Activity of cytochrome oxidase in centers of tectofugal and thalamofugal channels of the visual system of pigeon Columba livia

By using a histochemical method of determination of activity of cytochrome oxidase (CO), the level of metabolic activity in pigeons has been shown to be higher in centers of the tectofugal visual channel (pretectal nuclei: Pr, SP, SP/IPS, thalamic nucleus Rot, telencephalic entopallidum) than in centers of the thalamofugal visual channel (GLd, visual area of the hyperpallium Wulst). These data agree with the concept of the dominating role of the tectofugal visual channel in organization of the bird everyday behavior. The high CO activity is also characteristic of the mesencephalic structures (EM, isthmus nuclei: IMc, IPc, SLu) modulating transduction of visual information in tectum, Rot and GLd. Similar differences in the metabolic activities between two visual system channels have been shown earlier in reptiles, which indicates the evolutionary conservatism of the tectofugal visual channel among the sauropside amniotes. However, in pigeons the level of the CO activity in some GLd nuclei approaches that in Rot, which allows us to suggest a rise in birds of the role of the thalamofugal channel in processing of information necessary for performance of complex visual functions.     

Level of metabolic activity (cytochrome oxidase) as an index of functional significance of tectofugal and thalamofugal channels of the reptilian visual system

Using histochemical determination of activity of the mitochondrial oxidative enzyme cytochrome oxidase (CO) the metabolic activity in structures of brain of turtles and lizards was shown to be higher in centers of the tectofugal channel (tectal SGC, pretectal Ptv, thalamic Rot, telencephalic visual area of Advr of) than in the centers of the thalamofugal channel (thalamic GLd, Cxdl and Path of telencephalon) of the visual system. Some interspecies differences in distribution of CO activity in the tectal, thalamic, and telencephalic visual centers were revealed between terrestrial and pond turtles and lizards. The obtained data confirm the idea of the dominating role of the tectofugal visual pathway in information processing and organization of the usual behavior of reptiles.     

The level of metabolic activity (cytochrome oxidase) as an index of functional significance of tectofugal and thalamofugal channels of the reptilian visual system

Using histochemical determination of activity of the mitochondrial oxidative enzyme cytochrome oxidase (CO) in brain structures, metabolic activity both in turtles and in lizards has been shown to be higher in centers of the tectofugal channel (the tectal stratum griseum centrale, SGC; nucleus pretectalis ventralis, Ptv; thalamic nucleus rotundus, Rot; telencephalic visual area of the anterior dorsal ventricular ridge, Advr) than in the thalamofugal channel centers (the thalamic nucleus geniculatus lateralis pars dorsalis, GLd; cortex dorsolateralis, Cxdl; and pallial thickening, Path) of the visual system. Some interspecies differences in distribution of the CO activity in the tectal, thalamic, and telencephalic visual centers between terrestrial and pond turtles and lizards were revealed. The obtained data confirm the idea on the dominating role of the tectofugal channel over the thalamofugal channel of the visual system in information processing and organization of the day-to-day behavior of reptiles.     

Calcium-binding proteins and metabolic activity in thalamotelencephalic parts of the turtle visual system

Distribution of three calcium-binding proteins (CaBPr) calbindin (CB), calretinin (CR) and parvalbumin (PV) in parallel with metabolic activity (cytochrome oxidase, CO) was studied in telencephalic projection zones of the tecto- and thalamofugal visual pathways in experiments on the Horsfield's terrapin Testudo horsfieldi and the pond turtle Emys orbicularis. It was shown that the nucleus rotundus (Rot) and dorsal lateral geniculate nucleus (GLd) terminal fields in both zones (dorsolateral region of the anterior ventricular ridge, Advrdl and dorsolateral cortex, Cxdl, respectively) were CB-immunoreactive (-ir) in the both studied turtle species. The highest density of CB-ir terminals and the focus of rotundal projections in the Advrdl core coincided precisely. The GLd terminal field in Cxdl also was CR-ir. The PV contribution to innervation of both projectional zones was much lower, especially to innervation of Cxdl from GLd. In spite of similar CB-ir innervation, the projectional field of the tectofugal pathway of Advrdl had the much higher CO activity than of that of the thalamofugal pathway in Cxdl. The neurons immunoreactive to all three CaBPr types were distributed in Cxdl in different ratios in each of layers. In the visual Advrdl area the overwhelming majority were PV-ir neurons, whereas CB-ir neurons were absent. The conclusion is made that in spite of the CB- or CB/CR-immunoreactivity predominates over the PV-immunoreactivity in both thalamotelencephalic pathways of the visual system, the tectofugal (rotundo-Advrdl) pathway having the higher metabolic activity.     

