The central release of acetylcholine during stimulation of the visual pathway

1. In rabbits anaesthetized with Dial ACh has been collected from the surface of the cerebral cortex during stimulation of the visual pathways.2. The spontaneous release of ACh from the visual and non-visual areas of the cortex was found to be similar.3. Stimulation of the retinae by diffuse light produced a large increase in ACh release from the primary visual receiving areas (4.3 times the spontaneous release) and a smaller increase (1.9 times the spontaneous release) from other parts of the cortex.4. Direct unilateral electrical stimulation of the lateral geniculate body evoked a large increase in ACh release (3.4 times the spontaneous release) from the ipsilateral visual cortex and a smaller increase (1.7 times the spontaneous release) from the contralateral visual area and other regions of the cerebral cortex. The evoked increase from the contralateral cortex was not mediated by transcallosal pathways.5. The increase in ACh release evoked from the visual cortex by stimulation of the ipsilateral lateral geniculate body was dependent on the frequency of stimulation. The evoked release was smallest at low stimulus frequencies and increased to a maximum at 20 stimuli/sec.The evoked ACh release from other areas of the cortex was independent of the frequency at which the lateral geniculate body was stimulated.6. The possible central nervous pathways associated with the spontaneous release of ACh and the release evoked by stimulation of the eyes by light and by direct stimulation of the lateral geniculate body are discussed.7. It is concluded that two ascending cholinergic systems may be involved; the non-specific reticulo-cortical pathways responsible for the e.e.g arousal response, and the more specific thalamo-cortical pathways associated with augmenting and repetitive after-discharge responses. The first system is thought to be concerned with the small but widespread increase in ACh release from the cortex following stimulation of the visual pathway while the second system could give rise to the larger increases evoked from the primary receiving areas of cortex. The spontaneous release of ACh from the surface of the brain may be the result of contributions from both systems.     

Inactivation of prefrontal cortex abolishes cortical acetylcholine release evoked by sensory or sensory pathway stimulation in the rat

Sensory stimulation and electrical stimulation of sensory pathways evoke an increase in acetylcholine release from the corresponding cortical areas. The pathways by which such sensory information reaches the cholinergic neurons of the basal forebrain that are responsible for this release are unclear, but have been hypothesized to pass through the prefrontal cortex (PFC). This hypothesis was tested in urethane-anesthetized rats using microdialysis to collect acetylcholine from somatosensory, visual, or auditory cortex, before and after the PFC was inactivated by local microdialysis delivery of the GABA-A receptor agonist muscimol (0.2% for 10 min at 2 microl/min). Before PFC inactivation, peripheral sensory stimulation and ventral posterolateral thalamic stimulation evoked 60 and 105% increases, respectively, in acetylcholine release from somatosensory cortex. Stimulation of the lateral geniculate nucleus evoked a 57% increase in acetylcholine release from visual cortex and stimulation of the medial geniculate nucleus evoked a 72% increase from auditory cortex. Muscimol delivery to the PFC completely abolished each of these evoked increases (overall mean change from baseline = -7%). In addition, the spontaneous level of acetylcholine release in somatosensory, visual, and auditory cortices was reduced by 15-59% following PFC inactivation, suggesting that PFC activity has a tonic facilitatory influence on the basal forebrain cholinergic neurons. These experiments demonstrate that the PFC is necessary for sensory pathway evoked cortical ACh release and strongly support the proposed sensory cortex-to-PFC-to-basal forebrain circuit for each of these modalities.     

Input-selective potentiation and rebalancing of primary sensory cortex afferents by endogenous acetylcholine

