A microiontophoretic study on the nature of the putative synaptic neurotransmitter involved in the pedunculopontine-substantia nigra pars compacta excitatory pathway of the rat

Summary The nature of the synaptic transmitter involved in the excitatory fibers linking the nucleus tegmenti pedunculopontinus (PPN) to the pars compacta of the substantia nigra (SNPC) was investigated using microiontophoretic techniques in rats anesthetized with ketamine. Among the SNPC cells activated orthodromically by PPN electrical stimulation, only a few cells were weakly excited by iontophoretically administered acetylcholine (Ach) while most were not affected. Conversely all cells were promptly and powerfully excited by short pulses of glutamate (GLU). The administration of the GLU antagonists glutamic acid diethylester (GDEE) and D--aminoadipic acid (DAA) reversibly and simultaneously suppressed both the PPN-evoked orthodromic response and the GLU-induced excitation of SNPC cells without affecting their response to iontophoretic Ach. GDEE was more effective than DAA in counteracting the synaptically evoked excitation. On the other hand, atropine, while antagonizing the Ach response in those cells which were cholinoceptive, did not affect either the PPN-evoked or the GLU-induced excitation. Hence, despite the presence of cholinergic cells in the PPN region, Ach does not appear to be involved in the excitatory PPNSNPC pathway. The present findings suggest that the excitatory PPN fibers innervating the SNPC may utilize GLU or a closely related amino acid as a neurotransmitter.Supported by grants from the Ministero della Pubblica Istruzione     

A Possible Mechanism for the Dopamine-Evoked Synergistic Disinhibition of Thalamic Neurons Via the “Direct” and “Indirect” Pathways in the Basal Ganglia

The mechanism of synaptic plasticity which we have previously proposed for striatal spiny neurons, along with published data on the predominance of dopamine-sensitive D1/D2 receptors on strionigral/striopallidal neurons, was used as the basis to propose the hypothesis that the induction of long-term potentiation/depression of the efficiency of the cortical inputs to these cells may result from the excitatory/inhibitory actions of dopamine on the activity of the neurons originating the direct and indirect pathways through the basal ganglia. Thus, the action of dopamine increases disinhibition of thalamic neurons via the direct pathway and decreases their inhibition via the indirect pathway. Both effects lead to increases in the activity of thalamic cells and in the activity of the efferent neocortical neurons which they excite. The actions of dopamine on striosomal neurons, which mainly have D1 receptors, may also be to induce long-term potentiation of cortical inputs. This effect should lead to increased inhibition of dopaminergic cells and decreases in their dopamine release, which may promote the maintenance of a stable dopamine concentration in the cortex-basal ganglia-thalamus-cortex neural network.     

Changes in the excitability of Renshaw cells due to orthodromic tetanic stimuli

Summary Monosynaptic extensor reflexes and orthodromically activated Renshaw cells were recorded simultaneously before, during and after intermittent tetanization of gastrocnemius nerves. Renshaw cells of both short and long latency (with respect to the reflex) were studied. During potentiation, the cells with short latency responded with an increase, those with long latency with a decrease in number of spikes per burst. After the end of tetanization, the burst length of both types remained greater than that before PPT for some time.Supported by the Deutsche Forschungsgemeinschaft (SFB 33 Nervensystem und Biologische Information).     

Metabolic control of respiratory neuronal activity and the accompanying changes in breathing movements of the rabbit

Summary The property of the neuronal membrane to be permeable to metabolic modifiers of two regulatory enzymes has been utilized to manipulate the spike activity of inspiratory (I) and expiratory-inspiratory (EI) neurons of the bulbar respiratory centre. The neurons have been classified according to their response to lung distension or collapse (- or -type) and to hyperventilation (tonic firing denoted by +, cessation of activity by –). Using extracellular microelectrodes for single unit recording, the medulla oblongata was superfused with a metabolite-containing CSF. The various neuronal sub-types exhibited a differential activating or inhibitory response to one or several metabolic effectors. For example I ⁺ units were activated by 5 mM glucose-6-phosphate (G-6-P) and 3.5 mM 3-phosphoglycerate (3-PGA), which both inhibited I ⁺ neurons, while 5 mM AMP inhibited I ⁺ much more strongly than I ⁺ cells. The spike density of I ^– and I ^– neurons was increased in the presence of 2.5 mM fructose-6-phosphate and 3.5–5 mM AMP, but became reduced by G-6-P. In contrast, 3 mM fructose-1,6-diphosphate and 5 mM 3-PGA activated the I ^– but inhibited the I ^– neurons. The EI units were characteristically activated by 10 mM citrate, which inhibited all I-type neurons. Activations of the I and I neurons led to an accelerated respiratory rate and a higher tidal volume, while the opposite was true for EI neurons. Intravenous injection of metabolites could not duplicate the striking effects under local applications.Supported by the Deutsche Forschungsgemeinschaft, Grant Ch 25/1.     

