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1. Overview of Cell Biology2h 49m
2. Chemical Components of Cells1h 14m
3. Energy1h 33m
4. DNA, Chromosomes, and Genomes2h 31m
5. DNA to RNA to Protein2h 31m
6. Proteins1h 36m
7. Gene Expression1h 42m
8. Membrane Structure1h 4m
- The Lipid Bilayer
  38m
- Membrane Proteins
  25m
9. Transport Across Membranes1h 52m
10. Anerobic Respiration1h 5m
11. Aerobic Respiration1h 11m
12. Photosynthesis52m
13. Intracellular Protein Transport2h 18m
14. Cell Signaling1h 28m
15. Cytoskeleton and Cell Movement1h 39m
16. Cell Division3h 5m
17. Meiosis and Sexual Reproduction50m
18. Cell Junctions and Tissues48m
19. Stem Cells13m
- Stem Cells
  13m
20. Cancer44m
21. The Immune System1h 6m
22. Techniques in Cell Biology1h 41m

15. Cytoskeleton and Cell Movement

Actin Based Movement

15. Cytoskeleton and Cell Movement

Actin Based Movement: Videos & Practice Problems

Video Lessons Practice Worksheet

Topic summary

Cell crawling is a vital actin-based movement involving four key steps: protrusion, attachment, translocation, and detachment. During protrusion, actin filaments extend from the cell membrane, forming structures like pseudopodia. Attachment occurs via integrins, which anchor the cell to surfaces, akin to Velcro. Translocation involves the cell dragging its body forward, leveraging these attachments. Finally, detachment releases the integrins, allowing the process to repeat. This mechanism is crucial for processes like chemotaxis, where cells move in response to chemical gradients, showcasing the dynamic nature of cellular motility.

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Cell Crawling

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Cell Crawling Video Summary

Actin plays a crucial role in various non-muscle movements, particularly in processes such as cell crawling, chemotaxis, and cytoplasmic streaming. Among these, cell crawling is a significant mechanism that allows cells to move across surfaces, exemplified by the movement of amoebas. This process involves four key steps: protrusion, attachment, translocation, and detachment.

The first step, protrusion, involves the extension of actin-based structures from the cell's surface. These protrusions can take different forms depending on the cell type, with common examples being pseudopodia in amoebas and lamellipodia and filopodia in other organisms. As actin filaments polymerize, they push the plasma membrane outward, forming these protrusions.

Next, in the attachment phase, the protrusions must anchor themselves to the underlying surface. This is achieved through proteins known as integrins, which are transmembrane proteins located on the cell's plasma membrane. Integrins function similarly to Velcro, binding the cell to the extracellular matrix or the surface it is crawling on, thereby providing stability for the cell's movement.

The third step, translocation, occurs once the protrusions are securely attached. The cell then drags its body forward, using the integrin attachments as anchors. This movement is essential because it prevents the cell from retracting back to its original position, allowing it to progress forward effectively.

Finally, in the detachment phase, once the rear of the cell has moved forward to the front, the integrins release their grip, allowing the process to begin anew. This cycle of protrusion, attachment, translocation, and detachment enables cells to navigate their environments efficiently.

Understanding these mechanisms is vital for comprehending how cells interact with their surroundings and respond to various stimuli, such as chemical gradients in the case of chemotaxis, where cells move in response to chemical signals. Additionally, cytoplasmic streaming, characterized by the movement of cytosol within the cell, plays a role in distributing nutrients and organelles, particularly in plant cells and slime molds.

Problem

Pseudopodia are used by ameobas for cell crawling.

True

False

Problem

Which of the following proteins are used so that the cell can attach to the surface on which it is crawling?

ECM proteins

Filaments

Filopedia

Integrins

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Here’s what students ask on this topic:

What are the four steps involved in cell crawling?

Cell crawling involves four key steps: protrusion, attachment, translocation, and detachment. During protrusion, actin filaments extend from the cell membrane, forming structures like pseudopodia. Attachment occurs via integrins, which are transmembrane proteins that anchor the cell to surfaces, similar to Velcro. Translocation is the process where the cell drags its body forward, leveraging these attachments. Finally, detachment releases the integrins, allowing the process to repeat. This mechanism is crucial for processes like chemotaxis, where cells move in response to chemical gradients, showcasing the dynamic nature of cellular motility.

How do integrins function in cell crawling?

Integrins are transmembrane proteins that play a crucial role in cell crawling by facilitating attachment. They anchor the cell to surfaces, acting like Velcro. During the attachment phase, integrins bind to the extracellular matrix or other surfaces, providing a stable point for the cell to pull itself forward during translocation. Once the cell has moved, the integrins release their hold, allowing the cell to detach and repeat the process. This attachment and detachment cycle is essential for effective cell movement.

What is chemotaxis and how is it related to actin-based movement?

Chemotaxis is the movement of a cell in response to chemical gradients in its environment. It is closely related to actin-based movement because the cell uses actin filaments to extend protrusions in the direction of higher chemical concentration. These protrusions, such as pseudopodia, are stabilized by integrins that attach to the surface, allowing the cell to pull itself forward. This dynamic process enables the cell to navigate towards favorable conditions or away from harmful stimuli, demonstrating the importance of actin in cellular motility.

What are pseudopodia and how do they function in cell movement?

Pseudopodia are actin-based protrusions that extend from the cell membrane, playing a crucial role in cell movement. During the protrusion step of cell crawling, actin filaments polymerize to push the membrane outward, forming pseudopodia. These structures then attach to the surface via integrins, providing a stable anchor. The cell can then pull its body forward during translocation, using the pseudopodia as leverage. Once the cell has moved, the pseudopodia detach, allowing the process to repeat. Pseudopodia are essential for processes like chemotaxis and amoeboid movement.

What is cytoplasmic streaming and where can it be observed?

Cytoplasmic streaming is a process where the cytosol (the liquid component inside the cell) moves in a directed flow within the cell. Unlike cell crawling, the cell's exterior remains stationary while the cytosol circulates, resembling streams or rivers. This movement helps distribute nutrients, organelles, and other materials within the cell. Cytoplasmic streaming can be observed in plant cells and slime molds. Under a microscope, you can see the cytosol moving back and forth, facilitating efficient intracellular transport and contributing to cellular function.

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