Lateral turns in the Lamprey. I. Patterns of motoneuron activity.

The activity of motoneurons during lateral turns was studied in a lower vertebrate, the lamprey, to investigate how a supraspinal command for the change of direction during locomotion is transmitted from the brain stem and integrated with the activity of the spinal locomotor pattern generator. Three types of experiments were performed. 1) The muscular activity during lateral turns in freely swimming adult lampreys was recorded by electromyography (EMG). It was characterized by increased cycle duration and increased duration, intensity, and cycle proportion of the bursts on the side toward which the animal turns. 2) Electrical stimulation of the skin on one side of the head in a head-spinal cord preparation of the lamprey during fictive locomotion elicited asymmetric ventral root burst activity with similar characteristics as observed in the EMG of intact lampreys during lateral turns. The cycle duration and ventral root burst intensity, duration, and cycle proportion on the side of the spinal cord contralateral to the stimulus were increased; hence a fictive lateral turn away from the stimulus could be produced. The fictive turn propagated caudally with decreasing amplitude. The increase in burst duration during the turn correlated well with the increase in cycle duration, while changes in contralateral burst intensity and burst duration did not co-vary. Turning responses varied depending on the timing (phase) of the skin stimulation: stimuli in the first two-thirds of a cycle evoked a turn in the same cycle, whereas stimuli in the last third gave a turn in the following cycle. The largest turns were evoked by stimuli in the first third of a cycle. 3) Fictive turns were abolished after transection of the trigeminal nerve or a rhombencephalic midline split, but not in a rhombencephalic preparation with transected cerebellar commissure. High spinal hemisection was sufficient to block turning toward the lesioned side, while turns toward the intact side remained. Taken together these findings suggest that the reticulospinal turn command is essentially unilateral and generated in the rhombencephalon.

Lateral turns in the Lamprey. II. Activity of reticulospinal neurons during the generation of fictive turns.

We studied the neural correlates of turning movements during fictive locomotion in a lamprey in vitro brain-spinal cord preparation. Electrical stimulation of the skin on one side of the head was used to evoke fictive turns. Intracellular recordings were performed from reticulospinal cells in the middle (MRRN) and posterior (PRRN) rhombencephalic reticular nuclei, and from Mauthner cells, to characterize the pattern of activity in these cell groups, and their possible functional role for the generation of turns. All recorded reticulospinal neurons modified their activity during turns. Many cells in both the rostral and the caudal MRRN, and Mauthner cells, were strongly excited during turning. The level of activity of cells in rostral PRRN was lower, while the lowest degree of activation was found in cells in caudal PRRN, suggesting that MRRN may play a more important role for the generation of turning behavior. The sign of the response (i.e., excitation or inhibition) to skin stimulation of a neuron during turns toward (ipsilateral), or away from (contralateral) the side of the cell body was always the same. The cells could thus be divided into four types: 1) cells that were excited during ipsilateral turns and inhibited during contralateral turns; these cells provide an asymmetric excitatory bias to spinal networks and presumably play an important role for the generation of turns; these cells were common (n = 35; 52%) in both MRRN and PRRN; 2) cells that were excited during turns in either direction; these cells were common (n = 19; 28%), in particular in MRRN; they could be involved in a general activation of the locomotor system after skin stimulation; some of the cells were also more activated during turns in one direction and could contribute to an asymmetric turn command; 3) one cell that was inhibited during ipsilateral turns and excited during contralateral turns; and 4) cells (n = 12; 18%) that were inhibited during turns in either direction. In summary, our results show that, in the lamprey, the large majority of reticulospinal cells have responses during lateral turns that are indicative of a causal role for these cells in turn generation. This also suggests a considerable overlap between the command system for lateral turns evoked by skin stimulation, which was studied here, and other reticulospinal command systems, e.g., for lateral turns evoked by other types of stimuli, initiation of locomotion, and turns in the vertical planes.

Crossed reciprocal inhibition evoked by electrical stimulation of the lamprey spinal cord.

Activation of a motoneuron pool is often accompanied by inhibition of the antagonistic pool through a system of reciprocal inhibition between the two parts of the neuronal network controlling the antagonistic pools. In the present study, we describe the activity of such a system in the isolated spinal cord of the lamprey, when a tonic motor output is evoked by extracellular stimulation (0.5-1 s train of pulses, 20 Hz) of either end of the spinal cord. With two electrodes symmetrically positioned in relation to the midline, stimulation with either of them separately elicited prolonged (1-5 s) ipsilateral ventral root activity. Activity could be abolished by stronger, simultaneously applied, stimulation of the contralateral side of the cord, suggesting that reciprocal inhibition between hemisegments operates when a tonic motor output is generated. Simultaneous stimulation of both sides of the spinal cord with a single electrode with a large tip (300-400 microm in diameter), positioned over the anatomical midline, elicited inconsistent right-side, leftside, or bilateral ventral root responses. A minor displacement (10-20 microm) to the left or right from the midline resulted in activation of ipsilateral motoneurons, whereas the contralateral motoneurons were silent. These findings indicate that a small asymmetry in the excitatory drive to the left and right spinal hemisegments can be further amplified by reciprocal inhibition between the hemisegments. Longitudinal splitting of the spinal cord along the midline resulted in reduced reciprocal inhibition between the hemisegments separated by the lesion. The reduction was proportional to the extent of the split. The inhibition was abolished when the split reached nine segments in length. From these experiments, the longitudinal distribution of the commissural axons responsible for inhibition of contralateral motor output could be estimated.

