Summary
In normal, non-expanding toad epidermis more cells are produced than needed to replace cells lost by moulting. By implication, cell deletion additional to moulting must take place. This paper deals with the mechanisms by which the “surplus” of cells is deleted, taking advantage of the fact that the ratio between cell birth rate (K b) and the rate of desquamation (K d), which in normal toads is 2 to 3, can be manipulated. In toads deprived of the pars distalis of the pituitary gland it is decreased to 0.2 to 0.3, and in toads with hydrocortisone pellets implanted into the subcutaneous lymph space it is increased to 7 to 10. Thus, structures candidates for the morphological manifestation of the deletion process should occur rarely in toads in which the pars distalis has been removed and frequently in toads with hydrocortisone pellets implanted. Categorization and enumeration of such structures by light microscopy in the epidermis from operated, normal, and hormone-treated toads were performed. The incidence of structures referred to as “dark cells” and “omega-figures” were found to correlate relatively well with the K b/Kd-ratio. A subsequent ultrastructural analysis — on a cell-by-cell basis — of “dark cells” showed these to reflect various stages of apoptosis. The duration of the apoptotic process was calculated to be approximately 7 h. Light- and electron microscopy of “omega-figures” combined with histochemical observations of PSA-lectin binding were interpreted as reflecting a release of cells from the basal epidermis and their final elimination within the dermis. It is concluded (i) that apoptosis is an important mechanism of controlled cell deletion, (ii) that emigration to, and elimination in, the dermis is a possible deletion mechanism, and (iii) that necrosis is unlikely to play a role in controlled cell deletion.
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References
Abrahamson DR (1986) Recent studies on the structure and pathology of basement membranes. J Pathol 149:257–278
Alison MR, Wilkins MJE, Walker SM, Hully JR (1987) Cell population size control in the rat liver: the response of hepatocytes in various proliferative states to a mitotic stimulus. Epithelia 1:53–64
Beaulaton J, Lockshin RA (1982) The relation of programmed cell death to development and reproduction: Comparative studies and an attempt at classification. Int Rev Cytol 79:215–235
Beckingham-Smith K, Tata JR (1976) Cell death. Are new proteins synthesised during hormone-induced tadpole tail regression? Exp Cell Res 100:129–146
Bergstresser PR, Taylor JR (1977) Epidermal “turnover time” — a new examination. Br J Dermatol 96:503–509
Bowen ID (1981) Techniques for demonstrating cell death. In: Bowen ID, Lockshin RA (eds) Cell death in biology and pathology. Chapman and Hall, London New York, pp 379–444
Brown AW (1977) Structural abnormalities in neurones. J Clin Pathol 30 (suppl 11):155–169
Budtz PE (1979) Epidermal structure and dynamics of the toad, Bufo bufo, deprived of the pars distalis of the pituitary gland. J Zool Lond 189:57–92
Budtz PE (1982) Time-dependent effects of removal of the pars distalis of the pituitary gland on toad epidermal cell and tissue kinetic parameters. Cell Tissue Kinet 15:507–519
Budtz PE (1985a) Epidermal tissue homeostasis. I. Cell pool size, cell birth rate and cell loss by moulting in the intact toad, Bufo bufo. Cell Tissue Kinet 18:521–532
Budtz PE (1985b) Epidermal tissue homeostasis. II. Cell pool size, cell birth rate and cell loss in toads deprived of the pars distalis of the pituitary gland. Cell Tissue Kinet 18:533–542
Budtz PE (1986a) Amphibian skin as a model in studies on epidermal homeostasis. In: Marks R, Plewig G (eds) Skin models. Springer, Berlin Heidelberg New York, pp 58–72
Budtz PE (1986b) Expectations of human epidermal kinetic homeostasis. Br J Dermatol 114:645–650
Budtz PE (1988) Epidermal tissue homeostasis. III. Effect of hydrocortisone on cell pool size, cell birth rate and cell loss in normal toads and in toads deprived of the pars distalis of the pituitary gland. Cell Tissue Kinet (in press)
Budtz PE, Larsen LO (1973) Structure of the toad epidermis during the moulting cycle. I: Light microscopic observations in Bufo bufo. Z Zellforsch 144:353–365
