Pattern generator for repetitive avian vocalization: preliminary localization and functional characterization

Electrical stimulation of the midbrain call areas was used to drive medullary neurons. Their activity was recorded with fine (25 mum) wire electrodes that allowed the nearer ones to be resolved as units. Syringeal (hypoglossal) motor neurons were identified by antidromic activation. Various units were turned on, speeded, slowed, stopped, or caused to fire in repetitive bursts. All units that were antidromically activated by hypoglossal stimulation fired in repetitive bursts with a rhythms which closely resembled that of calling. Many other units also fired in this bursting pattern, and the large majority of them were found at the obex or caudal to it despite extensive search rostrally. The nature of likely inputs to the medullary call neurons is discussed.     

The spino-reticulo-spinal loop can slow down the NMDA-activated spinal locomotor network in lamprey

Lamprey spino-bulbar neurones modulate the activity of reticulospinal cells during locomotion. The aim of the present study was to investigate the effects of interrupting or increasing this feedback from the spinal cord on the fictive locomotor pattern. Double-bath experiments were performed on in vitro brain stem/spinal cord preparations. Fictive locomotion was induced by perfusing the spinal cord with 150 microM N-methyl-D-aspartate (NMDA). Blocking the synaptic transmission in the brain stem by exposing it to Mn2+ ions increased the locomotor rhythm. Conversely, stimulation of single reticulospinal neurones during the ipsilateral ventral root burst, when they were depolarized, increased the cycle duration by prolonging the ipsilateral motor burst. The spino-reticulo-spinal loop is an integral part of the locomotor network.     

Dysfunction of Ib (autogenic) spinal inhibition in patients with progressive supranuclear palsy

We compared the activity of Ib spinal interneurons in five patients with progressive supranuclear palsy (PSP) with six age-matched control subjects. Stimulation of the medial gastrocnemius nerve at motor threshold intensity activated Ib afferents that in turn inhibit H reflexes from the soleus muscle. Maximum inhibition occurred at interstimulus intervals of 6 and 8 ms for both control subjects and PSP patients and was significantly greater in the PSP patients. Increased Ib activity of PSP patients may be caused by loss of inhibition of Ib interneurons through degeneration of the medullary reticulospinal pathway. The corticospinal pathways, unopposed by the medullary reticulospinal tract, may excessively activate Ib interneurons.     

Medullary respiratory neuronal activity modulated by stimulation of the fastigial nucleus of the cerebellum

The ability of the rostral fastigial nucleus (FNr) of the cerebellum to modulate medullary respiratory neuronal activity was examined in 17 anesthetized, paralyzed and ventilated cats. A bipolar stimulating electrode was positioned into the FNr and tungsten microelectrodes used to record units within the nucleus tractus solitarius (NTS), nucleus ambiguus (NA) and nucleus retroambigualis (NRA). Transient stimuli (< 150 microA, 5-200 Hz) were delivered during inspiration or expiration, and the effects noted on medullary neuronal activity and the phrenic neurogram. The results showed that FNr stimulation: (1) modulated inspiratory and expiratory neuronal (ramp-, early- and late-inspiratory and stage I and II expiratory) discharges recorded from the NTS, NA and NRA (n = 67, 14 and 28) when stimuli (> or = 20-50 Hz) were delivered during either the inspiratory or expiratory phases; (2) terminated the burst durations of inspiratory (77%) and expiratory (94%) neurons with stimulus-response latencies of 28.2 +/- 3.1 ms (inspiratory) and 29.4 +/- 3.6 ms (expiratory); (3) elicited changes in phrenic neurogram concomitant with the effects noted on medullary neuronal activities; (4) failed to change heart rate and arterial blood pressure; and (5) did not affect medullary neuronal and phrenic nerve activity following kainic acid injection into the FNr. We conclude that activation of the FNr (likely its cell bodies) can modulate the respiratory output via influences on medullary respiratory-related neurons. The primary cerebellar effect across all sub-types of respiratory neurons was early termination.     

