The neuritic growth patterns obtained on substrates made of several glycosaminoglycans (GAGs) bound to type I collagen were analysed and compared in primary cultures of chick embryo dorsal root ganglion grown in serum-free supplemented medium. In 2-day cultures grown on type I collagen or heparan sulphate (HS)-collagen surfaces, ganglionic explants exhibit a dense, symmetrical network of long, parallel neuritic processes and very few flat migrating non-neuronal cells. In contrast, on either dermatan sulphate (DS), chondroitin-6-sulphate (C6S) or hyaluronic acid (HA)-bound collagen substrates, neurons form irregular nerve fibre patterns; indeed, neurites follow convoluted paths and often, after abrupt turns, totally reverse their direction of extension. Experiments were carried out in which a choice was given to growing neural processes between collagen or GAG-collagen substrates. While growth cones elongating over type I collagen easily cross the border with HS-bound collagen surface and indiscriminately extend on this substrate, in contrast, neurites generally avoid surfaces coated with DS, C6S or HA and change their direction of growth in order to stay on collagen. The binding of DS, C6S or HA, but not HS, to type I collagen thus decreases its ability to promote neurite elongation. The interaction of neuronal cells with these extracellular matrix components by restricting neurites in their paths of extension may, therefore, play a role in the patterning of the nervous circuitry.
Three-dimensional (3-D) reconstruction of images provided by confocal scanning laser microscopy (CSLM) is a powerful tool in a morpho-functional approach to cutaneous innervation studies. To investigate mechanoreceptors in the hand, a study of Merkel complexes was performed in human finger. A double fluorescent-conjugated immunolabeling with antibodies against neurofilament (NF 200) and cytokeratin (CK 20) on floating, thick cutaneous samples (80 to 100 microm), was used. After acquisition of serial optical planes by CSLM, reconstruction was performed with 3-D reconstruction software tools. Merkel cells were clearly labeled with CK 20, whereas nerve components were only NF 200 reactive. The cells, localized on the basal lamina of the epidermis, were usually arranged in clusters of five to eight cells. Each cell was connected to a nerve process ramification originating from a unique fiber. Quantitative data, compiled from a sample of 25 Merkel complexes, gave a mean cell diameter of 13 +/- 1 microm and a mean nerve fiber size of 3 +/- 1 microm. Surface measurements were done on a single reconstructed cluster with a mean and standard error which only refers to the optical 3-D resolution. It gives a surface of 12 +/- 1 microm2 for the contact zone between cell and nerve fiber and a cluster area of about 500 microm2. The great precision of reconstructed images provides a detailed analysis of spatial relationships between abutting nerve fibers and Merkel cells. Data interpretation is improved with complementary ultrastructural and physiological studies results, and this allows an accurate investigation of cutaneous sensory endings.
In the chicken Merkel corpuscles are located in the dermis and consist of specialized Merkel cells, discoid nerve endings and lamellar cells. Merkel cells contain characteristic membrane-bound dense-core granules and bundles of microfilaments. Asymmetric junctions, synapse like, with thickened membranes and clusters of dense-core vesicles were observed between the Merkel cells and the nerve endings. The nerve ending is derived from myelinated nerves and sometimes contains clusters of clear vesicles. A laminar system formed by lamellar cells of the Schwann cell type encloses the Merkel cells and the nerve endings. So called "transitional" cells, showing some of the morphological features of both keratinocytes and Merkel cells, were observed in the basal layer of the epidermis. One was located partly in the epidermis and partly in the dermis. The structure of Merkel corpuscles is compared with that of Merkel cells in other tetrapods. The developmental significance of "transitional" cells and the origin of Merkel cells are discussed.
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