Cellular Injury Lecture Notes PDF

Summary

This lecture discusses cellular injury and the various causes, mechanisms, and outcomes. The presentation covers a range of topics, such as hypoxia, physical and chemical agents, and immunological factors. The lecture is intended for students studying medical science and related fields.

Full Transcript

CELLULAR INJURY
CELL INJURY
Cell injury is defined as the effect of a variety
of stresses due to etiologic agents a cell
encounters resulting in changes in its internal
and external environment.
 STRESS= ETIOLOGICAL AGENTS LIKE BACTERIA

STRESS Effects

Affected
cell CHANGES IN
INTERNAL AND
STRESS EXTERNAL
ENVIRONMENT
OF CELL

STRESS
 CELLULAR RESPONSES TO CELL INJURY.
STRESS

ALTERED FUNCTIONAL SEVERE STRESS AND
DEMAND PERSISTANT STRESS

MILD TO MODERATE STRESS

ADAPTATIONS REVERSIBLE CELL INJURY IRREVERSIBLE CELL
-ATROPHY -DEGENERATIONS INJURY
-HYPERTROPHY -SUBCELLULAR ALTERATIONS -CELL DEATH
-HYPERPLASIA -INTRACELLULAR ACCUMULATIONS
-DYSPLASIA
ETIOLOGY OF CELL INJURY
The cells may be broadly injured by two major
ways:
A. Genetic causes
B. Acquired causes
 ETIOLOGY OF
CELL INJURY

ACQUIRED
GENETIC CAUSES
CAUSES

1. Hypoxia and ischemia
2. Physical agents
3. Chemical agents and drugs
4. Microbial agents
5. Immunologic agents
6. Nutritional derangements
7. Ageing
8. Psychogenic diseases
9. Iatrogenic factors
10. Idiopathic diseases.
HYPOXIA AND ISCHEMIA
Hypoxia is the most common cause of cell
injury
TWO REASONS

Reduced blood supply Due to defects in oxygen
to cells due to carrying RBC’S or due to
interruption in blood or HEART DISEASES,
flow leading to LUNG DISEASES, due to
ischemia increased demand from
tissues.
INTERRUPTED BLOOD FLOW HEART DISEASES

ABNORMAL RBC’S
LUNG DISEASES
1-PHYSICAL AGENTS
Physical agents in causation of disease are:
Mechanical Trauma (e.g. Road Accidents)
Thermal Trauma (e.g. By Heat And Cold)
Electricity
Radiation (e.g. Ultraviolet And Ionizing)
Rapid Changes in atmospheric pressure
 COLD TRAUMA HEAT TRAUMA

RADIATION TRAUMA
ELECTRICITY TRAUMA
2-CHEMICALS AND DRUGS
- Chemical poisons such as cyanide, arsenic,
mercury.
- Strong acids and alkalis
- Environmental pollutants
- Insecticides and pesticides
- Oxygen at high concentrations
- Hypertonic glucose and salt
- Social agents such as alcohol and narcotic drugs
- Therapeutic administration of drugs.
3-MICROBIAL AGENTS
Injuries by microbes include
Infections caused by bacteria, rickettsiae,
viruses, fungi, protozoa, metazoa, and other
parasites.
4-PSYCHOGENIC DISEASES
There are no specific biochemical or
morphologic changes in common acquired
mental diseases due to mental stress, strain,
anxiety, overwork and frustration
e.g. depression, schizophrenia.
However, problems of drug addiction,
alcoholism, and smoking result in various organic
diseases such as liver damage, chronic bronchitis,
lung cancer, peptic ulcer, hypertension, ischemic
heart disease etc.
5-IMMUNOLOGIC AGENTS
Immunity is a ‘double-edged sword’:
it protects the host against various injurious
agents but it may also turn lethal and cause
cell injury
e.g.
Hypersensitivity reactions;
Anaphylactic reactions; and
Autoimmune diseases.
6-AGEING
Cellular ageing or senescence leads to
impaired ability of the cells to undergo
replication and repair, and ultimately lead to
cell death culminating in death of the
individual.
PATHOGENESIS OF CELL INJURY
Objective of lecture
Types of Cell- injuries.
Pathogenesis of Cell-injury
Pathogenesis in Reversible and Irreversible
Hypoxic Cell-injury in particular
Outcomes/Events in Reversible and
Irreversible Hypoxic Cell injury.
 Injury to the normal cell by one or more of the
above listed etiologic agents may result in a
state of