Neurochemical organization of reptilian thalamus. Comparative analysis of amniote optical centers

Study of neurochemical characteristics of the turtle thalamus was performed using antibodies against several biologically active compounds; monoamines (5-HT, TH), neuropeptides (SP, m-Enk, NPY), against ChAT and by histochemical detection of NADPH-d. Based on our own results and literature data obtained on other representatives of reptiles, birds, and mammals, a comparative analysis was carried out of neurochemical organization of two thalamic optical centers—relay nuclei of thalamofugal (GLd) and tectofugal (Rot/LP-Pulv) systems of amniotes. Features of similarities and differences of these centers in representatives of non-mammalian and mammalian amniotes are revealed. GLd has a great similarity of the studied neurochemical characteristics in all amniotes. It receives innervation from all studied transmitter-modulatory systems with predominance of serotonin-, choline- and NPY-ergic projections. Neurochemical organization of Rot comparable with the tectorecipient part of mammalian LP-Pulv has a great resemblance in reptiles and birds, with considerable interspecies differences inside each class. In the majority of the studied systems, Rot is characterized by scant innervation. On the contrary, LP-Pulv receives sufficiently massive innervation from these systems. The most characteristic of this complex are rich SP- and cholinergic projections that are scant in Rot of reptiles and birds. The similar feature of Rot and LP-Pulv is the presence of massive serotonin- and NO-ergic (NADPH-positive) projections. The revealed similarities and differences of the neurochemical characteristics of thalamic optical centers among amniotes seem to reflect various transformations of thalamo- and tectofugal visual systems in the course of phylogenetic and adaptive evolution.     

Extrinsic cells, immunoreactive to Ca-binding protein, as sources of thalamic visual centres in tortoises

Extrinsic sources of calcium-binding proteins involved in immunoreactive innervation of the visual thalamic nuclei Rot and GLd in turtles (Testudo horsfieldi and Emys orbicularis) were studied using HRP tracing method and immunohistochemistry. In 1.5-4.5 months after monocular enucleation calbindin (Calb)-, parvalbumin (Parv)- and calretinin (Calr)-labeling was found in fragments of degenerated retinal fibers in the contralateral optic tract and in some retinorecipient structures (optic tectum, GLd and GLv). Changes in GLd were detected in its neuropil part. in 2.0-3.5 months after unilateral ablation of tectum and pretectum, the densities of Parv-, Calb- and Aclr-immunoreactivity terminals and fibers were diminisched in the ipsilateral n. Rot, with the maximum effect seen in Parv. Following HRP injection into the visual thalamus (Rot and GLd), retrogradely labeled cells with Parv label only, were revealed in the ventrothalamic nucleus Enta, pretectal nucleus Ptv, and in all types of Ca-binding proteins (CaBPr) in separately labeled cells of the optic tectum. Thus, it has been shown that thalamic visual centers in turtles have multiple extrinsic cells, which serve as sources of CaBPr projections. The present data suggest that organization of CaBPr inputs to visual thalamus in reptiles (turtle) and higher amniotes are fundamentally similar.     

