Title: Leicester Warwick Medical School
1Leicester Warwick Medical School
Cellular Adaptations Dr Gerald
Saldanha Department of Pathology Email
gss4_at_le.ac.uk
2Introduction
- This presentation will .
- Focus on adaptive responses in cell growth
differentiation - Describe cell signalling pathways
- Introduce the cell cycle
3Control of cell growth
- Cells in a multicellular organism communicate
through chemical signals - Hormones act over a long range
- Local mediators are secreted into the local
environment - Some cells communicate through direct cell-cell
contact
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5Control of cell growth
- Cells are stimulated when extra cellular
signalling molecules bind to a receptor - Each receptor recognises a specific protein
(ligand) - Receptors act as transducers that convert the
signal from one physical form to another.
6Signalling molecules
- Most signalling molecules cannot pass through the
cell membrane - Their receptors are in the cell membrane
- Small hydrophobic signal molecules can diffuse
directly into the cell cytoplasm - Their receptors are cytoplasmic or nuclear
7Signalling molecules
- Hormones
- Insulin,
- Cortisol
- etc
- Local mediators
- Epidermal Growth Factor (EGF),
- Platelet Derived Growth Factor (PDGF)
- Fibroblast Growth Factor (FGF)
- TGF?
- Cytokines, e.g. Interferons, Tumour necrosis
factor (TNF)
8Receptors
- There are three main classes of receptors.
- Ion-channel-linked receptors
- G-protein-linked receptors
- Enzyme-linked receptors
9Receptors
- Ion channel-linked receptors are important in
neural signalling - G-protein and enzyme linked receptors respond by
activating cascades of intracellular signals - These signals alter the behaviour of the cell
10G-protein-linked receptors
- G-protein-linked receptors activate a class of
GTP-binding proteins (G-proteins) - G proteins are molecular switches
- They are turned on for brief periods while bound
to GTP - They switch themselves off by hydrolysing GTP to
GDP
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12G proteins
- Some G proteins directly regulate ion channels
- Others activate adenylate cyclase, thus
increasing intracellular cyclic AMP - Some activate the enzyme Phospholipase C, thus
increasing intracellular inositol triphosphate
(IP3) and Diacylglycerol (DAG)
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14Enzyme-linked receptors
- Many receptors have intracellular domains with
enzyme function - Most are receptor tyrosine-kinases
- They phosphorylate tyrosine residues in selected
intracellular proteins - These receptors are activated by growth factors,
thus being important in cell proliferation
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16Receptor tyrosine kinases
- Receptor tyrosine kinase activation results in
assembly of an intracellular signalling complex - This complex activates a small GTP-binding
protein, Ras - Ras activates a cascade of protein kinases that
relay the signal to the nucleus - Mutations that make Ras hyperactive are a common
way of inducing increased proliferation in cancer
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18Signalling cytoplasm to nucleus
- Many signalling cascades culminate in activation
of nuclear transcription factors - Transcription factors alter gene expression
- C-jun and c-fos ( that form an AP1 complex) and
c-myc are three important transcription factors
19Signalling pathway interactions
- There are many signalling molecules and receptors
- A given cell expresses only a subset of receptors
- Different intracellular signalling pathways
interact - This enables cells to respond appropriately to
complex combinations of signals
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22Cell signalling and proliferation
- Animal cells proliferate when stimulated by
growth factors - These bind mainly to receptor tyrosine kinases
- These signalling pathways override the normal
brakes on proliferation - These brakes are part of the cell cycle control
system - This ensures that cells divide only under
appropriate circumstances
23The cell cycle
- The eukaryotic cell cycle consists of distinct
phases - The most dramatic events are nuclear division
(mitosis) and cytoplasmic division (cytokinesis) - This is the M phase
- The rest of the cell cycle is called interphase
which is, deceptively, uneventful - During interphase the cell replicates its DNA,
transcribes genes, synthesises proteins and grows
in mass
24Phases of the cell cycle
- S phase DNA replicates
- M phase nucleus divides (mitosis) and cytoplasm
divides (cytokinesis) - G1 phase gap between M and S phase
- G2 phase between S and M phase
25Cell cycle control
- Cell cycle machinery is subordinate to a cell
cycle control system - The control system consists mainly of protein
complexes - These complexes consist of a cyclin subunit and a
Cdk subunit - The cyclin has regulatory function, the Cdk
catalytic function
26Cell cycle control
- Cdk expression is constant, but cyclin
concentrations rise and fall at specific times in
the cell cycle - The Cdks are cyclically activated by cyclin
binding and by phosphorylation status - Once activated, Cdks phosphorylate key proteins
in the cell
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28Cell cycle control
- Different cyclin-Cdk complexes trigger different
cell cycle steps - Some drive the cell into M phase, others into S
phase - The cell cycle control system has in-built
molecular breaks (checkpoints) - The checkpoints ensure that the next step does
not begin until the previous one is complete
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30The G1 checkpoint
- The G1 checkpoint has been widely studied
- The retinoblastoma (Rb) protein plays a key role
at this checkpoint - The Rb protein function is determined by its
phosphorylation status - S phase cyclin-Cdk complexes phosphorylate Rb
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32The G1 checkpoint
- This checkpoint is influenced by the action of
cyclin-dependant kinase inhibitors (CKIs, e.g.