CELL REPAIR AND HEAL REVERSIBLE
CELL INJURY

CELL DEATH IRREVERSIBLE
CELL INJURY
OUTCOME OF THE CELL-INJURY DEPENDS ON:

TYPE,
DURATION, OF INJURIOUS AGENT
SEVERITY

TYPE,
STATUS ,
OF TARGET CELL
ADAPTABILITY
 BASED ON TYPE, DURATION, SEVERITY:

Small Dose of Chemical/Physical Agent Large Dose of Chemical/Physical Agent

REVERSIBLE CELL INJURY IRREVERSIBLE CELL INJURY
Short Duration of Ischemia Long Duration of Ischemia

REVERSIBLE CELL INJURY IRREVERSIBLE CELL INJURY
BASED ON TYPE, STATUS, ADAPTABILITY OF TARGET CELL:

IF A CELL IS HIGHLY SUSCEPTABLE TO HYPOXIA

EARLY CELL INJURY
EXAMPLE:
Skeletal muscle can withstand hypoxic injury for
long-time,

While cardiac muscle suffers Irreversible cell injury
if exposed to Hypoxia for > 20 mins
Skeletal Muscle Cardiac Muscle
PATHOGENESIS OF ISCHAEMIC AND
HYPOXIC INJURY
 Ischemia and hypoxia are the most common
forms of cell injury.
It leads to
- REVERSIBLE CELL INJURY
- IRREVERSIBLE CELL INJURY
REVERSIBLE CELL INJURY IN HYPOXIA
 If hypoxia is of short duration -> the effects
may be reversible on rapid restoration of
circulation.
Example:
In coronary artery occlusion, the myocardial
contractility, metabolism and ultra structure
are reversed if the circulation is quickly
restored
CORONARY ARTERY OCCLUSION
EVENTS IN REVERSIBLE CELL INJURY ARE:

1. DECREASED GENERATION OF CELLULAR ATP:
2. INTRACELLULAR LACTIC ACIDOSIS:
3. DAMAGE TO PLASMA MEMBRANE PUMPS:
4. REDUCED PROTEIN SYNTHESIS:
1. DECREASED GENERATION OF CELLULAR ATP:

All living cells require continuous supply of
oxygen to produce ATP which is essentially
required for a variety of cellular functions.
ATP is generated from:
- AEROBIC PATHWAY
- ANEROBIC PATHWAY
 ATP in human cell is derived from 2 sources

AEROBIC ANEROBIC
RESPIRATION PATHWAY
Anaerobic
Requires Oxygen Glycolytic
oxidation

ATP is generated
from
Takes place in the
Glucose/Glycogen
mitochondria.
in the absence of
Oxygen
WITH INTERRUPTED BLOOD WITH DEFECTS IN OXYGEN
SUPPLY CARRYING RBC’S OR HEART OR
LUNG DISEASES
BOTH OXYGEN AND GLUCOSE
SUPPLY IS COMPROMISED

ONLY OXYGEN COMPROMISED

COMPLETE ATP DEPLETION
ATP IS GENERATED BY
ANEROBIC PATHWAY

SEVERE CELL INJURY
CELL INJURY IS LESS
Cells which depend only
on Aerobic Respiration
for ATP generation

MYOCARDIUM CELLS
Hence these
tissues suffer
PROXIMAL TUBULAR more severely and
CELLS KIDNEYS rapidly due to
hypoxia

NEURONS OF CNS
 2. INTRACELLULAR LACTIC ACIDOSIS:

Low oxygen supply to the cell

Mitochondria fails (No Oxygen No ATP generation)

Switches to Anaerobic Glycolytic Pathway for the requirement of ATP.

Accumulation of Lactic Acid

Decreased Intracellular pH.

Clumping of Nuclear Chromatin.
CHROMATIN CLUMPING
3. DAMAGE TO PLASMA MEMBRANE PUMPS
 DECREASED A.T.P

(ATP)-Dependent Sodium pump Decreased Production of PHOSPHOLIPIDS
FAILURE
Repair of Cell membrane is stopped

Increased accumulation of
Na in cell Membrane damage

Swelling of Cell Calcium influx into cell
(HYGROPIC SWELLING) (Particularly mitochondria)

Swelling of Mitochondria
(Amorphous densities)
HYDROPIC SWELLING

Swelling of
Mitochondria
4. REDUCED PROTEIN SYNTHESIS:
Endoplasmic Golgi apparatus
Reticulum
 Membranes of endoplasmic
Reticulum and Golgi apparatus
swell up.

