Histology of Epithelia and Glands PDF

Summary

This document presents an overview of the histology of epithelia and glands. The document provides learning objectives, an explanation of tissue, types of tissues from different germ layers, and an introduction to cell junctions.

Full Transcript

Histology of
Epithelia and Glands

Nikolai P Pace
Learning Objectives
◼ Explain the ways in which epithelia are classified
◼ Distinguish between, simple, stratified, and
pseudostratified epithelia
◼ List characteristics of squamous, cuboidal, columnar,
and transitional epithelia
◼ Identify some common surface specializations of
epithelia
◼ Discuss how the organization, thickness, surface
specializations, and turnover of an epithelial layer might
reflect its function
What is a Tissue?

◼ A tissue is a group of cells
❑ Common embryonic origin
❑ Function together to carry out specialized
activities
◼ Hard (bone), semisolid (fat), or liquid (blood)
◼ Histology is the science that deals with the
study of tissues.
◼ Pathologist specialized in laboratory studies
of cells and tissue for diagnoses
4 Types of Tissues
❑ Epithelial
◼ Covers body surfaces and lines hollow organs,
body cavities, duct, and forms glands
❑ Connective tissues
◼ Protects, supports, and binds organs.

◼ Stores energy as fat, provides immunity, etc….

❑ Muscular
◼ Generates the physical force needed to make body
structures move and generate body heat
❑ Nervous
◼ Detect changes in body and responds by
generating nerve impulses
Development of Tissues

◼ Tissues of the body develop from three primary
germ layers:
◼ Ectoderm, Endoderm, and Mesoderm

❑ Epithelial tissues develop from all three germ

layers
❑ All connective tissue and most muscle tissues

drive from mesoderm
❑ Nervous tissue develops from ectoderm
Development of Tissues

◼ In all vertebrates, the tissues of the body develop from
three primary germ layers.

◼ These are called the
◼ Ectoderm
◼ Mesoderm
◼ Endoderm

◼ Following fertilization and the formation of a zygote,
repeated mitotic cell divisions convert the zygote into a
tiny ball of cells, called a blastula.
Germ Layers

◼ During the process of gastrulation, the morphology of
animal embryos is reorganized to form the three germ
layers

◼ These 3 germ layers are the forerunners of all adult
tissues.
Germ Layers
Body tissues

◼ 4 Types of body tissues arise from the 3 germ layers

1. Epithelia - arise from all 3 germ layers

2. Connective Tissue – mesodermal origin

3. Muscle Tissue – mesodermal origin

4. Nervous tissue – ectodermal origin
Cell Junctions

◼ Contact points between the
plasma membranes of
tissue cells
❑ 5 common types:

◼ Tight junctions
◼ Adherens junctions
◼ Desmosomes
◼ Hemidesmosomes
◼ Gap junctions
Tight Junctions

◼ Web-like strands of
transmembrane proteins
❑ Fuse cells together
❑ Seal off passageways
between adjacent cells
◼ Common in epithelial
tissues of the stomach,
intestines, and urinary
bladder
◼ Impair the passage of
substances between cells
and leaking into the blood
or surrounding tissues
Copyright 2009, John Wiley & Sons, Inc.
Copyright 2009, John Wiley & Sons, Inc.
Adherens Junctions
◼ Dense layer of proteins called
plaque
❑ Resist separation of cells
during contractile activities
❑ Located inside of the plasma
membrane attached to both
membrane proteins and
microfilaments of the
cytoskeleton
❑ Transmembrane glycoproteins
called cadherins insert into the
plaque and join cells
❑ In epithelial cells, adhesion
belts encircle the cell
Desmosomes

◼ Contain plaque and
cadherins that extends into
the intercellular space to
attach adjacent cells
together
❑ Desmosome plaque
attaches to intermediate
filaments that contain
protein keratin
❑ Prevent epidermal cells
from separating under
tension and cardiac
muscles cells from pulling
apart during contraction
Hemidesmosomes

