Your search keyword '"Animal Scales anatomy & histology"' showing total 6 results

1. Cellular structure of dinosaur scales reveals retention of reptile-type skin during the evolutionary transition to feathers.

Author

Yang Z, Jiang B, Xu J, and McNamara ME

Subjects

Animals, Animal Scales anatomy & histology, Epidermis anatomy & histology, Epidermis metabolism, Epidermis ultrastructure, beta-Keratins metabolism, Feathers anatomy & histology, Dinosaurs anatomy & histology, Fossils, Biological Evolution, Skin anatomy & histology, Skin metabolism, Reptiles anatomy & histology, Melanosomes metabolism, Melanosomes ultrastructure

Abstract

Fossil feathers have transformed our understanding of integumentary evolution in vertebrates. The evolution of feathers is associated with novel skin ultrastructures, but the fossil record of these changes is poor and thus the critical transition from scaled to feathered skin is poorly understood. Here we shed light on this issue using preserved skin in the non-avian feathered dinosaur Psittacosaurus. Skin in the non-feathered, scaled torso is three-dimensionally replicated in silica and preserves epidermal layers, corneocytes and melanosomes. The morphology of the preserved stratum corneum is consistent with an original composition rich in corneous beta proteins, rather than (alpha-) keratins as in the feathered skin of birds. The stratum corneum is relatively thin in the ventral torso compared to extant quadrupedal reptiles, reflecting a reduced demand for mechanical protection in an elevated bipedal stance. The distribution of the melanosomes in the fossil skin is consistent with melanin-based colouration in extant crocodilians. Collectively, the fossil evidence supports partitioning of skin development in Psittacosaurus: a reptile-type condition in non-feathered regions and an avian-like condition in feathered regions. Retention of reptile-type skin in non-feathered regions would have ensured essential skin functions during the early, experimental stages of feather evolution., (© 2024. The Author(s).)

Published

2024

2. Zebrafish twist2/dermo1 regulates scale shape and scale organization during skin development and regeneration.

Author

Jacob T, Chakravarty A, Panchal A, Patil M, Ghodadra G, Sudhakaran J, and Nuesslein-Volhard C

Subjects

Animals, Base Sequence, Gene Expression Regulation, Developmental, Genotype, Mutation genetics, Phenotype, Twist-Related Protein 2 genetics, Wnt Signaling Pathway, Zebrafish Proteins genetics, Animal Scales anatomy & histology, Regeneration physiology, Skin embryology, Twist-Related Protein 2 metabolism, Zebrafish embryology, Zebrafish genetics, Zebrafish Proteins metabolism

Abstract

Scales are skin appendages in fishes that evolutionarily predate feathers in birds and hair in mammals. Zebrafish scales are dermal in origin and develop during metamorphosis. Understanding regulation of scale development in zebrafish offers an exciting possibility of unraveling how the mechanisms of skin appendage formation evolved in lower vertebrates and whether these mechanisms remained conserved in birds and mammals. Here we have investigated the expression and function of twist 2/dermo1 gene - known for its function in feather and hair formation - in scale development and regeneration. We show that of the four zebrafish twist paralogues, twist2/dermo1 and twist3 are expressed in the scale forming cells during scale development. Their expression is also upregulated during scale regeneration. Our knockout analysis reveals that twist2/dermo1 gene functions in the maintenance of the scale shape and organization during development as well as regeneration. We further show that the expression of twist2/dermo1 and twist3 is regulated by Wnt signaling. Our results demonstrate that the function of twist2/dermo1 in skin appendage formation, presumably under regulation of Wnt signaling, originated during evolution of basal vertebrates., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

3. The skin of birds' feet: Morphological adaptations of the plantar surface.

Author

Höfling E and Abourachid A

Subjects

Animal Scales anatomy & histology, Animals, Phylogeny, Syndactyly, Toes anatomy & histology, Adaptation, Physiological, Birds anatomy & histology, Birds physiology, Foot anatomy & histology, Skin anatomy & histology

Abstract

The skin of the foot provides the interface between the bird and the substrate. The foot morphology involves the bone shape and the integument that is in contact with the substrate. The podotheca is a layer of keratinized epidermis forming scales that extends from the tarsometatarsus to the toe extremities. It varies in size, shape, amount of overlap and interacts with the degree of fusion of the toes (syndactyly). A study of toe shape and the podotheca provides insights on the adaptations of perching birds. Our analysis is based on micro-CT scans and scanning electron microscopy images of 21 species from 17 families, and includes examples with different orientations of the toes: zygodactyl (toes II and III forward), anisodactyl (toes II, III, and IV forward), and heterodactyl (toes III and IV forward). We show that in these three groups, the skin forms part of a perching adaptation that involves syndactyly to different degrees. However, syndactyly does not occur in Psittacidae that use their toes also for food manipulation. The syndactyly increases the sole surface and may reinforce adherence with the substrate. Scale shape and toe orientation are involved in functional adaptations to perch. Thus, both bone and skin features combine to form a pincer-like foot., (© 2020 Wiley Periodicals LLC.)