The immune response of cattle, persistently infected with noncytopathic BVDV, after superinfection with antigenically semi-homologous cytopathic BVDV

The present study was undertaken to investigate firing patterns, locations, and projections to the phrenic motor nucleus of respiratory neurons in medullary raphe nuclei of rat. Experiments were performed on spontaneously breathing rats anesthetized with sodium pentobarbital. Extracellular spikes of single respiratory neurons were explored in midline medullary tegmentum. A total of 107 respiratory neurons was recorded in the raphe magnus, obscurus and pallidus. They were classified into the following eight types based on the relation of their firing patterns to the phase of respiration: (1) Inspiratory (I) throughout (n = 42); (2) I-late (n = 9); (3) I-decrementing (n = 1); (4) Pre-I (n = 2); (5) I-frequency modulated (n = 13); (6) Post-I (n = 12); (7) Expiratory (E) (n = 23) and (8) E-frequency modulated neurons (n = 5). Twenty of the 45 respiratory neurons examined were antidromically activated from the phrenic motor nucleus at the C4 spinal level with thresholds of 2-58 microA and latencies of 0.4-2.4 ms. Among the 20 neurons, 11 neurons were I-throughout, five were I-frequency modulated and four were E neurons. These results suggest that there is a population of neurons in the medullary raphe nuclei that projects to the phrenic motor nucleus at the C4 spinal level. It is possible that this projection may, in part, mediate the control of the diaphragmatic muscle motor neurons located in the C4 segments.     

Motor patterns and kinematics during backward walking in the pacific giant salamander: evidence for novel motor output

Kinematic and motor patterns during forward and backward walking in the salamander Dicamptodon tenebrosus were compared to determine whether the differences seen in mammals also apply to a lower vertebrate with sprawling posture and to measure the flexibility of motor output by tetrapod central pattern generators. During treadmill locomotion, electromyograms (EMGs) were recorded from hindlimb muscles of Dicamptodon while simultaneous high-speed video records documented movement of the body, thigh, and crus and allowed EMGs to be synchronized to limb movements. In forward locomotion, the trunk was lifted above the treadmill surface. The pelvic girdle and trunk underwent smooth side-to-side oscillations throughout the stride. At the beginning of the stance phase, the femur was protracted and the knee joint extended. The knee joint initially flexed in early stance and then extended as the foot pushed off in late stance, reaching maximum extension just before foot lift-off. The femur retracted steadily throughout the stance. In the swing phase, the femur rapidly protracted, and the leg was brought forward in an "overhand crawl" motion. In backward walking, the body frequently remained in contact with the treadmill surface. The pelvic girdle, trunk, and femur remained relatively still during stance phase, and most motion occurred at the knee joint. The knee joint extended throughout most of stance, as the body moved back, away from the stationary foot. The knee flexed during swing. Four of five angles showed significantly smaller ranges in backward than in forward walking. EMGs of forward walking showed that ventral muscles were coactive, beginning activity just before foot touchdown and ceasing during the middle of stance phase. Dorsal muscles were active primarily during swing. Backward locomotion showed a different pattern; all muscles except one showed primary activity during the swing phase. This pattern of muscle synergy in backward walking never was seen in forward locomotion. Also, several muscles demonstrated lower burst rectified integrated areas (RIA) or durations during backward locomotion. Multivariate statistical analysis of EMG onset and RIA completely separated forward and backward walking along the first principal component, based on higher RIAs, longer durations of muscle activity, and greater synergy between ventral muscles during early stance in forward walking. Backward walking in Dicamptodon uses a novel motor pattern not seen during forward walking in salamanders or during any other locomotor activity in previously studied tetrapods. The central neuronal mechanisms mediating locomotion in this primitive tetrapod are thus capable of considerable plasticity.     

Cellular and synaptic modulation underlying substance P-mediated plasticity of the lamprey locomotor network

