Epithelium & Glands PDF

Summary

This document provides an overview of epithelial tissues, covering their characteristics, classification, and functions. It also explores different types of epithelial cells and glands, their structures, and roles in the body. The notes include details regarding various aspects of epithelial tissue, including functions like absorption, secretion, and transport.

Full Transcript

 The human body is composed of only four basic types
of tissue:
Tissue Main Functions

Nervous Transmission of
nervous
impulses Nervous tissue

Epithelial Lining of surface
or body cavities,
glandular
secretion
Muscle Movement
Connective Support and
protection Tissues are groups of cells that have a
similar structure and act together to
perform a specific function
 Objectives
describe the characteristic describe the characteristic
features and functions of features and functions of
epithelial tissues glandular tissue

describe the classification of describe the classification
epithelial tissues of glandular tissue

describe the surface describe the mode of
modifications of epithelial secretion of glandular tissue
tissue
identify the different types
describe the junctional of epithelial & glandular
complexes of epithelial tissue tissues
 Epithelium
is present in two forms:

1
1. as sheets of continuous cells
(epithelia) that cover the body
on its external surface and line 2
the body on its internal surface

2. as glands, which originate from
invaginated epithelial cells

are derived from all three
embryonic germ layers
Detection of sensations
via taste buds, retina of Protection of underlying
the eye and specialized tissues of body from
hair cells in the ear abrasion and injury

Absorption of material from a
lumen (e.g., intestinal
tract or certain kidney
The principal tubules)
functions of
epithelial tissues
Transcellular transport of
molecules across epithelial
layers

Control of movement of Secretion of mucus,
materials between body hormones, enzymes,
compartments via selective and etc., from
permeability of intercellular various glands
junctions between epithelial
cells
 Characteristic Features of Epithelial Cells
The forms and dimensions of
epithelial cells range from high
columnar to cuboidal to low
squamous cells

The nuclear form often
corresponds roughly to the cell
shape eg;
cuboidal cells have spherical
nuclei
squamous cells have flattened
nuclei

The long axis of the nucleus is
always parallel to the main axis of
the cell
 Epithelia can be divided Types of Epithelia
into two main groups
according to their
structure and function:

1. covering (or lining)
epithelia
2. glandular epithelia
 Covering or Lining Epithelia
cover the external surface or line the surface layer
cavities of the body

are classified according to the number
of cell layers and the morphologic
features of the cells in surface layer

Simple epithelia contain only one layer
of cells

Stratified epithelia contain more than
one layer

Based on cell shape, simple epithelia
are classified as
1. squamous (thin cells)
2. cuboidal (cells roughly as thick as
they are wide)
3. columnar (cells taller than they are
wide)
 Simple squamous epithelium
cells of the single layer

flat and very thin

nucleus appear as a bulge

are typically specialized as lining of
vessels and cavities

regulate substances which can enter
underlying tissue from vessel or cavity

often exhibit transcytosis

Epithelium present in/as
1. renal loops of Henle
2. mesothelium lining a mesentery
3. endothelium lining the inner surface
of the cornea
Simple cuboidal epithelium
vary in their height

roughly as tall as they are wide

thickness is cause by
❑ cytoplasm rich in mitochondria
▪ providing energy for a high level
of active transport of substances
across the epithelium
renal collecting tubule
Epithelium present in/as
1. renal collecting tubule
2. pancreatic duct
3. mesothelium covering an ovary

mesothelium covering an ovary
 Simple columnar epithelium
cells are taller

are usually highly specialized for absorption,
with microvilli, and often have interspersed
secretory cells or ciliated cells

always have tight and adherent junctional
complexes
for rapid transfer of absorbed material to the
space between the cells

additional cytoplasm allows additional
mitochondria and other organelles needed
for absorption and processing renal collecting duct

Epithelium present in/as
1. renal collecting duct
2. oviduct lining, with both secretory and
ciliated cells
3. lining of the gall bladder
lining of the gall bladder
Stratified epithelia Transitional

are classified according
to the cell shape of the
superficial layer(s)

Squamous
Cuboidal
Columnar
Transitional
 Stratified squamous epithelia keratinized
have protective functions: protection
against easy invasion of underlying tissue
by microorganisms and protection against
water loss

In the skin, protection against water loss
and desiccation is particularly important
and the epithelium is keratinized

When skin differentiate they will be
filled with keratin and other substances
lose their nuclei and other organelles

The superficial flattened squamous cells lose their nuclei
form a layer which
prevents water loss
slough off and are replaced from below
Stratified squamous epithelia non keratinized
lining many internal surfaces
such as esophagus and
cornea

cells layers are retain their nuclei
nonkeratinized because the
differentiating cells
accumulate less keratin and
retain their nuclei

