A&P Lecture 1. The Cell, Cell Adaptation, Injury, and Death PDF

Summary

This document is a lecture on cell biology, covering cell adaptation, injury, and death. It discusses the structure and function of normal cells, different types of cell injury, and cellular death mechanisms.

Full Transcript

The Cell, Cell Adaptation, Injury, and Death

Baha ADAM, MD, MSc, Ph.D., DABCC
Professor, Basic Pharmaceutical Science
Physician Assistant Program
College of Pharmacy, Xavier University of Louisiana
 The outline of this chapter:
The structure and function of the normal cell
Cell adaptation
Cell injury
(1) ischemic and hypoxic injury,
(2) ischemia-reperfusion injury,
(3) oxidative stress or accumulation of oxygen-
derived free radicals-induced injury, and
(4) chemical injury.
Cellular death
Necrosis
Apoptosis
Autophagy
 Cellular Functions

Movement: The cells can generate forces
that produce motion.
Conductivity: Conduction as a response to a
stimulus is manifested by a wave of
excitation.
Metabolic absorption: All cells can take in
and use nutrients and other substances from
their surroundings.
Secretion: Certain cells can secrete mucus,
saliva, CSF, synovial and serous fluid etc.
 Cellular Functions
Excretion: All cells can rid themselves of waste products
resulting from the metabolic breakdown of nutrients.
Respiration: Cells absorb oxygen, which is used to transform
nutrients into energy in the form of ATP.
Reproduction: Tissue growth occurs as cells enlarge and
reproduce themselves. Not all cells are capable of continuous
division.
Communication: Communication is vital for cells to survive as a
society of cells. Appropriate communication allows the
maintenance of a dynamic steady state.
Eukaryotic Cell
 Eukaryotic Cell
Nucleus:
The nucleus, which is surrounded by the
nucleoplasm and generally is located in
the center of the cell, is the largest
membrane-bound organelle.
Two pliable membranes compose the
nuclear envelope.
The nuclear envelope is pockmarked with pits, called nuclear pores,
which allow chemical messages to exit and enter the nucleus.
The outer membrane is continuous with membranes of the
endoplasmic reticulum.
 Eukaryotic Cell
Nucleus:
The nucleus contains:
the nucleolus (a small dense structure
composed largely of RNA),
most of the cellular DNA, and
the DNA-binding proteins (i.e., the
histones) that regulate its activity.
The primary functions of the nucleus are cell
division and control of genetic information.
Other functions include the replication and repair of DNA and the
transcription of the information stored in DNA.
 Eukaryotic Cell
Cytoplasm:
The cytoplasm is an aqueous solution
(cytosol) that fills the cytoplasmic matrix.
The cytosol represents about half the
volume of a eukaryotic cell.
It contains thousands of enzymes involved
in intermediate metabolism and is crowded
with ribosomes making proteins
The organelles suspended in the cytoplasm are enclosed in
biological membranes, so they can simultaneously carry out
functions requiring different biochemical environments.
 Eukaryotic Cell

Cytoplasm:
Many of these functions are directed by coded
messages carried from the nucleus by RNA.
The functions include synthesis of proteins and hormones and
their transport out of the cell, isolation and elimination of waste
products from the cell, performance of metabolic processes,
breakdown and disposal of cellular debris and foreign proteins
(antigens), and maintenance of cellular structure and motility.
The cytosol is a storage unit for fat, carbohydrates, and secretory
vesicles.
 Cytoplasmic Organelles
Ribosomes:
RNA protein complexes
Synthesized in nucleolus
Sites for cellular protein synthesis

Endoplasmic reticulum
Network of tubular channels
(cisternae) that extend throughout
the outer nuclear membrane.
Specializes in synthesis, folding, and transport of protein
and lipid components of most organelles.
A new role is sensing cellular stress.
 Cytoplasmic Organelles

Golgi complex:
Network of smooth membranes
and vesicles located near
nucleus.
Responsible for processing and packaging proteins onto
secretory vesicles that break away from the complex and
migrate to various intracellular and extracellular destinations,
including plasma membrane.
 Cytoplasmic Organelles

Golgi complex:
Best-known vesicles are those that have coats largely made of
the protein clathrin.
Proteins in the complex bind to the cytoskeleton, generating
tension that helps organelle function and keep its stretched
shape intact.
The complex is a refining plant and directs traffic.
 Cytoplasmic Organelles
Lysosomes:
Sac-like structures that contain
enzymes for digesting most cellular
substances to their basic form, such
as amino acids, fatty acids, and
carbohydrates (sugars).
Cellular injury leads to the release
of lysosomal enzymes that cause
cellular self-destruction.
A new function of lysosomes is signaling hubs of a
sophisticated network for cellular adaptation.
 Cytoplasmic Organelles

