Abstract
We used immunohistochemical techniques and monoclonal antibodies to localize two basement membrane components (laminin and type IV collagen) in the nerves and sensory nerve formations, or corpuscles, supplying human digital skin. Furthermore, neurofilament proteins, S-100 protein and epithelial membrane antigen were studied in parallel. In dermal nerve trunks, immunostaining for laminin and type IV collagen was found to be co-localized in the perineurium and the Schwann cells, the stronger immunoreactivity being at the external surface of the cells. In the Meissner digital corpuscles, the immunoreactivity for laminin and type IV collagen was mainly observed underlying the cell surface of lamellar cells, while the cytoplasm was weakly immunolabelled or unlabelled. Finally, within Pacinian corpuscles co-localization of the two basement membrane molecules was encountered in the inner core, intermediate layer, outer core and capsule. Laminin and type IV collagen immunoreactivities were also found in blood vessels and sweat glands, apparently labelling basement membrane structures. The present results provide evidence for the presence of basement membrane in all periaxonic cells forming human cutaneous sensory nerve formations, and suggest that all of them are able to synthesize and release some basement membrane components, such as laminin and type IV collagen. The possible role of laminin in sensory nerve formations is discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baron von Evercooren A, Kleinman HK, Ohno S, Marangos P, Schwartz JP, Dubois-Dalcq MF (1982) Nerve growth factor, laminin, and fibronectin promote neurite growth in human fetal ganglia cultures. J Neurosci Res 8:179–193
Beck K, Hunter I, Engel J (1990) Structure and function of laminin: Anatomy of a multidomain glycoprotein. FASEB J 4:148–160
Bixby JL (1989) Protein kinase C is involved in laminin stimulation of neurite outgrowth. Neuron 3:287–297
Bunge RP, Bunge MB, Eldridge CF (1986) Linkage between axonal ensheathment and basal lamina production by Schwann cells. Annu Rev Neurosci 9:305–328
Bunge MB, Wood PM, Tynan LB, Bates ML, Sanes JR (1989) Perineurium originates from fibroblasts: demonstration in vitro with a retroviral marker. Science 243:229–231
Conley FK, Rubinstein LJ, Spence AM (1976) Studies on experimental nerve sheath tumors maintained in tissue and organ culture systems. II. Electron microscopy observations. Acta Neuropathol (Berl) 34:293–310
Cornbrooks C, Carey D, McDonald J, Timple R, Bunge R (1983) In vivo and in vitro observations on laminin production by Schwann cells. Proc Natl Acad Sci USA 80:3850–3854
Edgar D (1989) Neuronal laminin receptors. Trends Neurosci 12:248–251
Erlandson RA (1991) The enigmatic perineurial cell and its participation in tumors and tumorlike entities. Ultrastruct Pathol 15:335–351
Ernsberger U, Edgar D, Rohrer H (1989) The survival of early chick sympathetic neurons in vitro is dependent on suitable substrate but independent of NGF. Dev Biol 135:250–262
Grant DS, Leblond CP (1988) Immunogold quantitation of laminin, type IV collagen, and heparan sulfate proteoglycan in a variety of basement membranes. J Histochem Cytochem 36:271–283
Halata Z, Grim M, Christ B (1990) Origin of spinal cord meninges, sheaths of peripheral nerves, and cutaneous receptors including Merkel cells. An experimental and ultrastructural study with avian chimeras. Anat Embryol 182:529–537
Haninec P (1988) Study of the origin of connective tissue sheaths peripheral nerves in the limb of avian embryos. Anat Embryol 178:553–557
Hslao LL, Engvall E, Peltonen J, Uitto J (1993) Expression of laminin isoforms by peripheral nerve-derived connective tissue cells in culture. Comparison with epitope distribution in normal human nerve and neuronal tumors in vivo. Lab Invest 68:100–108
Ide C (1976) The fine structure of the digital corpuscle of the mouse toe pad, with special reference to nerve fibers. Am J Anat 147:329–356
Ide C, Hayashi S (1987) Specializations of plasma membranes in Pacinian corpuscles: implications for mechano-electric transduction. J Neurocytol 16:759–773
Ide C, Tohyama K (1984) The localization of laminin and fibronectin on the Schwann cells basal lamina. Arch Histol Jpn 47:519–532
Ide C, Nitatori T, Munger BL (1987) The cytology of human Pacinian corpuscles: Evidence for sprouting of the central axon. Arch Histol Jpn 50:363–383
Iggo A, Andres KH (1982) Morphology of cutaneous receptors. Annu Rev Neurosci 5:1–31
Jaakkola S, Peltonen J, Uitto JJ (1989) Perineurial cells coexpress genes encoding interstitial collagens and basement membrane zone components. J Cell Biol 108:1157–1163
Kawakita N, Mizoguchi A, Masutani M, Arakawa M, Ide C (1992) Protein kinase C (α, β and γ) in Pacinian corpuscle. Histochemistry 98:381–387
Leblond CP, Inoue S (1989) Structure, composition, and assembly of basement membrane. Am J Anat 185:367–390
Leivo I, Engvall E (1988) Merosin, a protein specific for basement membranes of Schwann cells, striated muscles and trophoblasts, is expressed late in nerve and muscle development. Proc Natl Acad Sci USA 85:1544–1548
Lorimier P, Mezin P, Labat Moleur F, Pinel N, Peyrol S, Stoebner P (1992) Ultrastructural localization of the major components of the extracellular matrix in normal rat nerve. J Histochem Cytochem 40:859–868.