Ribosomes are
detached from granular (rough)
endoplasmic reticulum

Reduced protein synthesis
Other changes:
Loss of Microvilli and Intramembranous particles
Focal projections of the cytoplasm (blebs).
Myelin figures may be seen lying in the cytoplasm
 Note:
Up to this point,
withdrawal of acute stress
that resulted in reversible cell injury
can restore the cell to normal state.
IRREVERSIBLE CELL INJURY
IN HYPOXIA/ISCHEMIA
 Persistence of ischemia (i.e., reduced
blood flow to a tissue/organ) or hypoxia

Continuous ↓ in ATP,
↓ in Proteins,
↓ intracellular pH, and
leakage of lysosomal enzymes into the plasma.

Irreversible damage to the structure and function of the cell
Even after reperfusion with oxygen
i.e., CELL DEATH
CHANGES IN IRREVERSIBLE CELL INJURY ARE:

1. CALCIUM INFLUX
2. ACTIVATED PHOSPHOLIPASES
3. INTRACELLULAR PROTEASES
4. ACTIVATED ENDONUCLEASES
5. LYSOSOMAL HYDROLYTIC ENZYMES
1. CALCIUM INFLUX

Due to continued hypoxia - Large cytosolic influx of calcium ions occurs
(Esp. after reperfusion of irreversibly injured cell)

Vacuoles Formation in the Mitochondria
Deposition of amorphous calcium salts in the mitochondrial matrix

VACUOLES
2. ACTIVATED PHOSPHOLIPASES:

Increased cytosolic influx of calcium into the cell

Activation of endogenous phospholipases

Damage to phospholipids layer of Cell membrane

Damage to membrane function
Phospholipid phospholipids bilayer
3. INTRACELLULAR PROTEASES
Activated Intracellular Proteases
(released by Lysosomes)

Digestion of cytoskeleton of cell

Cytoskeleton Damage
4. ACTIVATED ENDONUCLEASES
Activated lysosomal enzymes such as Proteases and Endonucleases.

Damage to DNA/Nuclear proteins

Three types of nuclear damage can happen:
1- PYKNOSIS: 2- KARYORRHEXIS: 3- KARYOLYSIS:
Condensation and Nuclear Fragmentation Dissolution of Nucleus
clumping of nucleus Into small bits
5. LYSOSOMAL HYDROLYTIC ENZYMES
Lysosomal Membrane Damage

Escape of lysosomal hydrolytic enzymes into cell medium

Activation of hydrolytic enzymes by low pH and Low oxygen

Enzymatic digestion of cellular components

CELL DEATH

DEAD CELLS PHAGOCYTOSED BY MACROPHAGES
 Hydrolytic enzymes

Lysosomes

Digestion of cell organelles
Lysosome enzymes:
Hydrolase,
RNAase,
DNAase,
Protease,
Glycosidase,
Phosphatase,
Lipase,
Amylase.
COMMON ENZYME MARKERS IN SERUM FOR DIFFERENT
FORMS OF CELL DEATH:
ENZYME DISEASE
Aspartate aminotransferase Viral Hepatitis, Alcoholic Liver Disease
(AST, SGOT) Acute Myocardial Infarction

Alanine aminotransferase More specific for diffuse liver cell damage
(ALT, SGPT) than AST e.g. Viral Hepatitis

Creatine Kinase-MB Acute Myocardial Infarction, Myocarditis
(CK-MB)

Lipase More specific for acute pancreatitis
Amylase Acute Pancreatitis
Sialadenitis

Lactic dehydrogenase Acute Myocardial Infarction
(LDH) Myocarditis
Skeletal muscle injury

Cardiac troponin (CTn) Specific for Acute Myocardial Infarction
 Objectives of our lecture
- Learn the Morphological forms seen in
Reversible Cell Injury and Irreversible cell
Injury
MORPHOLOGY OF REVERSIBLE CELL INJURY
Morphologic Forms Of Reversible Cell Injury:

1. Hydropic change
2. Hyaline change
3. Mucoid change
4. Fatty change
1. HYDROPIC CHANGE/DEGENERATION

Accumulation of water within the cytoplasm
of the cell.
Synonym= CLOUDY SWELLING , VACUOLAR
DEGENERATION (Due to cytoplasmic
vacuolation).
It is entirely reversible.
Commonest form in cell injury
Earliest form in cell injury
Etiology:
- Hypoxia
- Microbes
- Chemicals agents
- Physical agents
- Etc…
 PATHOGENESIS
Cloudy swelling results from impaired
regulation of sodium and potassium at the
level of cell membrane.
MORPHOLOGIC FEATURES:
Grossly, the affected organ such as kidney, liver, pancreas,
or heart muscle is enlarged due to swelling.
The cut surface bulges outwards and is slightly opaque.
MICROSCOPICALLY:
The features of Hydropic swelling of kidney are as under
i) The tubular epithelial cells are swollen
ii) cytoplasm contains small clear vacuoles
iii) Small cytoplasmic blebs may be seen.
2. HYALINE CHANGE/DEGENERATION

The word ‘hyaline’ or ‘hyalin’ means glassy.
Hyalinisation is a common descriptive
histologic term.
It means glassy, homogeneous, eosinophilic
appearance of proteinaceous material in
haematoxylin and eosin-stained sections.
It does not refer to any specific substance.
 Hyaline change is seen in heterogeneous
pathologic conditions and may be intracellular
or extracellular.
INTRACELLULAR HYALINE

Intracellular hyaline is mainly seen in
epithelial cells.
A few examples are as follows:
1. Hyaline droplets in the proximal tubular
epithelial cells due to excessive reabsorption
of plasma proteins in proteinuria.
Hyaline droplets in proximal tubular epithelial cells
2. Hyaline degeneration of rectus abdominalis
muscle called Zenker’s degeneration,
occurring in typhoid fever.

Zenker’s degeneration
3. Mallory’s hyaline/Mallory bodies- seen in the
hepatocytes in alcoholic liver cell injury.
4. Russell’s bodies representing excessive
immunoglobulin in the rough endoplasmic
reticulum of the plasma cells
RUSSELL’S BODIES
EXTRACELLULAR HYALINE

Extracellular hyaline commonly seen in
connective tissues.
A few examples of extracellular hyaline change
are as under:
1. Hyaline degeneration in leiomyomas of the
uterus
2. Hyalinised old scar of fibrocollagenous
tissues.
3. Hyaline arteriolosclerosis in renal vessels in
hypertension and diabetes mellitus.
3. MUCOID CHANGE/ DEGENERATION

Mucoid means mucus-like
Mucin (constituent of mucus) is a glycoprotein
normally produced by epithelial cells of
MUCUS MEMBRANES and MUCUS GLANDS
and by some CONNECTIVE TISSUE (CT) cells.
The mucin produced by CT cells is called
MYXOID.
MUCUS GLANDS

MUCUS
What is Mucoid Degeneration?

Excessive mucus production by the
- Epithelial cells of mucous membranes and
mucous glands (EPITHELIAL MUCIN)
- Connective tissues (CONNECTIVE TISSUE MUCIN)
EPITHELIAL MUCIN

Examples of functional excess of epithelial
Mucin:
1. Catarrhal inflammation of mucous
membrane (e.g. of respiratory tract,
alimentary tract).
2. Cystic fibrosis of the pancreas/Lungs.
3. Mucin-secreting tumors (e.g. of ovary,
stomach, large bowel etc)
RESPIRATORY TRACT CATARRAL INFLAMMATION
- EXCESS MUCUS PRODUCTION
CYSTIC FIBROSIS OF THE LUNGS.
CONNECTIVE TISSUE MUCIN

Connective tissue mucin or myxoid change are
as under:
1. Mucoid or myxoid change in some tumours
like fibroadenoma.
2. Myxomatous change in the dermis in
Myxoedema.
MYXOEDEMA
4. FATTY DEGENERATION (STEATOSIS)

Intracellular accumulation of neutral fat
within parenchymal cells.
Fatty change is particularly common in the
liver but may occur in other non-fatty tissues
as well e.g. in the heart, skeletal muscle,
kidneys (lipoid nephrosis) and other organs.
FATTY LIVER
MORPHOLOGY OF IRREVERSIBLE CELL INJURY
(CELL DEATH)
 Cell death is a state of irreversible injury.
PROCESSES INVOLVED IN
CELL DEATH

LOCALLY CHANGES FOLLOWING
1- AUTOLYSIS LOCAL CHANGE
2- NECROSIS 1- GANGRENE
3- APOPTOSIS 2- CALCIFICATION
AUTOLYSIS (self-digestion)

