1. Histology and Ontogeny of Scales, Feathers and Hair

2. The Integument “Jack-of-all-Trades” organ system “Jack-of-all-Trades” organ system Forms interface b/w the internal and external environment Forms interface b/w the internal and external environment –Homeostasis –Protection from abrasion –Buffers drastic environmental change  Na, HOH, UV –Exchange of chemicals and gases (receptors)  Protective  Communicative  Nutritive –Coloration  Protection  Communication Structure and Function correlated with an organisms life style and environment Structure and Function correlated with an organisms life style and environment

3. Integument - Structure and Development Epidermis Epidermis –Stratified, squamous –Ectoderm Basement Membrane Basement Membrane –Fibrils Dermis Dermis –Fibrous connective tissue –Mesodermal dermatome of the somites

4. Integument - Structure and Development Stratum germinativum Stratum germinativum –Cuboidal –Mitotic Division –Migrate Distally –Differentiate –Sloughed off Synthesis of keratin Synthesis of keratin –Water insoluble protein that fills cells –Stratum corneum of Vertebrates

5. Integument - Structure and Development Beneath the Basement Membrane (Dermis) – –Proximal Migration and differentiation of of collagen fibers and other structures – –Two layers   Stratum laxum (spongiosum)   Stratum compactum –Blood vessels, nerves, pigment cells –Endotherms – bases of hair and feathers + erector muscles  “Ancient and persistent potential to form bone”

6. Interaction between dermis and epidermis Bony scales Bony scales Horny scales Horny scales Feathers Feathers Hair Hair Other skin derivatives – claws, antlers, horns, baleen Other skin derivatives – claws, antlers, horns, baleen Cells that form the skin layers Cells that form the skin layers –Respond to inductive influences of adjacent cells and to environmental influences.  Neural crest cells migrating between epidermis and dermis signal the building of these derivatives

7. Integument of Fishes Fish are aquatic Fish are aquatic –Conservation of structure and function among the different fish groups. –Bony scales  Characterize the skin of most fishes  Substances (tissues) that contribute to bony scales –Bone –Dentine –Enamel

8. Function of bony scales Protection from parasites, other predators Protection from parasites, other predators Positioning: Positioning: –Slide one atop the next –Allow for the distortion of body Hydrodynamic function to reduce drag Hydrodynamic function to reduce drag Feeding Feeding

9. Cellular Bone Cellular Bone –Extra-cellular matrix of collagen fibers –Embedded in polysaccharide ground substance –Matrix laid down by osteoblasts  Differentiate from mesenchyme cells of the dermis –Calcium phosphate crystals (hydroxyapatite) bind to fibers –During osteogenesis  Osteoblasts mature and become entrapped in matrix – osteocytes  Osteocytes are located in lacunae –Small cavities interconnected by canals (canaliculi) –Cell processes are extended through these canals Bone of fish scales Bone of fish scales –“dermal bone” (cf. “cellular bone”)

10. Bony scales Bone is deposited by osteocytes on the periphery of a developing scale Bone is deposited by osteocytes on the periphery of a developing scale Osteocytes move centrifugally away from center of scale Osteocytes move centrifugally away from center of scale No bone cells or processes are left behind No bone cells or processes are left behind Then dentine and enamel layers can be added to the surface of the bone for increased hardness of scale Then dentine and enamel layers can be added to the surface of the bone for increased hardness of scale

11. Dentine and Enamel Mesenchymal aggregation (papilla) beneath basement membrane Mesenchymal aggregation (papilla) beneath basement membrane Basal cells above the papillae respond and differentiate into ameloblasts Basal cells above the papillae respond and differentiate into ameloblasts –Ameloblasts – collectively called the enamel organ –Secrete enamel –Retreat Underlying dermal cells differentiate into odontoblasts Underlying dermal cells differentiate into odontoblasts –secrete dentine –Retreat in direction opposite of ameloblasts –Leave long cytoplasmic processes – dentine tubules

12. Types of Scales Four general types: Four general types: Placoid scales – paleozoic sharks, elasmobranchs Placoid scales – paleozoic sharks, elasmobranchs –Also called dermal denticles –Spinous process  From dermis –Dentine, surrounding a vascular pulp cavity and capped by enamel –Become teeth at jaws

