Cell and Molecular BiologyFifth Edition
CHAPTER 7 Part 1
Interactions Between Cells
and Their Environment
Copyright © 2008 by John Wiley & Sons, Inc.
Gerald Karp
7.1 The extracellular space
• Glycocalyx (cell coat): cell-cell interaction cell-substratum interaction
The extracellular matrix (ECM)
plays a regulatory role in determining the shape and activities of cells
a. Collagen
b. Proteoglycans
c. Fibronectin
d. laminin
Best-defined ECM
• Basement membrane (basal lamina): a continuous sheet 50-200 nm thick that
(1) surrounds muscle and fat cells (2) underlies the basal surface of epithelia
l tissues or the lining of the digestive and respiratory tracts
(3) underlies the inner ECs of blood vessels
a. Collagen (fibrous glycoprotein)
• Found throughout in animal kingdom• High tensile strength, that is, their
resistance to pulling forces is strong• A collagen fiber 1 mm in diameter is
capable of suspending a weight of 10 kg without breaking.
• Is the single most abundant protein in human body (25%)
Collagen (Cont.)
• Is produced primarily by fibroblasts, smooth muscle cells and epithelial cells
• More than 20 distinct types of collagen have been identified
• All share at least two structural features: trimers of α chains and wound around each other to form a rod-like triple helix
• Tendons : connect muscle and bone
• Stroma of cornea: transparency
• Type I collagen gene mutation: thin skin, death
• Type II mutation (cartilage tissue): skeletal deformaties
• Other mutations: hyperflexible joints, highly extensible skin
b. Proteoglycans (protein-polysaccharides comple
x)
GAG “-” H3O ”+”Hydrated gel with pores resists crushing forces
Collagens and GAGs give cartilage and other ECM strength and resistance to deformation.
The GAG chains also act as binding sites for many growth factors, affecting their interaction with cell-surface receptors
c. Fibronectin
d. Laminin• Three different polypeptide chains con
nected by S-S bonds
• Long arm and short arm
• Effect on cell migration and cell differentiation (laminin receptor on cell surface) i.e. guiding tips of embryoic axons, migration of primordial germ cell
Matrix metalloproteinases (MMPs)
• Zinc containing proteins either secreted into the extracellular space or anchored to the plasma membrane
• Tissue remodeling• Migration• Wound healing• Angiogenesis
• Athritis• Atherosclerosis• Hepatitis• Tooth and gum diseases• Tumor progression
7.2 Interactions of cells with extracellular materials
• Integrins (membrane receptors)• Focal adhesions and hemidesmo
somes: anchor cells to their substratum
•αβ chain spans membrane, non-covalently linked, 17α,8β, 20+ kinds of integrins (Fig. 7.5)
Integrin (cont.)
• Large extracellular portion
• Small cytoplasmic portion
• Ca2+ binding site on αchain
• βchain can recognize RGD sequence on fibronectin, activate FAK pathway
Change in conformation of the cytoplasmic domains, increasing the integrin’s affinity for an extracellular ligand
• “Inside-out” theory
• The aggregation of platelets during blood clotting occur only after the cytoplasmic activation of αIIbβ3 integrins which increases their affinity for fibrinogen
“Outside-in” signaling
• Integrin binds to fibronectin or collagen• Conformational changes at the cytoplasmic e
nd of the integrin• FAK• Protein phosphorylation• Nucleus (cell division, differentiation, motility,
growth, survival, cancer cells vs. normal cells)
Integrins link ECM to cytoskeletons
• Focal adhesion (in vitro with actin)
• Hemidesmosomes (in vivo with keratin, IF)
• Out-side-in
• Normal cells (integrin dependent) and malignant cells (integrin independent)
Bullous pemphigoid
• Individual’s bp proteins (autoantibodies) present in these adhesive structures.
• These autoantibodies cause the lower layer of the epidermis to lose attachment to the underlying basement membrane.
• The leakage of fluid into the space beneath the epidermis results in severe blistering of the skin.
• Epidermis, GI, urinary tracts
7.3 interactions of cells with other cells
• Cells can recognize the surfaces of other cells
• Interacting with some and ignoring others
Little was known about the nature of the molecules that mediate cell-cell
adhesion until
• The development of techniques for purifying integral membrane proteins
• The isolation and cloning of genes that encode these proteins
Four distinct families of integral membrane proteins play a major role in mediating cell-cell adhesion
• Cell-cell adhesion molecules• 1. Selectins• 2. Certain members of IgSFs and
integrins • 3. Cadherins• 4. Adherenes junctions and desmosome
s:
anchoring cells to other cells
1. Selectins
• LEU-CAM1 (L-selctins) in vivo: lymphocytes homing
• A family of intergral membrane glycoprotein
• Bind to the oligosaccharides of other cells
• Possess a small cytoplasmic domain and a large extracellular segment
• Role of selectins in inflammation (P.263)
2. Immunoglobulins and integrins
• Ig domains: 70-100 amino acids• Most IgSF mediate lymphocytes and macrophage
s and target cells for immune response • Calcium-independent cell-cell adhesion• Some IgSF such as VCAM, NCAM and L1 mediate
interaction between nonimmune cells i.e. nerve outgrowth, synapse formation, nervous development
• Deformed babies due to L1 mutation, water on the brain, mental retardation
• Integrins α4β1 binds to VCAM on blood vessels
3. Cadherins
• Transmit signals from ECM to the cytoplasm
• Mediate Ca2+-dependent cell-cell adhesion
• E-cadherins, N-cadherins, P-cadherins
4. Adherins junctions and desmosomes: anchoring cells to other cells
• Adhesive junctions (ca2+dependent):
1.adherens junctions
2.desmosomes
3.junctional complexes (tight junction and gap junction)