Lecture 01: Cell Adaptation, Injury, & Death PDF

Summary

This lecture covers cell adaptation, injury, and death. It describes different types of adaptations like hypertrophy, hyperplasia, atrophy, and metaplasia. Examples in different areas of the body like muscle cells, blood vessels. The lecture also discusses cellular injury and the processes involved, giving specific examples.

Full Transcript

January 10, 2025
LECTURE 01: CELL ADAPTATION, INJURY, & DEATH
I.​ INTRODUCTION
Cellular Adaptation, Injury, Death
​ Cell adaptation
○​ Reversible structural and functional response to changes that allow the cell to survive (continue to function)

​ Stimulus (Physiologic or Pathologic)
○​ Hormones can induce cellular adaptation, physiologically
○​ If stimulus is removed, it will go back to its original state
​ Cellular Adaptation
○​ Not necessarily pathologic; sometimes a normal process
○​ Reversible
○​ → Healthy cell
​ Cellular Injury
○​ Adaptive limits exceeded
○​ → Healthy cell (reversible)
​ Cell Death
○​ Severe (intensity) and/or Persistent (time)
○​ Irreversible

II.​ CELLULAR ADAPTATION
Cellular Adaptation: Healthy Cell
​ If there is an increase in demand for the function of the cell, they either:
○​ (1) Increase in organelles (Hypertrophy)
​ Preferred by muscles (as it saves energy)
○​ (2) Increase number of cells (Hyperplasia)
​ Occurs when there is damage to muscle fibers
​ If there is no need for those cells, they either:
○​ (1) Decrease in number and/or size (Atrophy)
○​ (2) Degrade molecules to recycle the biochemical substrates (Autophagy)
​ If there is a need in change of function:
○​ (1) Metaplasia

​ Increase in size and/or number
○​ Sometimes both hypertrophy and hyperplasia occur simultaneously
○​ Hypertrophy
​ Increase in cell volume/size
​ Increase in organelles or necessary components within cytoplasm or cell
○​ Hyperplasia
​ Increase in number of cells
​ Decrease
○​ Atrophy
​ Decrease in number and/or size
​ Opposite of hypertrophy and hyperplasia
​ Usually brought about by autophagy
○​ Autophagy
​ degradation of molecules to recycle the biochemical substrates
​ Metaplasia
○​ Change in phenotype
​ If cell is in need of another function
Hypertrophy
​ Increase in cell volume or size due to increased synthesis of intracellular components to keep up with the functional
demand
​ G0 and G1 → stage of cell cycle where there is protein synthesis

Example of Hypertrophy: Skeletal muscles
​ Skeletal muscles
○​ Develop from myoblast
​ Myoblasts fuse and form muscle fibers → muscle cells
​ Satellite cells — serve as reservoir
○​ Differentiate to produce precursor cells → new muscle fibers
○​ When there is a need to …????
​ A
​ Easier to increase cell size than make new cell
​ A
​ A
​ Hyperplasia comes in when there is damage/injury
○​ But muscles prefer hypertrophy because it is energy-saving
Example of hypertrophy: Cardiac muscle cells
​ Cardiac muscle cells → contrast of skeletal muscle cells (?)
○​ Cannot undergo mitosis
○​ Cells do not increase; contractile proteins increase
○​ Cardiac muscles are branching
​ Hypertension
○​ Blood vessels are contracted → resistance
○​ To overcome resistance, cardiac muscles need to increase contractile protein
​ Don’t undergo mitosis; only increase contractile proteins (actin and myosin)
​ Result in thickening of ventricular walls
​ Lumen is significantly decreased because ventricle walls are thickened
○​ Allows to overcome increasing pressure
​ However, it is space occupying condition
​ Patients with cardiomegaly have increased risk for ischemic heart because of the ventricle wall enlargement
○​ Give vasodilators to address this
​ Vasodilates blood vessels
​ Relieves hypertension
​ Dilates blood vessel
​ Lessens burden of the heart
​ a
Hyperplasia
​ Increase in the number of cells in response to a stimulus
​ Mitosis occurs
○​ One daughter cell stays as stem cells
○​ One daughter cell differentiates
○​ Some can still proliferate