Control of locomotion in marine mollusc Clione limacina IV. Role of type 12 interneurons

Summary 1. Type 12 interneurons in pedal ganglia of Clione limacina exerted a strong influence upon the locomotor generator during intense swimming. These neurons generated plateau potentials, i.e. their membrane potential had two stable states: the upper one when a neuron was depolarized, and the down one, separated by 30–40 mV. The interneurons could remain in each state for a long time. Short depolarizing and hyperpolarizing current pulses, as well as excitatory and inhibitory postsynaptic potentials, could transfer the interneurons from one state to another. 2. When the pedal ganglia generated the locomotory rhythm, type 12 neurons received an EPSP and passed to the upper state in the V₂-phase of a locomotor cycle. They remained at this state until the beginning of the D₁-phase when they received an IPSP and passed to the down state. The EPSP in type 12 neurons was produced by type 8d neurons, and the IPSP by type 7 neurons. 3. Type 12 neurons exerted inhibitory influences upon many neurons active in the V₁ and V₂ phases, and excitatory influences upon the D-phase interneurons (type 7). 4. The functional role of type 12 neurons was to limit the activity of neurons discharging in the V-phase of a locomotory cycle. In addition, they enhanced the excitation of the D-phase neurons and promoted, thus, the transition from the V-phase to the D-phase.     

Functional organization of inferior area 6 in the macaque monkey

Summary The functional properties of neurons located in the rostral part of inferior area 6 were studied in awake, partially restrained macaque monkeys. The most interesting property of these neurons was that their firing correlated with specific goal-related motor acts rather than with single movements made by the animal. Using the motor acts as the classification criterion we subdivided the neurons into six classes, four related to distal motor acts and two related to proximal motor acts. The distal classes are: Grasping-with-the-hand-and-the-mouth neurons, Grasping-with-the-hand neurons, Holding neurons and Tearing neurons. The proximal classes are: Reaching neurons and Bringing-to-the-mouth-or-to-the-body neurons. The vast majority of the cells belonged to the distal classes. A particularly interesting aspect of distal class neurons was that the discharge of many of them depended on the way in which the hand was shaped during the motor act. Three main groups of neurons were distinguished: Precision grip neurons, Finger prehension neurons, Whole hand prehension neurons. Almost the totality of neurons fired during motor acts performed with either hand. About 50% of the recorded neurons responded to somatosensory stimuli and about 20% to visual stimuli. Visual neurons were more difficult to trigger than the corresponding neurons located in the caudal part of inferior area 6 (area F4). They required motivationally meaningful stimuli and for some of them the size of the stimulus was also critical. In the case of distal neurons there was a relationship between the type of prehension coded by the cells and the size of the stimulus effective in triggering the neurons. It is proposed that the different classes of neurons form a vocabulary of motor acts and that this vocabulary can be accessed by somatosensory and visual stimuli.     

Firing characteristics of vestibular nuclei neurons in the alert monkey after bilateral vestibular neurectomy

Summary After destruction of the peripheral vestibular system which is not activated by moving large-field visual stimulation, not only labyrinthine-ocular reflexes but also optokinetic-ocular responses related to the velocity storage mechanism are abolished. In the normal monkey optokinetic-ocular responses are reflected in sustained activity changes of central vestibular neurons within the vestibular nuclei. To account for the loss of optokinetic responses after labyrinthectomy, inactivation of central vestibular neurons consequent on the loss of primary vestibular activity is assumed to be of major importance. To test this hypothesis we recorded the neural activity within the vestibular nuclear complex in two chronically prepared Rhesus monkeys during a period from one up to 9 and 12 months after both vestibular nerves had been cut. The discharge characteristics of 829 cells were studied in relation to eye fixation, and to a moving small and large (optokinetic) visual stimulus producing smooth pursuit (SP) eye movements and optokinetic nystagmus (OKN). Units were grouped into different subclasses.After chronic bilateral vestibular neurectomy (BVN) we have found: (1) a rich variety of spontaneously active cells within the vestibular nuclear complex, which — as far as comparison before and after BVN is possible — belong to all subclasses of neurons functionally defined in normal monkey; and (2) no sustained activity changes which are related to the activation of the velocity storage mechanism; this is especially true for pure-vestibular, vestibular-pause and tonic-vestibular-pause cells in normal monkey which show a pure, pause and tonic-pause firing pattern after BVN. Neurons which are modulated by eye position are, however, modulated with the velocity of slow eye movements with comparable sensitivity during SP and OKN. Retinal slip is extremely rarely encoded. The results of the present study do not directly answer the question why the velocity storage mechanism is abolished after BVN but they suggest that only a small number of central vestibular cells may be inactivated by neurectomy.Supported by SNF grant no. 3.510-0.86     

