Early locomotor behaviour and the structure of the nervous system in embryos and larvae of the Australian lungfish,Neoceratodusforsteri‡

Immunohistochemical localization of calbindin-D28k and calretinin in the spinal cord of lungfishes

A common pattern of distribution of neurons and fibers containing the calcium-binding proteins calbindin-D28k (CB) and calretinin (CR) in the spinal cord of terrestrial vertebrates has been recently demonstrated. Lungfishes are considered the closest living relatives of tetrapods, but practically no experimental data exist on the organization of their spinal cord. By means of immunohistochemical techniques, the localization of CB and CR was investigated in the spinal cord of the African (Protopterus dolloi) and Australian (Neoceratodus forsteri) lungfishes. Abundant cell bodies and fibers immunoreactive for either CB or CR were widely distributed throughout the spinal cord. A large population of immunoreactive cells was found in the dorsal column of the gray matter in both species, and abundant cells were distributed in the lateral and ventral columns. Ventrolateral motoneurons and multipolar cells were only intensely CB and CR immunoreactive in Neoceratodus. For the most part, separate cell populations contained either CB or CR, but a small subset of dorsally located neurons contained both in the two lungfishes. Colocalization was found in motoneurons and in ventrolaterally located cells only in Neoceratodus. Fiber labeling showed a predominance of CR-containing axons in the lateral and ventral funiculi of presumed supraspinal origin. These results show that lung-fishes and tetrapods have many features in common, suggesting that primitive anatomical, and likely functional, organization of the spinal cord of tetrapods is present in lungfishes.

Activation of embryonic red and white muscle fibers during fictive swimming in the developing zebrafish

Sub-threshold, motoneuron-evoked synaptic activity was observed in zebrafish embryonic red (ER) and white (EW) muscle fibers paralyzed with a dose of D-tubocurarine insufficient to abolish synaptic activity to determine whether muscle activation was coordinated to produce the undulating body movements required for locomotion. Paired whole-cell recordings revealed a synaptic drive that alternated between ipsilateral and contralateral myotomes and exhibited a rostral-caudal delay in timing appropriate for swimming. Both ER and EW muscle were activated during fictive swimming. However, at the fastest fictive swimming rates, ER fibers were de-recruited, whereas they could be active in isolation of EW fibers at the slowest fictive swimming rates. Prior to hatching, fictive swimming was preceded by a lower frequency, more robust and rhythmic synaptic drive resembling the "coiling" behavior of fish embryos. The motor activity observed in paralyzed zebrafish closely resembled the swimming and coiling behaviors observed in these developing fishes. At the early developmental stages examined in this study, myotomal muscle recruitment and coordination were similar to that observed in adult fishes during swimming. Our results indicate that the patterned activation of myotomal muscle is set from the onset of development.

Temperature and neuromuscular development in embryos of the trout (Salmo trutta L.)

Myogenesis and neural development were examined in the myotomes of trout (Salmo trutta L.) embryos reared at 2, 6 and 10 degrees C. The relative timings of myotube and muscle fibre formation were similar, with respect to somite stage, at all three temperatures. Myogenesis was seen to begin medially, adjacent to the notochord, and also in separate zones located near the outer surface of the myotomes, believed to be the sites of formation of future slow muscle fibres. Temperature did not affect the relative timings of most aspects of neural development, including HNK-1-immunoreactivity of myosepta, primary motor neuron axonogenesis, Rohon-Beard dendrite outgrowth, and expression of acetylcholinesterase in the spinal chord and at the myosepta. The posterior progression of the lateral line primordium was slightly but significantly delayed relative to somite stage in embryos reared at 10 degrees C compared to 6 and 2 degrees C, while formation of vacuoles in the notochord occurred relatively earlier at higher temperatures. No significant differences in neuromuscular development were observed between offspring of migratory and of non-migratory females.

Role of epidermal cilia in development of the Australian lungfish, Neoceratodus forsteri (Osteichthyes: Dipnoi)

In common with the embryos of other anamniotes, young of the Australian lungfish, Neoceratodus forsteri, have ciliated cells in the epidermis. These first appear at stage 28, ˜ 10 days before hatching, and develop progressively to a peak in numbers and in activity at stage 44, just after hatching. After this point, ciliary action in the epidermal cells slowly declines, and cilia disappear completely from the outer surface of the hatchling by stage 52. Cilia are lost earlier from the oral epithelium, between stages 45 and 46, and from the epithelium covering the gills and lining the operculum at stage 51, although they are retained in the nares and in the cavity of the olfactory organ. To assess possible functions for the ciliated epidermis in lungfish hatchlings, the presence of cilia in the epidermis of young N. forsteri is compared with landmarks of development. The ciliated epidermal cells are not associated with movements of the embryo within the egg capsule, nor are they a part of a feeding mechanism. They are not related to oxygen uptake. The ciliated epidermis appears to function as a mechanism for clearing the animal of particles and settling organisms before hatching, when the egg membranes have developed holes, and after hatching, when the young fish is living among the submerged rootlets of trees growing on the river bank or in dense stands of aquatic plants. The function of a ciliated epidermis in N. forsteri hatchlings in relation to microhabitat is discussed. © 1996 Wiley-Liss, Inc.