The tachykinin substance P modulates the lamprey locomotor network by increasing the frequency of NMDA-evoked ventral root bursts and by making the burst activity more regular. These effects can last in excess of 24 hr. In this paper, the effects of substance P on the synaptic and cellular properties of motor neurons and identified network interneurons have been examined. Substance P potentiated the amplitude of monosynaptic glutamatergic inputs from excitatory interneurons and reticulospinal axons. The amplitude and frequency of miniature EPSPs was increased, suggesting that the synaptic modulation was mediated presynaptically and postsynaptically. The postsynaptic modulation was caused by a specific effect of substance P on the NMDA component of the synaptic input, whereas the presynaptic component was calcium-independent. Substance P did not affect monosynaptic glycinergic inputs from lateral interneurons, crossed inhibitory interneurons, or ipsilateral segmental interneurons or postsynaptic GABAA or GABAB responses, suggesting that it has little effect on inhibitory synaptic transmission. At the cellular level, substance P increased synaptic inputs, resulting in membrane potential oscillations in motor neurons, crossed caudal interneurons, lateral interneurons, and excitatory interneurons. The spiking in response to depolarizing current pulses was increased in motor neurons, lateral interneurons, and excitatory interneurons, but usually was reduced in crossed inhibitory interneurons. Substance P reduced the calcium-dependent afterhyperpolarization after an action potential in motor neurons and lateral interneurons, but did not affect this conductance in excitatory or crossed inhibitory interneurons. The relevance of these cellular and synaptic changes to the modulation of the locomotor network is discussed.     

Vestibular inputs to bulbar respiratory interneurons in the cat

Vestibular inputs to medullary respiratory interneurons were studied in decerebrated and artificially ventilated cats. Extracellular recordings were made from 40 neurons located in the area of pre-B?tzinger complex and activated antidromically from the contralateral ventral respiratory group. Neuronal populations analyzed included inspiratory and expiratory neurons with augmenting, constant and decrementing firing patterns, and a late inspiratory neuron. Seventeen neurons responded to ipsilateral and/or contralateral vestibular nerve electrical stimulation. These responses were observed in all seven cell types. Most neuronal reflex responses consisted of inhibition, while a few consisted of either excitation or a combination of both inhibition and excitation. These results indicate that pre-B?tzinger respiratory interneurons, which may be involved in respiratory rhythmogenesis, also participate in vestibulorespiratory responses.     

Response diversity of pontine and deep cerebellar nuclear neurons to air puff stimulation of the eye in the alert cat

The discharge of antidromically identified brainstem and cerebellar nuclear neurons involved in the corneal reflex was recorded in the alert cat during corneal air puffs. Eye movements were measured with the search coil technique. Recorded sensory, motor, reticular formation and cerebellar nuclear neurons showed a wide diversity in latencies and patterns of response to air puff stimulation. This diversity suggests that each part of the circuit may contribute different properties to information processing for the corneal reflex, for sustained eyelid closure and, possibly, for the classical conditioning of the nictitating membrane response.     

Maximum discharge rates of respiratory neurons during opossum development

The observed low frequencies of action potentials observed in medullary respiratory neurons of immature opossums (Didelphis virginiana) could occur because these cells are incapable of achieving higher sustained firing rates. Nonsustainability of firing might also help explain why the inspired breath is brief (approximately 0.1 s) in the youngest opossums and rises very slowly during postnatal life. Firing frequencies of medullary respiratory neurons were examined in spontaneously breathing thiobarbiturate-anesthetized opossums before and after stimulation by the glutamate agonists, N-methyl-D-aspartate (NMDA; 20 mM) or kainic acid (KA; 0.5 mM). Drugs were applied using progressively larger pressure injections through a micropipette; animals were tested from the 5th postnatal wk to adulthood. With a sufficient injection volume, stimulation of cell firing would be followed by apparent suppression of action potentials. A maximum "sustained" firing frequency was obtained from the last injection where discharge remained elevated for at least 0.5 s. Inspiratory and expiratory neurons tested with either drug showed the lowest rates of firing in opossums at 5-9 wk of age compared with 10- to 14-wk-old animals and/or adults. Despite higher rates of discharge in 10- to 14-wk-old animals and/or adults, maximum sustained neuronal firing in the youngest animals was at a higher frequency than during spontaneous breathing and, at least in the cell population tested, does not represent a limitation that might affect breathing pattern.     