Evidence for a respiration-modulated cholinergic action on the activity of medullary respiration-related neurons in the rabbit

Effects of the iontophoretically administered cholinergic agonists acetylcholine, bethanechol and DMPP on the activity of medullary respiration-related neurons were examined in urethane-anaesthetized rabbits. Inhibitory effects prevailed over excitatory effects. Analysis of cholinergic effects by cycle-triggered averaging revealed three major types of neuronal responses: (i) constant alterations of spike-density throughout the whole period of activity (constant effects), (ii) effects increasing during the progression of the burst of discharge or effects restricted to a particular fraction of the burst (phasic effects) and (iii) effects which were characterized by an excitation during one respiratory phase and an inhibition during the other phase (bi-phasic effects). The latter type of effects was observed in phase-spanning respiration-related neurons. Phasic effects were mainly observed in inspiration-related neurons which were predominantly inhibited by stimulation of muscarinic receptors. Inspiratory R-neurons in no case were phasically affected by cholinergic agents. The mean muscarinic inhibition of inspiration-related neurons increased with the progression of inspiration. The mean nicotinic inhibition of expiration-related neurons decreased with the progression of expiration. Results suggest that the efficacy of (i) a central inspiration terminating mechanism and (ii) the onset of discharge of expiratory neurons is modulated by acetylcholine.     

Binocular interactions and disparity coding in area 21a of cat extrastriate visual cortex

We have examined, using both qualitative and quantitative techniques, binocular interactions of extracellularly recorded single neurons in the extrastriate cortical area 21a of anaesthetized and paralysed cats. Consistent with previous reports we have found that: (a) all area 21a neurons were orientation-selective, with about 65% of them preferring orientations within 30° of the vertical; and (b) over 75% of area 21a cells could be activated through either eye. Furthermore, a significant minority (4 cells; about 10%) of a subpopulation of 39 neurons in which binocular interactions were examined quantitatively, were obligatory binocular neurons, that is, they responded very weakly, if at all, to the monocular stimuli presented through either eye but responded vigorously to simultaneous stimulation through both eyes. Almost 70% (27/39) of neurons tested quantitatively for binocular interaction have shown significant modulation (over 50%) of their peak responses in relation to binocular positional retinal disparities. The majority of neurons sensitive to binocular positional disparities resembled either tuned excitatory (22 cells; 56.5% of the sample) or tuned inhibitory (2 cells; 5% of our sample) cells. In particular, they gave, respectively, maximal or minimal responses to optimally oriented, moving photic stimuli when the receptive fields plotted through each eye completely or partially overlapped. Although neurons recorded in area 21a have relatively large receptive fields (mean width 3.3±1.1°; range 2.0–5.6°), the mean width of the disparity tuning curve (2.8±1.0°; range 1.3–4.8°) for our sample of area 21a neurons was similar to those of neurons with significantly smaller receptive fields, recorded in areas 17 and 18 of cat's primary visual cortex. We conclude that area 21a of the cat, like areas 17 and 18 of primary visual cortex, is likely to play an important role in binocular depth discrimination and might constitute a higher order area for stereoscopic binocular vision.     

Lability in the responses of cells in the auditory cortex of squirrel monkeys to species-specific vocalizations

Summary The activity of 28 cells located mainly in the secondary auditory cortex (A II) of awake squirrel-monkeys, was extracellularly recorded for periods of up to 6 h. Seven different species-specific vocalizations, which were repeatedly presented to the monkey, were used as auditory stimuli. Twenty-six cells responded, at least once, to one or more vocalizations; 22 cells revealed some change in their response (pattern or strength) to at least one vocalization (change in response). Twenty-one cells exhibited a change in the number and/or type of vocalization to which they responded during the recording period (change in selectivity). At some time during the recording period all the responding cells exhibited a change in response and/or a change in selectivity (change in responsiveness). A change in response of a cell to a vocalization did not necessarily exclude a change in selectivity, associated with the same vocalization, later in time and vice-versa. A change in responsiveness to one vocalization was not necessarily correlated with changes in responsiveness to other vocalizations.     