Neurons of visual thalamic nuclei projecting to telencephalon express different types of calcium-binding proteins: A combined immunocytochemical and tracer study

In turtles (Testudo horsfieldi, Emys orbicularis), immunoreactivity to calbindin (CB), parvalbumin (PV), calretinin (CR) and co-localization of CB and PV were studied in neurons of the visual thalamic nuclei (Rot, GLd) projecting to the telencephalon using a combination of immunohistochemical and tracer methods. The prevalence of CB-immunoreactive (-ir) neurons in Rot, CB-ir and CR-ir neurons in GLd, and a smaller number of PV-ir neurons in both nuclei was shown. Double immunofluorescent labeling revealed that within both nuclei PV and CB are colocalized in most PV-ir and fewer CB-ir neurons. After injection of horseradish peroxidase into the Rot and GLs telencephalic projection fields, retrograde labeling was found in corresponding thalamic projection neurons immunoreactive to all the three proteins. After introduction of the fluorescent tracer Fluo-gold into the same telencephalic regions, retrograde labeling was detected in Rot and GLd neurons immunoreactive only to PV and CB as well as in neurons with colocalization of both proteins. These findings provide further evidence that in turtles the CB component prevails in the rotundo-telencephalic pathway while the CB/CR component is dominant in the geniculotelencephalic pathway. The role of functional specialization in segregation of neurons expressing distinct types of calcium-binding proteins is postulated.     

Calcium-Binding Proteins in the Turtle Thalamus. Analysis in the Light of Hypothesis of the “Core-Matrix” Thalamic Organization in Relation to the Problem of Homology of Thalamic Nuclei among Amniotes

Distribution of immunoreactivity (IR) to Ca-binding proteins (CaBPr) (calbindin, Calb, parvalbumin, Parv., and calretinin, Calr) was studied in the thalamus of the Central Asian terrestrial turtles (Testudo horsfieldi) and fresh water turtles (Emys orbicularis). There has been established a wide spread of these proteins, which combines overlapping and a relative alternation of distribution of different CaBPr in individual nuclei. A comparison of IR was made in two relay nuclei of the visual system, GLd and Rot. Both nuclei had IR to all CaBPr, but with different degree of intensity. In the terrestrial turtles, the amounts of Calb-, Parv-, and Calr-IR neurons in the cellular plate of the GLd were close. In this plate and in the neuropil part of this nucleus there was observed CaBPr-innervation of various density. Calr-IR neurons in the GLd of the fresh water turtles dominated over Parv- and Calb-IR neurons, whose detection varied significantly. In Rot, a clear predominance of Calb-IR neurons was shown over Parv- and Calr-IR cells by constancy of their detection, the number (1.5–2-fold higher), and intensity of the immune label, as well as the highest density of Calb and Parv innervation. The character of IR in the Rot was similar in the both turtle species. In the auditory and somatic relay thalamic nuclei and in the non-sensory anterior thalamic nuclei (Dma, Dla) there were present neurons and terminals with IR to all CaBPr without any predominance of Parv-IR in the relay nuclei and Calb-IR in the anterior thalamic nuclei. The constant and characteristic feature of Enta in the turtles of both species is a dense population of Parv-IR neurons, whose topography and cellular composition coincide with those of population of GABA-IR neurons in this nucleus. The data obtained have shown that the alternative presence of different CaBPr in the relay sensory and non-sensory thalamic nuclei, which has been established as a characteristic feature of the mammalian thalamus, is not characteristic at all of turtles. It seems that in the course of evolution there occurred a reorganization of distribution of different CaBPr in thalamic nuclei of amniotes due to changes of their functional loading. The reptilian thalamic sensory relay nuclei are likely to be represented mainly by less specific parts comparable with Calb-IR matrix of specific nuclei in the higher amniotes (mammals), while their more specialized (core) Parv-IR regions are formed later in evolution. Therefore, the distribution of Parv- and Calb-IR neurons in the turtle thalamic nuclei cannot be a criterion at evaluation of homology of thalamic nuclei in amniotes, but permits judging about the degree of their specialization.     

