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Cytoskeleton Providing structural support to the cell, the cytoskeleton also functions in cell motility and regulation.

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Presentation on theme: "Cytoskeleton Providing structural support to the cell, the cytoskeleton also functions in cell motility and regulation."— Presentation transcript:

1 Cytoskeleton Providing structural support to the cell, the cytoskeleton also functions in cell motility and regulation

2 Structural Support Mechanical support –Maintains shape Fibers act like a geodesic dome to stabilize and balance opposing forces Provides anchorage for organelles Dynamic –Dismantles in one spot and reassembles in another to change cell shape

3 Introduction The cytoskeleton is a network of fibers extending throughout the cytoplasm. The cytoskeleton organizes the structures and activities of the cell.

4 The cytoskeleton also plays a major role in cell motility. –This involves both changes in cell location and limited movements of parts of the cell. The cytoskeleton interacts with motor proteins. –In cilia and flagella motor proteins pull components of the cytoskeleton past each other. –This is also true in muscle cells. Fig. 7.21a

5 Motor molecules also carry vesicles or organelles to various destinations along “monorails’ provided by the cytoskeleton. Interactions of motor proteins and the cytoskeleton circulates materials within a cell via streaming. Recently, evidence is accumulating that the cytoskeleton may transmit mechanical signals that rearrange the nucleoli and other structures. Fig. 7.21b

6 There are three main types of fibers in the cytoskeleton: microtubules, microfilaments, and intermediate filaments.

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8 Microtubules, the thickest fibers, are hollow rods about 25 microns in diameter. –Microtubule fibers are constructed of the globular protein, tubulin, and they grow or shrink as more tubulin molecules are added or removed. They move chromosomes during cell division. Another function is as tracks that guide motor proteins carrying organelles to their destination. Fig. 7.21b

9 In many cells, microtubules grow out from a centrosome near the nucleus. –These microtubules resist compression to the cell.

10 Fig. 7.22 In animal cells, the centrosome has a pair of centrioles, each with nine triplets of microtubules arranged in a ring. During cell division the centrioles replicate.

11 Microtubules are the central structural supports in cilia and flagella. –Both can move unicellular and small multicellular organisms by propelling water past the organism. –If these structures are anchored in a large structure, they move fluid over a surface. For example, cilia sweep mucus carrying trapped debris from the lungs. Fig. 7.2

12 Cilia usually occur in large numbers on the cell surface. –They are about 0.25 microns in diameter and 2-20 microns long. There are usually just one or a few flagella per cell. –Flagella are the same width as cilia, but 10-200 microns long.

13 A flagellum has an undulatory movement. –Force is generated parallel to the flagellum’s axis. Fig. 7.23a

14 Fig. 7.23b Cilia move more like oars with alternating power and recovery strokes. –They generate force perpendicular to the cilia’s axis.

15 In spite of their differences, both cilia and flagella have the same ultrastructure. –Both have a core of microtubules sheathed by the plasma membrane. –Nine doublets of microtubules arranged around a pair at the center, the “9 + 2” pattern. –Flexible “wheels” of proteins connect outer doublets to each other and to the core. –The outer doublets are also connected by motor proteins. –The cilium or flagellum is anchored in the cell by a basal body, whose structure is identical to a centriole.

16 Fig. 7.24

17 The bending of cilia and flagella is driven by the arms of a motor protein, dynein. –Addition to dynein of a phosphate group from ATP and its removal causes conformation changes in the protein. –Dynein arms alternately grab, move, and release the outer microtubules. –Protein cross-links limit sliding and the force is expressed as bending. Fig. 7.25

18 Microfilaments, the thinnest class of the cytoskeletal fibers, are solid rods of the globular protein actin. –An actin microfilament consists of a twisted double chain of actin subunits. Microfilaments are designed to resist tension. With other proteins, they form a three- dimensional network just inside the plasma membrane.

19 Fig. 7.26 The shape of the microvilli in this intestinal cell are supported by microfilaments, anchored to a network of intermediate filaments.

20 In muscle cells, thousands of actin filaments are arranged parallel to one another. Thicker filaments, composed of a motor protein, myosin, interdigitate with the thinner actin fibers. –Myosin molecules walk along the actin filament, pulling stacks of actin fibers together and shortening the cell. Fig. 7.21a

21 In other cells, these actin-myosin aggregates are less organized but still cause localized contraction. –A contracting belt of microfilaments divides the cytoplasm of animals cells during cell division. –Localized contraction also drives amoeboid movement. Pseudopodia, cellular extensions, extend and contract through the reversible assembly and contraction of actin subunits into microfilaments. Fig. 7.21b

22 In plant cells (and others), actin-myosin interactions and sol-gel transformations drive cytoplasmic streaming. –This creates a circular flow of cytoplasm in the cell. –This speeds the distribution of materials within the cell. Fig. 7.21c

23 Intermediate filaments, intermediate in size at 8 - 12 nanometers, are specialized for bearing tension. –Intermediate filaments are built from a diverse class of subunits from a family of proteins called keratins. Intermediate filaments are more permanent fixtures of the cytoskeleton than are the other two classes. They reinforce cell shape and fix organelle location. Fig. 7.26


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