W8 Introduction to Epithelium (Mhawi).pdf

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Introduction to Epithelium
(Epithelium 1)
Amir Mhawi, DVM, PhD
Ross University School of Medicine
[email protected]

Introduction
This lecture describes the various general and specific
characteristic features of the various epithelia of the body. The
students will appreciate the structures and functions of the various
modifications of the apical, basal and lateral surfaces of the
epithelial cells. These modifications contribute significantly to the
health and well-being of the individual. The lecture briefly
highlights how the epithelial cells attach to and communicate with
each other via the different types of cell-to-cell junctions or cell-tomatrix junctions.

Learning Objectives
n
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n
n

n

Describe the various general and specific characteristic features of
the various epithelia of the body.
Identify and compare the functions of 8 or more morphologically
different types of epithelium and where they are located in the body.
Describe the structures and functions of the various modifications
of the apical, basal and lateral surfaces of the epithelial cells.
Identify the different types of cell-to-cell and cell-to-matrix junctions
Explain how the many functions of epithelia, including protective,
secretory, excretory, lubrication, absorptive and reproductive,
contribute to the health and well-being of the individual.
Describe the structure and function of the basal lamina.

Epithelial Tissue (Epithelium)
n

One of four basic tissues
– The other three basic tissues are: Connective, Nervous, muscular)

n

Epithelium is avascular tissue
– Depends on diffusion of nutrients from blood vessels in the underlying tissue

n

Comprised mainly of packed cells whose shape and
arrangement correlate with their function

epithelium lining intestine

epithelium covering finger tips

Epithelium
n

Cell characteristics:
– Arranged as sheets
§ Covers external surfaces (e.g., skin)
§ Lines internal surfaces (e.g., intestine and kidney
tubules)

– Or as masses (in glands)
– Placed very close to each other (very limited
intercellular space)
– Possess intercellular junctions
– Cells are polarized
§ Display distinct surface domains
§ Apical (free), lateral, and basal domains
§ Properties of each domain are determined by presence
of specific membrane proteins

– Rest on an underlying basal lamina
§ Non-cellular structure
§ Protein-polysaccharide-rich layer

Epithelium-Classification

n Classified

by:

– Cell arrangement (simple or stratified)
– And cell shape (squamous, cuboidal, or columnar)
– Usually by a combination of both arrangement and shape
§ NOT BY FUNCTION

Epithelium-Classification cont.
n

SQUAMOUS
– width of cell is greater than
height

n

SIMPLE SQUAMOUS
– One cell layer
– Location:
§ Lines blood and lymphatic
vessels
§ Wall of Bowman’s capsule in
kidney
§ Covers mesentery
§ Lines respiratory spaces
(alveoli) in lung

Simple squamous
Epithelium lining vein
(arrowheads). Arrows
point to smooth muscle
cells in the wall of the vein

Simple squamous epithelium
(arrows) in the wall of the
Bowman’s capsule of the
kidney.

Epithelium-Classification cont.
Special Terminologies for the
Simple Squamous:
n ENDOTHELIUM (upper
image)
n

Endothelial cells

– Name given to simple squamous
epithelia lining blood and lymph
vessels and the ventricles and
atria of the heart
n

MESOTHELIUM (lower image)
– Name for simple squamous
epithelia that line walls and
cover contents of closed cavities
of body:
§ Abdominal cavity
§ Thoracic cavity

Simple squamous
epithelium covering
the peritoneum
(mesothelium;
arrows). Some
blood capillaries
are indicated by
arrowhead. PT
(pararosanalinetoluidine) stain

Epithelium-Classification cont.
n

CUBOIDAL
– Width, depth and
height approximately
the same

n

SIMPLE CUBOIDAL:
– One cell layer
– Found in:
§ Wall of thyroid
follicles
§ Walls of kidney
tubules
§ Surface of ovary

(germinal epithelium)

Walls of thyroid gland is made of simple
cuboidal epithelium. Arrows point to
capillaries

Simple cuboidal epithelium from kidney
collecting ducts (upper part of the ducts).

ovary

Epithelium-Classification cont.
n

COLUMNAR

n

Height of cell greatly
exceeds width

n

SIMPLE COLUMNAR

n

One cell layer
Lines:

n

• Intestinal tract from
stomach to rectum
• Uterus and cervix
• Kidney collecting
ducts (lower part)

Small intestine lumen is lined by
simple columnar epithelium

Simple columnar epithelium covers the
inner cavity of the uterus

Simple columnar epithelium from the kidney collecting
ducts (lower parts of the ducts).