Acetylcholine (ACh) plays important roles in the modulation of activity and plasticity of primary sensory cortices, thus influencing sensory detection and integration. We examined this in urethane-anesthetized rats, comparing cholinergic modulation of short latency, large amplitude field postsynaptic potentials (fPSPs) in the visual cortex (V1) evoked by stimulation of the ipsilateral lateral geniculate nucleus (LGN), reflecting direct thalamocortical inputs, with longer latency, smaller amplitude fPSPs elicited by contralateral LGN stimulation, reflecting indirect, polysynaptic inputs. Basal forebrain (BF) stimulation (100 Hz) produced a significant (45%), gradually developing potentiation of the smaller, contralateral fPSPs, while ipsilateral fPSPs showed less enhancement (15%), shifting the relative strength of dominant/ipsi- and weaker/contralateral inputs to V1. Systemic or local, cortical blockade of muscarinic receptors (scopolamine) reduced potentiation of contralateral fPSP without affecting ipsilateral enhancement, thus preventing the relative amplification of contralateral inputs following BF stimulation. Systemic nicotinic receptor blockade (mecamylamine) resulted in depression of ipsilateral, and reduced enhancement of contralateral fPSPs after BF stimulation. N-methyl-d-aspartate receptor blockade (systemic MK-801) abolished ipsilateral fPSP enhancement without affecting contralateral potentiation. Neither drug reduced the amplification of contralateral relative to ipsilateral signals in V1. In a second experiment in the barrel cortex, BF stimulation enhanced multiunit activity elicited by whisker deflection in a muscarinic-sensitive manner. Similar to the observations in V1, this effect was more pronounced for weaker multiunit activity driven by a surround whisker than activity following principal whisker deflection. These experiments demonstrate that ACh release following BF stimulation exerts surprisingly selective effects to amplify non-dominant inputs to sensory cortices. We suggest that, by diminishing the imbalance between different afferent signals, ACh release during states of behavioral activation acts to induce a long-lasting facilitation of the detection and/or integration of signals in primary sensory fields of the cortical mantle.     

Properties of single neurons in the cat midsuprasylvian gyrus

Summary Responses of cells in the midsuprasylvian gyrus (MSSG) of cats were investigated following electrical stimulation of the central lateral nucleus (CL) of the thalamus and tooth pulp, low-threshold cutaneous or visual afferents. Electrical stimulation in CL induced excitation in many cells located in cortical areas 5 and 7. Cells in these areas also received input from somato-sensory and visual afferents. Cells in MSSG showed a wide convergence from tooth pulp, low-threshold cutaneous afferents and from the CL. The majority of wide convergent cells in area 5 were found in layers IV and V, while cells excited by CL and tooth pulp were found in layers II and III. Similarities were found between CL and tooth pulp evoked responses with regard to the excitation-inhibition pattern. The excitation evoked from CL and tooth pulp was less often followed by a hyperpolarizing potential compared to that seen after low-threshold lip, paw and visual afferent stimulation. Stimulation sites in the lateral parts of CL-evoked responses with the shortest latencies in area 5. In this part of the cortex, short latency synaptic potentials were found in cells in superficial layers. In the same area, synaptic potentials of short latency were also evoked by electrical stimulation of tooth pulp, lip and paw. Light-flash stimulation evoked responses with the shortest latencies in area 7. The results of this study demonstrate that putative nociceptive information reaches the parietal association cortex and that part of this input may be relayed via CL. We suggest that the excitatory influences of nociceptive and CL stimulation is related to behavioral arousal and attention mechanisms.Abbreviations AV anteroventral nucleus - CL central lateral nucleus - CM centre median nucleus - GL lateral geniculate nucleus - LD lateral dorsal nucleus - LP lateral posterior complex - MD mediodorsal nucleus - MSSG midsuprasylvian gyrus - OT optic tract - PAC paracentral nucleus - PF parafascicular nucleus - Po posterior thalamic nuclei - PP pes pedunculi - STT spinothalamic tract - VB ventrobasal complex - VA ventroanterior nucleus - VL ventrolateral complex - VMB basal ventromedial nucleus - VMH ventromedial hypothalamic nucleus - VPL ventroposterolateral nucleus - VPM ventroposteromedial nucleus - C.Max contralateral maxillary canine tooth - I.Max ipsilateral maxillary canine tooth - C.Mand contralateral mandibular canine tooth - I.Mand ipsilateral mandibular canine tooth - C.Lip contralateral upper lip - I.Lip ipsilateral upper lip - C.F.Paw contralateral forepaw - I.F.Paw ipsilateral forepaw - C.H.Paw contralateral hindpaw - I.H.Paw ipsilateral hindpaw - AP anteroposterior plane (in mm anterior to the interauricular plane) - ML mediolateral plane (in mm lateral to the midline)     

Different effects of electrical stimulation of the mesencephalic and pontine reticular formation on the release of dopamine and acetylcholine in the cat caudate nucleus