Provide protection against
microorganisms

Do not fill with keratin
because water loss is not an
issue
 Stratified cuboidal and stratified columnar epithelia
are rare

Stratified columnar
epithelium
can be found in the
conjunctiva lining the eyelids
is both protective and mucus
secreting organ or tissue

Stratified cuboidal
epithelium
is restricted to large
excretory ducts of sweat and
salivary glands
provides a stronger lining
than that of a simple
epithelium
ducts of sweat gland
Transitional epithelium or urothelium
lines only the urinary bladder,
ureter and upper part of the
urethra

is characterized by a
superficial layer of domelike
cells

also called umbrella cells

Essential in protection against
hypertonic and potentially
cytotoxic effects of urine

form of the surface cells
changes according to the
degree of distention of the
bladder wall
Pseudostratified Columnar Epithelium
It is so called because
1. all cells are attached to the
basal lamina

2. their nuclei lie at different
levels in the epithelium
give the false appearance
of cellular stratification

3. height of some cells does
not extend to the surface

epithelium is lining the
passages of the upper
respiratory tract
– heavily ciliated
Number of Cell Layers Cell Form Examples of Main Function
Distribution
Simple (one layer) Squamous Lining of vessels Facilitates the movement
(endothelium). Serous of the viscera
lining of cavities; (mesothelium), active
pericardium, pleura, transport by pinocytosis
peritoneum (mesothelium and
(mesothelium). endothelium), secretion of
biologically active
molecules (mesothelium).

Cuboidal Covering the ovary, Covering, secretion.
thyroid.

Columnar Lining of intestine, Protection, lubrication,
gallbladder. absorption, secretion.

Pseudostratified (layers Lining of trachea, bronchi, Protection, secretion; cilia-
of cells with nuclei at nasal cavity. mediated transport of
different levels; not all cells particles trapped in mucus
reach surface but all out of the air passages.
adhere to basal lamina)
Number of Cell Layers Cell Form Examples of Main Function
Distribution

Stratified (two or more Squamous keratinized Epidermis. Protection; prevents water
layers) (dry) loss.

Squamous nonkeratinized Mouth, esophagus, larynx, Protection, secretion;
(moist) vagina, anal canal. prevents water loss.

Cuboidal Sweat glands, developing Protection, secretion.
ovarian follicles.

Columnar Conjunctiva, male urethra Protection.
and ducts of some glands

Transitional Bladder, ureters, renal Protection, distensibility.
calyces.
Glandular Epithelia
 Glandular Epithelia
are formed by cells specialized to secrete

molecules to be secreted are generally stored
in the cells in small membrane-bound
vesicles called secretory granules

its cells may synthesize, store, and secrete
1. proteins (eg, in the pancreas)
2. lipids (eg, adrenal, sebaceous glands)
3. complexes of carbohydrates and proteins
(eg, salivary glands).

Mammary glands secrete all three
substances

The cells of some glands have low synthetic
activity (eg, sweat glands) and secrete
mostly water and electrolytes transferred
into the gland from the blood.
 Unicellular glands

Glandular Epithelia
Are classified according to
goblet cell
various criteria

Unicellular glands consist of
large isolated secretory cells
Multicellular glands
Multicellular glands have
clusters of cells

The classic unicellular gland
is the goblet cell in the lining
of the small intestine or
respiratory tract sebaceous gland
 Glands
are classified into two major
groups on the basis of the
method of distribution of their
secretory products:

Exocrine glands secrete their
products via ducts onto the
external or internal epithelial
surface from which they
originated.

Endocrine glands are ductless,
having lost their connections
to the originating epithelium,
Exocrine glands
and thus secrete their
products into the blood or
lymphatic vessels for
distribution Endocrine glands
 Exocrine Glands
have ducts that lead to an organ or
body surface

the duct runs through connecting
septa and branches repeatedly

Divided into

1. secretory portion, which contains
the cells specialized for secretion

2. ducts, which transport the
secretion out of the gland

This morphology allows the glands
to be classified according to the
scheme
 Exocrine Glands
Ducts can be

1. simple (unbranched)
2. compound (with two or more branches)

Secretory portions can be

1. tubular (either short or long and coiled)
2. acinar (round or globular)
Either type of secretory portion may be
branched

Compound glands can have tubular,
acinar or tubuloacinar secretory portions
 simple

compound
 Exocrine Glands
are classified functionally according to the way
the secretory products leave the cell