Epithelium-Classification cont.
n Stratified

epithelium

– Two or more cells thick
n Types

– Stratified squamous
§ Keratinized and non-keratinized

– Stratified cuboidal
– Stratified columnar
– Transitional

n

STRATIFIED
SQUAMOUS
– Multiple layered
– Superficial layer is
squamous
– Functions as barrier
– Protection of body
– Can be keratinized
(skin)

n

Skin. Stratified squamous epithelium keratinized

Esophagus. Stratified squamous epithelium nonkeratinized
At puberty, the rising levels of
estrogen promote the maturation,
proliferation and accumulation of
glycogen in the vaginal epithelial
cells.
Glycogen is catabolized to lactic acid
which along with components of the
epithelial mucosal barrier provide an
effective first line defense against
invading pathogens.

Location:
–
–
–
–
–

Epidermis
Lining of oral cavity
Lips
Lining of esophagus
Lining of vagina

Vagina. Stratified squamous non-keratinized

Note that the cytoplasm of most of the
epithelial cells of the vagina looks
empty due to the washing out of the
glycogen during the preparation of
the tissue for examination.

Epithelium-Classification cont.
n STRATIFIED

CUBOIDAL

– More than one layer of
cuboidal cells
n Located

in:

– Ducts of sweat gland
– Larger ducts of exocrine
glands (mammary gland, as
an example)
– Anal canal (most distal
portion of the GIT)
n Function

– Barrier
– Conduit

as:
Duct (solid arrows) of sweat gland lined by stratified cuboidal epithelium.
The stratification (represented by two rows of nuclei) is visible in the
oblique section of the duct (red star)

Epithelium-Classification cont.
n STRATIFIED

COLUMNAR

– More than one layer
of columnar cells
n Located

in:

– Largest ducts of
exocrine glands
– Anal canal
n Functions

– Barrier
– Conduit

duct lumen

as:
Wall of the excretory duct of the salivary gland is
comprised of stratified columnar epithelium.

Epithelium-Classification cont.
n

TRANSITIONAL (AKA urothelium)
– Stratified
– Upper most cells are dome-shaped
(arrows in the lower images)
– Functionally accommodates
distension
– Serves as barrier
– Located in:
§ Ureters
§ Urinary bladder
§ Renal calyces
§ Urethra

Cross section of the ureter which lined
by the transitional epithelium.

Higher magnification of the transitional epithelium lining the urinary bladder. Iron-hematoxylin
(left) and H&E (right). Note the dome-shaped surface cell (arrows)

Epithelium-Classification cont.
n

Special Classifications:

n

PSEUDOSTRATIFIED
– Has appearance of being stratified
– Some cells do not reach the free
surface
– ALL cells rest on the basal lamina
– It is actually a simple epithelium
– Limited distribution in body:
§ Upper respiratory tract (trachea,
bronchi)
§ Epididymis (male reproductive
system)
§ Ductus deferens (male
reproductive system)

BM, basal lamina; LCT, loose connective tissue

Pseudostratified columnar ciliated epithelium. Green arrows point to mucus-secreting (goblet) cells. Black arrows indicate the cilia.

Pseudostratified columnar epithelium lining the duct of the epididymis of the male reproductive system. The
lumen of the epididymis contains sperms. The appendages projecting from the free cell surface into the
lumen are not to be confused with cilia. They are stereocilia (extra long microvilli).

Basal Lamina
n AKA

Basement Membrane

– Acellular structure
– Structural attachment site
§ Attaches the overlying epithelial cells to
the underlying connective tissue

– Its components are
synthesized and secreted by
epithelial cells

§ Components assembled extracellularly
at the base of the epithelial cell

– basal lamina can be
demonstrated with:
§ Periodic Acid-Schiff stain (PAS)
§ Silver salts

Basal Lamina cont.
n

After conventional TEM observation
basal lamina reveals two layers:
- LAMINA DENSA
- Contains network fine filaments

- LAMINA LUCIDA (lamina rara)
- Clear space between base of cell and lamina
densa
- Believed to be an artifact caused by the
shrinkage of the epithelial cells

Lamina densa

Lamina lucida

Basal Lamina-Function
n

Structural attachment
– epithelial cells to connective tissue

n

Compartmentalization
– Separates connective tissue from epithelia, nerve, muscle tissue
– Connective tissue & its specializations are all within a continuous
single compartment
– Molecules require to move from one tissue to another (from one
compartment to another) MUST CROSS A BASAL LAMINA

Basal Lamina-Function cont.
n

Filtration
– Movement of blood filtrate in the kidney
§ Is regulated by basal lamina

– Through negatively charged
molecules in lamina rara and
network of collagen fibrils in
lamina densa
– i.e. filtration is regulated by ION
EXCHANGE and MOLECULAR SIEVE

