Neurite complexes with Merkel cells in larval tentacles of Xenopus laevis

Wall following in Xenopus laevis is barrier-driven

The tendency of animals to follow boundaries within their environment can serve as a strategy for spatial learning or defensive behaviour. We examined whether Xenopus laevis tadpoles and froglets employ such a strategy by characterizing their swimming pattern in a square tank with shallow water. Trajectories obtained from video recordings were analysed for proximity to the nearest wall. With the exception of young larvae, the vast majority of animals (both tadpoles and froglets) spent a disproportionately large amount of time near the wall. The total distance covered was not a confounding factor, but animals were stronger wall followers in smaller tanks. Wall following was also not influenced by whether the surrounding walls of the tank were black or white, illuminated by infrared light, or by the presence or absence of tentacles. When given a choice in a convex tank to swim straight and leave the wall or turn to follow the wall, the animals consistently left the wall, indicating that wall following in X. laevis is barrier-driven. This implies that wall following behaviour in Xenopus derives from constraints imposed by the environment (or the experimenter) and is unlikely a strategy for spatial learning or safety seeking.

Locomotor corollary activation of trigeminal motoneurons: coupling of discrete motor behaviors

During motor behavior, corollary discharges of the underlying motor commands inform sensory-motor systems about impending or ongoing movements. These signals generally limit the impact of self-generated sensory stimuli but also induce motor reactions that stabilize sensory perception. Here, we demonstrate in isolated preparations of Xenopus laevis tadpoles that locomotor corollary discharge provokes a retraction of the mechanoreceptive tentacles during fictive swimming. In the absence of sensory feedback, these signals activate a cluster of trigeminal motoneurons that cause a contraction of the tentacle muscle. This corollary discharge encodes duration and strength of locomotor activity, thereby ensuring a reliable coupling between locomotion and tentacle motion. The strict phase coupling between the trigeminal and spinal motor activity, present in many cases, suggests that the respective corollary discharge is causally related to the ongoing locomotor output and derives at least in part from the spinal central pattern generator; however, additional contributions from midbrain and/or hindbrain locomotor centers are likely. The swimming-related retraction might protect the touch-receptive Merkel cells on the tentacle from sensory over-stimulation and damage and/or reduce the hydrodynamic drag. The intrinsic nature of the coupling of tentacle retraction to locomotion is an excellent example of a context-dependent, direct link between otherwise discrete motor behaviors.

Ultrastructure of the larval tentacle and its skeletal muscle in Xenopus laevis

During premetamorphic development, tadpoles of Xenopus laevis possess a transitory pair of long, slender, mobile tentacles situated at the corners of the mouth. Microscopic examination of the larval tentacle typically reveals three distinct compartments: a central core of cartilage, a laterally situated skeletal muscle, and a nerve supply medially. Along the length of each tentacle, the epidermis is supplied by many unmyelinated nerve fibers, presumably sensory in nature, which terminate as naked axons in close association with the epidermal cells. The striated tentacular muscle, in the proximal region of the lateral compartment, consists of extrafusal muscle fibers of varying size which range in number from 36 to 48 per tentacle (n = 10). Using morphometric criteria, we have classified the skeletal muscle fibers of the larval tentacular muscle into three types: large (30-50 microns), intermediate (20-30 microns), and small (10-20 microns). By electron microscopy, each type displays characteristic sarcomeric banding patterns, sarcotubular and mitochondrial disposition, and motor endplate ultrastructure. Our morphological observations indicate that the tentacles of the Xenopus tadpole are complex mobile facial extensions which may play roles in mechanoreception and/or chemoreception during the waterborne stages of development. Because of its transitory nature, the Xenopus tentacle may be a useful experimental model in future studies of neuromuscular development and subsequent regression in a relatively short period of time.

Figures of Eberth in the amphibian larval epidermis

Figures of Eberth are prominent extensive filamentous structures in the basal epidermal cells of larval amphibians. They are compared and contrasted qualitatively and quantitatively in a number of species of the three groups of living amphibians. Fully developed Figures consist of massive skeins of tonofilaments oriented in three dimensions and hinged on hemidesmosomes within the cell. The overall appearance of the Figures is similar in anurans, urodeles and Ichthyophis among the apodans. However, in terms of size and number per unit length of the proximal cell margin, the hemidesmosomes and the thickness or their emergent skeins in anurans and Ichthyophis differ significantly from those parameters in urodeles, a feature that is presumably independent of cell size. Figures are poorly developed or missing in embryos of Typhlonectes, which has no larval stage in its life history. These ubiquitous skeletogenous structures in the aquatic larval amphibians, among other things, could be protective of underlying delicate tissues and act as a stabilizer in bodily movement during swimming. They could also serve as a reserve of cytokeratin for use during later cellular division and sloughing.

