Abstract
Micro-ornamentations characterize the surface of scales in lepidosaurians and are summarized in four main patterns, i.e., spinulated, lamellated, lamellate-dentate, and honeycomb, although variations of these patterns are present in different species. Although geckos are known to possess a spinulated pattern derived from the Oberhautchen layer, also other pattern variations of the spinulated micro-ornamentation are present such as those indicated as dendritic ramification, corneous belts, and small bare patches. The present study mainly describes the variation of micro-ornamentations present in scales of different skin regions in the Mediterranean gecko Tarentula mauritanica using scannig and transmission electron microscopy. The study reports that the accumulation of corneous material in Oberhautchen cells is not homogenous in different areas of body scales and, when mature, this process gives rise to different sculpturing on the epidermal surface generating not only spinulae but also transitional zones leading to the other main patterns. It is hypothesized that spinulae formation derives from the vertical and lateral symmetric growth of tubercolate, non-overlapped scales of geckos. Sparse areas also result smooth or with serpentine-ridges likely revealing the beta-layer located underneath and merged with the Oberhautchen. The eco-functional role of this variable micro-ornamentation in the skin of lizards however remains largely speculative.
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References
Alexander NJ, Parakkal PF (1969) Formation of α-and β-type keratin in lizard epidermis during the molting cycle. Z Zellforsch 110:72–87
Alibardi L (1998) Presence of acid phosphatase in the epidermis of the regenerating tail of the lizard (Podarcis muralis) and its possible role in the process of shedding and keratinization. J Zool 246:379–390
Alibardi L (1999a) Keratohyalin-like granules in embryonic and regenerating epidermis of lizards and Sphenodon punctatus (Reptilia, Lepidosauria). Amph Rept 20:11–23
Alibardi L (1999b) Formation of large microornamentations in the developing scales of agaminae lizards. J Morphol 240:251–266
Alibardi L (2000) Epidermal structure of normal and regenerating skin of the agamine lizard Physignatus lesueurii (McCoy 1878) with emphasis on the formation of the shedding layer. Ann Sci Natur (Zoologie) (Paris) 21:27–36
Alibardi L (2014) Comparative immunolocalization of keratin-associated beta-proteins (Beta-keratins) supports a new explanation for the cyclical process of keratinocyte differentiation in lizard epidermis. Acta Zool 95:32–43
Alibardi L, Bonfitto A (2019) Morphology of setae in regenerating caudal adhesive pads of the gecko Lygodactylus capensis (Smith, 1849). Zoology 133:1–9
Alibardi L, Meyer-Rochow BV (2017) Regeneration of tail adhesive pad scales in the New Zealand gecko Hoplodactylus maculatus (Reptilia; Squamata; Lacertilia) can serve as an experimental model to analyze setal formation in lizards generally. Zool Res 38:1–11
Alibardi L, Toni M (2006) Cytochemical, biochemical and molecular aspects of the process of keratinization in the epidermis of reptilian scales. Prog Histoch Cytoch 40:73–134
Ananjeva NB, Dilmuchamedov ME, Matveyeva TN (1991) The skin sense organs of some iguanian lizards. J Herpeth 25:186–199
Ananjeva NB, Matveyeva-Dujsebayeva TN (1996) Some evidence of Gonocephalus species complex divergence basing on skin sense organs morphology. Russ J Herpethol 3:82–88
Arnold EN (2002) History and function of scale microornamentation in lacertid lizards. J Morph 252:145–169
Bauer AM (1998) Morphology of the adhesive tail tips of Carphodactyline geckos (Reptilia: Diplodactylidae). J Morph 235:41–58
Bonfitto A, Bussinello D, Alibardi L (2022) Electron microscopic analysis in the gecko Lygodactylus reveals variations in micro-ornamentation and sensory organs distribution in the epidermis that indicates regional functions. Anat Rec. https://doi.org/10.1002/ar.25084
Dujsebayeva T, Ananjeva N, Bauer AM (2021) Scale microstructures of pygopodid lizards (Gekkota: Pygopodidae): phylogenetic stability and ecological plasticity. Russ J Herpeth 28:291–308
Dujsebayeva TN (1995) The microanatomy of regenerated bristle receptors of two gecko species, Cyrtopodion fedtschenkoi and Sphaerodactylus roosevelti. Russ J Herpeth 2:58–64
Ernst V, Ruibal R (1966) The structure and development of the digital lamellae of lizards. J Morph 120:233–266