Structural characterization of three genetic variants of human serum albumin modified in subdomains IIB and IIIA

Sympathetic outflow is regulated by a direct pathway of the rostral ventrolateral reticular formation (rvlm) to the thoracic spinal cord. For the first time, a dual retrograde/anterograde transport technique was used to demonstrate by light microscopy, potential disynaptic pathways from the rvlm to the thoracic spinal cord in the rat. An anterograde tracer, biotinylated dextran amine (BDA) was injected into the rvlm and a retrograde tracer, FluoroGold (FG) deposited into the upper thoracic spinal cord in the same animal. Rostral ventrolateral medullary efferents labeled with BDA were apposed to thoracic reticulospinal neurons labeled with FG in the ventrolateral tegmentum, ipsilateral and contralateral to the injection site in the rvlm. Suggestive evidence was obtained of synaptic interactions with neuronal somata and proximal dendrites. The results support the idea that the rvlm projects to the thoracic cord via disynaptic, intrareticular pathways paralleling the well established monosynaptic projection.     

The astrocytic response to afferent activity blockade in chick nucleus magnocellularis is independent of synaptic activation, age, and neuronal survival

Astrocytes in nucleus magnocellularis (NM) of the chick respond to afferent activity blockade with increased immunoreactivity for glial fibrillary acidic protein (GFAP). NM neurons respond to the same manipulations with reduced protein synthesis, ribosomal dissociation, and subsequent death of a subset of these neurons. In the present study, we sought to evaluate the relationship between these neuronal and glial responses and to determine if similar activity-dependent mechanisms mediate them. We first examined the anatomical relationship between NM neurons and astrocytic processes by electron microscopy and GFAP immunostaining. Both methods showed that NM neurons deprived of activity for 6 hr were apposed by more glial processes than active NM neurons. However, we found no preferential positioning of GFAP-immunoreactive processes near neurons of the dying or surviving populations, and there were no differences in glial process apposition to dying versus surviving neurons at the EM level. To determine whether the astrocytic response is similar to the neuronal response in age dependence, GFAP immunoreactivity was analyzed in adult chickens following unilateral afferent activity blockade. Unlike the neuronal response to activity blockade, the astrocytic response is equally strong in adult animals. These results imply an independence of the neuronal and astrocytic responses to activity blockade, raising the possibility that these two cell types may be responding to different activity-related signals. This possibility was tested using an in vitro slice preparation. Unilateral stimulation of NM was provided in three ways: orthodromically, antidromically, and orthodromically in a low-calcium medium. The regulation of astrocytic GFAP immunoreactivity by these manipulations of activity was then analyzed. The results of these experiments show that, unlike neuronal protein synthesis, astrocytic GFAP immunoreactivity can be suppressed by either presynaptic or postsynaptic neuronal activity. Therefore, the astrocytes and neurons are regulated by different activity-dependent signals and, by the present measures, their responses to activity blockade appear independent of one another.     

Organization of the lamprey striatum - transmitters and projections

The purpose of the present study is to characterize the striatum of the lamprey by immunohistochemical and tracing techniques. Cells immunoreactive for GABA and substance P (SP), and positive for acetylcholinesterase, are present in the lamprey striatum. Immunoreactive (ir) fibers were detected by antisera raised against SP, dopamine, enkephalin and serotonin. These immunoreactive fibers were mainly located in the periventricular neuropil that borders the striatum and in which GABAergic striatal neurons distributed their dendritic arbors. Putative connections between the striatum, the ventral part of the lateral pallium, and the diencephalic motor centers involved in the control of locomotion were studied by using fluorescein-coupled dextran amines (FDA) as a tracer. The striatum projects to the ventral part of the lateral pallium (lpv), where GABA-ir cells and SP-ir fibers were also present. The lpv in turn projects to the ventral thalamus, which has descending connections to the reticulospinal cells involved in the control of locomotion. These results, together with previous findings of histaminergic and neurotensin projections, suggest that the lamprey striatum and its inputs with regard to neurotransmitters/modulators are very similar to those of modem amniotes, including primates, and are thus conserved to a high degree.     