- - - - - - - - - - -

- - -

- - -

Basal Lamina-Composition
• Basal lamina composed of different molecules
• Molecules are synthesized by the epithelial cell
• And self-assemble into basal lamia sheet
extracellularly

Basal Lamina-Composition cont.
n LAMININS

– Glycoprotein molecules
– Polymerize at the basal cell
surface
– Possess binding sites for integrins
– Therefore, link basal lamina to
basal plasma membrane

laminins

Basal Lamina-Composition cont.
n COLLAGENS:
– Mainly type IV collagen
– Consists of short filaments
– Provides structural integrity to basal
lamina
– Serve as molecular sieve

collagen

Basal Lamina-Composition cont.
n ENTACTIN/NIDOGEN

– Glycoprotein
– Serves as a link between laminins
and type IV collagen network
– Support cell adhesion

Basal Lamina-Composition cont.
n

PROTEOGLYCANS:
– Makeup bulk volume of basal
lamia
– Consist of protein core to which
negatively charged
glycosaminoglycans (GAGs) are
attached
– Extensively hydrated
– Play a role in regulation of ions
passage across the basal lamina
Chondroitin sulfate
(GAG)
keratan sulfate
(GAG)

External Lamina
n

Peripheral extracellular
electron-dense material
– Visible in TEM
– Appears the same as basal
lamina
– Positive staining with PAS
and sliver
– Found on external surface of
non-epithelial cells:
§ Muscle cells
§ Nerve-supporting cells
(Schwann cells)
§ Adipocytes (fat-storing cells)

Sch

Sch

A

TEM of myelinated axon (A) in cross section. Schwann cell(Sch), responsible for the
myelination of the axon, is surrounded by external lamina which appears as a moderately
dense ribbon at the periphery of the cell (red arrows). Myelin sheath is visible as many
concentric layers of electron dense material (stars).

Cell Surface Modifications
n
n

Surface specializations relate to special functions:
MICROVILLI
– Cytoplasmic processes extending from cell surface

n

STEREOCILIA
– Microvilli of unusual length

n

CILIA
– Motile and non-motile cytoplasmic processes

n

LATERAL and BASAL CELL SURFACE FOLDS and PROCESSES
– Invaginations and evaginations of cell surface
– Create interdigitating and interleaving tongue and groove margins
§ For apposed cells

Cell Surface Modifications cont.
MICROVILLI
– Distinctive cytoplasmic
extensions at apical surface
seen with LM in fluid
transporting cells of gut and
kidney
– Provide enormous increase in
free surface area
– Number and shape of microvilli
§ Correlate with absorptive
capacity
In the small intestine called:

striated border

In the kidney tubules called: brush

border

Microvilli cont.
n

Contain conspicuous core of ACTIN
microfilaments
- Actin microfilaments are anchored to
plasma membrane at tip and sides
- Extend down where they interact
with horizontal network of actin
filaments, the TERMINAL WEB
- Filaments of terminal web are
contractile
- This could result in decreasing
diameter of apex of intestinal
absorptive cell
- Thereby the microvilli spread apart
and the intermicrovillus space
increases
- Leads to an increment in the effective
absorptive surface between microvilli

Longitudinal section

Cross section

Cell Surface Modifications cont.
STEREOCILIA (stereovilli)
•

Extremely long immotile processes
extending from apical cell surface

•

Like microvilli, they are supported
by actin filaments

•

Found in:
• Epididymis
• Facilitate absorption of fluid
• Aggregate into pointed bundles
• (like wet paintbrush)

Cell Surface modifications cont.
Basolateral folds
n

Basolateral surfaces show tortuous
boundary

Lateral folds

– Due to infoldings of cells with
neighbors
§ Increase surfaces
n

Prominent in cells that transport
fluid rapidly
– e.g. intestinal epithelium
§ Water in intestine enters cells apically
§ Then leaves cells at lateral surface

n

Water osmotically follows sodium
ions that are actively transported
across the lateral plasma membrane
(see next slide)

Basal folds of the basal plasma
membrane. Note the presence of the
mitochondria (asterisks) within the
folds.

