)C]valine into protein. 2. At all times studied the nuclear fraction of the homogenized tissue accounted for about 25% of the total labelled protein. 3. Electrical stimulation at first increased, but subsequently decreased, the rate of incorporation of [(14)C]valine into protein of the chopped tissue. 4. The initial increase in the incorporation of [(14)C]valine into protein occurred in the nuclear fraction. At later times electrical stimulation decreased the incorporation into all the subcellular fractions, but the relative contribution of the nuclear fraction to the total labelled protein increased. 5. These changes are discussed in relation to the changes in the rates of respiration, glycolysis, high-energy phosphate content and intracellular Na(+) and K(+) concentrations, which were measured under the same experimental conditions as those used to study protein synthesis.     

The uptake of horseradish peroxidase by cortical synapses in rat brain

Summary Horseradish peroxidase (HRP) was introduced directly into the cerebral cortex of adult rats, which were allowed to survive for 60 min before perfusion fixation. After the tissue had been incubated to demonstrate HRP at the LM and EM levels, blocks of cortical tissue were taken at varying distances from the injection site. These eight blocks of tissue constituted a time sequence for HRP diffusion.Qualitative examination of the presynaptic terminals showed that the most commonly encountered profiles are the plain synaptic vesicles, many of which accumulate tracer. In some terminals labelled vesicles are lined-up in tubular fashion. Other profiles commonly labelled are coated vesicles, tubular and vacuolar cisternae, and plain and coated pinocytotic vesicles.Quantitative analyses based on the number of terminals containing labelled profiles demonstrate an early rise in the rate of labelling of both plain synaptic vesicles and coated vesicles, after which synaptic vesicle labelling rises slowly towards a plateau. By contrast, there is a late parallel increase in the rate of labelling of coated vesicles and cisternae. A more detailed analysis, based on the actual numbers of labelled and total profiles within each presynaptic terminal, highlight early and late periods of rapid labelling for plain synaptic vesicles, coated vesicles and cisternae. A further aspect of HRP incorporation studied, concerns its uptake into four delineated regions of the presynaptic terminal.Our data indicate that membrane uptake into the presynaptic terminal is accomplished mainly via coated vesicles, although plain synaptic vesicles may also be involved. Coated vesicles, in turn, appear to give rise directly to plain synaptic vesicles, with some coalescing to produce vacuolar cisternae. The latter are involved in a two-way interchange of membrane with tubular cisternae, plain synaptic vesicles and coated vesicles. An additional source of plain synaptic vesicles are the tubular cisternae. Exocytosis of plain synaptic vesicles constitutes the mechanism by which transmitter is released from the presynaptic terminal.Supported by the Nuffield Foundation. We are grateful to Mr. M. Austin for help with the photography     

THE EFFECT OF ELECTRICAL STIMULATION ON THE TURNOVER OF PHOSPHATIDIC ACID IN SYNAPTOSOMES FROM GUINEA-PIG BRAIN

Synaptosomes prepared from guinea-pig cerebral cortex were suspended in a medium containing [³²P]orthophosphate and subjected to electrical stimulation. When the synaptosomal phospholipids were subsequently separated, the most highly labelled was phosphatidic acid and electrical stimulation over a 10 min period increased incorporation of ³²P₁ into this lipid. Stimulated synaptosomes were osmotically lysed and subsynaptosomal fractions isolated. The electrically stimulated increase in phosphatidic acid labelling was localized in a fraction enriched in synaptic vesicles. This phospholipid effect was not merely a reflection of an increased specific radioactivity of synaptosomal ATP, due to the electrically stimulated increase in respiration. The time course of the phosphatidic acid effect suggests that it is synchronous with release of transmitter.     

Effect of electrostimulation of the hypothalamus on protein biosynthesis in organs of adult and aged rats

The effect of hypothalamus electrical stimulation on total protein biosynthesis was studied in skeletal muscle, heart, liver, adrenal cortex and thyroid gland of adult rats. In adult animals hypothalamus stimulation provokes a pronounced increase in 3H-leucine incorporation into total protein of all tissues, as well as into liver chromatin proteins. No significant changes were observed in protein biosynthesis when hypothalamus of old rats was stimulated. This can serve as evidence of age-related decrease in the ability of the hypothalamus to stimulate protein synthesis in peripheral tissues.     

Cyclic nucleotides in central synaptic function.

