Epithelial
tissue
Dept. Histology & Embryology,
Faculty of Medicine MU
pvanhara@med.muni.cz
Petr Vaňhara, PhD
Epithelium
Muscle
Nerve
Connective
 Contemporary tissue classification
Based on morphology and function:
Myofibrils  contraction
Mesoderm – skeletal muscle, myocard, mesenchyme
– smooth muscles
Rarely ectoderm (eg. m. sphincter a m. dilatator pupillae)
Neurons and neuroglia
Reception and transmission of electric signals
Ectoderm, rarely mesoderm (microglia)
Dominant extracellular matrix
Connective tissue, cartilage, bone…
Mesenchyme
Continual, avascular layers of cells with different
function, oriented to open space, with specific
junctions and minimum of ECM and intercellular
space.
Derivates of all three germ layers
General characteristic of epithelial tissue
• Typical morphology and cell connections
 General characteristics of epithelial tissue
• Avascular (without blood supply) – nutrition by diffusion from a highly vascular and innervated area of
loose connective tissue (lamina propria) just below the basement membrane
• Highly cellular – cohesive sheet or groups of cells with no or little extracellular matrix
 Hallmarks of typical epithelial cell
www.webanatomy.net
 Basement membrane
• Attachment of epithelium to underlying tissues
• Selective filter barrier between epithelial and connective
tissue
• Communication, differentiation
PASHE
 Basal lamina vs. basement membrane
 50-100nm
 Glycosaminoglycans – heparansulfate
 Laminin, collagen III, IV, VI,
 Nidogen/entactin
 Perlecan
 Proteoglycans
 Architecture of basement membrane
Lamina
basalis
Lamina
fibroreticularis
Kolagenní
vazivo
BM
 Modifications of basement membrane architecture
• Two basic layers
– lamina basalis
• lamina densa,
• lamina rara ext. et int.
– lamina fibroreticularis
• Tissue specific modifications
‒ Descemet membrane (cornea)
‒ Glomerular BM (Bowman’s capsule)
‒ Part of Bruch’s membran of retina
…
 Basement membrane in corpusculum renis
 Basement membrane in corpusculum renis
• Clinical correlations – Membranous glomerulonefritis
- circulationg Abs bind to BM of capillary wall
- complement (C5b-C9) attacks glomerular endothelial cells
- filtation barrier compromised
- proteinuria, edema, hematouria, renal failure
 Embryonic origin of epithelial tissues
Germ layer Epithelial derivatives
Ectoderm 1. Epidermis (stratified squamous keratinized epithelium)
2. Sweat glands and ducts (simple and stratified cuboidal epithelium)
3. Oral cavity, vagina, anal canal (stratified squamous non-keratinized epithelium)
Mesoderm 1. Endothelium of blood vessels (simple squamous epithelium)
2. Mesothelium of body cavities (simple squamous epithelium)
3. Urinary and reproductive passages (transitional, pseudostratified and stratified
columnar epithelium, simple cuboidal and columnar epithelium)
Endoderm 1. Esophagus (stratified squamous non-keratinized epithelium)
2. GIT (simple columnar epithelium)
3. Výstelka žlučníku (simple columnar epithelium)
4. Solid glands (liver, pancreas)
5. Respiratory passages (ciliated pseudostratified columnar epithelium, ciliated simple
columnar epithelium, cuboidal, squamous)
 Embryonic origin of epithelial tissues
 derived from all three germ layers
 Covering (sheet) epithelium
 Trabecular epithelium
 Reticular epithelium
 Classification of epithelial tissues
by morphology
by function
 Covering
 Glandular
 Resorptive
 Sensory
 Respiratory
 Alveolar
 Germinal
 ...
Morphology of epithelial tissue
 Classification of epithelial tissues
Vessels
Kidney
Intestine
Respiratory passages
Skin
Oesophagus
Ducts
Urinary tract
Covering (sheet) epithelia
Endothelium.
heart, blood, and lymphatic vessels.
Mesothelium.