Evolutionary evaluation of reciprocity of connections in the turtle tectofugal visual system

In two turtle species—Emys orbicularis and Testudo horsfieldi—by the method of anterograde and retrograde traicing at the light and electron microscopy level, the existence is proven of direct descending projections from the thalamic nucleus of the tectofugal visual system n. rotunds (Rot) to the optic tectum. After injection of tracers into Rot alone and into Rot with involvement of the tectothalamic tract (Trtth), occasional labeled fibers with varicosities and terminals are revealed predominantly in the deep sublayers of SGFS of the rostral optic tectum, while in the lower amount—in other tectal layers. After the tracer injections into the optic tectum, a few retrogradely labeled neurons were found mainly in the Rot ventral parts and within Trtth. Their localization coincides with that of GABA-immunoreactive cells. Electron microscopy showed the existence of many retrogradely labeled dendrites throughout the whole Rot; a few labeled cell bodies were also present there, some of them being also GABA-immunoreactive. These results allow us to conclude about the existence of reciprocal connections between the optic tectum and Rot in turtles, these connections being able to affect processing of visual information in tectum. We suggest that reciprocity of tectothalamic connections might be the ancestral feature of the vertebrate brain; in the course of amniote evolution the functional significance of this feature can be decreased and even lost in parallel with a rise of the role of direct corticotectal projections.     

Components of the pigeon tectothalamic visual pathway, revealed with aid of study of cytochrome oxidase and immunoreactivity to calcium-binding proteins

Distribution of activity of cytochrome oxidase (CO) and immunoreactivity to parvalbumin (Pv) and calbindin (Cb) was studied in the optic tectum of the pigeon (Columba livia). In the first link of the tectofugal pathway in the central gray layer (SGC = layer 13), small amounts of the CO-active and Pv-immunoreactive (Pv-ir) cellular bodies were revealed in its internal part (sublayer 13b). Some of these neurons located along the SGC lower boundary had long dendritic processes ascending into the superficial tectum layer (SGF). In the retinorecipient SGF sublayers and particularly in neuropil of the sublayers 4 and 7, the high CO activity correlating with Pv-immunoreactivity was found. It is suggested that a great contribution to metabolic activity of these sublayers is made by the largely branching dendritic processes of Pv-ir neurons of sublayer 13b. The projectional neurons SGC located in its external part (sublayer 13a) were CO-inactive and contained Cb. They sent long dendrites into sublayer 5b; in its neuropil, the high density of Cb-immunoreactivity and a moderate CO activity were detected. Thus, the tectal link of the pigeon tectofugal visual channel consists of two components--the Pv-specific, highly metabolically active and the Cb-specific, metabolically less active ones that transduce visual information from different retinorecipient SGF sublayers. The absence of the significant amount of CO-positive bodies of projectional neurons in SGC can be due to that metabolically more active are their dendritic arborizations in the SGF sublayers.     

Components of the pigeon tectothalamic visual pathway, revealed with aid of study of cytochrome oxidase activity and immunoreactivity to calcium-binding proteins

Distribution of activity of cytochrome oxidase (CO) and immunoreactivity to parvalbumin (Pv) and calbindin (Cb) was studied in the optic tectum of the pigeon (Columba livia). In the first link of the tectofugal pathway in the central gray layer (SGC = layer 13), small amounts of the CO-active and Pv-immunoreactive (Pv-ir) cellular bodies were revealed in its internal part (sublayer 13b). Some of these neurons located along the SGC lower boundary had long dendritic processes ascending into the superficial tectum layer (SGF). In the retinorecipient SGF sublayers and particularly in neuropil of the sublayers 4 and 7, the high CO activity correlating with Pv-immunoreactivity was found. It is suggested that a great contribution to metabolic activity of these sublayers is made by the largely branching dendritic processes of Pv-ir neurons of sublayer 13b. The projectional neurons SGC located in its external part (sublayer 13a) were CO-inactive and contained Cb. They sent long dendrites into sublayer 5b; in its neuropil, the high density of Cb-immunoreactivity and a moderate CO activity were detected. Thus, the tectal link of the pigeon tectofugal visual channel consists of two components—the Pv-specific, highly metabolically active and the Cb-specific, metabolically less active ones that transduce visual information from different retino-recipient SGF sublayers. The absence of the significant amount of CO-positive bodies of projectional neurons in SGC can be due to that metabolically more active are their dendritic arborizations in the SGF sublayers.     