Example of Hyperplasia
​ Blood vessel obstruction
○​ When there is lipid accumulation → obstruction
○​ Vascular Endothelial growth factor
​ Involved in formation of new blood vessels
○​ In blood vessels: Newly formed blood vessels (Tunica intima/media/adventitia )
​ Tunica media is not well-developed yet in the image
​ Not that resistant to pressures
​ Prone to rupture
​ Physiologic hyperplasia in the endometrium (menstrual cycle)
○​ Estrogen smth
​ It becomes pathologic if there is too much estrogen
Hyperplasia (Pathologic: Thyroid)
​ When there is too much estrogen, it becomes pathologic

Eg: Thyroid
​ High thyroid hormone (T3 and T4) → Pituitary gland detects that you havve high thyroid hormone thus will stop it
○​ If lacking (e.g., iodine deficiency), no basic components to produce thyroid hormones
​ Send signals to pituitary gland to produce thyroid-stimulating hormones
○​ The branching is the increase in the number of cells
○​ Histologic slide:
​ Makes them appear like short columnar despite being supposedly cuboidial because of the crowding of the
cells undergoing hyperplasia

Atrophy
​ Reduction in size and number of the cells
○​ Opposite of hypertrophy and hyperplasia
​ Nature will always choose a path with less consumption of energy/resources
○​ Spontaneous reactions proceed with release of free energy (exergonic)
○​ Endergonic reactions proceed only if free energy can be gained
​ Rationale
○​ Not economic to maintain cells that we don’t need anymore
○​ Choosing paths that take lesser energy and resources
​ Importance of O
○​ Used in the ETC in order for energy to move forward
Example of Atrophy
​ Skeletal muscles
○​ After some time, muscles become smaller again
​ Body detects that there is no need to increase contractile proteins because they are not stimulated via work
out (Disuse atrophy)
○​ Decrease in number/size but do not necessarily die
○​ No stimulus/workload → atrophy

Types of Atrophy
​ Disuse atrophy (decreased workload)
○​ E.g., 1-month gym absence of a frequent body builder
​ Denervation atrophy (loss of innervation)
○​ E.g., Motor endplates
​ Found in skeletal muscles
​ Terminal axons innervating skeletal muscles
​ If axon is transected, then you don’t have acetylcholine that will initiate electrical activity of skeletal muscles
that open Ca+ channels → contraction
​ No muscle contraction = no need for the muscles = atrophy
​ Diminished blood supply
○​ Patients who undergo stroke, the specific blood vessels that are affected undergoes atrophy
○​ Abnormal: Decreased gyri sized and increased sulci
​ Inadequate nutrition
○​ Not enough nutrients for cells to produce proteins for cell function
○​ Inadequate nutrients = inadequate materials to produce cells
​ Loss of endocrine stimulation
○​ Decrease in TSH production (???)
​ Pressure
 ○​ Connected to diminished blood supply
○​ Also space occupying
​ E.g., growing embryo of mom with myoma
​ Baby competes with the space of the embryo because of ???? myoma???

Autophagy
​ Atrophy result from decreased protein synthesis or increased protein degradation (through autophagy or
ubiquitin-proteasome)
○​ Protein-degradation occurs mainly by ubiquitin-proteasome pathway
​ (almost all)
○​ Not exclusive, both can happen at the same time in one system
​ Ubiquitin-proteasome pathway
○​ Proteins fold via action of chaperone (links high energy and low energy reactions to cause folding)
○​ If folding is hampered (e.g., UV, reactive oxygen species) → misfolding of proteins
​ Recognized by ubiquitin-proteosome
​ Function of human ubiquitin: to link and target the misfolded proteins to proteasome for protein
degradation
​ If misfolded proteins cannot be guided, undergoes apoptosis (degradation of protein)
○​ This process acts as a solution to misfolded proteins