The effects of unilateral electrical stimulation of the pontine (PRF) and mesencephalic (MRF) reticular formation on the release of acetylcholine (ACh) and of [3H]dopamine continuously synthesised from [3H]tyrosine were examined in both caudate nuclei of halothane-anaesthetised cats implanted with push-pull cannulae. Stimulation of PRF led to a prolonged bilateral increase in the release of [3H]dopamine, whereas a significant reduction in [3H]amine release was observed in the ipsilateral caudate nucleus following stimulation of the MRF. Changes in ACh release were also seen, but they seemed to be independent from those in dopamine release: the release of ACh was enhanced markedly in both caudate nuclei following stimulation of the MRF, whereas a more moderate increase in the release of ACh occurred ipsilaterally following stimulation of the PRF. These data indicate that both the MRF and the PRF are involved in the control of dopaminergic and cholinergic transmission in the basal ganglia.     

The effect of topically applied atropine on resting and evoked cortical acetylcholine release

1. Cortical acetylcholine (ACh) output was measured in cats anaesthetized either with Dial compound (0.6 ml./kg) or with halothane-N(2)O. ACh output was found to be 1.67 ng/cm(2).min under Dial anaesthesia, and 0.30 ng/cm(2).min under halothane-N(2)O.2. Addition of atropine sulphate (1 mug/ml.) to the collection fluid increased ACh output fourfold under Dial anaesthesia but had no effect under halothane-N(2)O anaesthesia.3. Isolation of the cortex, lesions in the mesencephalon and topical application of tetrodotoxin (TTX) reduced ACh output under Dial anaesthesia to about 0.8 ng/cm(2).min. The effect of atropine on ACh output was somewhat reduced by isolation and completely abolished by mesencephalic lesions or TTX.4. ACh release evoked by reticular formation stimulation under halothane-N(2)O anaesthesia was increased fourfold by atropine but evoked release due to direct stimulation of the cortex was increased only twofold.5. ACh release due to depolarization of the cortex with KCl was not increased by atropine.6. Dihydro-beta-erythroidine (DHE) or D-tubocurarine failed to affect ACh output even in a concentration of 100 mug/ml.7. It is concluded that atropine does not increase spontaneous ACh release and only ACh release evoked by trans-synaptic stimulation of cholinergic neurones is potentiated by atropine.8. These findings are fully consistent with the hypothesis that atropine increases ACh output by blocking cortical cholinergic synapses which are a part of a circuit inhibiting cholinergic neurones.     

Transient and prolonged facilitation of tone-evoked responses induced by basal forebrain stimulations in the rat auditory cortex

We investigated the relationships between cortical arousal and cholinergic facilitation of evoked responses in the auditory cortex. The basal forebrain (BF) was stimulated unilaterally, while cluster recordings were obtained simultaneously from both auditory cortices in urethane-anesthetized rats. The global electroencephalogram (EEG; large frontoparietal derivation) and the local EEG (from the auditory cortex) were recorded. The BF was stimulated at two intensities, a lower one which did not desynchronize the EEG and a higher one which did. Twenty pairing trials were delivered, during which a tone was presented 50 ms after the end of the BF stimulation. At low intensity, the pairing procedure led to a transient increase in the ipsilateral tone-evoked responses. At high intensity, the pairing increased the ipsilateral evoked responses up to 15 min after pairing. Such effects were not observed for the contralateral recordings. Systemic atropine injection prevented the facilitations observed ipsilaterally. BF stimulations alone did not induce any increased evoked response either at low or at high intensity. These results show (1) that a tone, presented while the cortex is activated by cholinergic neurons of the BF, evokes enhanced cortical responses, and (2) that the duration of this facilitation is dependent on the stimulation intensity. These results are discussed in the context of neural mechanisms involved in general arousal and cortical plasticity.     