Calcium-binding proteins and cytochrome oxidase activity in the turtle optic tectum with special reference to the tectofugal visual pathway

Using immunohistochemistry and a tracer technique we investigated the distribution in the optic tectum of turtles (Emys orbicularis and Testudo horsfieldi) of the calcium-binding proteins (CaBPr) parvalbumin (PV), calbindin (CB) and calretinin (CR) before and after labeling of the nucleus rotundus (Rot) with horseradish peroxidase. The optic tectum activity of the cytochrome oxidase (CO) was studied in parallel. In the principal link of the tectofugal visual pathway (central gray layer, SGC) in both chelonian species, the sparse PV-ir as well as CB- and CR-ir neurons were found significantly varying both in number and the intensity of immunoreactivity of their bodies and dendrites. In contrast, the superficial (SGFS) and deeper periventricular (SGP) tectal layers comprised numerous cells immunoreactive to all three CaBPr in different proportions. Only few retrogradely labeled tectorotundal SGC neurons expressed PV, CB or CR. The very large PV-ir neurons in SGC and SAC were not retrogradely labeled; morphologically they matched the efferent neurons with descending projections. SGC neurons of two chelonian species differed in the level of CO activity. Intense immunoreactivity to all three CaBPr and high CO activity were detected in both species in SGFS neuropil with some differences in sublaminar distribution patterns. The peculiarities of the CaBPr and CO activity distribution patterns in different segments of SGC neurons are discussed as related to the laminar organization of the turtle tectum and its retinal innervation. It is suggested that in the projection tectorotundal SGC neurons the CaBPr are concentrated mainly in their distal dendrites that contact retinal afferents in the superficial retinorecipient tectal layer.     

Distribution of metabolic activity (cytochrome oxidase) and immunoreactivity to calcium-binding proteins in turtle brainstem auditory nuclei

Using histochemical and immunohistochemical techniques, distribution of activity of oxidative mitochondrial enzyme cytochrome oxidase (CO) and of immunoreactivity to calcium-binding proteins has been studied in spiral ganglion and auditory nuclei of brainstem in two turtle species. It has been shown that immunoreactivity to calbindin, parvalbumin, and calretinin in neurons and neuropil of nuclei of cochlear and superior olivary complexes, in nucleus of lateral lemniscus, and in spiral ganglion neurons coincides topographically with the high CO activity. The similarity of the studied metabolic and neurochemical characteristics of these auditory centers in reptiles, birds, and mammals indicates the existence of some common principles of their organization in amniotes in spite of phylogenetic differences and peculiarities of specialization of the auditory system in different species.     

Regulation of ipsilateral visual information within the tectofugal visual system in zebra finches

The eyes of zebra finches are placed laterally, the foveae are looking into different directions. It is unlikely that the birds are able to process different images from both eyes simultaneously. A neural mechanism might therefore be necessary to guide the birds' attention to one of the two eyes and to reduce the processing of information of the other. Previous studies revealed that information from the ipsilateral eye is indeed suppressed on its way to the telencephalon by the activity of the contralateral eye. It has been suggested that two nuclei of the tecto-thalamic tract, nucleus subpraetectalis and nucleus interstitio praetecto subpraetectalis, are a central part of such a suppressive mechanism. Using electrophysiological recordings, we investigated the influence of these two nuclei and nucleus rotundus on the processing of binocular visual information by treating the nuclei with picrotoxin or electrolytic lesions. Deactivation of inhibitory neurons within SP/IPS leads to a significant increase of the ectostriatal responses to ipsilateral and bilateral stimulation, the responses to contralateral stimulation remain unaffected. Lesioning SP/IPS does not alter the responses to visual stimuli. Treatment of nucleus rotundus with picrotoxin increases contralaterally and bilaterally, but not ipsilaterally evoked responses. A wiring diagram is presented which interprets these findings.     