Autophagy → Jeano
​ The digestion of organelles within the cell
​ Similar to ubiquitin-proteosome pathways, there are ??? that initiate ??
○​ Initiating complexes bind to proteins no longer needed to degrade organelles to recycle products to produce new
molecules
○​ A
○​ A
○​ A
​ A
​ A
​ A
Metaplasia
​ Reversible change from one differentiated cell type to another cell type
○​ Perform new function more capable for adapting to the environment
​ Most common metaplasia is columnar to squamous metaplasia (or simply squamous metaplasia)
○​ Unlike esophagus (squamous → columnar)
○​ Common likely because of smoking (cells are not equipped to resist toxic substances found in cigarettes)
​ Neither of the increase/decrease mechanisms
​ Another pathway that cells can take to adapt to environment

Example of Metaplasia
​ Stratified squamous mucosa
○​ One layer, BV are more vessels
​ With columnar/squamous metaplasia
○​ Because of the acidity, acid regurgitates into the esophagus
○​ Stem cells in the basal squamous mucosa, differentiates into intestinal mucosa
​ Becomes columnar cells
​ Now has presence of many goblet cells
○​ A
​ Slide (upper right): Squamous cell lung carcinoma
○​ Infiltration in the basement membrane
​ Squamous cells enter the stroma
​ Metaplasia is not malignant itself, but as time goes by
​ Accumulate mutation that allow them to invade the stroma
​ a
​
Example of Metaplasia
​ Small cell carcinoma (neuroendocrine cells) → Squamous cell carcinoma (basal type)
​ A
​ I wanna kms what the fuck
○​ Bruh buti nag voice record ako
○​ A
○​ A
​ A
​ A
​ A
​

III.​ CELLULAR INJURY
Cellular injury
​ When cell can no longer adapt
​ Initially it is reversible
○​ However, if stimulus is so severe, where the cell cannot keep up
​ It undergoes irreversible injury → cell death
​ If survived, it become malignant cells
​ Malignancy is the other end point not just cell death
​ Cellular swelling
​ Fatty change
​ Intracellular accumulations
Cellular swelling
​ Two features are consistently seen in reversibly injured cells:
○​ Cellular swelling
○​ Lipid accumulation
​ Usually caused by failure of ATP-dependent Na-K pumps
○​ Failure of sodium-potassium pumps
​ Derangement in cellular ???
​ Left: normal tubular cells
​ Right: larger in volume
○​ Pale staining due to presence of water
○​ Proteins are still present; however
​ Water inside will not uptake stain anymore
Example of Cellular swelling
​ Summary of how Na-K pump achieve function and the crossing over of different solutes etc.

​
​ Partial polarities allow interaction
○​ H+ interacts with I-

Fatty change
​ Two features are consistently seen in reversibly injured cells:
○​ Cellular swelling
○​ Lipid accumulation
​ Occurs when lipid metabolic pathway/s is/are disrupted
​ Ex: cardiac muscle: skeletal cells
○​ ???
○​ No longer adapt to stimulus then it disrupts metabolic pathway and lipid accumulates
○​ Brown pigmentation due to???
​ A
​ A
​ A
Fatty change
​ Most prominent in organs that are actively involved in lipid metabolism such as liver
○​ Liver involved mainly for lipid metabolism
​ Injury will accumulate lipids
​ Lipid is a neutral molecule = clear stain, appears as large droplets
○​ A
​ A
​ A
​ A

Intracellular accumulations
​ Manifestation of metabolic derangement
○​ Lipids
○​ Proteins → hyaline change
○​ Glycogen
○​ Pigments (exogenous or endogenous)
​ Endogenous →
​ Exogenous
​ Carbon pigment (harmless)from the environment that are not degraded
○​ Incidental finding during autopsy or biopsy
​ May be harmless or may cause further injury
Example of Intracellular accumulations
​ Abnormal metabolism
○​ RBC
​ Normally produce hemoglobin a (2 alpha 2 beta)
​ If there is an abnormality in the production of hemoglobin, there is an adaptation
​ Reduced betaglobin = increased alphaglobin (more degrative?? Than beneficial)
○​ Alphaglobulin aggregates are not effective
​ Interferes with liquid components?
○​ Degraded in the spleen
○​ → Resulting in anemia
○​ Response of bone marrow is to produce RBC
​ Defect in protein folding, transport
​ Lack of enzymes
○​ Can degrade/metabolize molecules
​.
​
​ Ingestion of indigestible materials
○​ Carbon pigments
○​ Silicone ???
○​ A
​ A
​ A
​ A
Intracellular accumulations
​ Defect in protein synthesis
○​ Alpha-secretase — supposed to cleave protein
○​ b-Secretase takes over if a-Secretase fails
​ Produce b-monomer
○​ Accumulation of amylate fibrase? → macroscopic __
​ Interferes with the interconnection of the neurons
○​ A
○​ A
​ A
​ A
​ A