serous membranes - body cavities
 Simple squamous epithelium
‒ Capillaries
‒ Lung alveolus
‒ Glomerulus in renal corpuscle
Selective permeabilty
‒ Single layer of flat cells with central flat nuclei
 Simple cuboidal epithelium
‒ Single layer of cubic cells with large, spherical
central nuclei
Examples:
‒ Ovarian surface epithelium
‒ Renal tubules
‒ Thyroid
‒ Secretion acini
‒ Secretion or resorption
Ovarian surface epithelium
Thyroid follicles
 Simple columnar epithelium
‒ GIT
- stomach
- small and large intestine
- gall bladder
Resorption / Secretion
‒ Single layer of columnar cells with large, oval, basally located nucleus
 Simple columnar epithelium with kinocilia
‒ Uterine tube
‒ flow of the oocyte towards the uterus
© http://www.unifr.ch
www.siumed.edu
 Simple columnar epithelium with kinocilia
(also pseudostratified)
‒ Upper respiratory passages
‒ Removal of mucus produced by epithelial glands
Other locations:
‒ Spinal cord ependyma
‒ Epididymis
‒ Vas deferens
 Stratified squamous epithelium
Keratinized vs. non-keratinized
 Constant abrasion
 Mechanical resilience
 Protection from drying
 Rapid renewal
Examples:
‒ Cornea
‒ Oral cavity and lips
‒ Esophagus
‒ Anal canal
‒ Vagina
 Multiple layers of cubic cells with central nuclei,
flattening towards the surface
 First layer in contact with BM, last layer – flat
 Stratified squamous epithelium
Keratinized
Skin (epidermis)
Nail
Keratins
Fibrous proteins, ~ 40 types
Very stable, multimeric
Disorders of keratin expression
– variety of clinical symptoms
e.g. Epidermolysis bullosa simplex
 Stratified cuboidal epithelium
Large ducts of :
‒ sweat glands
‒ mammary glands
‒ salivary glands
‒ Fluctuation of volume
‒ - organization of epithelial layers
‒ - membrane reserve
‒ Protection against hyperosmotic urine
‒ Urinary bladder, kidneys, ureters
 Transitional epithelium (urothelium)
Empty: rather cuboidal with a domed apex
Relaxed: flat,stretched
Basal cells
Intermediate layer
Surface cells
 Transitional epithelium (urothelium)
glycosaminoglycan layer (GAG) on the surface
‒ osmotic barrier
‒ antimicrobial properties
Barrier architecture:
‒ GAG-layer
‒ surface cells (tight junctions), uroplakin
proteins in the apical cell membrane
‒ capillary plexus in the submucosa
©http://www.cytochemistry.net/microanatomy/epithelia/salivary7.jpg
 Stratified columnar epithelia
‒ several layers of columnar cells
‒ secretion / protection
‒ ocular conjunctiva
‒ pharynx, anus – transitions
‒ uterus, male urethra, vas deferens
‒ intralobular ducts of salivary glands
 Classification of epithelial tissues
Trabecular epithelium
Liver parenchyma
• Cords of hepatocytes
Trabecular epithelium
Islets of Langerhans
Cords of endocrine active cells
 Endocrine glands
Function of epithelial tissue
 Glandular epithelium
• Secret ↔ excret
• Process of secretion:
Holocrine  Merocrine  Apocrine
 Glandular epithelium
 Single cell glands
– Goblet
– Enteroendocrine
 Goblet cells
- Mainly respiratory and intestinal tract
- Produce mucus = viscous fluid composed of
electrolytes and highly glycosylated glycoproteins
(mucins)
- Protection against mechanic shear or chemical
damage
- Trapping and elimination of particular matter
- Secretion by secretory granules constitutive or
stimulated
- After secretion mucus expands extremely – more than
500-fold in 20ms
- Dramatic changes in hydration and ionic charge
- Chronic bronchitis or cystic fibrosis – hyperplasia or
metaplasia of goblet cells
 Multicellular glands
• Shape of secretion part
– Alveolar (acinar)
– Tubular
– Tubuloalveolar (tubuloacinar)
• Branching
– Simple
– Branched
– Compound
• Secretion
– Mucous
– Serous
– Compound
 Multicellular glands
– Endocrine vs. endocrine
 Mucous glands
 Mucous glands
 Serous glands
 Compound glands
- both serous and mucous
 Respiratory epithelium
Respiratory passages
– Moisten, protect against injury and pathogen
– Remove particles by „mucociliary escalator“
– Pseudostratified columanr epithelim with cilia
– Basal cells- epithelium renewal
Alveolar epitheithelium
– Gas exchange
– Respiratory bronchiols, alveolar passages and alveoli
– Type I and II pneumocytes
 Sensory epithelium
– Supportive and sensory cells
Primary sensory cells – directly convert stimuli to membrane potential
Receptory region, body, axonal process
Nasal epithelium (regio olfactoria nasi), rods and cones
Secondary sensory cells
Receptory region and body
Signal is trasmitted by adjacent neurons terminating on secondary sensory cell
Taste buds, vestibulocochlear appratus
 Myoepithelium
– Star-like or spindle cells
– Connected by nexus and desmosomes
– Actin microfilaments, myosin and tropomyosin
– Contraction
– Sweat and salivary glands – enhancing secretion
 Regeneration of epithelial tissue
Different regenerative potential (epidermis  sensory epithelium of inner ear)
Multi- a oligopotent stem cells
Microenvironment – stem cell niche
Example: Regeneration of intestine epithelium
Metaplasia
Squamous metaplasia of cervix uteri
Respiratory passages
Simple columnar epithelium
Stratified squamous epithelium
 Plasticity of epithelial tissues
Simple columnar epithelium
Metaplasia
Development of precancerous lesions
 Plasticity of epithelial tissues
Wikipedia.org; http://radiology.uchc.edu
Hyperplasia
Normal prostate
Hyperplasia of prostate
glandular epithelium
Prostate
adenocarcinoma
 Plasticity of epithelial tissues
Epithelial to mesenchymal transition (EMT)
J Clin Invest. 2009;119(6):1420–1428. doi:10.1172/JCI39104.
 Plasticity of epithelial tissues
 EMT in embryonic development
 EMT in tumor dissemination
J Clin Invest. 2009;119(6):1438–1449. doi:10.1172/JCI38019.
 EMT
Thank you for attention
pvanhara@med.muni.cz
http://www.med.muni.cz/histology/education/
http://www.med.muni.cz/histology/petr-vanhara/