Recovery of locomotion after ventral and ventrolateral spinal lesions in the cat. I. Deficits and adaptive mechanisms

The recovery of treadmill locomotion of eight adult cats, subjected to chronic ventral and ventrolateral spinal lesions at low thoracic levels (T11 or T13), preserving at least one dorsolateral funiculus and the dorsal columns, was documented daily using electromyographic (EMG) and kinematic methods. The data show that all cats eventually recovered quadrupedal voluntary locomotion despite extensive damage to important pathways (such as the reticulospinal and the vestibulospinal) as verified by injection of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) caudal to the site of lesion. Initially (in the early period after the spinal lesion), all the cats suffered from pronounced locomotor and postural deficits, and they could not support their hindquarters or walk with their hindlimbs. Gradually, during the recovery period, they regained quadrupedal walking, although their locomotion was wobbly and inconsistent, and they suffered from poor lateral stability. EMG and kinematic data analyses showed a tendency for an increase in the variability of the step cycle duration but no major changes in the step cycle structure or in the intralimb coupling of the joints. However, the homolateral fore- and hindlimb coupling was highly perturbed in cats with the largest lesions. Although the general alternating pattern of extensor and flexors was maintained, there were various changes in the duration and amplitude of the EMG bursts as well as a lack of amplitude modulation during walking uphill or downhill on the treadmill. In cats with larger lesions, the forelimbs also seem to take a greater propulsive role than usual as revealed by a consistent increase of the activity of the triceps. In cats with smaller lesions, these deficits were transient, but, for the most extensively lesioned cats, they were pronounced and lasted long term postlesion even after reaching a more or less stable locomotor behavior (plateau period). It is concluded that recovery of quadrupedal locomotion is possible even after a massive lesion to ventral and ventrolateral quadrants, severing the vestibulospinal pathway and causing severe, although incomplete, damage to the reticulospinal tract. The quick recovery in the less lesioned cats can be attributed to remaining pathways normally implicated in locomotor function. However, in the most extensively lesioned cats, the long period of recovery and the pronounced deficits during the plateau period may indicate that the compensation, attributed to remaining reticulospinal pathways, is not sufficient and that other pathways in the dorsolateral funiculi, such as the corticospinal, can sustain and adapt, up to a certain extent, the voluntary quadrupedal walking.     

Effects of tap withdrawal response habituation on other withdrawal behaviors: The localization of habituation in the nematode Caenorhabditis elegans.

Four experiments were conducted to identify the possible loci of habituation of the nematode tap withdrawal response (TWR) by charactering the effects of TWR habituation on other nonmechanosensory withdrawal behaviors that are mediated by overlapping sets of neurons. Experiments 1–2 established behavioral and anatomical relationships between spontaneous and tap-induced backward locomotion in the worm. Experiment 3 demonstrated that habituation of the TWR affected neither the magnitude nor frequency of spontaneous reversal activity. Experiment 4 extended this result to an evoked response: Habituation of the TWR had no effect on reversals evoked by a thermal stimulus. These studies, which show that the loci of change associated with habituation of the TWR are presynaptic to the interneurons and motor neurons that control locomotion, probably distributed among the mechanosensory neurons, illustrate that a complete understanding of plasticity requires a knowledge of both the anatomical and molecular substrates of change. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Anatomical study of spinobulbar neurons in lampreys

The present study was aimed at identifying spinal neurons ascending to the brainstem outside the dorsal columns in the lamprey. Two retrograde tracers (cobalt-lysine and horseradish peroxidase [HRP]) were injected in the brainstem or rostral spinal cord in vivo or in vitro. Labeled cells were distributed bilaterally with a contralateral dominance, along the whole rostrocaudal extent of the spinal cord. The density of cells markedly decreased rostrocaudally. Several classes of brainstem-projecting neurons were identified. Most cells with a short axon were small and formed columns, in the dorsolateral and ventrolateral gray matter, at the transition between the rhombencephalon and the spinal cord. Dorsal elongated cells were spindle shaped, located medially, in the first two spinal segments. Lateral elongated cells were medium to large size neurons, located in the intermediate and lateral gray matter, mainly contralateral to the injection site. Their axon emerging from the lateral part of the soma crossed the midline, ventral to the central canal. These cells were present throughout the rostral spinal cord. Cells were also labeled in the lateral white matter. Some of them had the typical dendritic arborizations of edge cells (intraspinal stretch receptor neurons) and were located in the most rostral segments, bilaterally. Other medium to large size neurons were identified dorsal and medial to most of the edge cells. We suggest that at least the group of lateral elongated cells exhibits rhythmic membrane potential oscillations during fictive locomotion. These cells may, together with the rostral edge cells, be responsible for the locomotor-related modulation of activity in reticulospinal and vestibulospinal neurons.     