Disintegration of the cell by its own hydrolytic
enzymes liberated from Lysosomes
PACE OF AUTOLYSIS
RAPID INTERMEDIATE SLOW
in tissues rich in in tissues like the in fibrous tissue.
hydrolytic HEART, LIVER AND
enzymes- KIDNEY
PANCREAS,
GASTRIC
MUCOSA
 NECROSIS
Necrosis is defined as a localized area of death of
tissue followed later by degradation/breakdown
of tissue by hydrolytic enzymes liberated from
dead cells; it is invariably accompanied by
inflammatory reaction.
 DEAD
TISSUE

NECROSIS

DEGRADATION
/BREAKDOWN
OF TISSUE by INFLAMMATION
HYDROLYTIC
ENZYME
ETIOLOGICAL AGENTS:
- Hypoxia,
- Chemical
- Physical agents
- Microbial agents
- Immunological etc…
5 TYPES OF NECROSIS:
Coagulative
Liquefaction (Colliquative) Based on
Etiology and
Caseous Morphologic
Fat appearance
Fibrinoid Necrosis
1. COAGULATIVE NECROSIS

Most common type of necrosis caused by
irreversible focal injury.
Cause:
- From sudden cessation of blood flow
(ischemic necrosis)
- Less often from bacterial and chemical agents.
The organs commonly affected are the heart,
kidney, and spleen.
 APPEARANCE

GROSSLY/MACROSCOPICALLY

EARLY STAGE LATE STAGE

- Pale - Yellowish
INFARCT - Firm - Softer
- Slightly swollen - Shrunken.
 MICROSCOPICALLY

Hallmark of coagulative necrosis = ‘TOMB STONES’
i.e. outlines of the cells are retained and the cell type can still be
recognized but their cytoplasmic and nuclear details are lost.
OTHER FINDINGS MICROSCOPICALLY:
Nuclear changes of pyknosis, karyorrhexis and
karyolysis
Cell digestion and liquefaction fail to occur.
Eventually, the necrosed focus is infiltrated by
inflammatory cells and the dead cells are
phagocytosed leaving granular debris and
fragments of cells
2. LIQUEFACTION (COLLIQUATIVE) NECROSIS

Due to ischemic injury and bacterial or fungal
infections
Liquefaction is due to Hydrolytic enzymes.
The common examples are infarct brain and
abscess cavity.
 Grossly, the affected area is soft with
liquefied centre containing necrotic debris.
Later, a cyst wall is formed.
 Microscopically, the cystic space contains
necrotic cell debris and macrophages filled
with phagocytosed material.
The cyst wall is formed by
- Proliferating capillaries,
- Inflammatory cells, and
- Gliosis (proliferating glial cells) in the case of
brain and
Abscess cavity
- Proliferating fibroblasts
3. CASEOUS NECROSIS
Caseous (caseous= cheese-like) necrosis is
found in the centre of foci of tuberculous
infections.
It combines features of both coagulative and
liquefactive necrosis.
4. FAT NECROSIS
Fat necrosis is a special form of cell death
occurring at mainly fat-rich anatomic locations
in the body.
Examples are:
1. Traumatic fat necrosis of the breast,
2. Mesenteric fat necrosis due to acute
pancreatitis.
TRAUMATIC FAT NECROSIS OF BREAST
MESENTERIC FAT NECROSIS
 In fat necrosis:

HYDROLYSIS AND RUPTURE OF ADIPOCYTES

Release of neutral fat

CHANGES INTO GLYCEROL & FREE FATTY
ACIDS.

Free fatty acids complex with
Calcium to form CALCIUM SOAPS
(SAPONIFICATION)
 Fat necrosis appears as yellowish-white and
firm Deposits.
Formation of calcium soaps imparts the
necrosed foci FIRMER AND CHALKY WHITE
SAPONIFICATION APPEARANCE.
5. FIBRINOID NECROSIS

Fibrinoid necrosis is characterized by deposition
of fibrin-like material which has the staining
properties of fibrin such as phosphotungistic acid
haematoxylin (PTAH) stain.
It is encountered in various examples of
immunologic tissue injury.
E.g.
- Immune Complex Vasculitis
- Autoimmune Diseases
- Arthus Reaction Etc
APOPTOSIS
 Apoptosis is a form of ‘coordinated and
internally programmed cell death’.
When the cell is not needed, pathway of cell
death is activated (‘cell suicide’).
Unlike necrosis, apoptosis is not accompanied
by any inflammation and collateral tissue
damage.
APOPTOSIS IN BIOLOGIC PROCESSES