Peroxisomes:
Similar to lysosomes in appearance but
contain several oxidative enzymes (e.g.,
catalase, urate oxidase) that produce
hydrogen peroxide; reactions detoxify
various wastes
 Eukaryotic Organelles

Mitochondria:
Contain metabolic machinery needed
for cellular energy metabolism.
Enzymes of respiratory chain (electron-
transport chain), found in inner
membrane of mitochondria, generate
most of cell's adenosine triphosphate
(ATP) (oxidative phosphorylation).
Have a role in osmotic regulation, pH control,
calcium homeostasis, and cell signaling.
 Eukaryotic Organelles

Cytoskeleton
“Bone and muscle” of cell.
Composed of a network of protein
filaments, including microtubules
and actin filaments
(microfilaments); forms cell
extensions (microvilli, cilia, flagella).
Intermediate filaments bridge the cytoplasm from one
cell junction to another strengthening and supporting the
sheet of epithelium.
Membrane skeleton of the erythrocytes
 Hereditary spherocytosis (HS)

Spectrin, a cytoskeletal structure within the
erythrocyte, is in turn bound to ankyrin and
thereby plays an important role in
maintenance of the biconcave shape of
the erythrocyte.
Hereditary spherocytosis (HS) is a
congenital hemolytic disorder, wherein a
genetic mutation coding for a structural
membrane protein (ankyrin) phenotype
leads to a spherical shaping of erythrocytic
cellular morphology which are prone to
repture.
 Plasma Membrane

Membranes surround the cell or
enclose an intracellular organelle and
are exceedingly important to normal
physiologic function
Because they control the composition
of the space, or compartment, they
enclose.
Membranes can allow or exclude various molecules, and
because of selective transport systems, they can move
molecules in or out of the space
 Plasma Membrane Functions
Cellular Mechanism Membrane Functions
Structure Usually thicker than membranes of intracellular organelles
Containment of cellular organelles
Maintenance of relationship with cytoskeleton, endoplasmic reticulum, and
other organelles
Maintenance of fluid and electrolyte balance (ion channels)
Outer surfaces of plasma membranes in many cells are not smooth; they
are also studded with cilia or even smaller cylindrical projections called
microvilli; both are capable of movement
Protection Barrier to toxic molecules and macromolecules (proteins, nucleic acids,
polysaccharides)
Barrier to foreign organisms and cells
Activation of cell Hormones (regulation of cellular activity)
Mitogens (cellular division)
Antigens (antibody synthesis)
Growth factors (proliferation and differentiation)
 Plasma Membrane Functions
Cellular Mechanism Membrane Functions
Storage Storage site for many receptors
Transport (e.g., sodium [Na+] pump)
Diffusion and exchange diffusion
Endocytosis (pinocytosis, phagocytosis)
Exocytosis (secretion)
Active transport
Cell-to-cell Communication, anchors (integrins), and attachment at junctional
interaction complexes
Symbiotic nutritive relationships
Release of enzymes and antibodies to extracellular environment
Relationships with extracellular matrix
 Plasma Membrane

Membrane Composition:
The basic structure of cell
membranes is the lipid
bilayer, composed of two
opposing leaflets and
proteins.
 Plasma Membrane

Membrane Composition:

Different membranes have varying
percentages of lipids and proteins.
Intracellular membranes may have a
higher percentage of proteins than do
plasma membranes, presumably because
most enzymatic activity occurs within
organelles.
 Plasma Membrane
Membrane Composition:
The membrane organization is achieved
through noncovalent bonds that allow
different physical states called phases
(solid gel, fluid liquid–crystalline, and
liquid-ordered).
These phases can change under physiologic factors, such as
temperature and pressure fluctuations.
Carbohydrates are mainly associated with plasma membranes, in
which they are chemically combined with lipids, forming glycolipids,
and with proteins, forming glycoproteins
 Plasma Membrane
Membrane Composition:
The outer surface of the plasma
membrane in many types of cells, is
not smooth but dimpled with flask-
shaped invaginations known as
caveolae (“tiny caves”).
Caveolae are thought to
serve as a storage site for many receptors,
provide a route for transport into the cell and
may act as the initiator for relaying signals from several
extracellular chemical messengers into the cell's interior.
 Membrane Composition
Lipids:
Each lipid molecule is said to be
polar, or amphipathic, which means
that one part is hydrophobic
(uncharged, or “water hating”) and
another part is hydrophilic (charged,
or “water loving”).
The membrane spontaneously organizes itself into two layers
because of these two incompatible solubilities.
The hydrophobic region (hydrophobic tail) of each lipid molecule
is protected from water, whereas the hydrophilic region
(hydrophilic head) is immersed in it.
 We make cool things with
Liposome