Activity of reticulospinal neurons during locomotion in the freely behaving lamprey.

The reticulospinal (RS) system is the main descending system transmitting commands from the brain to the spinal cord in the lamprey. It is responsible for initiation of locomotion, steering, and equilibrium control. In the present study, we characterize the commands that are sent by the brain to the spinal cord in intact animals via the reticulospinal pathways during locomotion. We have developed a method for recording the activity of larger RS axons in the spinal cord in freely behaving lampreys by means of chronically implanted macroelectrodes. In this paper, the mass activity in the right and left RS pathways is described and the correlations of this activity with different aspects of locomotion are discussed. In quiescent animals, the RS neurons had a low level of activity. A mild activation of RS neurons occurred in response to different sensory stimuli. Unilateral eye illumination evoked activation of the ipsilateral RS neurons. Unilateral illumination of the tail dermal photoreceptors evoked bilateral activation of RS neurons. Water vibration also evoked bilateral activation of RS neurons. Roll tilt evoked activation of the contralateral RS neurons. With longer or more intense sensory stimulation of any modality and laterality, a sharp, massive bilateral activation of the RS system occurred, and the animal started to swim. This high activity of RS neurons and swimming could last for many seconds after termination of the stimulus. There was a positive correlation between the level of activity of RS system and the intensity of locomotion. An asymmetry in the mass activity on the left and right sides occurred during lateral turns with a 30% prevalence (on average) for the ipsilateral side. Rhythmic modulation of the activity in RS pathways, related to the locomotor cycle, often was observed, with its peak coinciding with the electromyographic (EMG) burst in the ipsilateral rostral myotomes. The pattern of vestibular response of RS neurons observed in the quiescent state, that is, activation with contralateral roll tilt, was preserved during locomotion. In addition, an inhibition of their activity with ipsilateral tilt was clearly seen. In the cases when the activity of individual neurons could be traced during swimming, it was found that rhythmic modulation of their firing rate was superimposed on their tonic firing or on their vestibular responses. In conclusion, different aspects of locomotor activity-initiation and termination, vigor of locomotion, steering and equilibrium control-are well reflected in the mass activity of the larger RS neurons.

Responses of reticulospinal neurons in intact lamprey to vestibular and visual inputs.

A lamprey maintains the dorsal-side-up orientation due to the activity of postural control system driven by vestibular input. Visual input can affect the body orientation: illumination of one eye evokes ipsilateral roll tilt. An important element of the postural network is the reticulospinal (RS) neurons transmitting commands from the brain stem to the spinal cord. Here we describe responses to vestibular and visual stimuli in RS neurons of the intact lamprey. We recorded activity from the axons of larger RS neurons with six extracellular electrodes chronically implanted on the surface of the spinal cord. From these multielectrode recordings of mass activity, discharges in individual axons were extracted by means of a spike-sorting program, and the axon position in the spinal cord and its conduction velocity were determined. Vestibular stimulation was performed by rotating the animal around its longitudinal axis in steps of 45 degrees through 360 degrees. Nonpatterned visual stimulation was performed by unilateral eye illumination. All RS neurons were classified into two groups depending on their pattern of response to vestibular and visual stimuli; the groups also differed in the axon position in the spinal cord and its conduction velocity. Each group consisted of two symmetrical, left and right, subgroups. In group 1 neurons, rotation of the animal evoked both dynamic and static responses; these responses were much larger when rotation was directed toward the contralateral labyrinth, and the dynamic responses to stepwise rotation occurred at any initial orientation of the animal, but they were more pronounced within the angular zone of 0-135 degrees. The zone of static responses approximately coincided with the zone of pronounced dynamic responses. The group 1 neurons received excitatory input from the ipsilateral eye and inhibitory input from the contralateral eye. When vestibular stimulation was combined with illumination of the ipsilateral eye, both dynamic and static vestibular responses were augmented. Contralateral eye illumination caused a decrease of both types of responses. Group 2 neurons responded dynamically to rotation in both directions throughout 360 degrees. They received excitatory inputs from both eyes. Axons of the group 2 neurons had higher conduction velocity and were located more medially in the spinal cord as compared with the group 1 neurons. We suggest that the reticulospinal neurons of group 1 constitute an essential part of the postural network in the lamprey. They transmit orientation-dependent command signals to the spinal cord causing postural corrections. The role of these neurons is discussed in relation to the model of the roll control system formulated in our previous studies.

