Epithelial Tissue Lecture 2025 PDF

Summary

These lecture notes provide an overview of epithelial tissue. Topics covered include cell structures, types of epithelial tissue, glands, and functions.

Full Transcript

Epithelium

Dr. Sally Selim
Dr. Nadia El- Akabawy
Characteristic features of epithelial tissue:
- Very cellular, little
intercellular space.

- Cells rest on BM.
- Numerous nerve
endings.
- No lymph vessels.
- Avascular.
- Cells show polarity. - Display surface modifications.
- Many functions;
Absorption; intestine

Protection; skin

Secretion; thyroid

Exchange; lung
Epithelia can be divided into 4 main groups:
Covering or
Lining Epithelia:

Secretory
Epithelia and
Glands:

Myo- Epithelia:
Neuro- Epithelia:
1- Covering or Lining Epithelia:
1.Simple squamous epithelium:
Cells have the appearance of thin scales.
Cell nuclei: flat
Site:
a-Endothelium lining of capillaries.
b-Lung alveoli: gases diffuse plus
segments of kidney tubules.
c-Mesothelium; the surface layer of the
serous membrane that lines body cavities
and internal organs.
Function: provide a smooth and
protective surface.
2.Simple cuboidal epithelium:
Cell nuclei: round and central.

Site:
a- Kidney tubules.
b- Ducts of the glands.
c- Thyroid follicles.

Function: active in the secretion
and absorptions of molecules.
3.Simple columnar epithelium:
= (Non- ciliated)
Cell nuclei: elongated and basal.

Site:
a- some sections of the digestive system.
[[[

b- some sections of the female
reproductive tract.

Function: active in the secretion and
absorptions of molecules.
4. Ciliated columnar epithelium :
Cell nuclei: elongated and basal.
Cells have cilia on their apical surfaces.
Site:
a- Fallopian tubes.
b- Some parts of the respiratory system.
Function: beating of the cilia helps to remove
particulate matter.
5.Pseudostratified columnar epithelium:
Appears to be stratified.
But instead, consists of a single layer of
irregularly shaped and differently sized
columnar cells.
The arrangement gives the appearance of
stratification.
But in fact, all the cells are in contact with the
basal lamina.

Site:
a- In the respiratory tract, where some of
these cells have cilia.
1. Stratified squamous epithelium:
The deeper layers are columnar.

In proceeding towards the surface, the
cells become increasingly flattened
(squamous).

This type may be keratinized or non-
keratinized.

Site:
a- Mammalian skin: keratinized.
b- Mouth cavity: non- keratinized.
2. Stratified cuboidal
epithelium:
Can be found in certain
glands and ducts.
Uncommon in the
human body.

3. Stratified columnar
epithelium:
The same as stratified
cuboidal epithelium.
4. Transitional epithelium:
So- called because of the gradual changes
in the shapes of the apical cells.

As the urinary bladder is empty, it appears
thicker and more multi-layered.

When the bladder fills up with urine and
more stretched out, the epithelium is less
stratified.

Site:
Only in the urinary system, specifically the
ureters and urinary bladder.
 These cells are called transitional as they undergo a change in
their shape and structure.

Facet cells or Umbrella cells: the cells of the superficial cell layer,
lines the lumen. This layer is fully differentiated, dome shaped with
many bi- nucleated cells.

The urothelium is the most impermeable membrane in the
mammalian body. It acts as an osmotic barrier against the contents
of the urinary tract, transitional epithelium is relatively
impermeable to water and salts.
2- Secretory Epithelia and Glands:
Secretory Epithelia and Glands:
-Some epithelial cells specialized to perform secretory function.

-Such cells, present singly or in groups, constitute glands.
# Based on number of secretory cells,
glands are classified as:
1. 1- Unicellular:
-Interspersed amongst other (non-secretory) epithelial
cells.
-Can be found in the epithelium lining the intestines
(Goblet cells).

1. 2- Multicellular:
-Most glands are multicellular.
-Glands develop as diverticula from epithelial surfaces.
-The ‘distal’ parts of the diverticula develop into
secretory elements, while the ‘proximal’ parts form
ducts through which secretions reach the epithelial
surface, e.g., lacrimal gland, parotid gland.
# Based on mode of secretion, glands are classified as:

1. 1- Endocrine glands: 1. 2- Exocrine glands:
Glands lose all contact with epithelial surface Glands pour their secretions on to an
from which they develop, and they pour their epithelial surface, directly or through
secretions into blood. “ Duct- less glands “.
ducts.
Exocrine glands can be further classified based on:
A- Branching of ducts: B- Shape of the secretory unit:
C- Nature of the secretions: D- Manner of secretions pouring out of the cells:
A- Branching of ducts:
Simple:
All the secretory cells of an exocrine gland
discharge into one duct, the gland is said to
be a simple gland, e.g., gastric glands,
sweat glands.
Compound:
Several groups of secretory cells, each
group discharging into its own duct. These
ducts unite to form larger ducts that drain
on to an epithelial surface. Such a gland is
said to be a compound gland, e.g., parotid
B. Shape of the secretory unit:

Tubular glands: :
Glands with secretory unit
tubular in shape. The tube may
be straight, coiled or branched,
e.g., gastric glands.