A suspension of phospholipids
(glycerophospholipids or sphingomyelins).
Closed, self-sealing solvent-filled vesicles
that are bounded by only a single bilayer.
Serve as models of biological membranes.
Hold promise as vehicles for drug delivery
since they are absorbed by many cells
through fusion with the plasma membrane
 Membrane Composition
Lipids:
The bilayer serves as a barrier to the
diffusion of water and hydrophilic
substances, while allowing lipid-soluble
molecules, such as oxygen (O2) and carbon
dioxide (CO2), to diffuse through the
membrane readily.
A major component of the plasma membrane is a bilayer of lipid
molecules—
glycerophospholipids,
sphingolipids, and
sterols (e.g., cholesterol).
 Membrane Composition

Lipids:
The most abundant lipids are phospholipids.
Phospholipids have a phosphate-containing
hydrophilic head connected to a
hydrophobic tail.
Phospholipids and glycolipids form self-
sealing lipid bilayers.
Lipids along with protein assemblies act as
“molecular glue” for the structural integrity of
the membrane.
 Membrane proteins
associate with the lipid
bilayer in different ways

Proteins:
A. Transmembrane proteins that extend across the bilayer and exposed
to an aqueous environment on both sides of the membrane.
B. Proteins are located almost entirely in the cytosol and associated with
the cytosolic half of the lipid bilayer.
C. Proteins that exist outside the bilayer and are attached to the
membrane by one or more covalently attached lipid groups.
D. Proteins are bound indirectly to one or the other bilayer membrane
face and held in place by their interactions with other proteins.
 Membrane Composition

Proteins:
Proteins directly attached to the membrane
bilayer can be removed by dissolving the
bilayer with detergents called integral
membrane proteins.
The remaining proteins that can be removed by gentler procedures
that interfere with protein–protein interactions but do not dissolve the
bilayer are known as peripheral membrane proteins.
Proteins exist in densely folded molecular configurations rather than
straight chains; thus most hydrophilic units are at the surface of the
molecule, and most hydrophobic units are inside.
 Endoplasmic Reticulum, Protein Folding, and
Endoplasmic Reticulum Stress

Protein folding in the endoplasmic reticulum (ER) is critical for
humans.
Most secreted proteins fold and are modified in an error-free
manner, but ER or cell stress, mutations, or random (stochastic)
errors during protein synthesis can decrease the folding amount or
the rate of folding.
Pathophysiologic processes, such as viral infections, environmental
toxins, and mutant protein expression, can perturb the sensitive ER
environment.
 Endoplasmic Reticulum, Protein Folding, and
Endoplasmic Reticulum Stress

These perturbations cause the accumulation of immature and
abnormal proteins in cells, leading to ER stress.
Fortunately, the ER is loaded with protective ways to help folding,
for example, protein so-called chaperones that facilitate folding and
prevent the formation of off-pathway types.
Misfolded proteins not repaired in the ER are observed in some
diseases and can initiate apoptosis, or cell death.
Specific diseases include Alzheimer’s disease, Parkinson’s disease, prion
disease, amyotrophic lateral sclerosis, diabetes mellitus, and sepsis.
 The functions of membrane proteins
Recognition and binding units (receptors) for substances moving into
and out of the cell
Pores or transport channels for various electrically charged particles.
Specific enzymes that drive active pumps to maintain the
concentration of certain ions against its concentration gradient (Na/K)
Cell surface markers, such as glycoproteins which identify a cell to its
neighbor
Cell adhesion molecules (CAMs), or proteins that allow cells to hook
together and form attachments of the cytoskeleton for maintaining
cellular shape (makes cells stronger)
Catalysts of chemical reactions (e.g., conversion of lactose to glucose
 Protein regulation in a cell: proteostasis
The cellular protein pool is in constant change or flux.
Proteostasis is a state of cell balance of the processes of protein
synthesis, folding, and dehydration. It is vital to health.
This adaptable system depends on how quickly proteins are made,
how long they survive, or when they are broken down.
The proteostasis network comprises:
ribosomes (makers); *protein synthesized by ribosomes*
chaperones (helpers); and
two protein breakdown systems or proteolytic systems—
Lysosomes *digests proteins* and
the ubiquitin–proteasome system (UPS).
 Protein regulation in a cell: proteostasis
These systems regulate protein
homeostasis under a large variety of
conditions, including variations in
nutrient supply, the existence of
oxidative stress or cellular
differentiation, changes in
temperature, and the presence of
heavy metal ions and other sources
of stress.
Malfunction or failure of the proteostasis network is
associated with human diseases.
 Membrane Composition