Intracellular accumulations
​ Lipid accumulation due to lack of enzymes
○​ Undergo beta oxidation
​ No enzyme to deal with betaoxidatiev lipids — causing it to accumulate
​ Macrophages will phagocytose it but not degrade it thus accumulating
​ Aka heart failure cells

​ Ingestion of indigestible materials
○​ When you have indigestible endogenous material
○​ “Coal miners pneumonosis(?)”
​ Coal particles are inhaled causing:
​ Accumulation of coal particles
​ Body can’t degrade it so it will wall the particles off
​ Fbiroblast block part where coal particles accumulate?
​ Some of the alveoli are significantly enlarged or damaged because of the increase in air
pressure
​ Becomes pathologic since it affects the function of the specific organ
​ Space occupying and compress alveoli
​ Some walls are damaged due to increase in pressure
 ​ It becomes pathologic if it affects the function of a specific organ

IV.​ CELL DEATH
Cell Death
​ Apoptosis
​ Necrosis
​ Necroptosis

Cell Death
​ Removal of damaged, unneeded, and aged cells is essential during development and maintenance of homeostasis
○​ Apoptosis has no inflammatory reaction, while necrosis have inflammatory reaction
​ [A] Morphologic
○​ Apoptosis → programmed cell death
○​ Necrosis → accidental cell death
​ [B] Biochemical
○​ Apoptosis
○​ Necroptosis
○​ Pyroptosis
○​ Ferroptosis
○​ Cuproptosis
​ Cell death subtypes:
○​ Regulated Cell Death
​ Molecules control the occurrence
 ​ Programmed Cell Death
​ Apoptosis
​ Important during embryologic development
○​ Accidental Cell Death
​ Necrosis
​ Cell death doesn’t necessarily mean pathologic

Cell Death
​ Cell death can be influenced either by:
○​ Genetics
​ Lack genetics or genes to promote cell death
○​ Environmental
​ Lack stimulus to promote cell death
Apoptosis
​ Tightly regulated suicide program that can either be physiologic or pathologic
○​ Physiologic: During development
○​ Pathologic: Force induces apoptosis
​ Plasma membrane remains intact → phagocytosed before contents leak out = minimal inflammatory
reaction
○​ No inflammatory reaction because it is organized(?) / because of organelles
​ No spillage of anything that can induce inflammatory reaction
​ Either deprived of survival signals (anti-apoptotic) or receive pro-apoptotic signals
​ Caspase (cysteine in the active site, cleaves proteins after aspartic residues)
○​ Induces apoptosis through cascade of caspases until the final caspase induce membrane fragmentation

​ Intrinsic pathway: Involve mitochondria
​ Extrinsic pathway doesn’t necessarily involve mitochondria
○​ The receptors can activate caspases
​ At the center: Initiation caspases
○​ Caspase → cysteine in active site, cleaves proteins after aspartic residues
○​ Aspartic residue: part of cleavage
○​ Once cleaved, activates caspase proteins
​ All will induce apoptosis
Apoptosis: Intrinsic Pathway
​ Intrinsic pathway:
○​ Translocation of either BAX or BAK proteins
​ Pores that attaches to the outer membrane
○​ Once pores form at outer membrane → release Cytochrome C
​ Mitochondrial outer membrane permeabilization? (MOMP)
​ Degrade ???
○​ Something is inhibited
○​ Lead to apoptosis
○​ Activation of Pyroptosis
​ Pyro– increase in temperature (reduces fever)
​ NIK molecule (induce nuclear factor kappa B) → attach to specific gene segments
​ Nuclear factor kappa B – in charge of expression of other something
​ Huchkiliphoma WHAT THE FUCK
○​ Mitochondrial DNA can leak out
​ Induce something
​ Activate stimulator of interferon genes — involved in activation of macrophage — for phagocytosis
​ This recruits macrophages towards site of apoptosis (ready to phagocytose)
​ Interferon genes are involved in activating macrophages
​ Macrophages have a role in apoptosis to phagocytose
○​ Release of double-stranded RNA
​ Product for mitochondrial dna
​ Mitochondrial permeable outer membrane
​ Why would dna go out even if membrane is intact?
Apoptosis: Extrinsic Pathway
​ How does mtDNA get out when the inner membrane is intact during MOMP?
○​ Ongoing question putek