Alveolar glands: :
Glands with secretory unit flask
shaped.
C. Nature of the secretions:
Mucous glands:
- Tall cells with flat nuclei at their bases,
Large lumen.
- Secretion contain mucopolysaccharides.

- Secretion collects in the apical parts of
the cells >>> nuclei are pushed to the
base of the cell, and flattened.

- With H& E, secretion remains unstained
so that they have ‘empty’ look.
Serous glands:
- Cells are triangular with rounded,
central nucleus, lumen is small.

- Secretions are protein in nature.

- With H& E, cytoplasm stains
bluish.

Mixed glands:
- Glands contain both serous and
mucous elements.
D. Manner in which their secretions pouring out of the cells:
Merocrine:
Secretions are thrown out of the cells by exocytosis, the cell remains intact, e.g., goblet cell.

Apocrine:
Apical parts of the cells are shed off to discharge the secretion. e.g., mammary glands.

Holocrine:
Entire cell disintegrates while discharging its secretion, and is seen typically in sebaceous glands.
3- Myo- Epithelia:
III- Myo- Epithelia:
- Epithelia of many exocrine
glands contain contractile cells at
the basal ends of the secretory
cells.
- Long processes of myoepithelial
cells are rich in actin filaments
and myosin.
- Strong contractions in these cells Myoepithelial cells wrapped
serve to help propel secretory around milk-producing alveoli in
products from acini into ducts. a lactating mammary glands.
4- Neuro- Epithelia:
IV- Neuro- Epithelia:
- Specialized sensory cells, such as those in ear, nose, and tongue.
- Neuroepithelial cells found in the nose are part of the olfactory
epithelium that is specialized to perform a receptor function and
transmit impulses through the olfactory nerve.
Epithelial Cell
Polarity
&
Membrane
Specialization:
 Epithelial Cell Polarity& Membrane Specialization:
1- Basement membrane (Basal Specialization):
- Epithelial cells rest on a thin basement membrane. In multi- layered epithelia, the deepest
cells lie on this membrane.

- LM: A distinct basement membrane cannot be seen in H&E, but can be well demonstrated
using the periodic acid Schiff (PAS). This stains the glycoproteins present in the membrane.
[

- EM: A basement membrane has a basal lamina (near to the epithelial cells) and a reticular
lamina (near to the underlying connective tissue); formed of type I and III collagen fibers.
- The basal lamina is divisible into the:
1- lamina densa: Formed of type IV collagen fibers.
2- lamina lucida: Formed of glycoproteins.
Functions of Basement membrane:
1- Good adhesion; on one side to epithelial cells and other to C.T.
2- Barrier to diffusion of molecules.
3- Membranes influence the regeneration of peripheral nerves after injury
and re-establishment of neuromuscular junctions.
4- Scaffold that allows rapid epithelial repair and regeneration.
 N.B. Deep infoldings of the
basal and lateral cell membranes:
- Only seen with electron microscopy.
- Found in certain cells, whose function is
to transport ions across cell membrane.

- E.g. Kidney tubules cells >>
selectively absorb useful or nutritious
components from the glomerular filtrate
and retain them in the body.
- Also, eliminate toxic or non-useful
metabolic waste products such as urea
and drug metabolites.
 Lateral surfaces specializations
Cell Junctions

Cell membrane specializations found on the lateral
surfaces of epithelial cells (between adjacent epithelial
cells).
Function:
1- Provide strong attachment to the adjacent cells.
2- Prevent passages of materials through the intercellular
space.
 Classification:

According to the distance between the cell membranes:
a) Tight junction (occluding junction) ( zero)
b) Adhering junction (anchoring junction) (20nm)
c) Gap junction (communicating junction) (2nm)

2- According to the Shape of the Junction:
a) Zonula junction (girdle or ring junction)
b) Fascia junction (band junction)
c) Macula junction (spot junction)
- lateral surfaces of epithelial cells
have complexes of several
specialized intercellular junctions
with different functions:
A- Tight or occluding junctions form a seal
between adjacent cells.

B- Adherent or anchoring junctions are sites of
strong cell adhesion.

C- Desmosomes.

D- Gap junctions; channels for communication
between adjacent cells.
A. Tight junctions; Zonulae Occludens:

Present in a definite order at the most
apical end of the cells.
“Zonula” indicates that the junction
forms a band completely encircling
each cell.
Function: Continuous junctions within cell
membranes prevent movement of molecules
at the apical surface into the lateral and
basal surfaces, and vice versa.
B. Adherens junction (Zonula
Adherens):
Encircles the epithelial cell, usually
immediately below the tight junction.