Effects of cholinergic depletion on neuron activities in the cat visual cortex

1. Unilateral lesions of the nucleus basalis magnocellularis (nBM), a source of cholinergic projection to the cerebral cortex, were produced by injection of kainic acid in the cat. The lesions caused a significant reduction in density of choline acetyltransferase-immunoreactive terminals in the visual cortex ipsilateral to the lesions. 2. In the primary visual cortex ipsilateral to the lesions [acetylcholine (ACh)-depleted cortex], about half of the cells had weak or undetectable visual responses, whereas in the contralateral visual cortex almost all the cells had normal responsivity. The response selectivity, such as orientation and direction selectivities, of cortical cells was not affected by the depletion of ACh. 3. The microionophoretic application of ACh to cells under observation facilitated visual responses in 83% of the cells recorded from the ACh-depleted cortex, whereas it suppressed the responses in only 9%. The application of a muscarinic antagonist, atropine, to cells in the ACh-depleted cortex was ineffective, suggesting no residual ACh activity. 4. The mean current required to induce facilitation in the cortex ipsilateral to the lesion was significantly smaller than that required in the contralateral cortex and the visual cortex of the normal cat, suggesting a supersensitivity of receptors mediating the effect or a reduction in catabolism of exogenous ACh in the ACh-depleted cortex. 5. More than half of the cells that had been unresponsive to visual stimuli became clearly responsive during the ACh application. The response magnitude of cortical cells, as a whole, increased to the same degree as that observed during the ACh application in the normal cat. 6. In addition to the decrease in the average response magnitude, there was a remarkable variability in responses of cells to motion of the slit from sweep to sweep in the ACh-depleted cortex. The application of ACh to cortical cells decreased the variability of responses and consequently made the responses much more consistent. 7. These results suggest that without ACh supplied from the nBM, most of the cortical neurons could not respond briskly and consistently to excitatory inputs and that exogenously applied ACh could reverse such an impairment of cortical neurons through intact or even supersensitive postsynaptic receptors.     

The effects of graded forelimb afferent volleys on acetylcholine release from cat sensorimotor cortex.

1. The acetylcholine (ACh)-releasing system in the cerebral cortex of pentobarbital anaesthetized cats was investigated by examining the effect of graded afferent volleys in forelimb nerves on ACh release from the sensorimotor cortices contralateral and ipsilateral to the site of stimulation. 2. Cortical ACh release was determined by bio-assay of neostigmine-containing perfusates which had been in contact with the cortical surfaces for 5-10 min periods. 3. Afferent volleys, generated by stimuli that were effective in activating as many fibres of a fibre group as possible without stimulating fibres in the group with the next highest threshold for activation, were monitored from dorsal roots C7 or C8 before entering the spinal cord. 4. Stimulation of the deep (DR) and superficial (SR) radial nerves and the radial (R) nerve proximal to the junction of the DR and SR were effective in enhancing ACh release only when either group III or groups III and IV fibres were included in the afferent volley. 5. The rates of ACh release from the primary receiving area of the sensorimotor cortex contralateral to the site of stimulation did not differ from those from the same area of the ipsilateral sensorimotor cortex. 6. The pertinence of this data to the various hypotheses concerning the nature of the ACh-releasing pathways to the cerebral cortex is discussed.     

Cholinergic mechanisms in the reticular control of transmission in the cat lateral geniculate nucleus

1. We examined the hypothesis that the ascending reticular arousal system influences thalamic transmission through a cholinergic mechanism. Extra- and intracellular recordings were obtained from neurons of the dorsal lateral geniculate nucleus (LGNd) and the perigeniculate nucleus (PGN) of cats anesthetized either with N2O and pentobarbital or with N2O and halothane. We compared the effects that electrical stimulation of the mesencephalic reticular formation (MRF) and ionophoretically applied acetylcholine (ACh) have on spontaneous and evoked activity of individual neurons and tested whether these effects could be antagonized by ionophoretic administration of the muscarinic receptor blocker scopolamine. The effects of ionophoretically applied glutamate (GLU), N-methyl-D-aspartate, and bicuculline were examined in addition. 2. The prominent effects in LGNd relay cells of both ACh application and of MRF stimulation were an enhancement of the resting discharge, a facilitation of the excitatory responses to light, a reduction of the amplitude and duration of evoked inhibitory episodes, and a blockade of postinhibitory rebound burst. These latter effects resembled those induced with bicuculline. Under barbiturate anesthesia neither ACh application nor MRF stimulation elicited discharges when the excitatory input from the retina was blocked. Ionophoretic application of hte muscarinic antagonist scopolamine abolished the effects of ACh ionophoresis in all relay cells tested (n = 20), and in 10 cells it also antagonized completely the effects of MRF stimulation. In the remaining cells scopolamine reduced the effects of MRF stimulation. 3. Increasing the depth of anesthesia reduced or abolished the effects of ACh application and MRF stimulation on the cells' resting activity but did not interfere with the facilitation of evoked responses. 4. The effects of the excitatory amino acids GLU and NMDA differed from those of MRF stimulation and ACh application, since the former always enhanced both spontaneous and evoked discharges but neither shortened phases of evoked inhibition nor abolished postinhibitory rebound bursts. 5. There was a high correlation between the effectiveness of MRF stimulation and ACh application in individual neurons. On the average, the facilitation of evoked responses was more pronounced in X- than in Y-cells, and the fraction of cells responding with an increase of resting activity to both procedures was considerably higher among X- than among Y-cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neocortical connections in fetal cats

