Post on 27-Dec-2015
CELL DEATHan overview
Dr Cathy Baker
22nd October 2007
Intercalated BSc 2007-08
How do cells die?
Killed by injurious agents
Induced to commit suicide
NECROSIS
APOPTOSIS
LEARNING OBJECTIVES
Understand, describe and illustrate …Differences: necrosis vs. apoptosisMorphological changes of apoptosisFunction of apoptosisPrincipal biochemical mechanisms Role of apoptosis in pathologies
Necrosis
Apoptosis
Pathology
Morphologicalchanges
Function
Biochemistry
Lecture overview
Necrosis
Mechanical injury & toxic agentsCell groupsMembrane integrity destroyedCells and organelles swell, burst
and leak contentsInflammatory responseOther cells and tissues damaged
Cell death by necrosis
John Kerr et al Br.J.Cancer 26: 239-257, 1972
Apoptosis
Essential biological process
Cells have role in own death - told or decide to commit suicide
Programmed cell death (PCD)
Apoptosis
Distinct form of single cell deathTightly regulatedVery localisedEnergy consuming processMembranes intact (early stages)Safe disposal of cell corpseNo inflammation
Necrosis
Apoptosis
Morphologicalchanges
Changes in cell morphology
Cells shrink and become detached from adjoining cells
Cytoskeleton collapsesMitochondria remain intactPlasma membrane develops bubbles
(blebs) on surface
Membrane blebs during apoptosis
Nucleus and chromatin condense
Aggregates at periphery of nucleus
Nuclear envelope disintegrates
DNA fragmentation
Budding off and breakage into small membrane wrapped fragments - apoptotic bodies
Formation of apoptotic bodies
What happens to apoptotic cells and apoptotic bodies?
Ingested & degraded by phagocytesMacrophages and dendritic cellsAdjacent cells in tissueHigh speed and efficiencyHistologically inconspicuousNo inflammation
Phagocytosis of apoptotic cells and bodies
Necrosis
Apoptosis
Morphologicalchanges
Function
Function of apoptosis?
Deliberate removal of specific, unwanted cells
Organised and controlled manner
Without damaging other cells or tissues
Circumstances?
Homeostasis
Constancy of internal environmentTissue turnoverCell numbers have to be maintained
Homeodynamics
Removal of unwanted cells
Damage
Organ and tissue differentiation
Vestigial structures
Alteration of tissue form
Embryonic development
5 weeks 8 weeks
Deletion of excess immature neurons that have failed to establish synaptic connections
Occurs in CNS and PNS
Prevents redundant cell in mature nervous system
Neurological development
Endometrial breakdown prior to menstruation
Regression of lactating breast tissue after weaning
Involution of tissue
Internal cell damage Inappropriate 3o protein structure
Cell InfectionViral
StressStarvation
DNA damage Ionizing radiation, ROS
Cell damage
Necrosis
Apoptosis
Morphologicalchanges
Function
Biochemistry
Biochemistry of apoptosis
Intense area of research
Complicated integrated mechanisms
Much more to be revealed!
Common core process
Underpins morphological changes
Four stage process
Stage 1 - The Death Signal
Stage 2 - Integration and Transduction
Stage 3 - Execution
Stage 4 - Cell Removal
Absence or withdrawal of positive survival factors
Presence of negative pro-apoptotic factors
Stage 1- The Death Signal
Survival or positive signals
Cell survival relies receiving positive stimuli
Withdrawal is a death signalDefault pathway for many cells
Neuronal growth factorInterleukin 2 for lymphocytesHormones
Signals to induce apoptosisDamaged DNA
UV light and X raysChemotherapeutic drugsOxidants/free radicals
Oxidative stressDeath activators or receptor
ligands
Death or negative signals
What are Death Activators?
Molecules that bind to specific receptors on cell surfaceTumour necrosis factor alphaLymphotoxin TNF betaFas ligand (CD95)
Binding of death activator to its specific receptor is a pro-apoptotic signal
Stage 2 - Integration and Transduction
Signals linked to execution phase through an integration stage
Uses positive and negative regulatory molecules
Inhibit, stimulate or forestall apoptosis
To die or not to die?
