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1 Cytoskeleton A cytoplasmic system of fibers -> critical to cell motility (movement) Macrophage cytoskeleton Cytoskeleton of a lung cell in mitosis
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2 The cytosol: 20-30 w% of cytosol are proteins -> ¼ - ½ of total protein is in cytosol Protein conc. 200-400 mg/ml -> complexes of protein It is believed that cytosol is highly organized -> Most soluble proteins are - bound to filaments - localized in specific regions
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3 Cytoskeleton of an epithelial cell and a migrating cell
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4 Eukaryotes Bacteria Actin filaments (AF) Intermediate filaments (IF) microtubule (MT)
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5 Cytoskeleton is made out of 3 different types of filaments
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6 Filaments differ in Size, Shape and Flexibility
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7 Filament network in the cell Filament network (fluorescence) From the nucleus to the plasma membrane Microtubules network Starting from the MT center near nucleus
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8 Cytoskeleton supporting the plasma membrane in human red blood cells
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9 Cell Signaling Regulates Cytoskeleton Function
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11 1. Microfilaments and Actin Structures Actin cytoskelet in a moving cell
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12 Actin monomers assemble into long helical polymers with polarity 1. Microfilaments and Actin Structures
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13 Actin Filament Assembly
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14 Actin Filaments grow faster at (+) end than at (-) end The rate of addition of ATP-G-actin is much faster at the (+) end than at the (-) end (rate of dissociation is similar) -> lower critical concentration (Cc) at (+) end in steady state -> filament grows preferentially at the (+) end If actin conc. is between Cc - and Cc + (steady state) -> actin subunits flow through filaments by attaching to (+) end and dissociating from (-) end Treadmilling phenomen -> involved in movement of cells
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15 Capping Proteins Block Assembly and Disassembly at Actin Filament Ends The presence of these 2 proteins at opposite ends prevent actin from dissociating during muscle contraction
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16 Actin Filament Branching Nucleation of branching mediated by Arp2/3
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17 Movement of invaders inside the cell Most infections are spread by lysed cells. Some Bacteria (Listeria monocytogenes) or viruses (vaccinia – related to smallbox virus) escape from cell on the end of a polymerizing actin filament. These organisms or viruses move through the cytosol at rates of 11μm/min. Actin generates the force necessary for movement
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18 Proteins that organize Microfilaments into networks Filamin forms networks Forms bundles
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19 Filaments attached to Membranes Microvilli on an epithelial cell showing polarity of actin filaments
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20 Myosins - Cellular Motor Proteins Tail: -> Locatized to cellular membranes -> vesicle attached (cargo) Form thick filaments in muscles S1 motor domain Head -> Motor domain (S1) -> ATP depentend
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21 Myosin heads walk along actin filaments -> towards (+) end Sliding-filament assay: Myosin tail absorbed onto glass surface -> a solution of actin filaments allowed to flow through In presence of ATP myosin heads walk towards (+) end of actin filaments -> sliding of filaments -> Movement of labeled actin filaments
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22 Myosins – Motor proteins responsible for cell movement These are the most important 3 myosins (out of ca. 40 we have in humans) Loss of more specialized ones -> causes deafness/blindness
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23 Myosin motion along actin Length of the neck domain -> determines rate of movement Step size -> Moves in 72 nm steps
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24 Actin fibers in the muscle
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25 Skeletal muscle contraction is regulated by Calcium and actin binding proteins Tropomyosin (TM) Troponin (TN)
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26 Cell Locomotion Coordination of motions generated by different parts of the cell Movement of fish epidermal cell Cell locomotion mechanism: Includes actin polymerization and branching- generated movement at the edge, assembly of adhesion structures, and contractions mediated by myosin II
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27 Myosin V Carries Many Cargoes Myosin V: -> carries secretory vesicles, organelles,... -> Used to prepare nucleus for mitosis -> used to segregate organelles
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28 2. Intermediate Filaments Keratin and lamin IF IF differ in stability, size and structure from other cytoskeleton fibers: - IF are extremely stable (hair, nails, wool) -10 nm diameter - α-helical rods -> assemble into ropelike filaments - assemble from different IF proteins - assembly through several intermediate structures Intermediate structures in the assembly of IF
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30 Cross-links between Microtubules and Intermediate Filaments in Fibrioblast cells Microtubules (red), Intermediate Filaments (blue), connection between fibers (green)
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31 3. Microtubules Kinesin-powered movement of a vesicle along a microtubule Microtubules are involved in cell movement: - Beating of cilia and flagella - transport of vesicles in the cytoplasm Microtubules organizing center (MTOC)
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32 Microtubules organization 2 type of MT in cells: - Stable and long-lived (found in non-replication cells) -> in cilia, flagella, neurons - unstable and short-lived (found in mitosis) -> spindle-shaped apparatus that partitions chromosomes equally to daughter cells
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33 Microtubules Arrangement Flagella
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34 Microtubules assemble from Microtubule Organizing Centers (MTOCs) MTOCs in non-mitotic cells -> centrosomes
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35 Microtubules Assembly preferably at (+) end Nucleation of microtubule assembly -> Treadmilling
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36 Microtubules Assembly/Disassembly Colchicine and Taxol: Drugs that interfere with Microtubules Assembly/Disassambly Colchicine: 2500 years ago Egyptians treated heart problems Nowadys: treatment of gout, skin and joint diseases Taxol: (stabilizes Microtubules) Anticancer agents -> treatment of ovarian cancer
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37 Microtubules Dynamic Instability Presence of GTP-β-tubulin cap determines stability
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39 Kinesin and Dynein – two Families of Motor Proteins Responsible for Transport along Microtubules Microtubules based vesicle transport
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41 Kinesin-catalysed Vesicle Transport Carries cargo
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42 Kinesin-1 uses ATP to walk down a microtubule to the (+) end
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43 Dynein-catalysed Vesicle Transport Moves towards the (-) end of microtubules
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44 Microtubule motors in a Cell Kinesins -> transport to cell periphery (+) Dyneins -> transport to cell center (-)
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45 Cooperation of Myosin and Kinesin at the cell cortex Secretory vesicles are handed over from Kinesin to Myosin -> last part of secretory pathway
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46 Rotory Motors – Cilia and Flagellar Sperm Bacterial Flagella (E. coli, Salmonella) Rotation of Flagellar -> Motion
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47 The Flagellar Motor
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48 Bacterial Flagellum is made out of subunits
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49 Motion of E. coli The points show the locations of the bacterium at 80 ms intervals. Changing of direction: Tumbling is caused by an abrupt reversal of the fagellar motor A second reversal restores smooth swimming -> almost always in a different direction
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50 Reversal of the direction of Flagellar Rotation is obtained by Proton Transport through Motor Proton flow drives flagella rotation !!!
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51 Chemotaxis Signaling Pathway Direction of bacterial movement depends on chemical substances: -> Bacteria swim towards high concentrations of glucose - chemoattractans -> Bacteria swim away from harmful substances, such as phenol - chemorepellants Receptor in plasma membrane initiate signal pathway -> Phosphorylation of CheY protein -> P-CheY binds to flagellar motor -> clockwise rotation favored Attractant binds to receptor -> pathway blocked -> smooth swimming Repellant binds to receptor -> pathway stimulated -> more frequent clockwise rotation -> tumbling
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