Merocrine secretion (eccrine)
– involves typical exocytosis of proteins or
glycoproteins.
– most common mode of secretion

Holocrine secretion
– Cell will be filled with secretory product
before the whole cell being disrupted and
shed
– seen in sebaceous glands of skin

Apocrine secretion
– an intermediate type
– secretory product is typically a large lipid
droplet and is discharged together with
some of the apical cytoplasm and
plasmalemma eg: mammary gland
Merocrine secretion Holocrine secretion Apocrine secretion
 Merocrine secretion

can be further categorized
as serous or mucous

– according to the nature
of the proteins or
glycoproteins secreted

– the resulting staining
properties of the
secretory cells
 Serous Cells
The acinar cells of the pancreas and
parotid salivary glands are examples
– secrete digestive enzymes
stain intensely

Each acinar cell is roughly pyramid-
shaped, with its apex at the lumen

Apical ends are eosinophilic due to
abundant immature and mature
secretory granules

basal ends contain large rounded
nuclei and an abundance of rough ER,
making the cells highly basophilic
basally filled apically with secretory granules
Acinar cells refers to any cluster of cells that
resembles a many-lobed “berry"
 Mucous Cells
Example is the goblet cells

Contains more flattened basal nuclei lumens

The apical region and most of cytoplasm
is filled with secretory granules
containing strongly hydrophilic lumens
glycoproteins known as mucin which has
important water-binding properties

The basal region contains the RER,
nucleus & well-developed Golgi
apparatus

The lumens are larger than serous acini
 Mixed Seromucous Gland
Mucous cells of large glands
are organized as secretory
tubules and in mixed
seromucous salivary glands

The submandibular salivary
glands have both mucous and
serous secretory units,
typically shaped as acini and
tubules

Clumps of serous cells at the
ends of some mucous tubules
appear as crescent-shaped
structures called serous
demilunes
 Holocrine Secretion
The sebaceous gland adjacent to hair follicles is
example

Entire cells fill with product and are released
during secretion

Undifferentiated cells deep and peripheral in the
gland fill with lipid-rich granules & metabolically
inactive

As they mature they move upward and toward
the gland's center
Since sebaceous glands has lack
myoepithelial cells; cell
When terminally differentiated, the cells
proliferation inside a dense,
separate and disintegrate to form the secretion inelastic connective tissue capsule
which serves to protect and lubricate adjacent continuously forces product into
skin and hair the duct
 Apocrine secretion
Mammary gland demonstrate
apocrine secretion

Characterized by the discharge
of secretory product with a
pinched off portion of the
apical cytoplasm (arrows)

The released portion of cell
contains lipid droplet(s)

Merocrine secretion also occurs
from the same and other cells
of the secretory units
 Exocrine glands
like sweat, lacrymal, salivary and
mammary glands contain stellate or
spindle-shaped myoepithelial cells
located between basal lamina and
the basal pole

Myoepithelial cells are connected
to each other and to the epithelial
cells by both gap junctions and
desmosome

These cells are specialized for
contraction, containing myosin and
large number of actin filaments

function is to contract around the
secretory or conducting portion of
the gland and help to propel
secretory products into the duct
Salivary gland: its organization, secretory units, and
system of ducts
 Endocrine Glands
produces hormones, which are
generally polypeptide or lipid-
derived factors that are released
into the interstitial fluid

Hormones diffuse into the blood
for circulation and bind specific
receptors on target cells elsewhere
in the body

The receptors may also be on cells
very close to the hormone-
secreting cells or on the secreting
cell itself
– the cellular signaling is termed
paracrine or autocrine
Polarity and Cell-Surface Specializations

Epithelial cell polarity and cell-surface
specializations are related to cellular
morphology and function
 Epithelial Cells Polarity
Epithelial cells generally show
polarity
1. basal pole
2. apical pole
3. lateral surfaces

The membranes on the lateral
surfaces often have numerous
infoldings to increase the area of
that surface, increasing its functional
capacity
Basal Surface Specializations
(Basal Pole)
 Hemidesmosomes
adhesive structures that
bind the cell to basal
lamina

the plaques contain
abundant integrins
– a transmembrane
proteins contain
receptors for the
extracellular
macromolecules laminin
and collagen type IV
 Lamina propria
Most epithelia rest on connective
tissue
is often called lamina propria
lining the cavity of internal organs
like digestive, respiratory and
urinary systems. Function is to
1. supports the epithelium
2. provides nutrition and binds it to
underlying structures

The area of contact is increased by
irregularities in its surface in the
form of small evaginations called
papillae (singular papilla)

