Lecture 1 - Cell injury and death 2023 - Tagged.pdf

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Cellular Injury &
Death
The Basis of
All Pathology
Andrew J Gow
[email protected]

Physiology vs Pathology

• Physiology is the study of the physical
(often termed natural philosophy)
• Pathology is the study of suffering (often
considered the disease discipline)
• Pathophysiology is the study of the
nature of suffering

Growth in Pathology and Physiology

Concentric and Eccentric Hypertrophy

Complex Function in Pathology and Physiology

Pathology
• Etiology
– Origin of
disease (Why)

• Pathogenesis
– Development of
disease (How)

Injury and Death are a Continuum

Apoptosis vs Necrosis
Necrosis

Apoptosis

Cell size

Enlarged (swelling)

Nucleus

Pyknosis → karyorrhexis
→ karyolysis

Reduced (shrinkage)
Fragmentation into
nucleosome-sized
fragments

Plasma membrane

Disrupted

Cellular contents

Enzymatic digestion; may Intact; may be released in
leak out of cell
apoptotic bodies

Adjacent inflammation

Frequent

Absent

Physiologic or pathologic
role

Invariably pathologic
(culmination of
irreversible cell injury)

Often physiologic; means
of eliminating
unnecessary cells; may be
pathologic

Intact; altered structure,
especially orientation of
lipids

Injury and Death are a Continuum

Etiology of Cellular
Death
•
•
•
•
•

Causative agent
Target within the cell
Intrinsic vs Extrinsic factors
Accumulation of error
Imbalance

Causative Agent Affects Death Pathway

Cellular Injury and Necrosis
• Cycle of injury and response
• Energy requiring
• Stimulus exceeds response
leads to death
• Programmed vs Unprogrammed
• Protein Synthesis???

Nuclear Changes in Necrosis
• Chromatin
condensation
• Nuclear
fragmentation
• Nucelar dissolution

Apoptosis
Condition
Physiologic

Mechanism of Apoptosis

During embryogenesis

Loss of growth factor signaling
(presumed mechanism)

Turnover of proliferative tissues
(e.g., intestinal epithelium,
lymphocytes in lymph nodes and
thymus)

Loss of growth factor signaling or
survival signals (presumed
mechanism)

Involution of hormone-dependent
tissues (e.g., endometrium)

Decreased hormone levels lead to
reduced survival signals

Decline of leukocyte numbers at the
end of immune and inflammatory
responses

Loss of survival signals as stimulus for
leukocyte activation is eliminated

Strong recognition of self antigens
Elimination of potentially harmful self- induces apoptosis by both the
reactive lymphocytes
mitochondrial and death receptor
pathways

Pathologic
DNA damage

Activation of proapoptotic BH3-only
proteins

Accumulation of misfolded proteins

Activation of proapoptotic BH3-only
proteins, possibly direct activation of
caspases

Infections, especially certain viral
infections

Activation of proapoptotic proteins or
caspases by viral proteins; killing of
infected cells by cytotoxic T
lymphocytes (CTLs), which activate
caspases

Apoptosis

• Intrinsic and
Extrinsic pathways
• Calcium and
Cytochrome c
• BCL genes
• Phosphorylation
required
• Protein synthesis
required

Autophagy
• Cellular response to
nutrient stress
• Cellular recycling
• Energetic process
• Requires protein synthesis

Initiating Events
• Loss of membrane integrity
• Oxidative stress

STRES

–Energetic imbalance

• Hypoxia
• Ischemia
• Cellular overload
–Accumulation

• Ageing and failure to maintain

Membrane Integrity

ER Stress Response

• Mistakes happen
– Leads to misfolded proteins
• ER source of protein synthesis
– Senses Misfolds
• Low level
– UPR

• Excess leads BH-3 activation
– Caspase activation
– Apoptosis
• CFTR, Hypercholesteremia (LDL-R)

Proteasome Function and Unfolded Proteins
•
•
•

•

Proteasome proteolyses
ubiquitinated substrates
It is an endopeptidase complex
that can be compared to a ‘trash
can’
Undegradable protein
aggregates play a role in a
number of neurodegenerative
diseases
–
–

Polyglutamine repeats
Parkin

Uncleavable aggregates lead to
cellular dysfunction and death

Oxidative Stress

•
•
•
•

Production of Reactive Oxygen Species (ROS)
– Fact of Life
Oxidative modifications is key (Free radicals????)
Reperfusion injury
Superoxide, Hydrogen peroxide, Hydroxy radical, Peroxynitrite
–

Nitric Oxide Synthase, NADPH Oxidase, Mitochondrial Respiration

Hypoxia & Ischemia
• Hypoxia

– Low oxygen level
– Reduces metabolic
capacity

• Ischemia
– Loss of flow
– Low oxygen, low supplies,
low waste removal

• Excess Injury

Accumulation of
Material

Cellular Ageing

Stem vs Somatic Cells

Summary of Mechanisms of Cell Injury

•
•
•
•
•

•

Mitochondrial damage and increased permeability of cellular membranes
are often late events in cell injury and necrosis from different causes.
Oxidative stress refers to accumulation of ROS, which can damage cellular
lipids, proteins, and DNA and is associated with numerous initiating causes.
ER stress: Protein misfolding depletes essential proteins and, if the
misfolded proteins accumulate within cells, triggers apoptosis.
DNA damage, e.g., by radiation, can also induce apoptosis if it is not
repaired.
Hypoxia and ischemia lead to ATP depletion and failure of many energydependent functions, resulting first in reversible injury and, if not
corrected, necrosis.
In ischemia-reperfusion injury, restoration of blood flow to an ischemic
tissue exacerbates damage by increasing production of ROS and by
increasing inflammation.

Response to Cell Death

Metaplasia
• Growth of other
• Death of somatic cells
leads to replacement
• Different from Dysplasia
– Mature vs immature

Hyperplasia

Inflammatory Lipid Signaling

Inflammation as Repair

Ischemia &
Excitotoxicity:
Keys to
Neuronal Loss