1. Physiological apoptosis
2. Pathological apoptosis
Physiologic Processes:
1. Physiologic involution of cells in hormone-
dependent tissues e.g. endometrial shedding,
regression of lactating breast after
withdrawal of breast-feeding.
2. Normal cell destruction followed by
replacement proliferation such as in intestinal
epithelium.
3. Involution of the thymus in early age.
Pathologic Processes:
1. Cell death in tumors exposed to
chemotherapeutic agents.
2. Progressive depletion of CD4+T cells in the
pathogenesis of AIDS.
3. Pathologic atrophy of organs and tissues on
withdrawal of stimuli e.g. prostatic atrophy
after orchiectomy.
5. Cell death in response to low dose of injurious
agent involved in causation of necrosis e.g.
radiation, hypoxia and mild thermal injury.
6. In degenerative diseases of CNS e.g. in
Alzheimer’s disease, Parkinson’s disease, and
chronic infective dementias.
7. Heart diseases e.g. in acute myocardial
infarction (20% necrosis and 80% apoptosis).
MOLECULAR MECHANISMS OF APOPTOSIS

Several physiologic and pathologic
processes activate apoptosis in a variety
of ways.
Molecular events involved in apoptosis:
1- INITIATORS OF APOPTOSIS
2- INTIAL STEPS IN APOPTOSIS
3- FINAL PHASE OF APOPTOSIS
4- PHAGOCYTOSIS
1. Initiators of apoptosis:
All cells have inbuilt effector mechanisms for
cell survival and signals of cell death.
It is the loss of this balance that determines
survival or death of a cell.
A cell may be initiated to programmed cell
death by:

Withdrawal of normal cell Agents of cell injury
survival signals: OR
e.g. absence of certain
hormones, growth e.g. Heat, Radiation, Hypoxia,
factors, cytokines. Toxins, Free Radicals.
2. Initial steps in apoptosis

After the cell has been initiated into self-destruct mode,
Cell death signaling mechanisms gets activated from
I. Intrinsic (mitochondrial) pathway
II. Extrinsic (cell death receptor initiated) pathway.

However, finally mediators of cell death are activated
caspases.
Caspases are a series of proteolytic or protein-splitting
enzymes which act on nuclear proteins and organelles
containing protein components.
Intrinsic (mitochondrial) pathway

Increased mitochondrial permeability activates this
pathway

Cytochrome- c (protein) released from mitochondria
into the cytoplasm of the cell

Cytochrome- c triggers the cell into apoptosis.

activates Caspases-9 APOPTOSIS
 The major mechanism of regulation of this
mitochondrial protein (Cytochrome- c) is by
pro-apoptotic and anti-apoptotic members
of Bcl proteins.
 BCL-2 is localized to the outer membrane of
mitochondria, where it plays an important
role in promoting cellular survival and
inhibiting the actions of pro-apoptotic
proteins.

BCL-2 proteins (Anti-apoptotic proteins)

Bad
Bim
BH3-only proteins (Pro- apoptotic proteins)
Extrinsic (cell death receptor initiated) pathway

It works by Activation of death receptors on the cell
membrane.

Cell Death Receptors are:
- Type 1 Tumour Necrosis Factor Receptor (TNF-
R1) and
- a related transmembrane protein called Fas
(CD95) and its ligand (FasL). (Fas belongs to TNF
Receptor family)
 TNF-α
(Death
Ligand)
FasL
Extracellular (Ligand)

Fas
Cell membrane TNFR1
Receptor
Receptor

ADAPTER
Intracellular Fas-associated
protein
Death domain
(FADD)
ADAPTER
Tumor Necrosis
Factor Receptor Type
1-associated Death APOPTOSIS
Activation of
Domain (TRADD) Caspases 8 and 10
3. Final phase of apoptosis
The activated caspases have proteolytic action

Proteolytic actions lead to
1. Nucleus damage
2. Chromatin clumping CELL DEATH
3. Cytoskeleton damage
4. Disruption of endoplasmic reticulum
5. Mitochondrial damage
6. Disturbed cell membrane.
4. Phagocytosis
Thrombospondin
molecules

Dead phagocyte
Apoptotic
Cell

Phosphatidylserine
molecule Phagocytosed dead cell