Carbohydrates:
The short chains of carbohydrates
contained within the plasma membrane
are mostly bound to membrane proteins
(glycoproteins) and lipids (glycolipids).
Long polysaccharide chains attached to membrane proteins are
called proteoglycans.
All of the carbohydrate on the glycoproteins, proteoglycans, and
glycolipids is located on the outside of the plasma membrane
and the carbohydrate coating is called the glycocalyx.
 The function of membrane carbohydrates
The glycocalyx helps protect the cell from mechanical damage.
Lubrication that assists the mobility of other cells, such as
leukocytes, to squeeze through the narrow spaces.
specific cell-to-cell recognition and adhesion. *FUNCTION OF CARB*
Intercellular recognition is an important function of membrane
oligosaccharides; for example, the transmembrane proteins
called lectins, which bind to a particular oligosaccharide,
recognize neutrophils at the site of bacterial infection.
This recognition allows the neutrophil to adhere to the blood
vessel wall and migrate from the blood into the infected tissue to
help eliminate the invading bacteria.
 Cellular adaptation

Cells adapt to their environment to avoid injury.
An adapted cell is neither normal nor injured; its status falls
somewhere between these two states.
Adaptations are reversible changes affecting the size,
number, phenotype, metabolic activity, or function of cells.
Adaptive responses have limits; additional stress can
compromise essential cell functions leading to cell injury or
death.
 Cellular adaptation
The most significant adaptive changes in cells
include the following:
Atrophy—decrease in cell size
Hypertrophy—increase in cell size
Hyperplasia—increase in cell number
Metaplasia—reversible replacement of one mature
cell type by another, less mature cell type or a
change in cell phenotype
Dysplasia—or deranged cellular growth, is not
considered a true cellular adaptation but rather an
atypical hyperplasia
 Cellular adaptation
Physiologic atrophy:
During childhood, the thymus decreases in size.
Age-related atrophic changes to the gonads occur
secondary to decreases in hormonal stimulation
Pathologic atrophy to muscle will occur when a limb is placed
in a cast. This form of atrophy, known as disuse atrophy, also
occurs with prolonged bed rest or other immobilization.
Physiological hypertrophy: is enlargement secondary to
aerobic exercise or a “runner's heart.”
Pathological hypertrophy: LVH occurs secondary to
hypertension.
 Cellular adaptation
Two types of physiologic (normal) hyperplasia occur: compensatory
hyperplasia and hormonal hyperplasia:
Compensatory hyperplasia: If the cancerous region of the liver is
removed, the remaining cells will undergo hyperplasia.
Hormonal hyperplasia occurs in organs that respond to endocrine
hormonal stimulation.
Physiologic hormonal hyperplasia: during the follicular phase
of the menstrual cycle, estrogen secretion by the ovary results
in hyperplasia and endometrial proliferation
Pathologic hormonal hyperplasia: the endometrial changes
that are due to hormonal imbalances.
 Cellular adaptation

The most significant adaptive changes in cells
include the following:
Dysplasia: An abnormal changes in the shape
and organization of cervical cells.
Metaplasia: In smoker the stratified squamous
epithelial cells replace the normal columnar
ciliated cells.
 Cellular injury

Injury to cells and the extracellular matrix (ECM) leads to
injury of tissues and organs and ultimately determines the
structural patterns of disease.
Cellular injury occurs when the cell is unable to maintain
homeostasis.
The injury may be reversible (the cell can recover) or
irreversible (cellular death).
Loss of function results from cell and ECM injury and cell
death.
Table 1. Types of progressive cell injury and responses

Type Responses
Adaptation Atrophy, hypertrophy, hyperplasia, metaplasia
Active cell injury Immediate response of “entire” cell
Reversible Loss of ATP, cellular swelling, detachment of ribosomes, autophagy of lysosomes
Irreversible “Point of no return” structurally when severe vacuolization of mitochondria occurs
and Ca++ moves into the cell
Necrosis Common type of cell death with severe cell swelling and breakdown of organelles
Apoptosis, or programmed Cellular self-destruction for elimination of unwanted cell populations
cell death
Autophagy Eating of self, cytoplasmic vesicles engulf cytoplasm and organelles, recycling
factory
Chronic cell injury Persistent stimuli response may involve only specific organelles or cytoskeleton
(subcellular alterations) (e.g., phagocytosis of bacteria)
Accumulations or Water, pigments, lipids, glycogen, proteins
infiltrations
Pathologic calcification Dystrophic and metastatic calcification
 Cellular injury
Cellular injury may occur secondary to a variety of factors:
Chemical agents,
Lack of sufficient oxygen (hypoxia),
Free radicals,
Infectious agents,
Physical and mechanical factors,
Immunologic reactions,
Genetic factors, and
Nutritional imbalances.
 Cellular injury

The extent of the cellular injury is a function of cell type,
level of differentiation, and adaptive mechanisms of the
cell.
Also important is the nature, severity, and duration of the
injury.
Fully differentiated, mature cells are more susceptible to
injury than are cell precursors.
 Cellular injury

Stages of cellular adaptation, injury, and death
The normal cell responds to physiologic and
pathologic stresses by adapting (atrophy,
hypertrophy, hyperplasia, metaplasia).
Cell injury occurs if the adaptive responses are exceeded or
compromised by injurious agents, stress, and mutations.
The injury is reversible if it is mild or transient, but if the
stimulus persists, the cell suffers irreversible injury and
eventually death.
 Cellular injury