Neuron Activity in the Prefrontal Cortex of the Brain in Rats with Different Typological Characteristics in Conditions of Emotional Stimulation

Male Wistar rats were separated according to the emotional resonance method (groups of animals avoiding (altruists) and not avoiding (egotists) the pain cries of partner rats) and neuron activity in the prefrontal areas of the cortex was studied in the right and left hemispheres. Assessments were made of changes in the frequency of nerve cell spike activity (in relation to the baseline activity of neurons in sated animals) in rats subjected to one day of food deprivation and after electrical stimulation of emotionally positive (lateral hypothalamus) and negative (tegmentum of the midbrain) brain structures and after exposure to the pain cries of partner rats. The results of these experiments revealed a series of differences in the cell activities of the two groups of rats. In conditions of hunger, the discharge frequency in the altruists was higher than that in egotists. Cortical neuron responses to positive stimulation were greater than those to negative stimulation in rats of both groups. Intracerebral stimulation produced significantly greater increases in discharge frequency in neurons of both prefrontal areas of the cortex in altruists than in egotists. In both groups of rats, neurons in the right hemisphere responded to emotionally negative stimulation with significantly greater activation than cells in the left hemisphere, while activity in the left hemisphere was greater in conditions of emotionally positive stimulation. Altruists showed significantly greater neuron responses during exposure to pain cries from victim rats in both the right and left hemispheres. The responses of egotists to victim cries were not significantly different from baseline activity levels.     

Amygdalar inputs to ADH-secreting supraoptic neurones in rats

Summary Effects of amygdala stimulation on the discharge activity of antidromically identified supraoptic neurosecretory neurones were studied in male rats anaesthetized with urethane. Stimulation of the medial and the basal amygdala produced excitation or inhibition of discharge activity both in phasically firing (phasic) and in continuously firing (continuous) neurones. More phasic neurones were excited than were inhibited after medial amygdala stimulation. On the other hand, fewer continuous neurones were excited by stimulation of the either amygdala area than were inhibited. This difference of responsiveness between phasic and continuous neurones is statistically significant. Synaptic inputs to supraoptic neurosecretory neurones after amygdala stimulation were also observed in rats with a lesion of the stria terminalis. Supraoptic nucleus stimulation activated antidromically 14 of the 336 amygdala neurones tested. Since phasic neurones have been identified as ADH-secreting neurones, it is concluded that ADH-secreting neurones in the rat supraoptic nucleus receive predominantly excitatory synaptic inputs from the medial amygdala and these amygdalar synaptic inputs are mediated by pathways which are at least in part monosynaptic and are not included in the stria terminalis.Supported by the grants nos. 56440079, 56121007 and 56770057 from the Ministry of Education, Science and Culture, Japan     

Nicotinic effects on excitatory field potentials recorded from the immature CA3 area of rat hippocampal slices

We investigated the nicotinic modulation of the excitatory field potentials recorded from the immature (postnatal day 10–20) hippocampal CA3 area, in the presence of the GABA_A antagonist bicuculline methiodide (BMI, 10 M). Nicotine (50 M) enhanced the evoked field potentials; its effects were also observed in the presence of the GABA_B antagonist 2-hydroxy-saclofen (250 M; added to BMI) and were blocked by pre-perfusion with the nicotinic antagonist hexamethonium (HXM, 50 M). The potentiating effects of nicotine in BMI persisted during prolonged perfusion (more than 20 min), while those in control perfusion medium were transient. The nicotinic antagonists HXM (50 M), methyllycaconitine (MLA, 0.01 M) and dihydro--erythroidine (DHE, 50 M) potentiated CA3-evoked field potentials. Perfusion of HXM in the presence of the anticholinesterase eserine (1 M) or the muscarinic antagonist atropine (1 M) did not alter its effects. None of the nicotinic agents tested changed the frequency of spontaneous BMI-induced epileptiform discharges (nicotine, HXM, MLA, DhE), suggesting that nicotinic receptors do not drive spontaneous epileptiform discharges in this in vitro model. These experiments demonstrate that nicotinic receptors are activated tonically during disinhibition and modulate the activity of excitatory synapses in the immature CA3 hippocampal area. The persistent nicotinic facilitatory effects during disinhibition versus the transient in control conditions indicate that nicotinic modulation depends on environmental conditions and also that nicotinic receptors may be a contributing factor in early-life seizures.     