◼ Resemble half of a
desmosome
❑ Do not link adjacent cells
but anchor cells to the
basement membrane
❑ Contains transmembrane
glycoprotein integrin
❑ Integrins attach to
intermediate filaments
and the protein laminin
present in the basement
membrane
Gap Junctions
◼ Connect neighboring cells
via tiny fluid-filled tunnels
called connexons
❑ Contain membrane proteins
called connexins
❑ Plasma membranes of gap
junctions are separated by
a very narrow intercellular
gap (space)
◼ Communication of cells
within a tissue
◼ Ions, nutrients, waste,
chemical and electrical
signals travel through the
connexons from one cell to
another
Copyright 2009, John Wiley & Sons, Inc.
Epithelial Tissues

◼ Epithelial tissue consists of cells arranged in
continuous sheets, in either single or multiple layers
❑ Closely packed and held tightly together
❑ Covering and lining of the body
❑ Free surface
◼ 3 major functions:
❑ Selective barrier that regulates the movement of materials
in and out of the body
❑ Secretory surfaces that release products onto the free
surface
❑ Protective surfaces against the environment
General Features of Epithelial Cells

◼ Surfaces of epithelial cells differ in structure and
have specialized functions
❑ Apical (free) surface
◼ Faces the body surface, body cavity, lumen, or duct
❑ Lateral surfaces
◼ Faces adjacent cells
❑ Basal surface
◼ Opposite of apical layer and adhere to extracellular
materials
General Features of Epithelial Cells

◼ Basement membrane
❑ Thin double extracellular layer that serves as the point of
attachment and support for overlying epithelial tissue
❑ Basal lamina
◼ Closer to and secreted by the epithelial cells
◼ Contains laminin, collagen, glycoproteins, and proteoglycans
❑ Reticular lamina
◼ Closer to the underlying connective tissue
◼ Contains collagen secreted by the connective tissue cells
Epithelial Cells
Epithelial Tissues
❑ Own nerve supply
❑ Avascular or lacks its own blood supply
❑ Blood vessels in the connective tissue bring in
nutrients and eliminate waste
❑ High rate of cell division for renew and repair
❑ Numerous roles in the body (i.e. protection and
filtration)
◼ Covering and lining epithelium
◼ Outer covering of skin and some internal organs
◼ Glandular epithelium
◼ Secreting portion of glands (thyroid, adrenal, and sweat
glands)
Covering and Lining Epithelium

◼ Normally classified according to:
❑ Arrangement of cells into layers
❑ Shapes of cells
Covering and Lining Epithelium

◼ Arrangement of cells in layers
❑ Consist of one or more layers depending on function
❑ Simple epithelium
◼ Single layer of cells that function in diffusion, osmosis,
filtration, secretion, or absorption
❑ Pseudostratified epithelium
◼ Appear to have multiple layers because cell nuclei at different
levels
◼ All cells do not reach the apical surface
❑ Stratified epithelium
◼ Two or more layers of cells that protect underlying tissues in
areas of wear and tear
Different Types of Covering and Lining
Epithelium
◼ Cells vary in shape depending on their
function
❑ Squamous
◼ Thin cells, arranged like floor tiles
◼ Allows for rapid passage of substances
❑ Cuboidal
◼ As tall as they are wide, shaped like cubes or hexagons
◼ May have microvilli
◼ Function in secretion or absorption
Different Types of Covering and Lining
Epithelium
❑ Columnar
◼ Much taller than they are wide, like columns
◼ May have cilia or microvilli
◼ Specialized function for secretion and absorption
❑ Transitional
◼ Cells change shape, transition for flat to cuboidal
◼ Organs such as urinary bladder stretch to larger size
and collapse to a smaller size
Simple Epithelium

❑ Simple squamous epithelium
❑ Simple cuboidal epithelium
❑ Simple columnar epithelium (nonciliated and
ciliated)
❑ Pseudostratified columnar epithelium (nonciliated
and cilated)
Simple squamous epithelium

❑ Single layer of cells that resembles a tiled floor on the
surface
◼ Nucleus is centrally located and appears flattened oval or
sphere
❑ Found at sites for filtration or diffusion
Covering and Lining Epithelium