Integrated balance between positive survival factors and negative death
signals decides fate of cell
Common intracellular machinery for apoptosis
The three main players
Family of enzymes - Caspases
Protein family - Bcl-2 proteins
Regulating gene - p53 gene
CaspasesFamily of protease enzymes
14 isoforms identified
Have Cysteine at active site
Synthesised as inactive precursors - procaspase
Not all involved in apoptosis
prodomain
large subunits
small subunits
cleavagesites
Procaspase structure
Procaspase are activated through cleavage
Re-association of large and small subunits
Activated caspase has proteolytic activity
Initiatorcaspases
Effectorcaspases
Effectorcaspases
Apoptosisexecution
Initiatorcaspases
• Activate other caspases• Amplify caspase activity
Bcl-2 proteins
Large family of proteins Named from B cell lymphoma Some are pro-apoptotic some are
anti-apoptotic
Bcl-2 proteins and apoptosis
Main mechanism is regulation of mitochondrial permeability
Cell survival stimuli induce the expression of anti-apoptotic Bcl proteins
Death signals induce pro-apoptotic Bcl proteins
p53 gene and p53 protein
p53 is tumour suppressor gene Active gene product p53 produced in
response to DNA and cell damagePrevents cell completing cell cycle If damage is minor - allows repairIf major - induces apoptosisComplex mechanisms
Apoptotic transduction pathways
Mitochondrial or intrinsic pathway
Death activator or extrinsic pathway
Intrinsic or mitochondrial pathway
Bcl-2
Bax
Cell and DNAdamage –Active p53
Bax
Bcl-2
●Changes in trans-membrane potential●Pores form in (outer) membrane●Inner & outer membrane proteins involved
Bax
Bcl-2
Cyt C
Irreversiblecell death
Cyt C
Apaf-1 Apoptosisactivating factor -1
Aggregation of Cyt C/Apaf 1 complexes
Binding of Procaspase - 9
ATP
Auto-activation of Procaspase - 9
ATP
Formation of Active Caspase -9
ADP
Death receptor or extrinsic pathway
Molecules that bind to specific receptors on cell surfaceTumour necrosis factor alpha (TNF)
Lymphotoxin TNF beta
Fas ligand (CD95)
Binding of death activator to specific receptor is pro-apoptotic signal - caspase activation
Cell membrane with specific death receptors
Binding sites for death activators
Death domains extending into cytosol
Death receptors bind Death Activators
Clustering of death domains
Binding of adaptor protein(s)
Binding of caspase-8
Release of activated caspase-8
3. Execution
Achieved through activation and deactivation of target proteins by effector caspases
Activated effector caspases lead to …
Digestion of cytoskeleton proteins
Nucleus and chromatin degradation
Plasma membrane changes
Cytoskeleton degradation
Chromatin degradation
Caspase-9 enlarges nuclear pores
Allows entry of Caspase-3 and 7
Activation of nucleases
Caspase Activated DNAase - CAD
ICAD CAD
Nucleosome cleavage
Nucleosome bead8 histone molecules +
146 nucleotide pairs of DNA
Linker DNA
CAD
mw ladder DNA from apoptotic cell
Other nuclear changes
Structural proteins - Lamins degraded by caspase-6
DNA repair enzymes inactivated
Nuclear membrane degraded
What is the eat me signal?
4. Cell removal
Enzyme system keeps PS on inner surface
Inhibited during apoptosisPS redistributed to extra-cellular
surface Macrophage receptors recognise
and bind PSPhagocytosis of apoptosomeRelease of anti-inflammatory
substances
Necrosis
Apoptosis
Morphologicalchanges
Function
Biochemistry
Pathology
Homeostasis
Cell numbers have to be maintained
Cell formation Cell death
Uncontrolled growth of cellsInsufficient apoptosis
Diseases featuring insufficient apoptosis
Many cancersAutoimmune Lymphoproliferative
Syndrome (ALPS)
Excessive apoptosisUncontrolled cell loss
Diseases featuring excessive apoptosis
NeurodegenerativeParkinson’s diseaseAlzheimer's diseaseAmyotrophic lateral sclerosis (ALS)Huntingdon’s disease
Diseases featuring excessive apoptosis
AIDS Excessive apoptosis of T helper cells
IschaemiaCerebral caused by strokeCardiac caused by MI
You should now be able to …
Understand, describe and illustrate …Differences: necrosis vs. apoptosisMorphological changes of apoptosisFunction of apoptosisPrincipal biochemical mechanisms Role of apoptosis in pathologies