Activation of atrial muscarinic K+ channels by low concentrations ofβγ subunits of rat brain G protein

Effects of G protein subunits from rat brain on cardiac K⁺ channel was examined in single atrial cells of guinea-pig, using patch clamp techniques. We found that 10 pM concentration of rat brain subunits preparation could activate the atrial muscarine receptor-gated K⁺ channel (I_K.ACh). Neither the detergent, CHAPS, used to suspend nor the boiled preparation activated I_K.ACh. Furthermore, preincubation of subunits preparation in Mg²⁺-free solution, which easily inactivated -GTP-S, did not affect -activation of I_K.ACh. We concluded, therefore, that subunits themselves can activate I_K.ACh.Supported by the grants from the Ministry of Education, Culture and Science of Japan and from the Calcium Signal Workshop on Cardiovascular Systems     

Control of locomotion in marine mollusc Clione limacina III. On the origin of locomotory rhythm

Summary 1. Neurons from the isolated pedal ganglia of the marine mollusc Clione limacina were recorded from intracellularly during generation of the locomotory rhythm. Polarization of single type 7 or type 8 interneurons (which discharge in the D-and V-phases of a swim cycle, respectively) strongly affected activity of the rhythm generator. Injection of depolarizing and hyperpolarizing current usually resulted in shortening and lengthening of a swim cycle, respectively. A short pulse of hyperpolarizing current shifted the phase of the rhythmic generator. The same effect could be evoked by polarization of efferent neurons of types 2, 3 and 4 which are electrically coupled to interneurons. On the contrary, polarization of types 1, 6 and 10 efferent neurons, having no electrical connections with interneurons, did not affect the locomotory rhythm. 2. A number of observations indicate that type 7 and 8 interneurons constitute the main source of postsynaptic potentials that were observed in all the rhythmic neurons of the pedal ganglia. Type 7 interneurons excited the D-phase neurons and inhibited the V-phase neurons; type 8 interneurons produced opposite effects. 3. Tetrodotoxin eliminated spike generation in all efferent neurons of the pedal ganglia, while in interneurons spike generation persisted. After blocking the spike discharges in all the efferent neurons, type 7 and 8 interneurons were capable of generating alternating activity. One may conclude that these interneurons determine the main features of the swim pattern, i.e., the rhythmic alternating activity of two (D and V) populations of neurons. 4. Both type 7 and type 8 interneurons were capable of endogenous rhythmic discharges with a period like that in normal swimming. This was demonstrated in experiments in which one of the two populations of rhythmic neurons (D or V) was inhibited by means of strong electrical hyperpolarization, as well as in experiments in which interaction between the two populations, mediated by chemical synapses, was blocked by Co²⁺ ions. 5. Type 7 and 8 interneurons were capable of rebound, i.e. they had a tendency to discharge after termination of inhibition. 6. V-phase neurons exerted not only inhibitory but also excitatory action upon D-phase neurons, the excitatory action being longer than the inhibitory one. 7. The main experimental findings correspond well to the model of rhythm generator consisting of two half centres possessing endogenous rhythmic activity. The half-centres exert strong, short duration inhibitory and weak long duration excitatory actions upon one another. The behaviour of such a model is considered and compared with that of the locomotor generator of Clione.     

Surface segregation driven by orientation-defined junctions

This study was designed to ascertain whether the human visual system can segregate overlapped surfaces by integrating texture borders at second-order X-junctions. The stimuli used were crossed vertical and horizontal stripes consisting of Gabor micro-patterns. We manipulated the orientation of the center region of each stripe. Observers judged whether the crossed stripes appeared as two overlapped stripes or five individual regions. The results showed that the probability of perceiving overlapped stripes exceeded the chance level (0.5) when the orientation differences between the center and flanking regions were less than 30°. We suggest that the integration of texture borders along each stripe occurs by the filter-rectify-filter mechanism, resulting in the impression of overlapped surfaces. When this fails, the outcome is the perception of five individual regions.     