Note the
mitochondria
between the
lateral folds
Mitochondria
provide energy
to Na/k pump
basement membrane
basement membrane

Cell-to-Cell Adhesion/Junction
cont.

n

Junctional Complex
consists of
– ZONULA OCCLUDENS
(AKA tight junction)
– ZONULA ADHERENS
– MACULA ADHERENS
(AKA DESMOSOME)
– GAP JUNCTIONS

Cell-to-Cell Adhesion/Junction cont.
n

ZONULA OCCLUDENS (AKA Tight Junction)
– Outer leaflets of adjoined plasma membranes are
fused
– Occurs in band or belt-like configuration around cell
– Seal created by transmembrane proteins (occludins
and claudins)

§

That traverse the outer leaflets of the cells
§ And join occludins (or claudins) of the neighboring cell
in the intercellular space
§ Cytoplasmic domain of occludins/claudins attach to
actin filaments
•

Functions:
• Controls the free molecular movement between the
cells
• Prevents diffusion of membrane proteins between
the apical and lateral membrane domains

Actin filament

blood capillary lumen

endothelial cell
endothelial cell
membrane fusion
membrane fusion

connective tissue

Tight junction between endothelial cells

Cell-to-Cell Adhesion/Junction cont.
n

ZONULA ADHERENS (AKA Adhering
Junction)

– Provides lateral adhesion between
epithelial cells
– Adherens occurs in band or belt-like
configuration around cell
– Formed by the binding of transmembrane
proteins cadherin of neighboring cells
§ Cytoplasmic domain of cadherin is linked to the
actin filaments of the cytoskeleton

– Morphology and integrity of adherens are
calcium dependent
§ Removal of Ca++ disrupts this junction

– Characterized by uniform 15-20 nm space
between apposed membranes

Occludin transmembrane protein
Claudin transmembrane protein
Cadherin transmembrane protein
Actin filament

n

FASCIA ADHERENS
– Sheet-like junction
– Called fascia because it has a broad
face
– Found in intercalated disc of cardiac
muscle

Cell-to-Cell Adhesion/Junction
cont.

n MACULA

ADHERENS (DESMOSOMES)

– Small localized on the lateral domain of the cell
– Strong attachment structure
– Transmembrane proteins from neighboring cells
interdigitate with each other
– In simple cuboidal or simple columnar epithelium found in
conjunction with occluding and adhering junctions (slides
36 and 39)

n

n
n
n

n

TEM shows a very dense material on
cytoplasmic sides of the membranes
of adjoining cells
Called ATTACHMENT PLAQUE
Attaches to intermediate filaments
Intermediate filaments appear to loop
through attachment plaques
§ And extend back out into
cytoplasm
Role in dissipating physical forces
through out the cell from attachment
site

Cell-to-Cell Adhesion/Junction
cont.

n

GAP JUNCTIONS, or NEXUSES
– found in:
§ epithelia
§ smooth muscle
§ cardiac muscle
§ nerves

n

needed where activity of adjacent cells must be
coordinated:
– heart muscle

Consist of accumulation of
TRANSMEMBRANE CHANNELS
(connexons)
– Each connexon comprised of six
connexin proteins
– Connexons in one cell membrane
precisely aligned with
corresponding connexons on
membrane of adjacent cell
– Tightly packed connexons create
gap junctional plaque (upper right
image)
– Allow:
§ Communication
§ Exchange of:
- Ions
- Regulatory molecules
- Small metabolites

n

Gap junction plaque as it appears in TEM freezefracture technique. Each little dote within the plaque
is a connoxon

Gap junction plaque (between the arrows) as it
appears in TEM thin plastic section

Cell-to-Matrix Adhesion
n HEMIDESMOSOMES
– Half-desmosome located on basal
plasma membrane of the cell
– In stratified squamous epithelium
connect the basal plasma membrane
of the cells to basal lamina
(illustration)
– Found in epithelia subject to abrasion
and mechanical shearing
§ Skin
§ Cornea
§ Mucosae of:
– Oral cavity
– Esophagus
– Vagina

Illustration of the keratinized stratified squamous
epithelium of the skin
= Hemidesmosome
= Desmosome
= Basal lamina

Hemidesmosomes cont.
n

TEM exhibits intracellular
attachment plaque
– On the cytoplasmic side of the
basal plasma membrane
– Composed of plectin and BP 230
proteins

n

n

Intermediate filaments of the
cytoskeleton bind to the
proteins of the attachment
plaque
Transmembrane proteins
integrins bind the attachment
plaque to the extracellular
matrix

Cell-to-Matrix Adhesion cont.
n FOCAL

ADHESIONS

– Dynamic attachments
– Linking actin filaments to extracellular
matrix proteins
– Role in attachment and migration of
cells
– Focal adhesion consists of:
§ Cytoplasmic part
– Actin filaments
§ Transmembrane region
– Integrins
§ Extracellular part
– Laminin and fibronectin

THE END OF THE LECTURE!

Extra reading if desired:
Junquiera’s Basic Histology
Relevant portions of Chapter 4,
“Epithelial Tissue”
Digital Histology

https://digitalhistology.org/