Positive feedback as a general mechanism for sustaining rhythmic and non-rhythmic activity

Our aim is to reassess our proposal that various states of motor output may be sustained by positive feedback generated within the premotor neural circuitry. The evidence for this proposal came from the Xenopus embryo which when touched can swim for many seconds even after all movement has been prevented by a neuromuscular blocking agent. Experiments showed that even the spinal cord could sustain its own swimming activity for a few seconds after stimulation. We proposed that this was the result of the glutamatergic excitatory spinal interneurons synapsing with each other. Because this excitation is of long duration compared to the swimming cycle period it can sum from cycle to cycle to sustain swimming by a form of positive feedback. We have tested the plausibility of these ideas by making realistic computer simulations of the spinal networks and have shown that positive feedback can sustain stable swimming activity. Pharmacological evidence recently suggested that acetylcholine contributes to the excitation underlying swimming in spinal embryos so we investigated the central synapses made by motoneurons. Recordings from pairs of synergistic motoneurons then showed: a) cholinergic chemical synapses from more rostral motoneurons activate nicotinic receptors and produce excitation; and b) local intrasegmental electrical synapses also lead to mutual excitation. The presence of central motoneuron synapses suggested that they could contribute to excitation during swimming. We therefore used local drug applications to see if spinal neurons received cholinergic or electrical excitation during fictive swimming. The results show that motoneurons received both types of excitation while interneurons received only cholinergic excitation. This evidence suggests that when motoneurons are active during swimming they contribute positive feedback excitation not only to themselves but also to the premotor interneurons of the spinal rhythm generating network. This excitation would sum with that from 'glutamatergic' excitatory interneurons. We conclude that in addition to our original proposal of feedback between excitatory interneurons, there are other forms of positive feedback during swimming in the Xenopus embryo spinal cord. Motoneurons feed excitation back to each other. They may also contribute cholinergic excitation to premotor interneurons which could sum with the excitation from 'glutamatergic' interneurons and help to sustain swimming. If they do this, motoneurons may be a component part of the central pattern generator for swimming. Since central motoneuron synapses are a feature of most vertebrate groups, these results suggest a reevaluation of such synapses in these groups also.

Spinal cord neuron classes in embryos of the smooth newt Triturus vulgaris: a horseradish peroxidase and immunocytochemical study

Spinal cord neurons were investigated in embryos of Triturus vulgaris, the smooth newt, just prior to hatching. These embryos can swim if freed from their egg membranes. Horseradish peroxidase (HRP) labelling, together with GABA and glycine immunocytochemistry (ICC), revealed nine distinct anatomical classes of neuron. 1. Ventrolateral motoneurons with mainly dorsal dendrites, sometimes a descending central axon and peripheral axon innervating the trunk muscles. 2. Dorsal primary sensory Rohon-Beard neurons innervating skin and with dorsal ascending and descending axons in spinal cord. 3. Commissural interneurons with mid-cord unipolar soma, glycine-like immunoreactivity, dendrites on initial segment of ventral axon which crosses cord to ascend or branch. 4. Dorsolateral commissural interneurons with multipolar soma in dorsolateral position with dorsal dendrites and ventral axon which crosses and ascends or branches. 5. Giant dorsolateral commissural interneurons with large dorsolateral somata widely spaced (130-250 microns spacing) with process projecting dorsally to other side, dorsolateral dendrites and ventral axon which crosses to ascend and branch. 6. Dorsolateral ascending interneurons in dorsolateral position with multipolar soma and ascending axon on same side. 7. Ascending interneurons with unipolar soma, GABA-like immunoreactivity and ascending axon on same side. 8. Descending interneurons with bi- or multi-polar soma, extensive dorsal and ventral dendrites, and descending axon on same side. They may also have ascending axons. 9. Kolmer-Agduhr cerebrospinal fluid contacting neurons with cilia and microvilli in lateral corners of neural canal. GABA-like immunoreactivity, no dendrites and ascending axon. Eight of the nine cells classes were found to bear a marked resemblance to neurons previously described in zebrafish and Xenopus embryos in terms of their anatomy, distribution and immunoreactivity to GABA and glycine. Homologies and possible functions are discussed. Giant dorsolateral commissural neurons, were not found in Xenopus or teleosts but were present in Ambystoma mexicanum and Neoceratodus. The regular, possibly segmental longitudinal distribution pattern of these cells within the cord is unusual among amphibian spinal neurons.