A wide array of interdisciplinary experiments have served to strengthen the general premise that some central synaptic effects of neurotransmitters may be mediated by cyclic nucleotides. Specific instances of such second messenger mediation are most strongly supported for certain noradrenergic connections of the locus coeruleus (LC) and for dopaminergic connections within the caudate nucleus. In these sites catecholamines selectively activate intraneuronal cyclic AMP synthesis, and exogenously applied cyclic AMP closely mimics the biophysical actions of the catecholamine on target neurons. In cerebellar cortex, iontophoresis of norepinephrine, stimulation of LC, or iontophoresis of cyclic AMP lead to hyperpolarization and increased membrane resistance. Although overtly inhibitory when examined in isolation, the effects of the LC system coupled to adenylate cyclase can initiate a holistic set of target cell responses which can enhance or "enable" the actions of other synaptic inputs to the target cells. Electrophysiologic and immunocytochemical evidence suggests that this heterosynaptic interaction may arise from phosphorylation of the synaptic membrane substrate of cyclic AMP-dependent protein kinase, or Protein 1.     

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.     

Glutamate-immunoreactive climbing fibres in the cerebellar cortex of the rat

The climbing fibre system, one of the two main excitatory inputs to the cerebellar cortex, is anatomically and physiologically well characterized, while the nature of its neurotransmitter is still a matter of debate. We wished to determine whether glutamate-immunoreactive profiles with the morphological characteristics of climbing fibres could be found in the rat cerebellar cortex. For this purpose, a monoclonal anti-glutamate antibody has been used in combination with a sensitive postembedding immunoperoxidase method on semithin sections or in combination with a postembedding immunogold method on ultrathin sections. At the light microscopic level, climbing fibres appeared as strongly stained fibrous profiles, chains of interconnected varicosities or heavily labelled dots of various sizes, often in close apposition to principal Purkinje cell dendrites. At the electron microscopic level, certain labelled varicosities or more elongated profiles resembling climbing fibre terminals were in synaptic contact with dendritic spines of Purkinje cells. Quantitative analysis of gold particle densities showed that such elements were about three to four times more heavily labelled than their postsynaptic partners. The results obtained in this study demonstrate that at least a subset of climbing fibres and their terminals contain relatively high levels of glutamate-like immunoreactivity and provide additional evidence for a role of glutamate as transmitter in these cerebellar afferents.     

Light-induced down-regulation of the rat class 1 dynein-associated protein robl/LC7-like gene in visual cortex

Dynein and kinesin are the main microtubule-dependent motors that mediate intracellular movement in eukaryotic organisms. We have cloned a full-length cDNA encoding rat dynein light chain protein, robl/LC7-like (class 1), from visual cortex. We found that rat robl/LC7-like gene is highly expressed in neocortex and displays the unusual feature of being rapidly down-regulated by sensory stimulation. This effect was seen at both mRNA and protein levels in visual cortex, being detectable in as little as 45 min after the onset of visual stimulation. Down-regulation by sensory stimulation was also found within ocular dominance columns of area V1 in monocularly deprived monkeys. Our results suggest a high turnover rate of the robl/LC7-like protein and the presence of a repressor mechanism in neurons that is tightly coupled to synaptic stimulation.     

Distribution and ultrastructure of thalamic afferents in the cat auditory cortex

Ultrastructural features of thalamic afferent fibers were studied in the cat auditory cortex in the early stages (on the 4th day) of experimental degeneration produced by destruction of the medial geniculate body. A coordinate grid was used in conjunction with an electron micro-scope to study the topography of the degenerating elements over wide areas of sections, so that the density of degeneration could be determined quantitatively in different layers of the cortex. Degenerating axons were found in all layers. Most of the large (5–7 µ) degenerating axons are located in layer VI; their diameters were smaller in the upper layers of the cortex. Degenerative changes affecting synaptic terminals of thalamo-cortical afferents were of the "dark" type. Fibers of the geniculo-cortical tract were shown to terminate mainly in cortical layer IV. A few degenerating synapses were found in the molecular layer. Terminals with sperical synaptic vesicles are found mainly on the spines of dendrites where they form "asymmetrical" contacts. A few degenerating axo-somatic synapses were observed on stellate neurons in layer IV. The results are discussed in connection with electrophysiological investigations of the cat auditory cortex during stimulation of specific afferent fibers.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 4, No. 6, pp. 612–620, November–December, 1972.     