Function: Firmly anchoring a cell to
its neighbors.
C. Desmosome:
Resembles a single spot and does not form a
belt around the cell.
At the site of a desmosome, the plasma
membrane of each cell is thickened (plaque).
The thickened areas of the two sides are
separated by a gap of 25 nm. The region of the
gap is rich in glycoproteins.

Intermediate filaments are inserted into these
plaques and loop back towards the cytoplasm.
Function: Firm cellular
adhesion and strength
throughout the epithelium.
D. Gap junctions:
Mediate intercellular
communication rather than
adhesion or occlusion
between cells.

Abundant in many
epithelia.

Gap junctions consist of
aggregated transmembrane
protein complexes that form
circular patches in the
plasma membrane.
Communicating Junctions
 Transmembrane gap
junction proteins,
connexins, form
hexameric complexes
called connexons.
Function: Permit
intercellular exchange of
molecules with small
diameters such as ions,
move rapidly through gaps.
Allowing cells to act in a
coordinated manner rather
than as independent units.
E:Hemidesmosomes Structure: half
(½) of desmosomes.
Site: between bases of epithelial
cells and basal lamina.
Function: help to attach bases of
epithelial cells to basal lamina.
 3- The Apical Cell Surface
(Apical Specialization):
- Apical ends of many columnar
and cuboidal epithelial cells
have specialized structures
projecting from the cells.

- Function: either to increase
surface area for absorption or
to move substances along
epithelial surface.
A. Microvilli:
Usually of uniform length.

Found in cells such as those
lining the small intestine.

LM: densely packed
microvilli visible as brush
or striated border
projecting into the lumen.
With hundreds or thousands
present on the end of each
absorptive cell.
 EM: Microvillus contains bundled actin
filaments bound to surrounding plasma
membrane by actin binding proteins.
Actin filaments insert into the terminal
web at the base of the microvilli.

Function:
1- Increase the surface area by 20: 30-fold.
2-The thick glycocalyx covering microvilli
of the intestinal brush border includes
membrane- bound proteins and enzymes
for digestion of certain macromolecules.
B. Stereocilia:
Much less common type of
apical process, best seen on the
epithelial cells lining the male
reproductive system.
Resemble microvilli in containing
microfilaments and actin-binding
proteins, with similar diameters,
and with similar connections to
the cell’s terminal web. Function: Like microvilli,
Stereocilia are much longer and stereocilia increase the cells surface
less motile than microvilli. area, facilitating absorption.
C. Cilia:
Long, highly motile apical
structures, larger than microvilli,
containing internal arrays of
microtubules not microfilaments.

LM: hair-like projections from
the free surfaces of some
epithelial cells.

EM: Cilia are made up of
microtubules coated by the
plasma membrane.
 Each cilium: 9 pairs of
microtubules that form the
outside ring and two central
microtubules. This structure is
called an axoneme.
The 9 outer pairs are made up of
motor proteins called dynein.
These are large and flexible that
allows the cilia to move.
Cilia are attached to cell at basal
body that is made up of
microtubules arranged in 9
triplets.
 Basal bodies have a
structure similar to
that of centrioles,
with nine triplets of
microtubules.

Cilia have dynamic
tubulin protofilaments
forming rootlets
anchoring the entire
structure to the
cytoskeleton.
Function:
1-Cilia move in coordination with one
another like a wave. As a result, fluid,
mucous, or small solids lying on
epithelium can be moved in a specific
direction.
4-In some situations, cilia-like
2-Movements of cilia lining the respiratory
structures perform a sensory function.
epithelium move secretions in the trachea
They may be non-motile.
and bronchi towards the pharynx.
Such ‘cilia’ present on the cells in the
3-Ciliary action helps in the movement of olfactory mucosa of the nose are
ova through the uterine tube, and of called olfactory cilia, they are
spermatozoa through the male genital tract. receptors for smell.
D. Flagella:
Larger processes having the same basic structure as cilia.
In the human body the best example of a flagellum is the tail of
the spermatozoon.
 " Immotile Cilia Syndrome" (Kartagener syndrome):
Several mutations in the proteins of the cilia and flagella.
Responsible for certain symptoms; chronic respiratory infections, male infertility
and female infertility.
 RENEWAL OF
EPITHELIAL CELLS:
✓ Epithelial tissues are
renewed continuously by
mitotic activity and stem cell
populations.
✓ The rate of renewal varies
widely; it can be fast in
tissues such as the intestinal
epithelium, which is replaced Intestinal stem cells reside at the
every week, or slow, as in the bottom and replicate daily, generating
large glands. new cells to maintain the tissue.