The major extrinsic projections to and from visual and auditory areas of cerebral cortex were examined in fetal cats between 46 and 60 days of gestation (E46-E60) using axonal transport of horseradish peroxidase either alone or in combination with tritiated proline. Projections to visual cortex from the dorsal lateral geniculate nucleus and lateral-posterior/pulvinar complex exist by E46, and those from the contralateral hemisphere, claustrum, putamen, and central lateral nucleus of the thalamus are present by E54-E56. In addition, cells in the medial geniculate nucleus project to auditory cortex by E55. At E54-E56 efferent cortical projections reach the contralateral hemisphere, claustrum, putamen, lateral-posterior/pulvinar complex and reticular nucleus of the thalamus. Cells in visual cortex also project to the dorsal and ventral lateral geniculate nuclei, pretectum, superior colliculus and pontine nuclei, and cells in auditory cortex project to the medial geniculate nucleus. Except for interhemispheric projections, all pathways demonstrated are ipsilateral, and projections linking cerebral cortex with claustrum, dorsal lateral geniculate nucleus and lateral-posterior/pulvinar complex are reciprocal. The reciprocal projections formed with the dorsal lateral geniculate nucleus, lateral-posterior/pulvinar complex and the claustrum show a greater degree of topological organization compared to the projections formed with the contralateral hemisphere and superior colliculus, which show little or no topological order. Therefore, the results of the present study show that the major extrinsic projections of the cat's visual and auditory cortical areas with subcortical structures are present by the eighth week of gestation, and that the origins and terminations of many of these projections are arranged topologically.     

A comparison of the effects of bilateral and unilateral infusions of muscimol into the basal forebrain on cued detection of visual targets in rats

This study investigated the role of the basal forebrain cholinergic system (BFCS) in rats' performance of a visuospatial attention task. Muscimol was infused bilaterally and unilaterally into the BFCS to inhibit cholinergic projections to the cortex. Muscimol slowed responding without significantly affecting side-bias. Bilateral infusions increased accuracy for all targets, whereas unilateral infusions reduced accuracy for targets contralateral to the infusion and increased accuracy for targets ipsilateral to the infusion. After a low unilateral dose of muscimol, invalid cues impaired detection of contralateral targets and spared detection of ipsilateral targets. A high unilateral dose of muscimol impaired detection of contralateral targets independently of cueing. These results suggest that interhemispheric imbalance in cortical activity by pharmacological manipulation of the BFCS can impair the detection of lateralized visual stimuli.     

Effects of unilateral electrical stimulation of various thalamic nuclei on the release of dopamine from dendrites and nerve terminals of neurons of the two nigrostriatal dopaminergic pathways

The role of several motor and intralaminar thalamic nuclei in the regulation of dopamine release from terminals and dendrites of the nigrostriatal dopaminergic neurons was investigated in halothane-anaesthetized cats. For this purpose, the effects of the unilateral electrical stimulation of various thalamic nuclei on the release of newly synthesized [3H]dopamine were simultaneously determined in both substantiae nigrae and caudate nuclei using the push-pull cannula method. The electrical stimulation of the motor nuclei was the only one to induce asymmetric changes in the four structures since [3H]dopamine release was enhanced in the ipsilateral caudate nucleus and reduced in the contralateral structure while opposite responses were observed in the corresponding substantiae nigrae. A reduction of [3H]dopamine release occurred in the four structures or only in the contralateral substantia nigra and caudate nucleus following the stimulation of the parafascicularis nucleus and the adjacent posterior part of the nucleus centrum medianum or of the nucleus centralis lateralis and the adjacent paralaminar part of the nucleus medialis dorsalis, respectively. The stimulation of the anterior part of the nucleus centrum medianum, which in contrast to other thalamic nuclei examined, receives few nigral inputs, selectively enhanced [3H]dopamine release in the contralateral substantia nigra. No significant changes in [3H]dopamine release were seen either in the substantiae nigrae or in the caudate nuclei following the stimulation of midline thalamic nuclei. These results indicate that the motor and intralaminar thalamic nuclei exert multiple and selective influences on the release of dopamine from terminals and/or dendrites of the dopaminergic neurons. They also further support a role of thalamic nuclei in the transfer of information from one substantia nigra to the contralateral dopaminergic neurons. The possible involvement of connections between paired thalamic nuclei was underlined by the observations of evoked potentials in contralateral homologous nuclei following unilateral stimulation of motor, or some intralaminar, nuclei. The present report provides new insights on the mechanisms contributing to the reciprocal and/or bilateral regulations of nigrostriatal dopaminergic pathways.     