Interferon-gamma alters nerve-induced redistribution of acetylcholine receptors in cultured rat skeletal muscle cells.

The influence of recombinant interferon-gamma (rIFN-gamma) on the development of acetylcholine receptor (AChR) aggregates in cocultures of rat embryonic muscle cells and spinal cord neurons was studied by counting the number of AChR aggregates in relation to cholinergic nerve fibers coming to the muscle fibers. rIFN-gamma caused no decrease in the number of cholinergic nerve fibers, but inhibited the increase in the number of AChR aggregates that occurs early during cocultivation and is an early sign in the development of neuromuscular junctions. rIFN-gamma stimulated release of nitric oxide, but no effects on aggregation of AChRs occurred after exposure to a nitric oxide synthase inhibitor, L-NG-monomethylarginine, or by the addition of nitroprusside, a generator of nitric oxide. No effect was seen on the number of AChR aggregates when the cultures were exposed to rIFN-gamma at later time points of cocultivation, when the increase in number of AChRs had already occurred. These studies indicate that the key immunoregulatory cytokine IFN-gamma can cause alterations in the early process of synapse formation and that these effects are independent of the nitric oxide release caused by the cytokine.

Monosynaptic input from cutaneous sensory afferents to fin motoneurons in lamprey.

The sensory control of lamprey dorsal fin motoneurons was studied by using paired intracellular recordings combined with a morphological analysis. Dorsal cells innervating the skin of the dorsal fin and fin motoneurons were retrogradely labeled by injecting fluoresceincoupled dextran amines into the dorsal fin. Labeled motoneurons and dorsal cells showed close appositions, suggesting that the dorsal cells innervating the fin region make monosynaptic connections with fin motoneurons. By using conventional electrophysiological criteria, monosynaptic excitatory connections were found between fin dorsal cells and fin motoneurons. In addition, Lucifer yellow injection followed by confocal three-dimensional (3-D) reconstructions of monosynaptically connected pairs, revealed close apposition between dorsal cell axons and the distal dendrites of fin motoneurons. Each fin motoneuron received monosynaptic excitatory input from at least four different afferents. The amplitude of the monosynaptic excitatory postsynaptic potential (EPSP)s was reduced by administration of the N-methyl-D-aspartate (NMDA) receptor antagonist DL,2 amino-5-phosphovaleric acid (APV). Sensory stimulation could also elicit di- or oligosynaptic inhibitory postsynaptic potential (IPSP)s, which were blocked by the glycine antagonist strychnine, resulting in the appearance of large monosynaptic EPSPs, which could induce action potentials.

Immunocytochemical localization of glycine in the lamprey spinal cord with reference to GABAergic and glutamatergic synapses: a light and electron microscopic study.

The distribution of glycine immunoreactivity in the lamprey (Lampetra fluviatilis and Ichthyomyzon unicuspis) spinal cord was studied at the light and electron microscopic levels by use of postembedding techniques and antibodies against glutaraldehyde-conjugated glycine. To determine if glycine may be co-stored with other amino acid transmitters, the levels of glycine immunolabeling in identified GABAergic and glutamatergic synapses were examined. The most intense glycine labeling occurred in axon profiles of different diameter distributed throughout the ventral and lateral columns, with the highest density in the areas bordering the lateral cell column. Intermediate levels of glycine labeling were present in certain interneurons in the lateral cell column and in stretch receptors (edge cells) at the lateral margin of the spinal cord. Most other cell bodies, including glutamatergic dorsal cells, were virtually unlabeled. Examination of adjacent sections incubated with GABA antiserum revealed that many of the glycine-containing cells and fibers also contained high levels of GABA. At the ultrastructural level, the glycine immunolabeling was accumulated in two morphologically distinct types of terminal, one of which co-contained GABA. The terminals which exhibited glycine, but not GABA immunoreactivity, contained flattened synaptic vesicles and formed symmetrical synaptic specializations. The terminals that exhibited both GABA and glycine labeling contained pleomorphic synaptic vesicles and had either symmetrical or asymmetrical synaptic specializations. In both cases the glycine labeling was accumulated over the synaptic vesicles. Examination of identified glutamatergic axons in glycine-labeled sections did not provide any evidence for an accumulation of glycine in the synaptic vesicles or other structures of these exons. The present study provide the first morphological description of the localization of glycine in the lamprey spinal cord. The results confirm previous physiological and pharmacological studies, which have implicated glycine as a major fast inhibitory transmitter in the interneuronal network for locomotion, and in a proportion of stretch receptor neurons. The data also show that a significant proportion of the GABAergic synapses, but not the glutamatergic synapses, may utilize glycine as co-transmitter.