Two individuals exposed to an identical stimulus may incur
varying degrees of cellular injury.
Individual differences, including genetics, nutritional
status, and immunologic competency, can profoundly
influence the extent of cell injury.
The precise “point of no return” with respect to cell death
remains unclear.
Once changes to the nucleus have occurred or cell
membranes are disrupted, or both, irreversible injury and
cell death are inevitable.
 Cellular injury
General mechanisms of cell injury
Regardless of the cause of injury, a host of biochemical
events result in cell injury and death.
Such events include;
Adenosine triphosphate (ATP) depletion,
Damage from oxygen-derived free radicals, and
Alterations in calcium level.
Injury to cell components includes;
Membrane damage,
Protein folding defects,
Mitochondrial compromise, and
DNA damage.
Table 2. Common themes in cell injury and cell death.

Theme Comments
ATP depletion Loss of mitochondrial ATP and decreased ATP synthesis; results include cellular
swelling, decreased protein synthesis, decreased membrane transport, and lipogenesis,
all changes that contribute to loss of integrity of plasma membrane
Reactive oxygen Lack of oxygen is key in the progression of cell injury in ischemia; activated oxygen
species (↑ROS) species (Superoxide, H2O2, OH−) destroy cell membranes and structure.
Ca++ entry Normally intracellular cytosolic calcium concentrations are very low; ischemia and certain
chemicals cause an increase in cytosolic Ca++ concentrations; sustained levels of Ca++
continue to increase with damage to plasma membrane; Ca++ causes intracellular
damage by activating many enzymes
Mitochondrial It can be damaged by increases in cytosolic Ca++, ROS; two outcomes of mitochondrial
damage damage are loss of membrane potential, which causes depletion of ATP and eventual
death or necrosis of cell, and activation of another type of cell death (apoptosis)
Membrane damage Early loss of selective membrane permeability found in all forms of cell injury, lysosomal
membrane damage with release of enzymes causing cellular digestion
Protein misfolding, Proteins may misfold, triggering unfolded protein response that activates corrective
DNA damage responses; if overwhelmed, response activates cell suicide program or apoptosis; DNA
damage (genotoxic stress) also can activate apoptosis
 Cellular injury

The most common forms of cell injury include
(1) ischemic and hypoxic injury,
(2) ischemia-reperfusion injury,
(3) oxidative stress or accumulation of oxygen-
derived free radicals-induced injury, and
(4) chemical injury.
 Cellular injury
Ischemic and hypoxic injury
Hypoxia, the lack of sufficient oxygen within cells, is the most
common cause of cellular injury.
Hypoxia can result from many circumstances, such as;
Reduced oxygen content in the ambient air,
Loss of hemoglobin,
Decreased red blood cell (RBC) production,
Respiratory and cardiovascular diseases, and
Poisoning of the cellular oxidative enzymes (cytochromes).
 Cellular injury

Ischemic and hypoxic injury
Hypoxia negatively impacts
normal physiologic processes:
differentiation, angiogenesis,
proliferation, erythropoiesis, and
overall cell viability.
 Ischemic and hypoxic injury

The role of reactive oxygen species (ROS) in cell injury

Mitochondria are the
primary consumers of
oxygen.
Hypoxia triggers the
mitochondrial complex to
produce reactive oxygen
species (ROS).
ROS can promote oxidative stress, which can damage cells
(Adapted from Kumar V et al, editors: Robbins and Cotran pathologic basis of disease, ed 9, Philadelphia, 2015, Elsevier.)
 Cellular injury
Ischemic and hypoxic injury
Arteriosclerosis and thrombus can result in localized tissue
ischemia.
Progressive hypoxia, caused by gradual arterial narrowing,
is better tolerated than acute anoxia caused by an acute
obstruction or a thrombus.
An acute obstruction in a coronary artery can result in a
rapidly evolving myocardial infarction (“heart attack”) if the
blood supply is not restored.
Gradual onset of ischemia, however, usually results in
myocardial adaptation.
 Cellular injury

Ischemic and hypoxic injury
Ischemia-induced reduction in ATP levels
causes a failure of the plasma
membrane's sodium–potassium (Na+-K+)
pump and sodium–calcium (Na+-Ca++)
exchange mechanisms.
Sodium and calcium influx into and accumulate in the cell.
Potassium (K+) diffuses out of the cell.
Without the pump mechanism, sodium and water can freely enter
the cell resulting in cellular swelling and dilation of the ER.
 Cellular injury
Ischemic and hypoxic injury
With dilation, ribosomes detach from the rough ER, reducing
protein synthesis.
If hypoxia persists, the entire cell becomes markedly
swollen.
These disruptions are reversible if oxygen (O2) is restored.
If oxygen is not restored, vacuolation occurs within the
cytoplasm.
The damaged outer membrane causes lysosomes to swell;
marked swelling occurs to the mitochondria.
 Cellular injury