Budtz PE, Larsen LO (1975) Structure of the toad epidermis during the moulting cycle. II. Electron microscopic observations in Bufo bufo. Cell Tissue Res 159:459–483
Denefle J-P, Lechaire J-P, Zhu Q-L (1987) Fibronectin (FN) localization in mitochondria-rich cells of frog epidermis. Biol Cell (Paris) 59:181–184
Dongen WJ van, Jørgensen CB, Larsen LO, Rosenkilde P, Lofts B, van Oordt PGWJ (1966) Function and cytology of the normal and autotransplanted pars distalis of the hypophysis in the toad Bufo bufo (L). Gen Comp Endocrinol 6:491–518
Ebner H, Gebhart W (1975) Light and electron microscopic differentiation of amyloid and colloid or hyaline bodies. Br J Dermatol 92:637–645
Ferguson DJP (1988) An ultrastructural study of mitosis and cytokinesis in normal “resting” human breast. Cell Tissue Res 252:581–587
Fujita T (1976) The gastro-enteric cell and its paraneuronic nature. In: Coupland T, Fujita T (eds) Chromaffin, enterochromaffin and releated cells. Elsevier, Amsterdam, pp 191–208
Gottschaldt KM, Vahle-Hinz CH (1981) Merkel cell receptors: structure and transducer function. Science 214:183–186
Gottschaldt KM, Vahle-Hinz CH (1982) Evidence against transmitter function of met-enkephalin and chemosynaptic impulse generation in “Merkel cell” mechanoreceptor. Exp Brain Res 45:459–463
Gould VE, Moll R, Moll I, Lee I, Franke WW (1985) Biology of disease. Neuroendocrine (Merkel) cells of skin: hyperplasias, dysplasias, and neoplasms. Lab Invest 52:334–353
Grubauer G, Romani N, Kofler H, Stanzl U, Fritsch P, Hintner H (1986) Apoptotic keratin bodies as autoantigen causing the production of of IgM-anti-keratin intermediate filament autoantibodies. J Invest Dermatol 87:466–471
Hartschuh W, Weihe E, Reineche M (1985) The Merkel cell. In: Bereiter-Hahn J, Matoltsy AG, Richards KS (eds) Biology of the integument, vol 2: Vertebrates. Springer, Berlin Heidelberg New York Tokyo, pp 605–620
Hashimoto K (1976) Apoptosis in lichen planus and several other dermatoses. Acta Dermatovener (Stockholm) 56:187–210
Heng MCY, Kloss SG, Kuehn CS, Chase DG (1986) Significance and pathogenesis of basal keratinocyte herniations in psoriasis. J Invest Dermtol 87:362–366
Hoffman CW (1978) Epidermal proliferation in lower vertebrates. In: Jeter JR, Cameron IL, Padilla GM, Zimmerman AM (eds) Cell cycle regulation. Academic Press, New York San Francisco London, pp 221–232
Hume WJ (1983) Stem cells in oral epithelia. In: Potten CS (ed) Stem cells: their identification and characterization. Churchill Livingstone, Edinburgh, pp 233–270
Hume WJ (1985) Keratinocyte proliferative hierarchies confer protective mechanisms in surface epithelia. Br J Dermatol 112:493–502
Iggo A (1980) Electrophysiology of cutaneous sensory receptors. In: Spearman RIC, Riley PA (eds) The skin of vertebrates. Linn Soc Symp Ser 9, Academic Press, London, pp 255–270
Iggo A, Muir AR (1969) The structure and function of slowlyadapting touch corpuscle in hairy skin. J Physiol (Lond) 200:763–796
Jørgensen CB (1988) Nature of moulting control in amphibians: effects of cortisol implants in toads Bufo bufo. Gen Comp Endocrinol 71:29–35
Jørgensen CB, Levi H (1975) Incorporation of 3H-thymidine in stratum germinativum of epidermis in the toad Bufo bufo bufo (L): An autoradiographic study of moulting cycle and diurnal variations. Comp Biochem Physiol 52A:55–58
Kefalides NA (1975) Basement membranes: structural and biosynthetic considerations. J Invest Dermatol 65:85–92
Kerr JFR, Wyllie AH, Currie AR (1972) Apoptosis: a basic biological phenomenon with wide-ranging implications in tissue kinetics. Br J Cancer 26:239–257
Klein-Szanto AJP, Slaga TJ (1981) Numerical variation of dark cells in normal and chemically induced hyperplastic epidermis with age of animal and efficiency of tumor promotor. Cancer Res 41:4437–4440
Larsen LO (1976) Physiology of moulting. In: Lofts B (ed) Physiology of Amphibians, vol 3. Academic Press, New York San Francisco London, pp 53–100
Levi H, Nielsen A (1982) An autoradiographic study of cell kinetics in epidermis of the toad Bufo bufo bufo (L). J Invest Dermatol 79:292–296
Linser I, Auböck J, Romani N, Smolle J, Grubauer G, Fritsch P, Hintner H (1987) The keratin body phenomenon. Epithelia 1:85–99