Distribution of metabolic activity (cytochrome oxidase) and immunoreactivity to calcium-binding proteins in the turtle brainstem auditory nuclei

Using histochemical and immunohistochemical techniques, distribution of activity of oxidative mitochondrial enzyme cytochrome oxidase (CO) and calcium-binding proteins-immunoreactivity was studied in the spiral ganglion and auditory nuclei of brainstem in two turtle species. Calbindin-, parvalbumin-and calretinin-immunoreactivity in neurons and neuropil of cochlear, supraolivary complexes, the lateral lemniscal nucleus and neuropil of spiral ganglion is shown to coincide topographically with high activity of CO. Similarity of the studied metabolic and neuro-chemical characteristics of these auditory centers in reptiles, birds and mammals suggests some general principles of their organization in amniotes, despite phylogenetic differences and peculiarities of auditory system in different species.     

Calcium-Binding Proteins and Cytochrome Oxidase Activity in the Pigeon Entopallium: A Comparative Analysis of Interspecies Variability as Related to the Discussion on Avian Entopallium Homology

We report the results of our studies of the distribution patterns of calcium-binding proteins (parvalbumin, PV, and calbindin, CB) and metabolic activity (cytochrome oxidase, CO) in the pigeon entopallium—the telencephalic projection field of the tectofugal visual system. These characteristics were comparatively analyzed in different avian species in the light of the recent revision of entopallial projections’ nomenclature (Krützfeldt and Wild, 2005). We demonstrate that in the pigeon neuropil both high PV immunoreactivity and CO activity as well as lower CB immunoreactivity are confined to the core region of the entopallium (E). The latter contains cells immunoreactive (ir) to PV and CB and having a heterogenous repertoire: small/medium-sized granular and large multipolar cells. They overlap in E and partly colocalize within the same cell, but differ in the internal (Ei) and external (Ex) portions by distribution density and labeling intensity. CO activity was identified in both cellular morphotypes. Sparse PV- and CB-ir cells were found in the perientopallium (Ep). The interspecies variability of PV and CB immunoreactivity, described in the avian entopallium by other authors, indicates its dependence on the adaptive functional specialization which underlies selective expression of these calcium-binding proteins. The above as well as the pertinent literature data are discussed in the wake of the current discussion on homology of the avian entopallium, supporting the idea of the existence in sauropsid amniotes of the ancestral precursor of the mammalian extrastriate visual cortex.     

Neurotransmitter Receptor Ligand Binding and Enzyme Regional Distribution in the Pigeon Visual System

The relative importance of acetylcholine, dopamine, endogenous opiates, gamma-aminobutyric acid (GABA), glutamate, glycine, noradrenaline, and serotonin as transmitters in the pigeon visual system was estimated by measuring the activity of choline acetyltransferase (ChAT), glutamic acid decarboxylase (GAD), and aromatic amino acid decarboxylase (AAD) as well as the binding of dihydroalprenolol, etorphine, kainic acid, muscimol, serotonin, spiroperidol, strychnine, and quinuclidinyl benzilate (QNB) in the tectum opticum, nucleus rotundus, ectostriatum, dorsolateral thalamus, and hyperstriatum (Wulst). As a nonvisual reference structure, the paleostriatal complex was included in the examination. The regional distribution of most of these parameters was very similar to data reported in the mammalian CNS supporting the hypothesis that the avian tectofugal and thalamofugal visual systems are homologous to the mammalian tecto-thalamo-cortical and retino-geniculo-striate pathways, respectively. On the basis of the low values of their parameters, some transmitters can be excluded as significant contributors in a number of structures. As a hypothesis for further investigations, the presence of cholinergic and serotoninergic systems in the Wulst, possibly originating in the dorsolateral thalamus and nucleus raphe, respectively, and of glycinergic and dopaminergic terminals in the paleostriatal complex is proposed.     

Developmental study of cytochrome oxidase activity in the brain stem respiratory nuclei of postnatal rats.

