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The Cytoskeleton and Cell Motility

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CHAPTER 9 The Cytoskeleton and Cell Motility Microtubules (11) Microtubules (12) Basal Bodies and Other MTOCs Basal body structure where outer microtubules in a ... – PowerPoint PPT presentation

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Title: The Cytoskeleton and Cell Motility


1
CHAPTER 9
  • The Cytoskeleton and Cell Motility

2
Introduction
  • The cytoskeleton is a network of filamentous
    structures microtubulues, microfilaments, and
    intermediate filaments.

3
Properties of cytoskeletal components
4
9.1 Overview of the Major Functions of the
Cytoskeleton (1)
  • The cytoskeleton has many roles
  • Serves as a scaffold providing structural support
    and maintaining cell shape.
  • Serves as an internal framework to organize
    organelles within the cell.
  • Directs cellular locomotion and the movement of
    materials within the cell.

5
Structure and functions of the cytoskeleton
6
Overview of the Major Functions of the
Cytoskeleton (2)
  • Provides anchoring site for mRNA.
  • Serves as a signal transducer.
  • An essential component of the cells division
    machinery.

7
9.2 Study of the Cytoskeleton (1)
  • The Use of Live-Cell Fluorescence Imaging
  • Can be used to locate fluorescently-labeled
    target proteins.
  • Molecular processes can be observed (live-cell
    imaging).
  • Used to reveal the location of a protein present
    in very low concentrations.

8
Applications using fluorescence imaging
9
Study of the Cytoskeleton (2)
  • The Use of In Vitro Single-Molecule Assays
  • They make possible to detect the activity of an
    individual protein molecule in real time.
  • Can be supplement with atomic force microscopy to
    measure the mechanical properties of cytoskeletal
    elements.

10
Using video microscopy to follow activities of
molecular motors
11
9.3 Microtubules (1)
  • Structure and Composition
  • Microtubules are hollow, cylindrical structures.
  • The microtubule is a set of globular proteins
    arranged in longitudinal rows called
    protofilaments.
  • Microtubules contain 13 protofilaments.
  • Each protofilament is assembled from dimers of a-
    and ß-tubulin subunits assembled into tubules
    with plus and minus ends.

12
The structure of microtubules
13
Microtubules (2)
  • Microtubule-Associated Proteins (MAPs)
  • MAPs comprise a heterogeneous group of proteins.
  • MAPs attach to the surface of microtubules to
    increase their stability and promote their
    assembly.
  • MAPs are regulated by phosphorylation of specific
    amino acid residues.

14
MAPs
15
Microtubules (2)
  • Microtubules as Structural Supports and
    Organizers
  • The distribution of microtubules determines the
    shape of the cell.
  • Microtubules maintain the internal organization
    of cells.

16
Microtubules (3)
  • Microtubules as Structural Supports and
    Organizers
  • Microtubules function in axonal transport.
  • Microtubules play a role in axonal growth during
    embryogenesis.

17
Microtubules (4)
  • Microtubules as Structural Supports and
    Organizers
  • In plant cells, microtubules help maintain cell
    shape by influencing formation of the cell wall.

18
Microtubules (5)
  • Microtubules as Agents of Intracellular Motility
  • They facilitate movement of vesicles between
    compartments.
  • Axonal transport
  • Movement of neurotransmitters across the cell.
  • Movement away from the cell body (anterograde)
    and toward the cell body (retrograde).
  • Mediate tracks for a variety of motor proteins.

19
Axonal transport
20
Axonal transport
21
Visualizing axonal transport
22
Microtubules (6)
  • Motor Proteins that Traverse the Microtubular
    Cytoskeleton
  • Molecular motors convert energy from ATP into
    mechanical energy.
  • Molecular motors move unidirectionally along
    their cytoskeletal track in a stepwise manner.
  • Three categories of molecular motors
  • Kinesin and dynein move along microtubule tracks.
  • Myosin moves along microfilament tracks.

23
Microtubules (7)
  • Kinesins
  • Kinesinmember of a superfamily called KLPs
    (kinesin-like proteins).
  • A kinesin is a tetramer of two identical heavy
    chains and two identical light chains.
  • Each kinesin includes a pair of globular heads
    (motor domain), connected to a rod-like stalk.
  • Kinesin is a plus end-directed microtubular motor
    based on its movement.

24
Kinesin
25
Microtubules (8)
  • Kinesins (continued)
  • They move along a single protofilament of a
    microtubule at a velocity proportional to the ATP
    concentration.
  • Movement is processive, motor protein moves along
    an individual microtubule for a long distance
    without falling off.
  • KLPs move cargo toward the cells plasma
    membrane.

26
Kinesin-mediated organelle transport
27
Microtubules (9)
  • Cytoplasmic Dynein
  • Dynein responsible for the movement of cilia
    and flagella.
  • Cytoplasmic dynein Huge protein with a
    globular, force-generating head.
  • It is a minus end-directed microtubular motor.
  • Requires an adaptor (dynactin) to interact with
    membrane-bounded cargo.

28
Cytoplasmic dynein
29
Cytoplasmic dynein
30
Microtubules (10)
  • Microtubule-Organizing Centers (MTOCs)
  • MTOCs specialized structures for the nucleation
    of microtubules.
  • Centrosome structures responsible for
    initiating microtubules in animal cells.
  • It contains two barrel-shaped centrioles
    surrounded by pericentriolar material (PCM).
  • Centrioles are usually found in pairs.

31
The centrosome
32
The centrosome
33
Microtubules (11)
  • Centrosomes (continued)
  • Responsible for initiation and organization of
    the microtubular cystoskeleton.
  • Microtubules terminate in the PCM.

34
Microtubules (11)
35
Microtubules (12)
  • Basal Bodies and Other MTOCs
  • Basal body structure where outer microtubules
    in a cilia and flagella are generated.
  • Plant cells lack MTOCs and their microtubules are
    organized around the surface of the nucleus.

36
Microtubules (13)
  • Microtubule Nucleation
  • MTOCs control the number of microtubules, their
    polarity, the number of protofilaments, and the
    time and location of their assembly.
  • The protein ?-tubulin is found in all MTOCs and
    is critical for microtubule nucleation.

37
The role of ?-tubulin in centrosome function
38
Microtubules (14)
  • The Dynamic Properties of Microtubules
  • There are four distinct arrays of microtubules in
    a dividing plant cell
  • Widely distributed throughout the cortex.
  • Making a single transverse band.
  • In the form of a mitotic spindle.
  • As a phargmoplast assisting in the formation of
    the cell wall of daughter cells.

39
Four arrays of microtubules in a plant cell
40
Microtubules (15)
  • The Dynamic Properties of Microtubules
  • Newly formed microtubules branch at an angle of
    pre-existing microtubules.
  • The changes in spatial organization of
    microtubules are a combination of two mechanisms
  • Rearrangement of existing microtubules.
  • Disassembly of existing microtubules and
    reassembly of new one in different locations.

41
Nucleation of plant microtubules
42
Nucleation of plant microtubules
43
Microtubules (16)
  • The Underlying Basis of Microtubule Dynamics
  • Insight into factors that influence microtubule
    assembly and disassembly came from studies in
    vitro.
  • GTP is required for microtubule assembly.
  • Hydrolysis of GTP leads to a replacement of bound
    GDP by new GTP to recharge the tubulin dimer.

44
Microtubule assembly in vitro
45
Structural cap model of dynamic instability
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