A functional role of cholinergic innervation to neurons in the cat visual cortex

1. Effects of microionophoretic application of acetylcholine (ACh) and its antagonists on neuronal responses to visual stimuli and to electrical stimulation of the lateral geniculate nucleus were studied in the cat striate cortex. 2. Responses elicited visually and electrically were facilitated by ACh in 74% of the cells tested, whereas the responses were suppressed in 16%. These ACh effects were blocked by a muscarinic antagonist, atropine, but not by a nicotinic antagonist, hexamethonium, indicating that the ACh effects are mediated through muscarinic receptors. A single application of atropine suppressed visual responses of cells facilitated by ACh, whereas it enhanced those of cells inhibited by ACh, suggesting that endogenous ACh may tonically modulate visual responsivity of cortical neurons. 3. In most cells with the facilitatory ACh effect, responses with single spikes to the electrical stimulation became more consistent, often with double spikes, during the ACh application. The suppressive effects of ACh were noted most often in cells with a longer response latency to electrical stimulation of lateral geniculate nucleus. 4. In most of the facilitated cells the spontaneous activity remained null or very low during ACh application, in spite of marked enhancement of visual responses, suggesting that ACh may improve the signal-to-noise ratio (S/N) of cortical neuron activity. To confirm this suggestion, we calculated a S/S + N index by counting the total number of spikes in the responses (S) and that in peristimulus time histogram (S + N) and found that it was improved during the ACh application in about a half of the cells, whereas it became worse in about one-fifth. 5. In most of the facilitated cells, ACh enhanced visual responses not only to optimal but also to nonoptimal stimuli, resulting in no improvement or even worsening of the orientation selectivity. This was also the case in the selectivity of direction of stimulus movement. 6. The laminar location of the facilitated cells was biased toward layers V and VI of the cortex, although they also made up the majority in layers II + III and about half the tested cells in layers IVab and IVc. 7. In the light of recent understanding of cortical circuitry, these results suggest that the cholinergic innervation to cortical neurons may play a role in improvement of the S/N ratio of information processing in the striate cortex and in facilitation of sending processed informations to other visual centers.     

Convergence of specific visual and commissural impulses upon inhibitory interneurones in cat's visual cortex

Interaction between inhibition converging from the specific visual and commissural pathways to the efferent cells of cat's visual cortex was studied by paired stimulation of the lateral geniculate body and the corpus callosum. When stimulation of the lateral geniculate body was preceded by relatively weak stimulation of the corpus callosum, there was facilitation of the test inhibitory postsynaptic potentials (IPSPS) at an interval of about 1 msec and depression at longer intervals. With conditioning by stronger stimulation of the corpus callosum, the facilitation disappeared leaving the depression starting at 1 msec and continuing for more than 100 msec. Double shock stimulation of the lateral geniculate body or the corpus callosum alone also revealed similar depression of the test IPSPs. The IPSPs evoked by stimulation of the cortical surface close to the penetrated cell also exhibited similar depression after stimulation of the lateral geniculate body or corpus callosum.These findings suggest that the specific visual and commissural pathways share an inhibitory interneurone in the final common pathway to the efferent cells in the visual cortex.     