Papillae occur most frequently in
epithelial tissues subject to friction,
such as covering of the skin or
tongue
 Basal Laminae & Basement Membranes
At basal surfaces, all epithelial An electron-lucent layers:
laminae lucida
cells attach to a sheet of
extracellular material known as dense layer or
basal lamina lamina densa

Basal lamina
Basal lamina
is often called a basement
membrane
is used to denote the lamina reticular lamina
densa and its adjacent layers structures seen with the *TEM
and structures seen with the
*TEM

Basement membrane
is used to denote the structures
seen with the light microscope
is formed by the combination of
a basal lamina & reticular
lamina
 Basal Laminae & Basement Membranes
Nutrients for epithelial cells diffuse
across the basal lamina through
basolateral surfaces of epithelial cell,
usually by an energy-dependent
process

Nerve fibers normally penetrate this
structure

Capillaries (being epithelial themselves)
never enter an epithelium across a basal
lamina

Blood vessels do not normally
penetrate an epithelium
basement membrane
Receptors for chemical messengers (eg,
hormones, neurotransmitters) that
influence the activity of epithelial cells
are localized in the basolateral *TEM ; transelectron microcope
membranes
 Basal Laminae & Basement
Membranes
Its macromolecular components form precise
three-dimensional arrays like
1. Laminin:
– are large glycoprotein
– they are held in place by transmembrane
integrins

2. Type IV collagen:
– contain three polypeptide chains
Entactin (nidogen)
Glycoprotein
Perlecan
Proteoglycan with heparan sulfate side
chains

– are glycosylated proteins that serve to link
the laminin and type IV collagen sheets
– are secreted at basal poles of epithelial cells
 Basal laminae are attached to
reticular fibers made of type III
collagen in underlying
connective tissues by anchoring
fibrils of type VII collagen.

These proteins are produced by
cells of connective tissue and
form the reticular lamina

Basal laminae also found in
other cell types
muscle cells, adipocytes and
Schwann cells
 Functions Of Basal Laminae
filtering functions contain the information
necessary for many cell-to-cell
are also able to influence cell polarity interactions, such as the
reinnervation of denervated
muscle cell
regulate cell proliferation and
differentiation by binding and
concentrating growth factors establishment of new
neuromuscular junctions in
muscle cell
influence cell metabolism and survival

organize the proteins in the adjacent
plasma membrane (affecting signal
transduction)

serve as pathways for cell migration
 Clinical Importance
Goodpasture's syndrome
– is an antiglomerular
basement antibody disease
– is a rare autoimmune disease
in which antibodies attack the
basement membrane in lungs
and kidneys, leading to
bleeding from the lungs and
kidney failure

The Goodpasture antigen
– is located on the alpha3 chain
of type IV collagen, a major
supporting component of the
basement membrane
Lateral Membrane Specializations
(Lateral surfaces)
 Intercellular Adhesion & Other Junctions
Several membrane-associated
structures contribute to
adhesion and communication
between cells

Present in most tissues but are
numerous and prominent in
epithelia

Epithelial cells are extremely
cohesive and strong

Intercellular adhesion is
especially marked in epithelial
tissues that are subjected to
traction and pressure (eg: skin)
 Intercellular Adhesion & Other Junctions
The lateral membranes of epithelial cells
exhibit several specialized intercellular
junctions

Various junctions serve to function as:
1. Tight junction/ occluding
junctions/zona occludens Seals to
prevent the flow of materials between
the cells

2. Adhesive or anchoring junctions
Sites of adhesion

3. Gap or communicating junctions
Channels for communication between
adjacent cells

In several epithelia such junctions are
present in a definite order from the
apical to the basal ends of the cells
 or zonulae occludens located
at the apical of the junctions

Zonula indicates that the
junctions form bands
completely encircling each
cell

Occludens refers to
membrane fusions that close
off the space between cells

membranes are tightly
apposed or fused is because
of direct interactions of
transmembrane protein
claudin
 The number of these sealing strands or
fusion sites is inversely correlated with
the leakiness of the epithelium

Its principal function is to form a seal
that
1. prevents the flow of materials between
epithelial cells (the paracellular
pathway) in either direction
2. prevent the integral membrane
proteins of the apical surface from
being transferred to the basolateral
surface and vice versa

This allows the two sides of the
epithelium to maintain different
receptors and function differently
 apical compartment

It also help to form two
functional compartments:

apical compartment that is
composed of an organ
cavity (such as the lumen of
a secretory unit or the gut)

basal compartment that
begins at the junctions and
encompasses the
underlying tissue basal compartment
2. Adherent Junction or Zonula
Adherens

provides for the firm adhesion of
one cell to its neighbors

Adhesion is mediated by
transmembrane glycoproteins of
each cell, the cadherins, which
lose their adhesive properties in
the absence of Ca2+