◼ Endothelium
❑ The type of simple squamous that lines the heart,
blood vessels, and lymphatic vessels
◼ Mesothelium
❑ The type of epithelial layer of serous membranes
such as the pericardium, pleura, or peritoneum
◼ Both are derived from embryonic mesoderm
Simple cuboidal epithelium

❑ Cuboidal shaped cells
❑ Cell nuclei round and centrally located
❑ Found in thyroid gland and kidneys
❑ Functions in secretion and absorption
Simple columnar epithelium

❑ Column shaped cells
❑ Oval nuclei at near base
❑ Nonciliated and ciliated
Nonciliated simple columnar epithelium

❑ Contains columnar cells
with microvilli at their
apical surface and goblet
cells
❑ Secreted mucus serves
as lubricant for the lining
of digestive, respiratory,
reproductive and urinary
tracts
❑ Also prevents the
destruction of the
stomach lining by acidic
gastric juices
Ciliated simple columnar epithelium
❑ Columnar epithelial cells
with cilia at the apical
surface
◼ In respiratory tract,
goblet cells are
interspersed among
ciliated columnar
epithelia
◼ Secreted mucus on the
surface traps inhaled
foreign particles.
Beating cilia moves
particles to the throat for
removal by coughing,
swallowing, or sneezing
◼ Cilia also moves oocytes
to the uterine tubes
Covering and Lining Epithelium

◼ Pseudostratified columnar epithelium
❑ Appears to have several layers due to nuclei are
various depths
❑ All cells are attached to the basement membrane
in a single layer but some do not extend to the
apical surface
❑ Ciliated cells secrete mucus and bear cilia
❑ Nonciliated cells lack cilia and goblet cells
Covering and Lining Epithelium
 Stratified Epithelium

◼ Two or more layers of cells
◼ Specific kind of stratified epithelium depends
on the shape of cells in the apical layer
❑ Stratified squamous epithelium
❑ Stratified cuboidal epithelium
❑ Stratified columunar epithelium
❑ Transitional epithelium
Stratified Squamous Epithelium
❑ Several layers of cells that are flat in the apical layer
◼ New cells are pushed up toward apical layer
◼ As cells move further from the blood supply they dehydrate, harden,
and die
❑ Keratinized form contain the fibrous protein keratin
◼ Found in superficial layers of the skin
❑ Nonkeratinized form does not contain keratin
◼ Found in mouth and esophagus
Stratified Cuboidal Epithelium

❑ Fairly rare type of epithelium
❑ Apical layers are cuboidal
❑ Functions in protection
Stratified columnar epithelium

❑ Also very uncommon
❑ Columnar cells in apical layer only
❑ Basal layers has shorten, irregular shaped cells
❑ Functions in protection and secretion
Transitional Epithelium
❑ Found only in the urinary system
❑ Variable appearance
❑ In relaxed state, cells appear cuboidal
❑ Upon stretching, cells become flattened and appear
squamous
❑ Ideal for hollow structure subjected to expansion
HISTOLOGY OF GLANDS
Glands - Classification
◼ Classified into 2 depending on how their
products are released
◼ Exocrine:
❑ Secrete onto a body surface directly/through
epithelial ducts connected to surface
❑ Ducts may/may not alter secretion from gland by
absorbing/secreting substances
◼ Endocrine:
❑ Lack a duct
❑ Secrete into circulation ➔ hormones
Glands

◼ Paracrine secretion refers to cellular
secretions that do not reach the circulation
but act locally on cells within the same tissue

◼ Exocrine glands have 3 release mechanisms
:
❑ Merocrine
❑ Apocrine
❑ Holocrine
Release Mechanisms

◼ Merocrine
❑ Release by exocytosis – fusion to apical cell membrane of
filled vesicles
❑ Commonest, e.g. pancreatic acinar cells