A study of the organization of the locus coeruleus projections to the lateral geniculate nuclei in the albino rat

The lateral geniculate nuclei of the rat are known to receive an innervation from catecholamine-containing neurons. In the present study the origin, axonal projections and terminal distribution of this innervation was studied. The lateral geniculate nuclei contain a356 ± 20 ng norepinephrine/g and64 ± 7 ng dopamine/g tissue; the latter is within the range expected for dopamine as a precursor in a region innervated by a norepinephrine-containing terminal system. When separate norepinephrine-containing cell groups located at various brain stem levels are ablated or their axonal projections destroyed, only lesions in the locus coeruleus produce a significant decrease in the norepinephrine content of the lateral geniculate nuclei. Injections of horseradish peroxidase into the lateral geniculate nuclei result in retrograde transport of horseradish peroxidase only to the noradrenergic neurons of the locus coeruleus. The labelled neurons are pretent throughout the rostrocaudal and dorsoventral axes of both the ipsilateral (60%) and contralateral (40%) nucleus. Autoradiographic and fluorescence histo-chemical experiments indicate that axons that ascend from the locus coeruleus reach the lateral geniculate nuclei via the dorsal tegmental catecholamine-containing bundle and the medial forebrain bundle. These fibers enter the ventral lateral geniculate nucleus from the zona incerta and the dorsal lateral geniculate nucleus from the superior thalamic radiation, thalamic reticular nucleus, and lateral posterior nucleus. Contralateral fibers from the locus coeruleus cross in the posterior commissure, supraoptic and pontine decussations and join the ipsilateral projections to the lateral geniculate nuclei. The bilateral locus coeruleus innervation of the nuclei is comprised of a highly branched network of varicose axons. Neither the ipsilateral nor the contralateral projections appear to be topographically organized; instead, a single fiber may have collateral axons that branch throughout large areas of the nuclei. This innervation is moderately dense in the ventral, and very dense in the dorsal, lateral geniculate nucleus.The study indicates that both the dorsal and ventral lateral geniculate nuclei receive a diffuse catecholamine-containing innervation which arises solely from the norepinephrine-containing neurons of the locus coeruleus. The innervation of each lateral geniculate nucleus is bilateral, with noradrenergic neurons located throughout both the ipsilateral and the contralateral locus coeruleus contributing to ascending pathways that terminate as a diffuse, plexiform innervation interspersed among other afferents to the lateral geniculate nuclei. It is speculated that such a diffuse noradrenergic innervation might depress the spontaneous activity of neurons in the lateral geniculate nuclei, while preserving or enhancing their responsiveness to afferent optic stimulation.     

The effects of stimulating the cerebellar nodulus in the cat on the responses of vestibular neurons

In a first series of experiments, recordings were obtained from cat abducens and trochlear motorneurons and from axons of secondary vestibular neurons terminating in these motor nuclei, and the effects of cerebellar nodulus stimulation on utricular- and canal-evoked responses in these neurons were studied. Ultricular activation of vestibular axons recorded in the ipsilateral VIth and contralateral IVth nuclei was probably monosynaptically inhibited by nodular stimulation provided conditioning-test intervals were in the range between 0-10 ms and the test stimuli were close to threshold intensities. Of the vestibular axons activated by stimulation of the semicircular canal nerves only those evoked by the horizontal canal stimulation and recorded in the ipsilateral VIth nucleus were weakly inhibited. When the vestibular stimuli were strong enough to produce clear field potentials in the motor nuclei and/or postsynaptic potentials in motorneurons, nodular stimulation had practically no effect on their amplitudes. It is concluded that inhibition of vestibuloocular transmission is weak as compared to floccular inhibition studied previously. In a second series of experiments, recordings were obtained from vestibular neurons which were activated antidromically and/or transsynaptically by stimulation of the contralateral fastigial nucleus, and the effects of ipsilateral nodular stimulation on these responses were studied. It was found that nodular stimulation inhibited both antidromic as well as transsynaptic fastigial activations of vestibular neurons. Most of these vestibular neurons were located in the descending vestibular nucleus and received polysynaptic vestibular and spinal inputs. It is concluded that in addition to its weak inhibitory effect on vestibuloocular transmission the nodulus exerts a powerful inhibition on vestibular neurons transmitting vestibular and spinal inputs to cerebellar nuclei and/or cortex. It is suggested that the nodulus controls cerebellar projecting vestibular neurons which carry vestibular and spinal information to the cerebellum. The vestibular, proprioceptive and visual information which is present in the nodulus may aid the role of the nodulus in controlling body posture.     