Ischemic and hypoxic injury
With continued hypoxia, cell death
rapidly follows as calcium
accumulates within the cell, essential
metabolic processes cease, and cell
membranes become dysfunctional.
Influx of calcium into the cell activates enzymes that trigger
apoptosis.
Restoration of blood flow and oxygen can result in an additional
injury known as ischemia–reperfusion injury.
 Cellular injury

Ischemia-reperfusion injury
Restoration of blood flow and oxygen to
ischemic tissues can increase recovery of
cells reversibly injured, but paradoxically
result in an additional injury known as
ischemia–reperfusion injury and cause
cell death.
Reperfusion is a serious complication and an important
mechanism of injury in instances of tissue transplantation and
other ischemic syndromes (e.g., hepatic, intestinal, renal).
Redrawn from Damjanov I: Pathology for the health professions, ed 3, St Louis, 2006, Saunders.
 Cellular injury
Several mechanisms are proposed for reperfusion injury, including
the following:
Oxidative stress: Reoxygenation induces oxidative stress by
generating high ROS and nitrogen species.
Increased intracellular calcium concentration: Intracellular and
mitochondrial calcium accumulates within the cell during acute
ischemia.
Inflammation: Ischemic injury promotes inflammation. Dead cells
stimulate immune cells to release cytokine-mediated danger
signals, thus initiating an inflammatory response.
Complement activation: Complement activation may exacerbate
damage that has occurred secondary to reperfusion injury.
 Cellular injury

Free radicals and reactive oxygen species—oxidative stress
Free radicals are an important mechanism of cellular injury,
especially injury caused by ROS.
This form of injury is called oxidative stress.
Reactive oxygen species (ROS) are reactive molecules
from molecular oxygen formed as a natural oxidant species
in cells during mitochondrial respiration and energy
generation.
Oxidative stress is caused by increased reactive species,
depletion of antioxidant defense, or both.
 Cellular injury
Free radicals and reactive oxygen species—oxidative stress
Oxidative stress results in the detrimental oxidation of different
molecules, including proteins, lipids, nucleic acids, and others.
Oxidative stress can activate several intracellular signaling
pathways because ROS can regulate enzymes and
transcription factors.
Free radicals are generated in a variety of conditions,
including;
chemical and radiation injury,
ischemia–reperfusion injury,
cellular aging, and
microbial destruction by phagocytes.
 Cellular injury
Free radicals and reactive oxygen species—oxidative stress
A free radical is an electrically uncharged atom or group of
atoms with an unpaired electron.
Having one unpaired electron makes the molecule unstable;
the molecule becomes stabilized either by donating or by
accepting an electron from another molecule.
The free radical has the potential to form a damaging chemical
bond with proteins, lipids, and carbohydrates found within the
cell membrane.
Free radicals are highly reactive. They have low chemical
specificity—that is, they can react with most molecules in their
proximity.
 Cellular injury
Free radicals also cause several damaging effects, such as the
following:
1. Lipid peroxidation—the destruction of polyunsaturated
lipids, which leads to membrane damage and increased
permeability.
2. Protein alteration—a process whereby polypeptide chains
become fragmented, leading to protein loss, protein
misfolding, and alters protein–protein interaction.
3. DNA damage—results in mutations.
4. Mitochondrial effects—mitochondria can become damaged
by ROS, compromising available energy for the cell.
 Cellular injury
Free radicals and reactive oxygen species—oxidative stress
The toxicity of certain drugs and chemicals can be attributed
to free radicals.
The drug/chemical may be converted to a free radical or it
may generate oxygen-derived metabolites.
Free radicals have been either directly or indirectly linked with
a growing number of diseases and disorders:
Atherosclerosis, diabetes, cataract,
Ischemic brain injury,
Reduced cognitive performance (Alzheimer’s disease), and
Cancer
 Cellular injury

Free radicals and reactive oxygen species—oxidative stress
The body has various mechanisms to eliminate free radicals.
As an example, the oxygen free radical superoxide may
spontaneously decay into oxygen and hydrogen peroxide.
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Method Process
Antioxidants Endogenous or exogenous; either blocks synthesis or inactivates (e.g., scavenges)
free radicals; includes vitamin E, vitamin C, cysteine, glutathione, albumin,
ceruloplasmin, transferrin, γ-lipoacid, others
Enzymes Superoxide dismutase, which converts superoxide to hydrogen peroxide (H2O2);
Catalase (in peroxisomes) decomposes H2O2;
Glutathione peroxidase decomposes hydroxyl radical (OH−) and H2O2
 Cellular injury

