Contractile Proteins

Question 1

The structural, spatial and mechanical functions of cells depend on what?

Answer 1

The cytoskeleton which is a remarkable system of filaments scaffolding the cell

Question 2

What do actin and actin binding proteins determine?

Answer 2

The shape of the cell, its locomotion and ability to divide into two

Question 3

What is myosin (motor protein)?

Answer 3

Molecular machine that converts biochemical energy from ATP hydrolysis to mechanical energy that can move filaments on proteins or move organelles along filaments

Question 4

Describe actin

Answer 4

Major component of cytoskeleton
Subunits = globular actin or G actin which can rapidly diffuse in the cytosol
Associates with ATP or ADP
Actin monomer is divided by a central cleft into two equal sized lobes

Question 5

Describe G-actin subunit assembly/polymerization

Answer 5

Assemble from head to tail to form a tight right handed helix called filamentous actin/microfilaments/F-actin

Question 6

How are actin filaments polar and how is it important?

Answer 6

Have a slower growing minus end and a faster growing plus end
Important in both their assembly and in establishing a unique direction of myosin movement relative to actin

Question 7

What are the three different phases of assembly of actin polymers?

Answer 7

Nucleation (lag) phase 
Elongation (growth phase) 
Steady stage (equilibrium phase)

Question 8

Actin filaments become organized into what?

Answer 8

Higher order structures forming bundles of 3D networks within cells
May be associated with other cell structures such as the plasma membrane

Question 9

Where are actin filaments abundant?

Answer 9

Beneath the plasma membrane where they form a network that provides mechanical support, determines cell shape and allows movement of the cell surface thereby enabling cells to migrate, engulf particles and divide

Question 10

What is organization of actin into networks regulated by?

Answer 10

A variety of actin binding proteins which are critical components of the actin cytoskeleton

Question 11

Cross linking of F actin is achieved by what?

Answer 11

Accessory proteins that typically have at least two actin binding domains (ABD)

Question 12

What are bundling or cross linking proteins?

Answer 12

Typically small ridged proteins that force the actin filaments to align closely with each other

Question 13

The nature of association of actin filaments is determined by what?

Answer 13

Size and shape of the cross linking proteins

Question 14

What are the two general types of structures actin can assemble into?

Answer 14

Actin bundles or networks

Question 15

What are actin bundles?

Answer 15

Cross linked into closely packed parallel arrays

Polarity of actin filaments same

Question 16

What are actin networks?

Answer 16

Loosely cross linked in orthogonal arrays that form 3D meshwork with more flexible gel-like properties
Makes cell flexible
Polarity of actin filament different

Question 17

What is an important mechanism by which cells control shape and movement?

Answer 17

Regulation of actin filament formation

Question 18

What is the issue with small oligomers of actin?

Answer 18

Associate spontaneously but are unstable and disassemble readily

Question 19

What is filament nucleation?

Answer 19

For a new actin filament to form subunits must assemble into an initial aggregate (nucleus made of 3 actin monomers) that is stabilized by multiple-subunit contacts 
This core (aggregate) then elongates rapidly by the addition of more subunits

Question 20

Describe assembly of actin polymers

Answer 20

First go through filament nucleation
Then actin filaments grow by reversible addition of monomers to both ends
Plus end elongates 5-10 times faster than the minus end

Question 21

Following filament assembly what occurs to the bound ATP on the actin monomers?

Answer 21

It is hydrolyzed to ADP and Pi which plays a key role in the assembly and dynamic behavior of actin filaments

Question 22

How is actin polymerization reversible?

Answer 22

Filaments can depolymerize as needed by the dissociation of actin monomers

Question 23

An equilibrium exists between which two structures of actin?

Answer 23

Actin monomers and filaments which is dependent on concentration of free monomers

Question 24

Describe the critical concentration of actin monomers

Answer 24

The critical concentration of actin monomers at which the rate of their polymerization into filaments = the rate of dissociation
At this concentration the monomers and filaments are in apparent equilibrium

Question 25

What are parallel bundles?

Answer 25

Made of closely spaced actin filaments in parallel arrangement
Fimbrin monomer binds to actin filaments and has 2 actin binding domains (ABD)
Holds two parallel filaments close together together

Question 26

What are the two types of actin bundles?

Answer 26

Parallel and contractile bundles

Question 27

What is the function of parallel bundles?

Answer 27

Increase cell surface and gives the structure stability
Allows for placement of additional receptors and channels which facilitate signaling, transport, uptake of nutrients, etc

Question 28

What is an example of a structure that has parallel actin bundles?

Answer 28

Microvilli

Question 29

What are contractile bundles?