The numerous actin filaments
has a role in cytoplasmic
motility
2. Desmosome Or Macula Adherens

resembles a single "spot-weld" (L.
macula, spot)

is a disk-shaped structure

Between cell membranes at a
desmosome are larger members of
the cadherin family

Cable-like filaments of cytokeratin
are very strong and provide firm
adhesion

In nonepithelial cells, the
intermediate filaments attached to
desmosomes are composed of
other proteins, such as desmin or
vimentin
 can occur anywhere along
lateral membranes of epithelial
cells

are aggregated transmembrane
protein complexes that form
circular patches in the plasma
membrane

A protein known as connexins,
form hexameric complexes
called connexons that has a
central hydrophilic pore

Connexons permit rapid
exchange of molecules
between cells
 Some molecules mediating
signal transduction, such
as cyclic AMP, cyclic GMP,
and ions move readily
through gap junctions,
allowing cells in many
tissues to act in a
coordinated manner
rather than as
independent units

A good example is heart
muscle, where abundant
gap junctions are greatly
responsible for the heart's
coordinated beat
Apical Domain
 Specializations of the Apical cell Surface

The apical surface of epithelial cells
has specialized structures

1. Microvilli
2. Stereocillia
3. Cillia

to increase the cell surface area or
to move substances or particles
bound to the epithelium

many cells are seen to have
cytoplasmic projections that may be
short or long fingerlike extensions or
folds
 Microvilli
In absorptive cells, such as
the lining epithelium of
the small intestine, the
apical surface contains
hundreds of microvilli

The total surface area can
be increased as much as
20- or 30-fold

The complex of microvilli
and glycocalyx is called the
brush or striated border
 Stereocilia
are long apical processes of
cells in other absorptive
epithelia
✓ Eg: lining the epididymis,
ductus deferens

longer, less motile than
microvilli & branched

Increase cells' surface area,
facilitating the movement of
molecules into and out of the
cell
 Cilia
are elongated, highly motile
structures on epithelial cells
surface

longer and x2 wider than a Apical portions of cells lining the respiratory tract
typical microvillus

bounded by cell membrane
that contains axoneme with a
central pair of microtubules
surrounded by nine peripheral
microtubular pairs

inserted into basal bodies, at
the apical pole just below the Basal bodies have a structure similar to that of
cell membrane centrioles
 Cilia
It exhibit rapid back-and-forth
movements coordinated to
propel a current of fluid and
suspended matter in one
direction with adenosine
triphosphate (ATP) as the energy
source

A ciliated cell of the trachea
lining is estimated to have about
250 cilia

Flagella, present in the human
body only in spermatozoa are
similar in structure to cilia but are
much longer and are normally
limited to one flagellum per cell
https://youtube/xWpWn8W5nlA?t=19
 Transport Across Epithelia
all cells have the ability to actively transport
certain ions against a concentration and
electrical-potential gradient

Example is active extrusion of Na+ by means
of Mg2+-activated Na+/K+-ATPase (sodium
pump)
– The cells maintain the required low intracellular
sodium concentration (5-15 mmol/L vs. ~140
mmol/L in extracellular fluid)

Some epithelial cells actively transfer ions
and fluid across the epithelium, from its
apex to its base or vice-versa; this is known The apical surface of proximal
as transcellular transport
renal tubule cell is freely
permeable to Na+ in the lumen.
For transport in either direction, the tight
junctions play an important role in the
transport process, sealing the apical
portions of the epithelium and preventing
back-diffusion of materials
 Transport Across Epithelia
To maintain electrical and osmotic
balance, equimolar amounts of
chloride and water follow the Na+
ion into the cell

Interdigitation of membrane folds
between adjacent cells, all of which
increase the surface area for
transport

Sodium pumps are localized in
basal and lateral plasma
membranes

Between the folds are vertically
oriented mitochondria that supply
the ATP for active extrusion of Na+
from the cell basally
 Both benign and malignant tumors can
arise from most types of epithelial cells

A carcinoma is a malignant tumor of
epithelial cell origin

Malignant tumors derived from glandular
epithelial tissue are usually called
adenocarcinomas these are the most
common tumors in adults

In children up to age 10 years, most tumors
develop (in decreasing order) from
hematopoietic organs, nerve tissues,
connective tissues and epithelial tissues.

This proportion gradually changes, and
after age 45 years, more than 90% of all
tumors are of epithelial origin
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