Chemical or toxic injury
Mechanisms of cell stress from chemical agents
include oxidative stress, ER stress, heat shock
response, DNA damage response, mental stress,
inflammation, and osmotic stress.
Chemicals are classified under these types of cell
stress mechanisms.
Xenobiotics (from Greek Xenos, “foreign”; bios,
“life”) are compounds and chemicals that have
toxic, mutagenic, or carcinogenic properties.
 Cellular injury
Chemical or toxic injury
Many xenobiotics are hepatotoxic.
The liver is the initial contact site for many ingested
compounds—xenobiotics, drugs, and alcohol—
predisposing this organ to chemically induced injury.
Many chemical compounds used in household
cleaning, insect control, outdoor maintenance, or
chemical manufacturing are potential carcinogens.
The extent of chemically induced liver injury varies
from minor liver injury to acute liver failure, cirrhosis,
and liver cancer.
 Cellular injury

Chemical or toxic injury
Hepatic detoxification occurs through enzyme-mediated
biotransformation and antioxidant systems.
Biotransformation is a process whereby enzymatic
reactions convert one chemical into a less toxic or nontoxic
compound.
The liver has the highest supply of biotransformation
enzymes of all organs and plays a key role in protecting
the host from chemical toxicity.
 Cellular injury
Antioxidants
Antioxidants are molecules that inhibit the oxidation of other
molecules, thereby preventing the formation of free radicals.
Antioxidants often terminate a chain reaction, which would
otherwise result in free radical formation.
Endogenous antioxidants are antioxidants produced by the
body:
Superoxide dismutase (SOD),
Alpha lipoic acid (ALA),
Catalase,
Coenzyme Q 10 (CoQ10), and
Glutathione peroxidase (GPX).
 Cellular injury
Chemical agents, including drugs
Numerous chemical agents cause cellular injury.
Minute amounts of some, such as arsenic and cyanide, can rapidly
destroy cells and cause individual death.
Chronic exposure to air pollutants, insecticides, and herbicides can
cause cell injury.
CCl4, alcohol, and social drugs can significantly alter cellular function
and injure cellular structures.
Over-the-counter (OTC) and prescribed drugs are important causes
of cellular injury.
The abuse and addiction to opioids, such as heroin, morphine,
fentanyl, and other prescription pain relievers, are a serious global
problem that affects all societies.
 Cellular injury
Infectious Injury
The pathogenicity (virulence) of microorganisms lies in
their ability to survive and proliferate within the host.
The disease-producing potential of a microorganism is a
function of its ability to
(1) invade and destroy cells,
(2) produce toxins, and
(3) produce damaging hypersensitivity reactions.
 Cellular injury
Immunologic and inflammatory injury
Cellular membranes are injured as a result of direct contact with
immune or inflammatory-mediated responses, such as
phagocytes and biochemical substances generated during an
inflammatory response.
Potentially injurious biochemical agents include;
Histamine,
Antibodies,
Lymphokines,
Complement system products, and
Proteases.
 Cellular injury

Immunologic and inflammatory injury
The complement system is responsible for several
membrane alterations associated with immunologic injury.
Membrane alterations can facilitate a rapid leakage of
potassium out of the cell, along with an influx of water.
Antibodies can bind and occupy receptor molecules on
the plasma membrane, interfering with its function.
Antibodies also can block or destroy cellular junctions,
obstructing intercellular communication.
 Cellular death

With sufficient structural or physiologic damage,
cell injury becomes irreversible and cells die.
Historically, cell death has been attributed to
either necrosis or apoptosis.
 Cellular death
Necrosis
Necrosis is the sum of cellular changes
occurring after local cell death.
It is characterized by autolysis or autodigestion,
a cellular self-digestion process.
Cellular death is initiated long before any
necrotic changes can be detected by light
microscopy.
Dense clumping of nuclear material and the
progressive disruption of plasma and organelle
membranes portend irreversible injury, and
necrosis follows.
Cellular death Necrosis
As membrane integrity is lost, necrotic cell
contents leak into the surrounding intracellular
spaces, triggering an inflammatory response
within the tissue.
In the later stages of necrosis, when most
organelles are disrupted, karyolysis (dissolution)
occur.
Pyknosis, a process where the nucleus shrinks
into a small, dense mass of genetic material,
occurs. Eventually, lysosomal enzymes break up
the pyknotic nucleus called karyorrhexis.
Karyorrhexis is the fragmentation of the nucleus
into small particles or “nuclear dust.”
 Cellular death
Coa

Apoptosis
Apoptosis is an active process
of cellular self-destruction,
resulting in programmed cell
death.
It has been implicated in both
normal and pathologic tissue
changes.
Cells die as a part of a normal
physiologic process.
 Cellular death
Apoptosis
Death by apoptosis also causes loss of cells in
many pathologic states, including the following:
Severe cell injury: When cell injury exceeds
the capacity for repair mechanisms, cell
signaling triggers apoptosis.
Accumulation of misfolded proteins: This
condition results from either genetic
mutations or free radicals.
 Cellular death
Coa

Apoptosis
Death by apoptosis also causes loss of cells in
many pathologic states, including the following:
Infections: Apoptosis may result from the host's
immune response to the presence of a virus
infecting the cell.
Obstruction in tissue ducts: Obstruction of
blood flow to the organ results in pathologic
atrophy, commonly noted in the pancreas,
kidney, or parotid gland.
 Cellular death
Table 4. Features of necrosis and apoptosis.