Regulation of retinal dopamine biosynthesis and tyrosine hydroxylase activity by light

Dopamine (DA)-containing neurons of the rat retina are apparently activated transsynaptically by photic stimulation. Exposure of dark-adapted rats to light increases retinal DA biosynthesis and metabolism. Associated with the light-evoked increase of DA biosynthesis is a rapid activation of tyrosine hydroxylase (TH), the rate-limiting enzyme of catecholamine biosynthesis. The activation of TH is characterized by an increased affinity of the enzyme for the pteridine cofactor. Because TH in dark-adapted retinas is apparently not saturated with cofactor, the light-evoked increase of affinity is probably responsible for the observed stimulation of DA biosynthesis. Cyclic AMP (cAMP)-dependent protein phosphorylation in vitro activates TH extracted from dark-adapted retinas, and phosphorylation-induced TH activation is very similar and not additive with light-evoked activation of the enzyme. Incubation of viable cell suspensions of dissociated retinas with 8-bromo cAMP also activates TH, which indicates the availability of sufficient cAMP-dependent protein kinase in the proper subcellular compartment to regulate the enzyme in situ. The DA-containing neurons of the rat retina are tonically inhibited in darkness, and evidence is presented that this tonic inhibition involves direct synaptic input to the DA neurons from gamma-aminobutyric acid-containing amacrine cells. The DA-containing neurons are also subject to feedback inhibition through DA receptors, and to modulation by alpha 2-adrenergic receptors.     

Synaptic NMDA receptor stimulation activates PP1 by inhibiting its phosphorylation by Cdk5

The serine/threonine protein phosphatase protein phosphatase 1 (PP1) is known to play an important role in learning and memory by mediating local and downstream aspects of synaptic signaling, but how PP1 activity is controlled in different forms of synaptic plasticity remains unknown. We find that synaptic N-methyl-d-aspartate (NMDA) receptor stimulation in neurons leads to activation of PP1 through a mechanism involving inhibitory phosphorylation at Thr320 by Cdk5. Synaptic stimulation led to proteasome-dependent degradation of the Cdk5 regulator p35, inactivation of Cdk5, and increased auto-dephosphorylation of Thr320 of PP1. We also found that neither inhibitor-1 nor calcineurin were involved in the control of PP1 activity in response to synaptic NMDA receptor stimulation. Rather, the PP1 regulatory protein, inhibitor-2, formed a complex with PP1 that was controlled by synaptic stimulation. Finally, we found that inhibitor-2 was critical for the induction of long-term depression in primary neurons. Our work fills a major gap regarding the regulation of PP1 in synaptic plasticity.     

TRANSPORT OF 14C INCORPORATED PROTEIN IN THE CORTICOSPINAL TRACT OF THE RAT BRAIN

Abstract— The origin of fibres of a corticospinal pathway in rat brain was located by cortical ablation and Marchi staining and also by electrical stimulation of the motor cortex.
Enzyme changes investigated histochemically over 0–14 days post-injection of 5 μ10.15 m NaCl into the neocortex indicated that very little apparent disturbance of nerve cell metabolism beyond a narrow band adjacent to the path of the microneedle within the cortex had occurred. [¹⁴ C]Leucine as a precursor of protein synthesis was used to study incorporation of the amino acid into protein. At the site of injection the maximum level of labelled protein was recorded at 30 min post-injection, the level decreasing to less than 2 per cent of this at 6 hr.
The subsequent axonal flow of labelled protein along the corticospinal pathway was investigated during the period 15 min to 21 days post-injection. Within 24 hr increasing amounts of labelled proteins were measured caudally, but not more than 6 per cent had migrated beyond 5 mm from the site of injection. At 3 days this percentage had increased to 14.6 per cent, the labelled proteins being distributed in progressively decreasing amounts to a further 13 mm caudal. Very little change from this position was seen during the following 18 days.     

Neuronal mechanisms of interaction of Deiters nucleus with the cerebral cortex.

The effects of stimulation of the vestibular nerve and five different cerebral cortex areas on the neuronal activity of the lateral vestibular nucleus of Deiters were studied. Stimulation of the cerebral cortex is shown to lead to antidromic and synaptic activation of Deiters neurons. The synaptic potentials of Deiters neurons evoked from the cerebral cortex were of mono- and polysynaptic origin. In particular, stimulation of the cerebral cortex evoked in Deiters neurons mono- and polysynaptic excitatory postsynaptic potentials. Collaterals of vestibulospinal neurons reaching different cortex fields as well as convergence of influences from these cortex fields on Deiters neurons were revealed. Inhibitory effects of the cerebral cortex on Deiters neurons were of polysynaptic origin and occurred rarely. The topical correlation between Deiters nucleus and different areas of the cerebral cortex was found. The peculiarities and functional significance of the effects obtained are discussed.     

