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Concept and types of tissues, epithelial tissue, epithelial cells. Dr. Zita Puskár EDI. 22/09/2017. Levels of Body Organization. Where can we find epithelia?. Surface (covering or lining) epithelia. Sensory/Neuroepithelia. Pigment epithelia. Glandular epithelia. Epithelial Tissue.
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Concept and types of tissues, epithelial tissue, epithelial cells Dr. Zita Puskár EDI. 22/09/2017
Where can we find epithelia? Surface (covering or lining) epithelia Sensory/Neuroepithelia Pigment epithelia Glandular epithelia
Epithelial Tissue • Features of the epithelial cells: • Closely aggregated polygonal cells • Very little extracellular space • Strong adhesion among the cells • Epithelial tissue is non-vascularized (no blood vessels) !!! • Functions: • Covering, lining and protecting the surfaces • Absorption, resorption (epithelia in the intestines) • Secretion (glands) • Contractility (myoepithelial cells) • Specialized sensory function (taste bud, olfactory epithelium)
Basement membrane Function: structural and filtering function, influence cell polarity, regulate cell ploriferation and differentiation, influence cell metabolism and survival, pathway for migration
Classification by shape and number of layers Cell shape and number of layers • Number of layers • - simple • - stratified Simple epithelium: It is formed by a singe cell layer where each cell is attached to the basement membrane. Stratified epithelium: It is formed by more than one layer of cells but only cells in the basal layer are attached to the basement membrane. Pseudostratified epithelium: Each cell is attached to the basement membrane but the cell nuclei are at several different levels giving a stratified appearance of the tissue.
Morphological types of epithelial tissue Simlpe squamous cuboidal columnar Pseudostratified columnar Stratified (Classification is based on the cell shape of the superficial layer) squamous cuboidal columnar transitional epithelium (urothelium) keratinized non-keratinized
Functional types of epithelial tissue Surface (Covering) Surface (Lining) Glandular Modified epithelial cells Myoepithel cells Sensory cells - Neuroepithelium Pigment epithelium taste buds in the tongue
Types of simple squamous epithelia epithel endothel mesothel kidney glomerulus blood vessel serous membrane According to the location and function
Simple cuboidal epithelia Exretory ducts of glands Kidney tubule
Simple columnar epithelia intestine
Composition of the cytoskeleton Microtubules Microfilamens - actin filaments Filaments Cytoskeleton Intermediate filaments Accessory proteins Motor proteins
Specializations of the apical surface microvilli stereocilia (kino)cilia
Microvilli intestine
Stereocilia epididymis
Specializations of the basal surface - basal striation Kidney
Cell adhesion Specific binding of a cell to other cells or to the extracellular matrix (ECM) is called cell adhesion, mediated by interactions between transmembrane glycoproteins called cell adhesion molecules (CAM) Function: development of tissues, cell migration, regulation of gene expression, cell proliferation and cell death, pathological processes (eg. cancer metastasis)
Adhesion proteins • Common features: • Extracellular domain (interaction with other CAMs (homophilic binding) or ECM (heterophilic binding) • Trans membrane domain • Intracellular domain (interaction with the cytoskeleton)
Junctional complexes gj (a) Occluding junction, zonula occludens (tight junction) (b) adhesive junction, zonula adherens (c) macula adherens (desmosome) (d) hemidesmosome (e) gap junction
General features of junctional complexes Transmembrane adhesion proteins: Connecting cell to cell → homophil binding (occludin, cadherin: Ca2+ dependent adhering protein), Connecting cell to matrix → heterophil binding (integrins) Link proteins– connecting transmembrane adhesion proteins to cytoskeleton (spectrin) Components of the cytoskeleton (actin filaments, intermedier filaments) Types: Homophil-heterophil Ca2+ dependent – Ca2+ independent Strong - weak
Zonula occludens – tight junction Transmembrane proteins: occludin (Ca2+ dependent) claudin, JAM (Junctional Adhesion Protein) Link (anchoring) proteins: Zo1, Zo2, Zo3 Actin filaments Function: separation of the apical and basolateral surfaces, diffusion barrier in the membrane and intercellular space, prevention of the lateral diffusion of membrane components
Zonula adherens Function: • Firm mechanical junction • Encircles the cell • Ca2+ sensitive • Insensitive to osmotic changes • Not a diffusion barrier Actin related (in heart muscle: band like - fascia adherens, in synapse: patch like - punctum adherens)
Macula adherens - desmosome plaque • Related to intermedier filaments (keratin filaments) → form networks • Patch like (patent) • Firm connection (skin, heart muscle) Desmosomal cadherins : desmoglein and desmocollin - together desmoglea Cytoplasmatic plaque: desmoplakin, plaktoglobin
A disease of desmosomes: pemphigus Blistering autoimmune disease in which antibodies form against desmoglein (the transmembrane desmosomal cadherin) and the cells of stratum spinosum are separated from each other (unglued). (Blisters→sores)
Hemidesmosome - Half desmosome This is not a desmosome! Binds the epithelium to the basement membrane Transmembrane proteins – integrins bind to intermedier filaments of the cell and to laminin molecule of basal lamina
Gap junction Channel pore: 1.5 nm • Structural unit: connexon that consists of 6 subunits. The major protein of the subunits: connexin • Small molecules, ions move through the pores • Special signal transduction (cAMP, cGMP) • Opening and closing of the channel is Ca2+ and pH dependent • Appears also in heart muscle, electric synapse gap: 2-4 nm
Transport across epithelia Sodium pumps (Mg2+ activated Na+/K+ ATP-ase) Transcellular transport (fluids and ions) Transcytosis (pinocytotic vesicles)
References: Röhlich Pál: Szövettan, Budapest, 2006 Anthony L. Mescher: Junqueira’s Basic Histology, New York, 2010 Michael Ross and Lynn J. Romrell: Histology, Baltimore, 1989 Geoffrey M. Cooper and Robert E. Hausman: The Cell, A molecular Approach, (ASM, Sinauer), Washington, Sunderland, 2009 Darvas Zsuzsa és László Valéria: Sejtbiológia, Budapest 2005