Lecture #8 - Cytoskeleton and ish

Question 1

Cytoskeleton - what does it do and what three things does it contain?

Answer 1

• Helps maintain cell SHAPE and POSITION of organelles (organelles don’t function optimally unless right position)
• Unlike the body’s skeletal system the cytoskeleton rapidly disassembles and reassembles - allows CHANGES in cell structure
• Highly dynamic but still provides stability
• microtubules
• intermediate filaments
• microfilaments

Question 2

Microtubules

1. Composed of?
2. May radiate out from?
3. Resist?
4. Provide?
5. Look like?

Answer 2

1. Composed of TUBULIN subunits
2. May radiate out from an organizing centre (CENTROSOME)
3. Resist COMPRESSION
4. Provide cell MOTILITY:
   • whole cell
   • organelle movement
5. Pipe in a helix form - can build up larger or become smaller

Question 3

Whole cell motility - how does it work?

Answer 3

Move by CILIA: “rowing-like” motion perpendicular to the direction of movement
• when cells are fixed in place the beating of cilia can move fluid past the cells
• Power stroke and recovery stroke (comes back up bendingly)

*Can also move by Flagella - undulates

Question 4

Organelle motility

1. How does it work?
2. Does what?

Answer 4

1. ATP-powered motor proteins can “walk” organelles along microtubules
2. Can thus TRANSPORT vesicles to targets or damaged organelles from distant sites e.g nerve terminals

The vesicles have a receptor motor

Question 5

Microfilaments

1. What is it?
2. Forms what?
3. Resists what?
4. What does it do?
5. Provides what?
6. Look like?
7. Function

Answer 5

1. Double chain of ACTIN subunits
2. Forms LINEAR STRANDS and they run in three directions (with the aid of branching proteins)
3. Resists TENSION
4. Cortical network under plasma membrane helps maintain cell SHAPE
5. Provide a GEL-LIKE consistency to outer cytoplasm (meshwork makes it somewhat solid)
6. Ropes that are twisted together into one long rope
7. Cell shape, changes in cell shape, muscle contraction, cytoplasmic streaming in plant cells, cell motility (amoeboid movement), division of animal cells

Question 6

Linear actin microfilaments support movement in…..

Answer 6

Linear actin microfilaments support movement
• in muscle - they are arranged in parallel with the motor protein myosin
• can achieve cellular or organism movement

(even in non-muscle cells, there are actin filaments and they interact with myosin but they’re more ‘spectacular’ in muscles)

Question 7

Intermediate Filaments:

1. Composed of?
2. More or less dynamic MT/MF
3. Function?
4. Look like?

Answer 7

1. Various PROTEINS including
   keratins, vimentins and
   lamins
2. LESS DYNAMIC than MT or MF (because not made of subunits - can’t build, breakdown quickly etc)
3. Maintain cell SHAPE (TENSION bearing elements)
   • ANCHOR organelles
   • formation of nuclear lamina
   • neuronal processes – neurofilaments
4. Supercoiled into “CABLES”

Question 8

How are cells joined together?

Answer 8

Cell junctions (tight, desmosomes and dap) and the ECM (?)

Question 9

Tight junctions

1. Do what?
2. May form what?
3. Prevent what?

Answer 9

1. Keeps neighbouring cells TIGHTLY PRESSED together
2. May form a continuous
   SEAL
3. PREVENT movement of FLUID
   across cell layers

Question 10

Desmosomes

1. Are what?
2. Attachments between what?
3. Act like what?

Answer 10

1. Anchoring junctions
2. Attachments between sheets of cells (e.g. muscle - when contracts, all the cells come w/ it bc held together by des)
3. Act like rivets (a “torn muscle” is a torn desmosome)

Question 11

Gap junctions

1. What are they?
2. Allow what?

Answer 11

1. A point of CYTOPLASMIC
   CONTACT between cells
2. Ions and molecules may
   pass from cell to cell
   • allow rapid intercellular
   COMMUNICATION

Question 12

Extracellular matrix

1. What is it?
2. Composed of what?

Answer 12

1. In many tissues, cells do not make direct contact with other cells - cells lie within an extracellular matrix (no junctions bw fibroblasts)
2. Material secreted by cells (fibroblasts)
   • mainly glycoproteins (protein with carbohydrate) - proteoglycans in Hubs
   • most abundant glycoprotein is collagen

Question 13

Collagen fibres - give 3 details (they’re the purple thick things around the cell in the ECM)

Answer 13

1. Great tensile strength
2. Approx 50% of total body protein
3. Like other proteins collagen is “turned over” and must be replaced

It’s similar in structure to intermediate filaments

Question 14

How does scurvy come about?

Answer 14

A lack of vitamin C results in a failure of collagen synthesis
• hydroxyproline amino acids not formed
• collagen fibres cannot cross-link correctly
• results in scurvy

Question 15

Collagen embedded in a proteoglycan matrix (green thin strings around cell in ECM)

Answer 15

Proteins with extensive sugar additions
• traps water in ECM
• resists compression and retains shape

Question 16

And all the other ish around the cell in the ECM/surface

Answer 16

Other glycoproteins (fibronectins) attach cells to ECM

Membrane proteins (integrins) link ECM to cytoskeleton - a communication link from ECM to the cell interior