Changes in the ultrastructure of the cerebral cortex in rats during learning and in disorders of higher nervous activity]

The results are outlined of a complex study of the ultrastructure of the rat cerebral cortex after learning and higher nervous activity disturbance. In the case of learning with preliminary stimulation with al-amphetamine or without it, the subcortical processes in the motor and auditory analysers of the cerebral cortex are characterized by sharp structural-functional activation of the apparatus of energy supply, of protein synthesis and of the synaptic zones. The length of the synaptic active zones increases, and extensive development of spine apparatuses is recorded in the postsynaptic area in the form of intricate membrane complexes. Quite the contrary, in cases of higher nervous activity disturbances, destruction of the organelles and desintegration of spine apparatuses is clearly pronounced. The question of the role of the latter in the memory processes is discussed.     

Dual effect of the locus coeruleus on neuronal activity in the visual cortex

The effects exerted by electrical stimulation of the locus coeruleus (LC) on neuronal activity in the visual cortex have been studied in acute experiments on rabbits. The pattern of cortical afterprocesses affecting poststimulus histograms of neuronal activity has been found not always to correspond to the direction of change in the neuronal excitation level in the period of LC stimulation. An analysis of crossed interval histograms for a pair of neurons located in the same microvolume of the cortex has revealed the existence of two independent postsynaptic effects of LC stimulation: a fast (synaptic) effect and a slow (modulatory) effect. The findings are discussed with allowance for morphological features of the synaptic connections and interneuronal transmission in the noradrenergic system of the brain.Neirofiziologiya/Neurophysiology, Vol. 25, No. 4, pp. 243–246, July–August, 1993.     

Transsynaptic Regulation of Galanin, Neurotensin, and Substance P in the Adrenal Medulla: Combinatorial Control by Second-Messenger Signaling Pathways

The adrenomedullary content of neurotensin and substance P was examined 1, 6, and 12 days after hypoglycemic shock. The neurotensin content was increased 60-fold within 24 h and remained elevated for up to 12 days, whereas the substance P content was increased approximately sevenfold within 24 h of insulin treatment and returned to control levels by 12 days poststimulation. Because protein kinase A, protein kinase C, and calcium influx in the rat adrenal medulla are all stimulated following splanchnic nerve stimulation, the differential regulation of neurotensin and substance P biosynthesis following stimulation of these three pathways was examined in bovine chromaffin cells in vitro. Neurotensin levels were up-regulated by elevated potassium, forskolin, and phorbol ester in bovine chromaffin cells. Substance P levels were up-regulated by elevated potassium and forskolin but not by phorbol ester treatment. When chromaffin cells were treated with phorbol ester in combination with forskolin, neurotensin levels were increased in a synergistic fashion, whereas phorbol ester antagonized the forskolin-induced elevation of substance P levels. Earlier, it was reported that galanin biosynthesis, like neurotensin biosynthesis, is upregulated by depolarization, phorbol ester stimulation, and forskolin treatment in chromaffin cells in vitro. Here we report that galanin is also, like neurotensin, increased greater than 60-fold after stimulation of the rat adrenal medulla in vivo. Neuropeptide-specific combinatorial effects of stimulating the calcium, protein kinase A, and protein kinase C signaling pathways may underlie the quantitative differences between galanin and neurotensin compared with substance P up-regulation in rat adrenal medulla after splanchnic nerve stimulation in vivo.     

The thalamo-fronto-striate system: ultrastructural evidence of appropriate synaptic integration of embryonic neurones grafted within the frontal cortex of newborn rats

Previous light microscopical studies have indicated that fibres from the ventrolateral thalamic nucleus (VL) establish direct axo-somatic and axo-dendritic presumed contacts with layers III and V neurones of the intact frontal cortex projecting to the striatum. Additional experiments provided evidence that this thalamo-fronto-striate pathway could be partly reconstructed by transplantation of embryonic frontal tissue into the damaged cortex. The present study was undertaken to validate these results at the ultrastructural level. Several months after the transplantation of fetal frontal tissue into the damaged frontal cortex of newborn rats, a retrograde neurotracer (subunit b of the cholera toxin) was used to label the grafted neurones projecting to the striatum whereas an anterograde neurotracer (Phaseolus vulgaris leuco-agglutinin) was used to label within the transplant, axons and terminations arising from the VL. The same injection procedures were applied to intact adult rats (control). The distribution of retrograde and anterograde labellings within the intact cortex and within the graft was examined at light and electron microscopic levels to identify the synaptic contacts. Our findings showed that labelled contacts were less numerous within the transplant than within the intact cortex but their synaptic organization was similar: asymmetrical synaptic axo-dendritic and axo-somatic contacts. This synaptic articulation is probably supplied by a thalamic excitatory input. These results provide ultrastructural evidence of the capacity of a frontal cortical transplant placed in damaged frontal cortex of newborn rats to help reconstruction of appropriate synaptic integration within the thalamo-fronto-striate system.     