Relationships between the morphology and function of gastric and intestinal distention-sensitive neurons in the dorsal motor nucleus of the vagus

The activity of vagal motor neurons is influenced by sensory information transmitted to the brainstem. In particular, there is evidence that distention of the stomach increases activity of motor neurons in the dorsal vagal motor nucleus, whereas distention of the duodenum, small intestine, and colon reduces neuron firing. In this study, we determined 1) the response of vagal motor neurons to distention of the stomach and duodenum and 2) whether the response properties were associated with specific morphological features. Using the single-cell recording and iontophoretic injection technique, we identified four groups of vagal motor neurons affected by gastric and/or duodenal distention. Group 1 neurons responded to either gastric or duodenal stimulation. Neurons in groups 2, 3, and 4 were affected by both gastric and duodenal distention. Group 2 neurons were excited by duodenal distention and were inhibited by gastric distention. Group 3 neurons were inhibited by duodenal distention and were excited by gastric distention. Most neurons belonged to group 4. Neurons in this group were inhibited by both gastric and duodenal distention. Our analyses revealed that the neurons affected by both stimuli had distinctive structural features. Neurons in group 2 had the largest somata, the most dendritic branches, and the greatest cell surface area. Neurons in group 3 were the smallest and had the shortest dendritic length. In addition, we were able to demonstrate that the neurons in group 4 had a smaller total dendritic length and a smaller cell volume than neurons in group 2 and had more dendritic branch segments than neurons in group 3. These results suggest that morphological features are associated with specific response properties of vagal motor neurons.     

On the heterogeneity of the mitochondrial C27-steroid 26-hydroxylase system

Time characteristics of the monosynaptic EPSP evoked by stimulation of the motor cortex in reticulospinal neurons were studied in detail. Negative correlation was revealed between latency duration of EPSP and conduction velocity of the corticobulbar fibres and positive correlation between such characteristics and conduction velocity of axons. Reticulospinal neurons with conduction velocity from 10.8 to 65.0 m/s were activated by fast and slow corticobulbar fibres, but neurons with conduction velocity from 65.0 to 155 m/s were activated only by slow ones. A functional role of different cortico-reticulo-spinal connections is discussed.     

Estrogen-sensitive neurons with preoptic projection in the lower brain stem of the female rat

Fifty-one neurons in the ventrolateral part of the medulla oblongata were antidromically activated by electrical stimulation of the suprachiasmatic part of the preoptic area in urethane-anestetized, ovariectomized and estrogen-primed female rats. Two types of antidromic responses were distinguished on the basis of their spike configurations and antidromic spike latencies. One type ("fast spikes") was characterized by a fast and smooth rising phase and a shorter duration of the initial positive deflection. The other type ("slow spikes") had a notch in the rising phase and took a longer time to complete the initial deflection. Mean antidromic spike latency for the fast spikes was 9.8 msec while the value for the slow spikes was 30.2 msec. Ionophoretic injection of estradiol was accomplished on 37 of the 51 antidromically identified cells, of which 21 showed slow responses and 16 responded with fast spikes. In cells with slow spikes, estradiol facilitated (n = 9) or suppressed (n = 3) their generation of action potentials. None of cells with fast responses changed their activity in response to estradiol. It is evident from the present experiment that neurons in the ventrolateral part of the medulla oblongata send their axons directly to the suprachiasmatic part of the preoptic area which plays an important role in the control of the ovulatory surge of LH and that some of these neurons themselves are the sensitive sites of estradiol.     

Preliminary investigation of the association of oral lichen planus and hepatitis C

The autopsy findings of a 78-year-old man mimicking primary lateral sclerosis (PLS) are reported. He showed slowly progressive spasticity, pseudobulbar palsy and character change, and died 32 months after the onset of symptoms. Autopsy revealed severe atrophy of the frontal and temporal lobes, remarkable neuronal loss and gliosis in the precentral gyrus, left temporal lobe pole and amygdala, mild degeneration of the Ammon's horn, degeneration of the corticospinal tract, and very mild involvement of the lower motor neurons. The anterior horn cells only occasionally demonstrated Bunina body by cystatin-C staining, and skein-like inclusions by ubiquitin staining. This is a peculiar case with concomitant involvement in the motor cortex and temporal lobe in motor neuron disease predominantly affecting the upper motor neuron.