Lovas JGL (1986) Apoptosis in human epidermis: a postmortem study by light and electron microscopy. Aust J Dermatol 27:1–5
Marks R (1980) Is epidermal homeostasis a necessity? — comments on epidermal growth control. Br J Dermatol 103:697–702
Moll I, Moll R, Franke WW (1986) Formation of epidermal and dermal Merkel cells during human fetal skin development. J Invest Dermatol 87:779–789
Nafstad PHJ, Baker RE (1973) Comparative ultrastructural study of normal and grafted skin in the frog, Rana pipiens, with special reference to neuroepithelial connections. Z Zellforsch 139:451–462
O'Connell JF, Klein-Szanto AJP, DiGiovanni DM, Fries JW, Slaga TJ (1986) Enhanced malignant progression of mouse skin tumors by free-radical generator benzoyl proxide. Cancer Res 46:2863–2865
Olson RL, Everett MA (1975) Epidermal apoptosis: cell deletion by phagocytosis. J Cutan Pathol 2:53–57
Parducz A, Leslie RA, Cooper E, Turner CJ, Diamond J (1977) The Merkel cells and the rapidly adapting mechanoreceptors of the salamander skin. Neurosciences 2:511–521
Parsons DF, Marko M, Braun SJ, Wansor KJ (1983) “Dark cells” in normal, hyperplastic, and promotor-treated mouse epidermis studied by conventional and high-voltage electron microscopy. J Invest Dermatol 81:62–67
Pearse AGE (1968) Common cytochemical and ultrastructural characteristics of cells producing polypeptide hormones (the APUD series) and their relevance to thyroid and ultimobranchial C cells and calcitonin. Proc R Soc Lond [Biol] 170:71–80
Pearse AGE (1969) The cytochemistry and ultrastructure of polypeptide hormone-producing cells of the APUD-series and the embryologic, physiologic and pathologic implications of the concept. J Histochem Cytochem 17:303–313
Pollard JW, Pacey J, Cheng SVY, Jordan EG (1987) Estrogens and cell death in murine uterine luminal epithelium. Cell Tissue Res 249:533–540
Potten CS, Al-Barwari SE, Hume WJ, Searle J (1977) Circadian rhythms of presumptive stem cells in three different epithelia of the mouse. Cell Tissue Kinet 10:557–568
Read J, Watt F (1988) A model for in vitro studies of epidermal homeostasis: proliferation and involucrin synthesis by cultured human keratinocytes during recovery after stripping off the suprabasal layers. J Invest Dermatol 90:739–743
Reimer KA, Ganote CE, Jennings RB (1972) Alterations in renal cortex following ischaemic injury. III. Ultrastructure of proximal tubules after ischaemia or autolysis. Lab Invest 26:347–363
Ridge BD, Batt MD, Palmer HE, Jarrett A (1988) The dansyl chloride technique for stratum corneum renewal as an indicator of changes in epidermal mitotic activity following topical treatment. Br J Dermatol 118:167–174
Slaga TJ, Klein-Szanto AJP (1983) Initiation-promotion versus complete skin carcinogenesis in mice: importance of dark basal keratinocytes (stem cells). Cancer Invest 1:425–436
Smith CA, Monaghan P, Ellis V (1985) Epithelial cells of the normal human breast. J Pathol 146:221–226
Weedon D, Searle J, Kerr JFR (1979) Apoptosis: its nature and implications for dermatopathology. Am J Dermatopathol 1:133–144
Weinstein GD, McCullough JL, Ross P (1984) Cell proliferation in normal epidermis. J Invest Dermatol 82:623–628
Wyllie AH (1981) Cell death: a new classification separating apoptosis from necrosis. In: Bowen ID, Lockshin RA (eds) Cell death in biology and pathology. Chapman and Hall, London New York, pp 9–34
Wyllie AH, Kerr JFR, Currie AR (1980) Cell death: the significance of apoptosis. Int Rev Cytol 68:251–306
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Supported in part by the Danish National Science Research Council (grant no. 11-6498) (PB)
Part of this work was presented at the XVth Meeting of the European Study Group for Cell Proliferation, Sundvollen, Norway, 16–20 September 1987
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Budtz, P.E., Spies, I. Epidermal tissue homeostasis: Apoptosis and cell emigration as mechanisms of controlled cell deletion in the epidermis, of the toad, Bufo bufo . Cell Tissue Res. 256, 475–486 (1989). https://doi.org/10.1007/BF00225595
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DOI: https://doi.org/10.1007/BF00225595