Selective potentiation of crossed vs. uncrossed inputs from lateral geniculate nucleus to visual cortex by the basal forebrain: Potential facilitation of rodent binocularity

Cholinergic projections originating in the basal forebrain (BF) play important roles in the heterosynaptic facilitation of synaptic strength in various sensory cortices, including the primary visual cortex (V1). Here, using urethane-anesthetized rats, we find that pairing burst stimulation of the BF with single pulse stimulation of the lateral geniculate nucleus (LGN) does not consistently increase field postsynaptic potentials (fPSPs) in V1 elicited by ipsilateral LGN stimulation. However, longer latency fPSPs recorded in V1 in response to stimulation of the contralateral LGN, reflecting crossed, polysynaptic inputs, show significant potentiation when paired with preceding BF stimulation. This synaptic enhancement requires relatively short time intervals between paired BF burst and LGN pulse stimulation (40 ms) and is abolished by systemic or local V1 muscarinic receptor blockade (scopolamine), while systemic nicotinic receptor blockade (mecamylamine) is ineffective. Together, these data provide evidence for a differential capacity for cholinergic/muscarinic-dependent plasticity induction among different signals in V1, with inputs reaching V1 from the contralateral LGN exhibiting potentiation in the face of stable strength in ipsilateral LGN-V1 projections. This preferential readiness for potentiation in crossed fiber systems could serve to amplify binocular responses in V1 elicited by synchronized excitation of ipsi- and contralateral LGN neurons.     

Growth of a new fiber projection in the brain of adult rats: Re-innervation of the dentate gyrus by the contralateral entorhinal cortex following ipsilateral entorhinal lesions

Summary Ablation of the entorhinal cortex of the rat removes the major synaptic input to the granule cells of the ipsilateral dentate gyrus. Following unilateral entorhinal lesions in adult rats, we have examined the efferent projections of the remaining contralateral entorhinal cortex to determine if these might sprout to re-innervate the deafferented dentate gyrus. Autoradiographical tracing of the fiber projections of the remaining contralateral entorhinal cortex 60 days following lesions indicates that new fibers sprout and grow for several hundred microns into the denervated regions, to terminate on portions of the granule cell dendrites which would normally receive ipsilateral entorhinal afferents.These re-innervating fibers form electrophysiologically functional synaptic connections with the denervated dentate granule cells. In the normal animal, unilateral stimulation of the entorhinal cortex does not result in short latency activation of the contralateral dentate gyrus whereas following ipsilateral entorhinal lesions, re-innervation by contralateral entorhinal afferents is reflected electrophysiologically by the appearance of a new short latency evoked potential to contralateral entorhinal stimulation. By field potential analysis, we demonstrate that this new short latency evoked potential is a reflection of mono-synaptic activation of the denervated dentate granule cells by the re-innervating contralateral entorhinal fibers.In addition, the time course of contralateral entorhinal re-innervation is determined electrophysiologically. The new short latency response to contralateral entorhinal stimulation appears as early as 9 days post-lesion, matures functionally between 9 and 15 days, and after 15 days, remains apparently undiminished for as long as 200 days. This implies that the new synapses formed in response to a deafferenting lesion are formed rapidly and remain permanently capable of activating the dentate granule cells which had been deprived of ipsilateral entorhinal input.The material in this paper was included in a dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy at the University of California at Irvine, Irvine, California 92664.     

Selective optogenetic stimulation of cholinergic axons in neocortex

Acetylcholine profoundly affects neocortical function, being involved in arousal, attention, learning, memory, sensory and motor function, and plasticity. The majority of cholinergic afferents to neocortex are from neurons in nucleus basalis. Nucleus basalis also contains projecting neurons that release other transmitters, including GABA and possibly glutamate. Hence, electrical stimulation of nucleus basalis evokes the release of a mixture of neurotransmitters in neocortex, and this lack of selectivity has impeded research on cholinergic signaling in neocortex. We describe a method for the selective stimulation of cholinergic axons in neocortex. We used the Cre-lox system and a viral vector to express the light-activated protein channelrhodopsin-2 in cholinergic neurons in nucleus basalis and their axons in neocortex. Labeled neurons depolarized on illumination with blue light but were otherwise unchanged. In anesthetized mice, illumination of neocortex desynchronized the local field potential, indicating that light evoked release of ACh. This novel technique will enable many new studies of the cellular, network, and behavioral physiology of ACh in neocortex.