p21, p16) - E.g. p53 senses DNA damage and induces p21
expression - CKIs inactivate cyclin-Cdk complexes
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34Cellular adaptations of growth and differentiation
- Cells must respond to a variety of stimuli that
may be hormonal, paracrine or through direct cell
contact - These stimuli may arise under physiological or
pathological conditions - The way that cells adapt in terms of growth and
differentiation depends in part on their ability
to divide
35Cellular proliferative capacity
- Tissues can be classified according to the
ability of their cells to divide - Some tissues contain a pool of cells that move
rapidly from one cell cycle to the next. These
are labile cells
36Cellular proliferative capacity
- Some cells dismantle their cell cycle control
machinery and exit the cell cycle - These cells are said to be in G0.
- Some of these cells can re-enter the cell cycle
when stimulated, e.g. by growth factors. These
are stable cells - Others are unable to re-enter the cell cycle.
These are permanent cells
37Growth and differentiation responses
- Hyperplasia
- Hypertrophy
- Atrophy
- Metaplasia
38Hyperplasia
- Increase in the number of cells in an organ or
tissue, which may then have an increased size
39Hyperplasia causes
- Hyperplasia can only occur in tissues containing
labile or stable cells - Hyperplasia may occur under pathological or
physiological conditions
40Physiological Hyperplasia
- Hormonal e.g. endometrium
- Compensatory, e.g. partial hepatectomy
- TGF alpha, HGF
- TGF beta
41Pathological hyperplasia
- Excessive hormone/growth factor stimulation
- Often occurs alongside hypertrophy
- Associated with increased risk for cancer
- E.g. Prostate, endometrium
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45 46Hypertrophy
- An increase in cell size, and resultant increase
in organ size
47Hypertrophy causes
- Occurs in permanent cells
- Due to synthesis of more cellular structural
components - Physiological or pathological causes
48Physiological hypertrophy
- Increased functional demand, e.g. skeletal muscle
- Mechanical
- Hormonal, e.g. Uterus in pregnancy
- Usually a combination of hypertrophy and
hyperplasia
49Pathological hypertrophy
- Increased functional demand e.g. cardiac muscle
- Hypertension
- valvular heart disease
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52Atrophy
- Shrinkage in cell size by loss of cell substance
- Term is often used loosely to describe reduced
organ size that may be related to cell loss
rather than shrinkage
53Atrophy causes
- Reduced workload
- Loss of innervation
- Reduced blood supply
- Inadequate nutrition
- Loss of endocrine stimulation
- Ageing
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57Metaplasia
- Reversible change of one adult cell type to
another adult cell type
58Metaplasia causes
- An adaptive response to various stimuli
- New cell type is better adapted to exposure to
the stimulus - The stimulus that induced metaplasia may, later,
induce cancer, e.g. squamous cell carcinoma of
the bronchus - Metaplasia in mesenchymal tissues is often less
clearly adaptive
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61Hypoplasia
- Incomplete development of an organ with reduced
cell numbers
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63Summary
- Cells communicate through signalling pathways
- Signalling pathways influence the cell cycle
control system - This determines a cells ability to divide
- A cells replicative capacity influences its
adaptive responses to changes in the tissue
environment