◼ Apocrine
❑ Release from apical cell surface of contents surrounded by
cytoplasm and an envelope of the cellular plasma
membrane
❑ Lactating mammary gland (relases lipid droplets into milk)
❑ Ciliary glands (Moll’s) of eyelid,
❑ Ceruminous glands of EAM
Release Mechanisms

◼ Holocrine Secretion
❑ Secretory products accumulate within a maturing
cell
❑ Cell undergoes apoptosis, thereby discharging
both products and cell debris into gland lumen
❑ Sebaceous glands of skin
Glands

◼ Also classified as Unicellular or Multicellular

◼ Unicellular
❑ Single secretory cells distributed amongst other
nonsecretory cells
❑ E.g. Goblet cells in columnar epithelium
Simple columnar epithelium, ileal mucosa
Multicellular Glands
◼ Multicellular
❑ Exhibit varying degrees of complexity
❑ Further sub classified according to the
arrangement of the secretory cells and the
presence or absence of branching duct elements

❑ multicellular glands form tubular invaginations
forming a secretory portion and a duct
Multicellular Glands
◼ Ducts :
❑ Simple glands ➔ duct is not branched
❑ Compound glands ➔ duct is branched

◼ Secretory portion :
❑ Tubular if shaped like a tube
❑ Alveolar/acinar if shaped like a flask
❑ Tubuloalveloar if duct terminates in a sac-like
dilatation

❑ Tubular portions can be straight/branched/coiled
❑ Alveolar portions can be single or branched
Structural Classification of Exocrine
Glands
◼ Multicellular glands are categorized
according to two criteria:
❑ Ducts are branched or unbranched
❑ Shape of the secretory portion of the gland
◼ Simple gland duct does not branch
◼ Compound gland duct branches
◼ Tubular glands have tubular secretory parts
◼ Acinar glands have rounded secretory parts
◼ Tubuloacinar glands have both tubular and rounded
secretory parts
Gland secretions

◼ Exocrine glands that empty into internal body
surfaces (GIT, Respiratory and urogenital tracts)
have mucous and/or serous secretions

◼ Mucous secretions are viscous
❑ Goblet cells, cells of sublingual salivary glands, stomach
goblet cells
❑ Protein secretion that is extensively glycosylated with
anionic oligosaccharides
❑ PAS +ve mucinogenic granules that are lost in tissue
preparation
❑ Therefore in H&E sections, the cytoplasm of mucous cells
appears empty with a basal nucleus
GLAND SECRETIONS

◼ Serous sections are watery
❑ Contain non-glycosylated protein secretions
❑ Cells have cytoplasm that stains intensely with
eosin
❑ E.g. parotid gland
GLAND SECRETIONS
◼ The staining difference is
important and reflects
fundamental differences in cell
function.
◼ Serous acini secrete a protein-rich
product and stain fairly well due to
the presence of rER and secretory
granules (dense protein-filled
vesicles) in the cytoplasm.
◼ Mucous acini, like goblet cells,
secrete mucus, which contains
less protein but much watery
mucopolysaccharide.
◼ Mucous cells stain very poorly
because they contain little rER
and their mucin granules tend to
react poorly with most stains.
QUIZ
Identify - 1
Identify - 2

Copyright 2009, John Wiley & Sons, Inc.
Identify - 3
Identify - 4
Identify - 5
THE SKIN
The integumentary system

◼ Made up of the skin and its accessory structures

◼ Different tissue types constitute the largest organ in the
body

◼ 3 principal components:

1. Epidermis
2. Dermis
3. hypodermis
Functions of the skin

◼ Protection: an anatomical barrier from pathogens
◼ Sensation: contains a variety of nerve endings that react to heat and
cold, touch, pressure, vibration, and tissue injury
◼ Thermoregulation: constricted blood vessels reduce cutaneous blood
flow and conserve heat, while dilated blood vessels increase cutaneous
blood flow and release heat. Sweat glands release sweat, which cools
down the body. Erector pili muscles contact and cause the hair follicles
to move upwards and retain heat (gooseflesh). The subcutaneous fat
also serves as insulation.
◼ Control of evaporation: the skin provides a relatively dry and semi-
impermeable barrier to fluid loss.
◼ Storage and synthesis: acts as a storage centre for lipids
(subcutaneous fat) and water
◼ Absorption: Oxygen, nitrogen and carbon dioxide can diffuse into the
epidermis in small amounts.
◼ Water resistance: The skin acts as a water resistant barrier so
essential nutrients aren't washed out of the body.
Epidermis