Merkel cells and the mechanosensitivity of normal and regenerating nerves in Xenopus skin

We have investigated some of the physiological, morphological and trophic characteristics of the Merkel cell-neurite complexes in the skin of Xenopus laevis. The Merkel cells, which are specialized sensory cells, occur in groups of 2-4 around the openings of the cutaneous gland ducts. A voltage-controlled mechanical stimulator was used to determine the distribution of mechanosensory thresholds across the skin; an analysis of the results revealed the presence of a single population of rapidly adapting, low threshold mechanoreceptors, whose locations coincided with those of the epidermal Merkel cell-neurite complexes. The possible role of the Merkel cell in the mechanosensory process, and its trophic interactions with the sensory nerve, were examined (i) by following the development of mechanosensitivity when sensory nerves regenerated into denervated, or newly regenerated, skin; (ii) by looking for possible correlations between the expression of physiological function and the appearance of morphological features characteristic of the Merkel cell-neurite complex; and (iii) by investigating the mechanosensitivity that remained after elimination of the Merkel cells. Not only did Merkel cells survive denervation without obvious changes in their fine structure, but they developed with normal morphology in new skin that had regenerated in nerve free limbs. Ingrowing sensory nerves contacted these Merkel cells, and eventually normal mechanosensory function was established; thus the Merkel cells act as targets for these nerves. The full recovery of the normal pattern of mechanosensitivity in the skin following nerve regeneration was correlated with the redevelopment of the specialized contacts between the nerve endings and Merkel cells, that eventually included reciprocal synapses. However, following the mechanical removal of the epidermis by enzymatic treatment, or the selective elimination of the Merkel cells by irradiation after they had taken up the fluorescent dye quinacrine, essentially normal mechanosensory responses could be initiated, though with somewhat increased thresholds. The results indicate that the Merkel cells are not involved in mechanosensory transduction; they do, however, act as targets for the growing nerves, thereby ensuring the appropriate distribution of low threshold mechanosensitivity, and they may have a role in enhancing and even inducing the excitability of the mechanosensitive nerve endings.

The development of the Merkel cells in the tentacles of Xenopus laevis larvae

The Merkel cells in the larval tentacles of Xenopus laevis were examined by TEM. Different forms of Merkel cells were found, depending on the age of the larvae or the location in the tentacles. These forms have the appearance of intermediate states between Merkel cells and superficial epidermal cells; thus an epidermal origin for the Merkel cells seems more likely than an immigration from the neural crest. The forms differ in (1) their location in the epidermis, (2) their shape, (3) the number and extension of their desmosomes, (4) the content and distribution of dense-core granules, and (5) the outgrowth of their finger-like processes. Also the relation to a nerve ending is different. By marking Merkel cells with quinacrine, fluorescence spots were observed between the superficial and basal epidermal cells or, in the very tip, within the superficial epidermal cells. These latter spots represent immature Merkel cells, as confirmed by TEM. This indicates a development of Merkel cells from superficial epidermal cells and migration towards the basal layer. Dermal Merkel cells were never observed.

Merkel cells and Merkel cell tumors. Ultrastructure, immunocytochemistry and review of the literature

Certain monomorphic cellular tumors that occur in the dermis have been called trabecular carcinomas or Merkel cell tumors. Forty-six cases have been reported to date and the literature on these is reviewed here, with six additional cases reported. Cytologic features include sparse cytoplasm, dispersed chromatin with inconspicuous nucleoli in round nuclei and many mitoses. Trabeculae and pseudorosettes may be identified. Electron microscopy is required for definitive diagnosis. Like normal Merkel cells, tumor cells contain electron-dense granules (80-200 nm), 10 mm filaments and desmosomes. Filament-rich cytoplasmic spikes were found in four tumors. These resemble corresponding protrusions of normal Merkel cells and have not been described in other APUDomas.