We utilized cytochrome oxidase (CO) as a marker of neuronal functional activity to examine metabolic changes in brain stem respiratory nuclei of rats from newborn to 21 day of age. The pre-B?tzinger complex (PBC), upper airway motoneurons of nucleus ambiguus (NA(UAM)), ventrolateral nucleus of solitary tract (NTS(VL)), and medial and lateral parabrachial nuclei (PB(M) and PB(L), respectively) were examined at postnatal days (P) 0, 1, 2, 3, 4, 5, 7, 14, and 21. CO histochemistry was performed, and the intensity of CO reaction product was quantitatively analyzed by optical densitometry. In addition, CO histochemistry was combined with neurokinin-1 receptor (NK1R) immunogold-silver staining to doubly label neurons of PBC in P14 animals. The results showed that levels of CO activity generally increased with age in all of the nuclei examined. However, a significant decrease was found in NA(UAM) at P3 (P < 0.01), and a distinct plateau of CO activity was noted at P3 in PBC and at P3 and P4 in NTS(VL), PB(M), and PB(L). Of the neurons examined in PBC, 83% were doubly labeled with CO and NK1R. Of these, CO activity was high in 33.9%, moderate in 27.3%, and light in 38.8% of neurons, suggesting different energy demands in these metabolic groups that may be related to their physiological or synaptic properties. The transient decrease or plateau in CO activity at P3 and P4 implies a period of synaptic adjustment or reorganization during development, when there may be decreased excitatory synaptic drive or increased inhibitory synaptic drive, or both, in these brain stem respiratory nuclei. The adjustment, in turn, may render the system less responsive to respiratory insults. This may bear some relevance to our understanding of pathological events during postnatal development, such as occurs in sudden infant death syndrome.     

Role of substance P in hypercapnic excitation of carotid chemoreceptors

Experiments were performed on 17 anesthetized, paralyzed, and artificially ventilated cats to evaluate the importance of substance P-like peptide (SP) on the carotid body responses to CO2. Single or paucifiber carotid chemoreceptor activity was recorded from the peripheral end of the cut carotid sinus nerve. In eight of the cats the influence of SP on hyperoxic hypercapnic responses was studied. While the animals breathed 100% O2, intracarotid infusion of SP (1 microgram.kg-1.min-1, 3 min) increased chemoreceptor activity by +4.8 +/- 0.3 impulses/s. After SP infusion, inhalation of CO2 in O2 caused a rapid increase in activity that reached a peak and then adapted to a lower level, whereas similar levels of CO2 before SP caused only a gradual increase in carotid body discharge rate without any overshoot in response. Furthermore SP significantly increased the magnitude and slope of the CO2 response. In the other nine cats the effect of intracarotid infusion of an SP antagonist, [D-Pro2,D-Trp7,9] SP (10-15 micrograms.kg-1.min-1), on carotid body responses to 1) hyperoxic hypercapnia (7% CO2-93% O2), 2) isocapnic hypoxia (11% O2-89% N2), and 3) hypoxic hypercapnia (11% O2-7% CO2-82% N2) was examined. SP antagonist had no effect on carotid body response to hyperoxic hypercapnia but significantly attenuated the chemoreceptor excitation caused by isocapnic hypoxia and hypoxic hypercapnia. These results suggest that 1) SP may play an important role in carotid body responses to hypoxia but not to CO2, and 2) the mechanisms of stimulation of the carotid body by hypercapnia and by hypoxia differ.     

Stimulus size selectivity and receptive field organization of ectostriatal neurons in the pigeon

The avian ectostriatum is the telencephalic recipient zone of the tectofugal pathway, which may be homologous to the colliculo-pulvinar-cortical pathway in mammals. The present paper studies the visual response properties and receptive field organization of ectostriatal cells in pigeons with extracellular recording and computer mapping techniques. The results indicate that 90% of ectostriatal cells prefer forward, downward and upward motion of visual stimuli at velocities in the range of 16-128 degrees s(-1). They respond optimally to small stimuli (1-4 degrees visual angle), mostly preferring a target of 2 degrees. Most cells (78.8%) have one excitatory receptive field that usually possesses one or two hotspots, some cells (13.5%) have two excitatory receptive fields each having one or two hotspots, and a few cells (7.7%) have one excitatory receptive field with an unresponsive region in the center. An inhibitory receptive field is not found surrounding the excitatory receptive field in the ectostriatal cells examined. These response properties and receptive field organization may reflect the possible roles of the ectostriatum in stimulus discrimination and visual cognition.