13. Types of Bony Scales Cosmoid plates and scales Cosmoid plates and scales –Ostracoderms –Cosmine – “dentine” Ganoid plates and scales Ganoid plates and scales –Actinopterygian fishes –Bichirs (Polypterus), Garpikes

14. Modern Modern –Cycloid and Ctenoid –Most teleosts Types of Bony Scales

15. Horny Scales Scales of reptiles Scales of reptiles –“scale”  Many layers of cells  Thick stratum corneum –Keratin with phospholipids  Outer epidermal generation  Inner epidermal generation –Function  Protection  Reduce water loss

16. Feathers Most conspicuous integumental derivative Most conspicuous integumental derivative Keratin Keratin Function Function –Flight –Heat Conservation  Reduced convective and evaporative heat loss  Increased insulation

17. Feathers Types Types –Contour feathers  Flight feathers on tail and wings –Down –Filoplumes  Barbs reduced or lost  Rictal bristles Calamus Rachis

18. Feathers Development triggered by an interaction b/w epidermis and dermal mesenchyme Development triggered by an interaction b/w epidermis and dermal mesenchyme Formation of dermal papilla (placode) Formation of dermal papilla (placode) Mitotic divisions in a collar zone of the stratum germinativum near the base of the papilla form a crown of barbs Mitotic divisions in a collar zone of the stratum germinativum near the base of the papilla form a crown of barbs Covered by a horny sheath of epidermis Covered by a horny sheath of epidermis

19. Feathers As development proceeds: As development proceeds: –Differential cell division on one side of the papilla  Timing of expression of two proteins: Shh & Bmp2 –These cells form a shaft away from the body  carrying the barbs that are formed in the collar –The base of the feather recedes into the skin  Accompanied by layers of epithelial cells  Feather follicle –Degeneration of epidermal sheath

20. Feather morphogenesis Contour feather movie from John Fallon’s lab at UWisc Contour feather movie from John Fallon’s lab at UWisc Contour feather movie from John Fallon’s lab at UWisc Contour feather movie from John Fallon’s lab at UWisc

21. Cross-section of feather follicle 1.Barb ridges of epithelial 2.Surrounding dermal core of connective tissue 3.Space of the follicle 4.Epithelial tissue of follicle 5.Associated musculature

22. Hair Keratinized derivative of mammalian skin Keratinized derivative of mammalian skin Function Function –Protective –Insulation –Tactile

23. Hair Structure Structure –Shaft of dead, cornified cells –Base is embedded in follicle in the dermis –Follicle wall composed of epidermal cells

24. Hair Development Development

25. Shaft Shaft Follicle Follicle Epidermis Epidermis Dermis Dermis Root Root Hair papilla Hair papilla Cuticle Cuticle Cortex Cortex Medulla Medulla Air vacuole Air vacuole

26. Hair

27. Hair

28. Hair derivatives Antlers – Cervidae –Bony outgrowths, shed annually. True horns – Bovidae –Bony cores covered with horny sheaths; permanent.

29. SLIDE 35. BMP2 and SHH expression in the scale and feather rudiments. (Harris et al., 2002) What about the creation of a new morphological structure--a novelty. Avian feathers have long been proposed as an evolutionary novelty. But the mechanism to produce feathers has remained elusive. However, a paper recently published from John Fallon's laboratory provides a developmental mechanism by which feathers can be generated from scales. They provide evidence that the differences in the expression of sonic hedgehog and BMP proteins separate the feather from the scale. Both the scale and the feather start off the same way, with the separation of BMP2 and SHH- secreting domains. However, in the feather, both domains shift to the distal region of the appendage. Moreover, this pattern becomes repeated serially around the proximal distal axis. The interaction between BMP2 and Shh then causes each of these regions to form its own axis--the barb of the feather. Matt Harris and others in the Fallon laboratory have shown that when you alter the expression of Shh or BMP2, you change the feather pattern. The results correspond exceptionally well to a proposed mechanism of feather production from archosaurian scales.