Cellular Adaptations - Shape Shifters
Cells adapt to stress by altering size, number, or phenotype. These are reversible changes.
| Adaptation | Definition | Mechanism Highlights | Examples |
|---|---|---|---|
| Hypertrophy | ↑ cell size | ↑ protein synthesis, ↑ organelles | Cardiac muscle (LVH in hypertension), skeletal muscle (exercise) |
| Hyperplasia | ↑ cell number | Growth factor-driven proliferation of mature/stem cells | Benign Prostatic Hyperplasia (BPH), endometrial hyperplasia, calluses |
| Atrophy | ↓ cell size/number (due to loss of cell substance) | ↓ protein synthesis, ↑ protein degradation (ubiquitin-proteasome) | Disuse atrophy, denervation atrophy, senile atrophy, ↓ blood supply |
| Metaplasia | Reversible change: one adult cell type to another | Reprogramming of stem cells, altered differentiation pathway | Barrett's esophagus (squamous to columnar), squamous metaplasia in bronchi |
⭐ Barrett's esophagus (intestinal metaplasia in the distal esophagus due to chronic GERD) significantly ↑ risk of esophageal adenocarcinoma.
Cell Injury Mechanisms - Damage Control
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Cellular response to stress, if overwhelmed, leads to injury. Key players:
- Mitochondria: ATP depletion (↓5-10% of normal → irreversible), ROS ($O_2^{\cdot-}$, $H_2O_2$, $\cdot OH$) production.
- Calcium homeostasis: ↑ cytosolic $Ca^{2+}$ activates damaging enzymes (phospholipases, proteases, endonucleases, ATPases).
- Membrane integrity: Damage to plasma & organellar membranes is crucial.
- DNA & protein damage: Misfolded proteins, DNA damage.
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Reversible Injury: Cellular swelling, fatty change, plasma membrane blebbing, loss of microvilli, mitochondrial swelling, ER dilation, ribosome detachment, nuclear chromatin clumping.
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Irreversible Injury: Severe mitochondrial damage (vacuolization), profound membrane damage (plasma, lysosomal), nuclear changes (pyknosis → karyorrhexis → karyolysis).
- Point of no return: Irreversible mitochondrial dysfunction, critical membrane damage.
⭐ Plasma membrane damage is a critical event in irreversible cell injury, leading to enzyme leakage (e.g., troponins, CK-MB) and $Ca^{2+}$ influx.
- Free radical injury: Lipid peroxidation, protein modification, DNA damage. Neutralized by antioxidants (e.g., SOD, catalase, glutathione peroxidase).
Necrosis vs. Apoptosis - Deathly Duo
Key Differences:
| Feature | Necrosis | Apoptosis |
|---|---|---|
| Nature | Pathologic; acute injury | Programmed (physiologic/pathologic) |
| Cell Size | Swelling (oncosis) | Shrinkage |
| Nucleus | Pyknosis, karyorrhexis, karyolysis | Chromatin condensation, fragmentation |
| Plasma Membrane | Disrupted, contents leak | Intact, blebbing; PS flip |
| Cellular Contents | Enzymatic digestion, uncontrolled release | Packaged into apoptotic bodies |
| Inflammation | Significant | Absent; bodies phagocytosed |
| ATP | Depleted | Required (energy-dependent) |
| DNA Breakdown | Random, diffuse | Internucleosomal cleavage (laddering) |
| Key Mediators | Lysosomal enzymes, ROS, $Ca^{2+}## Necrosis vs. Apoptosis - Deathly Duo |
Key Differences:
influx | Caspases (initiator & executioner) |* Necrosis: Uncontrolled "cell homicide" from severe injury (e.g., ischemia). Pathologic, causes inflammation. - Types: Coagulative, Liquefactive, Caseous, Fat, Fibrinoid, Gangrenous. (📌 Mnemonic: Can Lazy Cats Feel Good Frequently?)
- Apoptosis: Regulated "cell suicide." Physiologic (embryogenesis) or pathologic (DNA damage). No inflammation.
- Forms apoptotic bodies, phagocytosed. Key enzymes: Caspases.
⭐ Caspases (Cysteine-dependent Aspartate-directed proteases) are the central executioners of apoptosis. Initiator caspases (e.g., -8, -9) activate executioner caspases (e.g., -3, -6, -7).
Apoptosis Pathways:
Subcellular Responses & Accumulations - Inner Workings
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Autophagy: Lysosomal degradation of damaged organelles; cellular housekeeping.
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Endoplasmic Reticulum (ER) Stress: Misfolded proteins accumulate, triggering Unfolded Protein Response (UPR).
- UPR: ↑chaperones, ↓protein synthesis, or apoptosis if severe.
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Heat Shock Proteins (HSPs): Molecular chaperones; protect against stress, aid protein folding.
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Intracellular Accumulations:
- Lipids: Steatosis (e.g., fatty liver).
- Proteins: E.g., Russell bodies (plasma cells), Mallory bodies (liver).
- Glycogen: Glycogenoses; visible as clear vacuoles.
- Pigments:
- Lipofuscin:
High‑Yield Points - ⚡ Biggest Takeaways
- Key cellular adaptations: hypertrophy, hyperplasia, atrophy, metaplasia.
- Reversible injury signs: cellular swelling (hydropic change), fatty change.
- Irreversible injury: critical membrane damage, massive Ca²⁺ influx, mitochondrial failure.
- Necrosis causes inflammation; apoptosis is programmed, non-inflammatory cell death.
- Heat Shock Proteins (HSPs) are crucial for protein folding and stress protection.
- Oxidative stress (↑ROS) damages cells; countered by antioxidants.
- ER stress activates the unfolded protein response (UPR).
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