Mitochondrial localization of a phosphoprotein that rapidly accumulates in adrenal cortex cells exposed to adrenocorticotropic hormone or to cAMP

We have reported previously that a phosphoprotein, ib, is present in adrenal cortex, corpus luteum, and Leydig cells stimulated with either tissue-specific peptide hormone or with cAMP. The accumulation of protein ib in each of these cell types has been found to parallel the stimulation of steroid synthesis with respect to both time course and stimulant dose response. Thus, protein ib is a potential mediator in the acute stimulation of steroidogenesis by peptide hormone or cyclic AMP. A second protein, pb, the unphosphorylated form of ib, is synthesized constitutively in unstimulated but not stimulated cells and is not converted post-translationally to ib upon stimulation. Using two-dimensional gel electrophoresis of subcellular fractions isolated from rat adrenal cortex cells labeled with [35S] methionine, we have determined the intracellular localization of proteins p and i. We demonstrate that proteins ib and pb are localized predominantly in the mitochondria and are tightly associated with that organelle. We also find that inhibition of mitochondrial protein synthesis by chloramphenicol affects neither the accumulation of these proteins nor the stimulation of steroidogenesis. Thus, protein pb and its phosphorylated counterpart, ib, are synthesized in the cytosol and transported to the mitochondria, the site of the rate-limiting step in steroid hormone biosynthesis.     

The thalamo-fronto-striate system: ultrastructural evidence of appropriate synaptic integration of embryonic neurones grafted within the frontal cortex of newborn rats

Previous light microscopical studies have indicated that fibres from the ventrolateral thalamic nucleus (VL) establish direct axo-somatic and axo-dendritic presumed contacts with layers III and V neurones of the intact frontal cortex projecting to the striatum. Additional experiments provided evidence that this thalamo-fronto-striate pathway could be partly reconstructed by transplantation of embryonic frontal tissue into the damaged cortex. The present study was undertaken to validate these results at the ultrastructural level. Several months after the transplantation of fetal frontal tissue into the damaged frontal cortex of newborn rats, a retrograde neurotracer (subunit b of the cholera toxin) was used to label the grafted neurones projecting to the striatum whereas an anterograde neurotracer (Phaseolus vulgaris leuco-agglutinin) was used to label within the transplant, axons and terminations arising from the VL. The same injection procedures were applied to intact adult rats (control). The distribution of retrograde and anterograde labellings within the intact cortex and within the graft was examined at light and electron microscopic levels to identify the synaptic contacts. Our findings showed that labelled contacts were less numerous within the transplant than within the intact cortex but their synaptic organization was similar: asymmetrical synaptic axo-dendritic and axo-somatic contacts. This synaptic articulation is probably supplied by a thalamic excitatory input. These results provide ultrastructural evidence of the capacity of a frontal cortical transplant placed in damaged frontal cortex of newborn rats to help reconstruction of appropriate synaptic integration within the thalamofronto-striate system.     

Origins of the BOLD changes due to synaptic activity at astrocytes abutting arteriolar smooth muscle

We have recently provided a detailed model that links glutamatergic synaptic activity to volume and blood flow changes in nearby arterioles [Bennett, M.R., Farnell, L., Gibson, W.G., 2008. Origin of blood volume change due to glutamatergic synaptic activity at astrocytes abutting on arteriolar smooth muscle cells. J. Theor. Biol. 250, 172-185]. This neurovascular coupling model is used in the present work to predict changes in deoxyhemoglobin (Hbr) in capillaries, arterioles, venules and veins due to glutamatergic synaptic activity and hence the changes in the blood oxygen level dependent (BOLD) signals recorded by functional magnetic resonance imaging. The model provides a quantitative account of Hbr changes observed in each of the vascular compartments following stimulation of somatosensory cortex and visual cortex and of the BOLD signal following stimulation of motor and visual cortex.