◼ A keratinized stratified squamous epithelium

◼ The predominant cell type is the keratinocyte

◼ Other cell types are melanocytes,
Langerhans cells and Merkel cells
Epidermis - Melanocytes

◼ Melanocytes are the melanin producing cells, the
compound responsible for skin color

◼ Melanin absorbs UV light to protect from damaging UV
radiation
Epidermis – Langerhans cells

◼ These are dendritic cells of monocytic origin and contain
intracellular Birbeck granules

◼ They are immune cells – antigen presenting cells. They
function in the capture, processing and presentation of
antigen
Epidermis – Merkel Cells

◼ Located in the deep epidermis these cells contact the
tactile disc of sensory neurons

◼ Function in sensation of touch (mechanotransduction)
Epidermal Layers
◼ Stratum basale

◼ Deepest layer of cuboidal / columnar cells

◼ regenerative cells undergoing mitosis
◼ Includes scattered melanocytes and Langerhans cells
Epidermal Layers
◼ The stratum spinosum is the layer above the basal
layer

◼ Polyhedral keratinocytes adopt a gradually more
flattened appearance

◼ Spine like appearance on histology sections where the
intracellular intermediate filaments insert into
desmosomes
Epidermal Layers

◼ The middle layer of flattened keratinocytes undergoing
apoptosis is called the stratum granulosum

◼ Named after the conspicuous keratohyalin granules that
stain darkly

◼ Also contain lamellar granules,
these are lipid rich intracellular
organelles that secrete a lamellar
layer between the epidermal
cell layers
Epidermal layers

◼ Stratum lucidum - present only in very thick skin
(palms, soles)

◼ Pale-staining layer of cells between the stratum corneum
and stratum granulosum in which the dying keratinocytes
contain a lot of keratin but are not completely replaced
by it
Epidermal layers

◼ The stratum corneum

◼ Composed of dead flat (squame) keratinocytes and
densely packed intermediate filaments and keratohyalin

◼ Continually shed off and replaced by cells from the
deeper layers.
The Dermis

◼ Composed of typical connective tissue containing
collagen and elastin, fibroblasts and macrophages

◼ Divided into two regions

1. A superficial papillary dermis

2. A deeper reticular dermis
The dermis

◼ The papillary dermis - consists of loose areolar
connective tissue containing collagen and fine elastic
fibers

◼ It forms finger like projections – the dermal papillae –
that indent the adjacent epidemis and contain capillary y
loops

◼ Also contains free nerve endings
The dermis

◼ The reticular dermis contains contains dense, irregular
and coarse collagen fibers and thick elastic fibers
interspersed with fibroblasts and blood vessels and
nerves

◼ Also contains sweat and sebaceous glands
BASAL CELL CARCINOMA

◼ The most common
type of skin cancer.
◼ Development of a
shiny pearly nodule.
◼ Commonly seen on
sun exposed areas of
the body.
◼ Malignant but does
not usually
metastasize.
SQUAMOUS CELL CARCINOMA
◼ Malignant tumour of
squamous cell epithelium.
◼ Slow growing but rapidly
spreads to neighbouring
tissues.
◼ Often starts off as actinic
keratosis (rough red
bumps on skin) but may
later be transformed to
invasive squamous cell
carcinoma.
◼ Commonly seen in fair
skinned people.
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MELANOMA
◼ A malignant tumour of
melanocytes – cells
responsible for the
formation of melanin
pigment of the skin.
◼ Early signs of melanoma
are summarised by the
mnemonic
◼ A – asymmetry
◼ B – border (irregular)
◼ C – colour (variegated)
◼ D – diameter
◼ E – evolving over time