Fahrenbach WH, Knutson DD (1975) Surface adaptations of the vertebrate epidermis to friction. J Inv Dermatol 65:39–44
Gamble T (2019) Duplications in corneous beta protein genes and the evolution of gecko adhesion. Integr Comp Biol 59:193–202
Gower DJ (2003) Scale microornamentation of uropeltid snakes. J Morphol 258:249–268
Griffing AH, Sanger TJ, Epperlein L, Bauer AM, Cobos A, Higham TE, Naylor E, Gamble T (2021) And thereby hangs a tail: morphology, developmental patterns and biomechanics of the adhesive tail of crested geckos (Correlophus ciliates). Proceed Royal Soc B 288:20210650
Harvey MB (1993) Microstructure, ontogeny, and evolution of scale surfaces in xenosaurid lizards. J Morph 216:161–177
Harvey MB, Gutberlet RL (1995) Microstructure, evolution and ontogeny of scale surfaces in cordilyd and gerrosaurid lizards. J Morph 226:121–136
Hiller U (1972) Licht- und elektronenmikroskopische Untersuchungen zur Haftborstenentwicklung bei Tarentola mauritanica L. (Reptilia, Gekkonidae). Zeitfr Morphol Tiere 73:263–278
Hiller U (1977) Regeneration and degeneration of setae-bearing sensilla in the scales of the gekkonid lizard Tarentola mauritanica L. Zool Anz 199:113–120
Hiller U (1978) Morphology and electrophysiological properties of cutaneous sensilla in Agamid lizards. Plugers Arch Europ J Physiol 377:189–191
Irish F, Williams E, Seiling E (1988) Scanning electron microscopy of changes in epidermal structure occurring during the shedding cycle in squamate reptiles. J Morphol 197:105–126
Maderson PF, Rabinowitz T, Tandler B, Alibardi L (1998) Ultrastructural contributions to an understanding of the cellular mechanisms involved in lizard skin shedding with comments on the function and evolution of a unique lepidosaurian phenomenon. J Morph 236:1–24
Maderson PFA, Flaxman BA, Roth SI, Szabo G (1972) Ultrastructural contribution to the identification of cell types in the lizard epidermal generation. J Morph 136:191–209
Matveyeva TN, Ananjeva NB (1995) The distribution and number of the skin sense organs of agamids, iguanid and gekkonid lizards. J Zool (London) 235:253–268
Peterson JA (1984a) The scale microarchitecture of Sphenodon punctatus. J Herpethol 18:40–47
Peterson JA (1984b) The microstructure of the scale surface in iguanid lizards. J Herpethol 18:437–467
Povel D, Van Der Kooij J (1997) Scale sensillae of the file snake (Serpentes: Acrochordidae) and some other aquatic and burrwing snakes. Neth J Zool 47:443–456
Price R, Kelly P (1989) Microdermatoglyphics: basal patterns and transitional zones. J Herpethol 23:244–261
Riedel J, Schwarzkopf L (2022) Variation in density, but not morphology, of cutaneous sensilla among body regions in nine species of Australian geckos. J Morphol 283:637–652
Russel AP (2002) Integrative functional morphology of the gekkotan adhesive system (Reptilia: Gekkota). Integr Comp Biol 42:1154–1163
Sawyer RH, Glenn TC, French JO, Mays B, Shames RB, Barnes GL, Rhodes W, Ishikawa Y (2000) The expression of beta (β) keratins in the epidermal appendages of reptiles and birds. Amer Zool 40:530–539
Spinner M, Gorb SN, Westhoff G (2013) Diversity of functional microornamentation in the slithering geckos Lialis (Pygopodidae). Proc Royal Soc B 280:20132160
Stewart GR, Daniel RS (1973) Scanning electron microscopy from different body regions of three lizard species. J Morphol 139:377–388
Von During M, Miller MR (1979) Sensory nerve-endings of the skin and deeper structures. In: Gans C (ed) Biology of the reptilia, Neurology A, vol 9. Academic Press, New York and London, pp 407–441
Whimster IW (1980) Neural induction of epidermal sensory organs in gecko skin. In: The skin of vertebrates (eds Spearman RIC & Riley PA), Linnean Society Symposium Series 9, London, pp 161-171
Acknowledgements
The present work was supported by “Canziani Bequest” fund, University of Bologna (grant number A.31.CANZELSEW), Bologna, Italy (A. Bonfitto), and from Comparative Histolab Padova (L. Alibardi).
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Bonfitto, A., Randi, R., Magnani, M. et al. Micro-ornamentation patterns in different areas of the epidermis in the gecko Tarentola mauritanica reflect variations in the accumulation of corneous material in Oberhautchen cells. Protoplasma 260, 1407–1420 (2023). https://doi.org/10.1007/s00709-023-01860-8
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DOI: https://doi.org/10.1007/s00709-023-01860-8