Localization of Triton-insoluble cAMP-dependent kinase type RIbeta in rat and mouse brain

In eukaryotic cells, cAMP regulates many different cellular functions. Its effects are in most cases mediated by cAMP-dependent protein kinases. These consist of two regulatory and two catalytic subunits. In mammals, four different isoforms of cAMP-dependent protein kinases regulatory subunits have been characterized (RI and , RII and ). These four isoforms show a high level of homology and slightly different biochemical properties. In addition to biochemical properties, a different anatomical distribution of the regulatory isoforms may contribute to determine the specificity of diverse cAMP effects. By immunohistochemistry, the distribution of the detergent-insoluble fraction of RI isoform has been examined in rat and mouse brain. Biochemical fractionation shows that a large fraction of both RI and RI isoforms is bound to the cytoskeleton. RI labelling can be observed only in few locations: Purkinje cells, olfactory mitral cells, lateral thalamic neurons, superior olivary complex neurons. These cell populations are involved in the so called Purkinje cell degeneration. On the other hand, RI aggregates have a more widespread distribution, in brain areas involved in visceroemotional control. At the subcellular level, these two subunits show a different pattern of labelling: in most cells a sharply defined clustered labelling is observed for RI isoforms, while the RI isoform presents a weaker, diffuse intracytoplasmic distribution. Competition experiments point to the presence of, as yet unidentified, different and selective anchoring proteins for the two similar RI and isoforms. It is suggested that, as is the case for structural proteins, a different supramolecular organization of similar regulatory proteins may be crucial in order to fulfill different functions.     

In vivo intracellular recordings of medial septal and diagonal band of Broca neurons: relationships with theta rhythm

Transmembrane potentials from medial septal and diagonal band of Broca (MS-DBB) neurons and hippocampal field activity were recorded in curarized and urethanized rats. MS-DBB cells were studied during large amplitude irregular activity and during hippocampal rhythm, elicited by either sensory (i.e. stroking the fur on the animal's back) or electrical stimulation of the reticularis pontis oralis nucleus (RPO). Three types of cells were described according to their firing pattern and the characteristics of their intracellular rhythm. Type A neurons displayed continuous rhythmic oscillations in the membrane potential (Vm) of approximately 17 mV. These oscillations generated rhythmic high-frequency spike trains which were phase-locked with hippocampal rhythm. Type A cells revealed intracellular rhythm even in the absence of hippocampal rhythm, suggesting that the activity of this type of cell was the most important in hippocampal genesis. Type B cells were characterized by marked postspike afterhyperpolarization and intracellular oscillations of smaller amplitude than in type A cells. Type C cells revealed a post-spike afterdepolarization and a lower amplitude, intracellular rhythm only in the presence of hippocampal rhythm. Type C neurons could fire slow spikes at depolarizing (46% of cells) or hyperpolarizing (15% of cells) Vms. Type B and C cells were intracellularly stained with Lucifer yellow. Although type B and C neurons revealed dissimilar electrophysiological properties, they had comparable morphological shapes. RPO electrical stimulation generated hippocampal rhythm and intracellular rhythm in types A and B cells but not in type C cells, and increased the spike rate in type C neurons. Electrical stimulation of the fornix only evoked synaptic responses in type B and C neurons, with antidromic responses being elicited in 12% of type C cells. These results indicate that probably most of the type A rhythmic cells did not receive direct hippocampal feedback and that at least some type C cells were projecting neurons. The present findings demonstrate that rhythm oscillations in the Vm of MS-DBB neurons elicit different rhythmic discharge patterns.     

Pattern of projection and physiological properties of cortico-cortical connections from the posterior bank of the ansate sulcus to the motor cortex,area 4γ, in the cat

Summary The physiological properties of neurons lying along the posterior bank of the ansate sulcus and the projection of these neurons to area 4 of the motor cortex of the cat were studied and the following results were obtained: (1) Short latency antidromic responses were recorded from neurons along the medial-lateral bank of the posterior ansate sulcus following intracortical microstimulation (ICMS) delivered to motor cortex, area 4. (2) The posterior ansate region projects topographically to the motor cortex. Neurons in the most medial part of the ansate region project to the medial part of 4, while neurons in the central and lateral parts of the ansate region project to the more lateral parts of area 4. (3) In 33 cases, receptive field information was available for both the antidromically activated ansate neuron and from neurons around the stimulating site in 4. In 58% of the cases, both cortical sites received afferent input from within the same part of the periphery. (4) Afferent input to the motor cortex was examined following combined ablations of the primary somatosensory cortex (SI) and third somatosensory cortex (SIII) including all of area 5. We conclude that the integrity of these cortical regions is not necessary for afferent input to reach the motor cortex.Supported by the NIH Grant NS-10705