Necrosis
​ Don't form vesicles
​ The cytoplasmic are not membrane bound
○​ Leaks out components within the cell → cell “bursts”
○​ Induces inflammatory reaction
​ Unlike apoptosis (no inflammatory reaction)
​ Ex: Ischemic heart disease
○​ decrease/obstruction of blood flow, cardiomycocytes undergo necrosis
○​ Initially no inflammatory reaction kasi lumalabas pa lang cellular components
○​ After 24hs, there’s a different reaction of the???? → inflammatory reaction
○​ [Re: systemic moving out:] Unang lalabas ang CK-MII sunod ang troponin
​ Therefore you’ll know that the condition is going on for quite some tie at the presence of troponin in CBC
​ Systemic moving out of the components
○​ Free flowing goes out first
​ Enzymes
​ Freely flowing in the cytoplasm
○​ The structural proteins follows
​ If degradation is matagal na pota
Patterns of Necrosis
​ Morphologically
​ Not exclusive to each other

​ Coagulative
○​ Wherein you can still see the architecture/structure, it's still intact
​ Eventually will liquefy
○​ Seen for quite some time
○​ Architecture is preserved
​ Maintained by the structural skeleton
○​ Presumably, enzymes are neutralized during injury preventing proteolysis

​ Liquefactive
○​ Digestion → viscous liquid
○​ E.g., Absence of fibroblasts in brain
​ No protein factors that support structural integrity of the tissue thus, will liquefy directly
​ No longer undergo Coagulative necrosis
○​ Viscous
○​ Produces a cavity?
​ Macrophages surrounding area of liquefaction
Patterns of Necrosis
​ Caseous
○​ “Cheeselike”
○​ Friable white areas of necrosis enclosed within a distinctive inflammatory border
​ Ex: tuberculosis
​ Tuberculosis bacilli
​ Macrophages increase ____ that digests and dissolves/degrades the area
​ To contain the enzymes, there are walling off by fibroblasts
​ Macrophages in the periphery, that are fused together
​ Also digest normal tissues
​ With lymphocytes and fibroblasts surrounded, respectively

​ Fat Necrosis
○​ Pancreatic enzyme leak out → liquefy adipocyte’s membrane
○​ Fatty acids combine with calcium to produce chalky-white lesions
​ Lesions = Digested lipids

Patterns of Necrosis
​ Fibrinoid Necrosis
○​ An-Ab complexes + plasma proteins deposit in the vessel wall (fibrin-like: bright pink and amorphous) →
inflammatory reaction
​ Inhibits smth???
○​ Occur during antibody-antibody formation
○​ Due to leakage of coagulative factors
Necroptosis
​ Recently discovered
​ Since viruses develop intracellularly, the mechanism to neutralize viruses is to kill the infected cell → induce
apoptosis
○​ However, some viruses were able to adapt to pathways involved in apoptosis
○​ When tried to inhibit caspase 8, cell death still occurred even if its not suppose to occur
​ One of the adaptive mechanisms of the virus so the cell they use would not die
​ Virus inhibited caspase 8 to avoid apoptosis of its host cell
○​ With
○​ A

​ Called necroptosis because it is necrosis but pathway involves apoptosis*

Summary
​ Normal cell (homeostasis)
○​ Stress → Adaptation
​ If unable to adapt → Cell Injury
○​ Injurious stimulus → Cell injury
​ If severe, progressive → Irreversible injury
​ Cell Death
○​ Necrosis
○​ Apoptosis
​ If mild, transient → Reversible injury → Normal cell
Titl