Feature Necrosis Apoptosis
Cell size Enlarged (swelling) Reduced (shrinkage)
Nucleus Pyknosis → karyorrhexis Fragmentation into nucleosome-size
→ karyolysis fragments
Plasma membrane Disrupted Intact; altered structure, especially orientation
of lipids
Cellular contents Enzymatic digestion; may Intact; may be released in apoptotic bodies
leak out of cell
Adjacent Frequent No
inflammation
Physiologic or Invariably pathologic Often physiologic, means of eliminating
pathologic role (culmination of irreversible unwanted cells; may be pathologic after some
cell injury) forms of cell injury, especially
deoxyribonucleic acid (DNA) damage
 Cellular death
Apoptosis
Accumulation of misfolded proteins:
Excessive accumulation of misfolded proteins in the ER leads
to a condition known as endoplasmic reticulum stress (ER
stress).
ER stress culminates in cell death secondary to apoptosis.
This mechanism has been linked to several degenerative
diseases of the CNS and other organs.
Amyotrophic lateral sclerosis (ALS), multiple sclerosis
(MS), Parkinson's disease, Alzheimer's disease, and
Huntington's.
 Cellular death
The unfolded protein response, endoplasmic stress, and apoptosis.
 Cellular death
Apoptosis
Initiation of apoptosis requires tightly regulated cell signaling.
Key components involve proteases, enzymes that divide other
proteins.
Caspases are a family of aspartic acid–specific enzymes that
trigger proteolytic activity in response to signals, which induce
apoptosis.
Specifically, activated caspases cleave other proteins within the
system, initiating a series of sequential reactions known as the
“suicide” cascade.
 Cellular death

Apoptosis
The cascade results in rapid and contained cell
death.
Cells undergoing apoptosis release chemical
factors, which recruit phagocytes.
The phagocytes quickly engulf cellular
remnants, reducing their potential to induce
damaging inflammation.
 Cellular death
Coagu

Apoptosis

Caspase activation triggers two
different but convergent pathways:
the mitochondrial (intrinsic)
pathway and
the death receptor (extrinsic)
pathway.
 Cellular death

Manifestations of cellular injury
Cellular Manifestations: Accumulations
Metabolic disturbances can result from cell
injury, particularly where there is an
excessive intracellular accumulation of
biochemical substances.
Most accumulations result from four types of
mechanisms,
 Cellular death
Most accumulations result from four types of mechanisms:
Insufficient removal of the normal substance because of altered
configuration or transport. Example: steatosis, fatty changes in the
liver.
Accumulation of abnormal substance because of defects in protein
folding, transport, or abnormal degradation. Such occurrences are
usually secondary to gene mutation.
Inadequate metabolism of an endogenous substance, usually
because of a lack of a lysosomal enzyme. Example: storage diseases.
Harmful exogenous materials. Example: heavy metals and mineral
dust inhalation and ingestion or the presence of pathogenic
microorganisms.
Cellular death
Coagulative necrosis

Manifestations
of cellular injury
 Cellular death
Autophagy
The Greek term autophagy means “eating of self.” Autophagy is
a “recycling factory” as well as a survival mechanism.
It is a self-destructive process that delivers cytoplasmic contents
to the lysosome for degradation.
When cells are starved or nutrient deprived, autophagy initiates
a “cannibalization response,” which digests the cell and recycles
the contents.
Autophagy can maintain cellular metabolism under conditions of
starvation.
Under conditions of stress, autophagy removes damaged
organelles, thus enhancing the likelihood of survival.
 Cellular death
Autophagy
Autophagy holds promise for formulating new therapeutic
strategies in treating disease.
Evidence also suggests that autophagy may be the last immune
defense against infectious microorganisms that have invaded
the intracellular environment.
The “garbage collecting” and recycling functions, characterizing
autophagy, becomes less efficient and less discriminating in
aging individuals.
Consequently, harmful agents accumulate and cause increased
cell damage as people age.
 Cellular death

Autophagy
Failure to clear protein products in neurons of the CNS
has been linked with dementia.
Similarly, failure to clear mitochondria, which generates
ROS, can lead to nuclear DNA mutations and cancer.
These processes may even partially define normal aging.
Enhancing autophagy may decrease cancer incidence
and prevent the development of particular degenerative
diseases.