L4 Cytoskeletons

Objectives

• Discuss the components of the Cytoskeleton

• Discuss Actin Polymerization

• Discuss Actin Binding Proteins

• Discuss Intermediate Filaments and Microtubules

1. What is Cytoskeleton made up of?

   • Microtubules, Microfilament, Intermediate Filaments

2. What are the 3 functions of Microtubules?

   1. Chromosomal Movements during nuclear divisions (mitosis/meiosis)

   2. Formation of Cilia and Flagella in certain cell types

   3. Intracellular Transport of Materials

3. Elaborate Microtubules’ role in Chromosomal Movements

   • MTs pull and push chromosomes to enable genetic material separation into daughter cells

4. What is a Mitotic Spindle

   • Disassembled Cytoplasmic MTs which are later reassembled

5. What is Cilia?

   • Slender protuberances that project from a larger cell body to provide movement in fluids and across epithelial cells of the respiratory tract

6. What are Flagella?

   • Lash-like appendage, longer than cilia, that protrudes from a cell body and helps moves an entire cell through fluids

7. What are Dynein and Kinesin?

   • MT Motor Proteins that facilitate movement of intracellular cargo such as membrane-bound organelles and transport vesicles on MT tracks

8. What are Microtubules composed of?

   • Alpha and Beta Tubulin Heterodimers that forms into linear chains called Protofilaments

9. What structure can form from Protofilaments?

   • 13 protofilaments forms the outer wall of a cylindrical microtubule structure with a GTP cap that is immediately hydrolyzed to GDP after being added to the structure

10. Explain the dynamic instability of a protofilament

    • microtubules are continuously growing and shrinking

    • when the GTP cap is gone after hydrolysis catches up, the tubulin heterodimers dissociate from protofilament by peeling back

11. What is a Centrosome?

    • the major Microtubule Organizing Center (MTOC) of the cell by regulating MTs by number, location, and cytoplasmic orientation

    • origin of most microtubules (MTs)

12. What is the purpose of Microfilaments?

    • involved in the movement of cell

13. What is the purpose of Intermediate Filaments?

    • located in the cytosol, between the nuclear envelope and plasma membrane, to provide support to the cell and resists mechanical stress

    • has 6 categories: Types I-VI

14. What is Actin?

    • present in most cell types and forms microfilaments that radiate from the nucleus to the plasma membrane to regulate the physical state of the cytosol

15. What type of tissue is Actin typically known to be found in?

    • Muscle cells to help with muscle contraction

16. What is Actin Polymerization?

    • Globular Actin (G-Actin) monomers are polymerized to form an Filamentous Actin (F-Actin) molecule

17. What energy is required for actin polymerization?

    • ATP is hydrolyzed to ADP + P_i

18. Explain the structure of F-Actin

    • Two stands of G-Actin monomers wrap around each other to form a mature F-Actin microfilament with an + end for new added monomers and a - end to subtract monomers

19. What are the phases of Actin Polymerization

    1. Lag Phase

    2. Polymerization

    3. Steady State

20. What is treadmilling?

    • The process of addition to the + end and subtraction from the - end of G-Actin monomers at an equal rate

21. What are the 2 possible physical nature of cytosol?

    • Gel and Soluble — “Gel-Sol”

22. Describe the Gel State.

    • a more firm state due to more structured actin

23. Describe the Soluble state.

    • a more soluble state due to less structured or more fragmented actin

24. In which state of Gel-Sol is actin continuously treadmilling?

    • both gel and sol states

25. What are Actin-Binding Proteins

    • regulators of the gel-sol nature of the cytosol

26. What is Cofilin?

    • an Actin-Binding protein that PREVENTS F-Actin lengthening to create a more STABLE structure

27. What roles is Cofilin a part of?

    • Cell Motility, Migration, Shape, and Metabolism

28. What is Gelsolin?

    • an Actin-Binding protein that FRAGMENTS the F-Actin to create a more SOLUBLE state of the cytosol

29. What is Spectrin?

    • an actin-binding protein family that binds to F-Actin to strengthen and support the Erythrocyte membrane

30. How does Spectrin contribute to erythrocytes’ shape?

    • maintains its Biconcave Disc Shape which maximizes the Hemoglobin and Oxygen carried by each RBC

31. What can occur when there is an absence or presence of abnormal Spectrin?

    • Hereditary Spherocytosis

32. What can Spherical Erythrocytes cause?

    • Hemolytic Anemia due to its low membrane pliability, making it susceptible to lyse

      • can be life threatening and require frequent blood transfusions

33. What is Dystrophin

    • an actin-binding protein that provides tensile strength to muscle fibers and contributes to the framework for signaling molecules

34. What are can possibly be a result due to defects in Dystrophin?

    • Muscular Dystrophy (MD)

      • muscle wasting

    • Duchenne MD (DMD) and Becker MD

      • mutation in the dys gene

35. What function can Actin participate in in nonmuscle cells?

    • Contractile functions due to the effects of an ATP hydrolyzing motor protein of the Myosin family

36. Explain how Myosin II and F-Actin interacts to mediate local contractions.

    • Myosin slides F-Actin over each other which can create a contractile ring to divide a cell into two daughter cells in mitosis

37. How does Myosin II and F-Actin affect cells?

    • provides stiffness to cell cortex and prevent deformation of the plasma membrane

38. Why is Contraction important?

    • Wound healing, cell division, cytokinesis, and cytoplasmic division following nuclear division of mitosis