Published

2021

4. Structure and function of skin in the pelagic sea snake, Hydrophis platurus.

Author

Lillywhite HB and Menon GK

Subjects

Animal Scales anatomy & histology, Animal Scales ultrastructure, Animals, Epidermis ultrastructure, Molting, Skin ultrastructure, Hydrophiidae anatomy & histology, Skin anatomy & histology

Abstract

We describe and interpret the functional morphology of skin of the Yellow-bellied sea snake, Hydrophis platurus. This is the only pelagic sea snake, and its integument differs from what is known for other species of snakes. In gross appearance, the scales of H. platurus consist of non-overlapping, polygonal knobs with flattened outer surfaces bearing presumptive filamentous sensillae. The deep recesses between scales ('hinge') entrap and wick water over the body surface, with mean retention of 5.1 g/cm of skin surface, similar to that determined previously for the roughened, spiny skin of marine file snakes, Acrochordus granulatus. This feature possibly serves to maintain the skin wet when the dorsal body protrudes above water while floating on calm oceanic slicks where they forage. In contrast with other snakes, including three species of amphibious, semi-marine sea kraits (Laticauda spp.), the outer corneous β-protein layer consists of a syncytium that is thinner than seen in most other species. The subjacent α-layer is also thin, and lipid droplets and lamellar bodies are seen among the immature, cornifying α-cells. A characteristic mesos layer, comprising the water permeability barrier, is either absent or very thin. These features are possibly related to (1) permeability requirements for cutaneous gas exchange, (2) reduced gradient for water efflux compared with terrestrial environments, (3) less need for physical protection in water compared with terrestrial ground environments, and (4) increased frequency of ecdysis thought to be an anti-fouling mechanism. The lipogenic features of the α-layer possibly compensate for the reduced or absent mesos layer, or produce layers of cells that comprise what functionally might be termed a mesos layer, but where the organization of barrier lipids nonetheless appears less robust than what is characteristically seen in squamates., (© 2019 Wiley Periodicals, Inc.)

Published

2019

5. Effect of an exfoliating skincare regimen on the numbers of epithelial squames on the skin of operating theatre staff, studied by surface microscopy.

Author

Wernham AG, Cain OL, and Thomas AM

Subjects

Adult, Animals, Female, Humans, Male, Microscopy, Middle Aged, Operating Rooms, Volunteers, Animal Scales anatomy & histology, Emollients administration & dosage, Hand Disinfection methods, Skin anatomy & histology, Skin drug effects, Surgical Wound Infection prevention & control

Abstract

Background: The shedding of epithelial squames (skin scales) by staff in operating theatre air is an important source of deep infection following joint replacement surgery. This is a serious complication, resulting in significant morbidity for the patient and substantial cost implications for healthcare systems. Much effort has been put into providing clean air in operating theatres, yet little attention has been given to reducing the shedding of surface skin scales at source., Aim: To develop a novel method for calculating surface skin scale density using surface microscopy, and to use it to evaluate the effect of a skincare regimen on operating theatre staff., Methods: Surface microscopy with Z-stacked imaging was used to visualize the effect of a skincare regimen involving three stages: washing with soap; exfoliation; and application of emollient. A USB microscope was then used in a field study to take images of the skin of operating theatre staff who applied the regimen to one lower limb the night before testing. The other limb was used as a control. Two blinded assessors analysed scale density., Results: Z-stack images from the surface microscope enabled observations of the skincare regimen. The USB microscope also provided adequate images that enabled assessment of skin scale density. In the operating theatre staff, a 72.1% reduction in visible skin scales was observed following application of the skincare regimen., Conclusions: Further work is required to demonstrate how this effect correlates with dispersion of skin particles in a cleanroom, and subsequently in live operating theatre studies., (Copyright © 2018 The Healthcare Infection Society. Published by Elsevier Ltd. All rights reserved.)

Published

2018

6. Experimental study of laminar and turbulent boundary layer separation control of shark skin.

Author

Afroz F, Lang A, Habegger ML, Motta P, and Hueter R

Subjects

Animal Scales anatomy & histology, Animals, Biomimetics, Friction, Models, Biological, Pressure, Rheology, Animal Scales physiology, Sharks physiology, Skin anatomy & histology, Skin Physiological Phenomena, Swimming physiology

Abstract

The Shortfin Mako shark (Isurus oxyrinchus) is a fast swimmer and has incredible turning agility, and has flexible scales known to bristle up to 50° in the flank regions. It is purported that this bristling capability of the scales may result in a unique pass flow control method to control flow separation and reduce drag. It appears that the scales have evolved to be only actuated when the flow over the body is reversed; thereby inducing a method of inhibiting flow reversal close to the surface. In addition, bristled scales form cavities which could induce boundary layer mixing and further assist in delaying flow separation. To substantiate the hypothesis, samples of skin from the flank region of the mako have been tested in a water tunnel facility under various strengths of adverse pressure gradient (APG). Laminar and turbulent separation over the skin was studied experimentally using time-resolved digital particle image velocimetry, where the APG was generated and varied using a rotating cylinder. Shark skin results were compared with that of a smooth plate data for a given amount of APG. Both the instantaneous and time-averaged results reveal that shark skin is capable of controlling laminar as well as turbulent separation. Under laminar conditions, the shark skin also induces an early transition to turbulence and reduces the degree of laminar separation. For turbulent separation, the presence of the shark skin reduces the amount of backflow and size of the separation region. Under both flow conditions, the shark skin also delayed the point of separation as compared to a smooth wall.

Published

2016