Low FN (1976) The perineurium and connective tissue of peripheral nerve. In: Landon DN (ed) The peripheral nerve. Chapman & Hall, London, pp 159–187
Maeda T, Sato O, Kannari K, Takagi H, Iwanaga T (1991) Immunohistochemical localization of laminin in the periodontal Ruffini endings of rat incisors: a possible function of terminal Schwann cells. Arch Histol Cytol 54:339–348
Maier A, Mayne R (1988) Immunohistochemical demonstration of connective tissues macromolecules at the equator of chick muscle spindles. In: Mechanoreceptors. Development, Structure and Function. Hink P, Soukup T, Vejsada R, Zelena J (eds) Plemum Press, New York, pp 275–280
Malinovsky L (1986) Mechanoreceptors and Free Nerve Endings. In: Bereiter-Hahn J, Matoltsy AG, Richards KS (eds) Biology of the integument, vol 2. Vertebrates. Springer, Berlin Heidelberg New York, pp 535–560
Malinovsky L, Pac L (1982) Morphology of sensory corpuscles in mammals. Acta Fac Med Univ Brunnesis 79:1–129
Marinkovich MP, Keene DR, Rimberg C, Burgeson RE (1993) Cellular origin of the dermal-epidermal basement membrane. Develop Dyn 197:255–267
Munger BL, Ide C (1988) The structure and function of cutaneous sensory receptors. Arch Histol Cytol 51:1–34
Munger BL, Yoshida Y, Hayashi S, Osawa T, Ide C (1988) A re-evaluation of the cytology of cat Pacinian corpuscles. I. The inner core and clefts. Cell Tissue Res 253:83–93
Nolte C, Schachner M, Martini R (1989) Immunocytochemical localization of the neural cell adhesion molecules L1, N-CAM, and J1 in Pacinian corpuscles of the mouse during development, in the adult and during regeneration. J Neurocytol 18:795–808
Renehan WE, Munger BL (1990) The development of Meissner corpuscles in primate digital skin. Dev Brain Res 51:35–44
Saxod R (1988) Morphogenetic interaction in the development of avian cutaneous sensory receptors. In: Hinik P, Soukup T, Vejsada R, Zelena J (eds) Mechanoreceptors. Development, Structure and Function. Plenum Press, New York, pp 3–5
Siironen J, Sandberg M, Vourinen V, Röyttä M (1992) Laminin B1 and collagen type IV gene expression in transected peripheral nerve: reinnervation compared to denervation. J Neurochem 59:2184–2192
Taniuchi M, Clark HB, Schweitzer JB, Johnson EM Jr (1988) Expression of nerve growth factor receptors in Schwann cells of axotomized peripheral nerves: ultrastructural location, suppression by axonal contact, and binding properties. J Neurosci 8:664–681
Timpl R, Dziadek M (1986) Structure, development and molecular pathology of basement membranes. Int Rev Exp Pathol 29:1–112
Tohyama K, Ide C (1984) The localization of laminin and fibronectin on the Schwann cell basal lamina. Arch Histol Jpn 47:519–532
Vega JA, Haro JJ, De Lamo A, Ordieres M, Del Valle ME, Calzada B (1992) Distribution of low-affinity nerve growth factor receptor (NGFr) immunoreactivity in the human digital skin. Eur J Dermatol 2:509–516
Vega JA, Del Valle ME, Haro JJ, Calzada B, Suárez-Garnacho S, Malinovsky L (1993) Nerve growth factor receptor IR in Meissner and Pacinian corpuscles of the human digital skin. Anat Rec 236:730–736
Vega JA, Del Valle ME, Haro JJ, Naves FJ, Calzada B, Uribelarrea R (1994a) The inner-core, outer-core and capsule of the human Pacinian corpuscles: an immunohistochemical study. Eur J Morphol 32:11–18
Vega JA, Vázquez E, Naves FJ, Del Valle ME, Calzada B, Represa J (1994b) Immunohistochemical localization of the high-affinity NGF receptor (gp140-trkA) in the human adult dorsal root ganglia and sympathetic ganglia, and in the nerves and sensory corpuscles supplying human digital skin. Anat Rec 240 (in press)
Velli's J de (1993) Supporting Cells Central and Peripheral. In: Neuroregeneration, A Gorio (ed), Raven Press, New York, pp. 61–75
Vitellaro-Zuccarello L, Garbelli R, Dal Pozzo Rossi V (1992) Immunocytochemical localization of collagen types I, III, IV, and fibronectin in the human dermis. Cell Tissue Res 268:505–511
Wang G-Y, Hirai K-I, Shimada H (1992) The role of laminin, a component of Schwann cell basal lamina, in rat sciatic nerve regeneration within antiserum-treated nerve grafts. Brain Res 570:116–125
Yip JW, Yip YPL (1992) Laminin — developmental expression and role in axonal outgrowth in the peripheral nervous system of the chick. Dev Brain Res 68:23–33
Yoshida Y, Ushiki T, Takashio M, Munger BL, Ide C (1989) Membrane relationships in murine Meissner corpuscles: cytology of freeze-substituted tissue. Anat Rec 223:437–445
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Vega, J.A., Esteban, I., Naves, F.J. et al. Immunohistochemical localization of laminin and type IV collagen in human cutaneous sensory nerve formations. Anat Embryol 191, 33–39 (1995). https://doi.org/10.1007/BF00215295
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00215295