Answer 29

Loosely bundled actin filaments
Loose structure is due to cross linking protein known as alpha actinin dimers
Actin filaments are separated by a greater distance
E.g. contractile ring in mitosis which allows squeezing of cytoplasm by contractile ring to cause cell division
Also allows myosin to interact during contraction

Question 30

What are actin networks?

Answer 30

Actin filaments held together by large actin binding proteins such as filamin
Creates a 3D meshwork
Present in cells that need to withstand forces

Question 31

What is spectrin?

Answer 31

Actin binding protein located in erythrocytes

Spectrin-actin network interacts with membrane proteins via interactions with ankyrin and protein 4.1

Question 32

What is hereditary spherocytosis?

Answer 32

Caused by mutations in erythrocyte cortical cytoskeleton proteins such as spectrin, ankyrin or protein 4.1
Characteristics of the disease include impaired deformability which is required for movement from large vessels to capillaries, reduced stability of RBCs and spherical RBCs, anemia, splenomegaly, jaundice

Question 33

What is myosin?

Answer 33

A superfamily of motor proteins
20 different types in eukaryotes
All move along actin filaments via ATP hydrolysis

Question 34

Describe the structure of myosin II

Answer 34

Bipolar filaments
Heads exposed at both ends
Tails associate to form shaft of filament
Neck binds light chains

Question 35

What are the three major domains of myosin?

Answer 35

Head, neck and tail

Question 36

Describe the head of myosin

Answer 36

Contain actin binding and ATP binding sites

Has ATPase activity

Question 37

Describe the neck of myosin

Answer 37

Flexible region

Binds myosin light chain peptides

Question 38

Describe the tail of myosin

Answer 38

Intertwine to bring myosin head regions in close proximity

Bind membrane/organelles

Question 39

What are the 3 different types of myosin?

Answer 39

Class I, II and V

All three move toward the + end of actin filaments

Question 40

What is the function of class I myosin?

Answer 40

Membrane association and endocytosis

Question 41

What is the function of class II myosin?

Answer 41

Muscle contraction

Question 42

What is the function of class V myosin?

Answer 42

Organelle transport

Question 43

Describe the structure of myosin class I

Answer 43

One heavy chain with a head domain and neck domain (only single headed myosin)

Question 44

Describe myosin class II

Answer 44

Two heavy chains - each with head and neck domain that binds two different light chains 
Heavy chain long helical tail homodimerizes via coiled-coiled interaction 
Only class that can assemble into bipolar fragments through tail interactions

Question 45

Describe myosin class V

Answer 45

Two heavy chains and six light chains per neck
Also homodimerizes
End of tails interact with specific receptors on organelles, which they transport along filament tracks

Question 46

Describe the steps of ATP driven myosin movement along actin filaments

Answer 46

1. ATP binding causes conformational change in the myosin head actin binding domain and head release from actin
2. The head hydrolyzes ATP which induces rotation of the head causing a “cocked” state that stores the energy released by ATP hydrolysis as elastic energy
3. Myosin remains in the cocked state until it binds to an actin filament
4. Binding to actin causes myosin to release Pi which release the elastic energy to drive the power stroke involving a conformational change in the neck region which moves the actin filament with respect to the end of the myosin neck
5. The head remains tightly bound to the actin filament unit ADP is released

Question 47

What occurs in the absence of ATP?

Answer 47

Myosin head attaches firmly to the actin filament and is short lived in living muscle but cause rigor mortis stiffness in death when cells lack ATP

Question 48

The power stroke mechanism is proportional to what?

Answer 48

Length of the myosin neck domain

Longer neck domain -> increases rate of movement

Question 49

Describe the filaments found in skeletal muscle

Answer 49

Thick filaments made of 6 myosin polypeptide chains

Thin filaments made of 3 proteins including actin, tropomyosin and troponin

Question 50

What is the sarcomere stabilized by?

Answer 50

Capping and scaffolding proteins

Question 51

What are actin filaments stabilized by?

Answer 51

Stabilized on their + ends by CapZ and on their - ends by tropomodulin

Question 52

What is nebulin?

Answer 52

A large protein that extends along the thin actin filaments all the way from the Z line to tropomodulin to which it binds
Has a number of actin binding repeats
Length of nebulin determines the length of thin filaments

Question 53

What are thick filaments of a sarcomere made of?

Answer 53

Myosin II

Question 54

What is the structure of titin?

Answer 54

A large protein that has its head associated with the Z line/disc and extends to the middle of the thick filament where another titin molecule extends to the subsequent thin filaments

Question 55

What is the function of titin?

Answer 55

Holds the thick filaments in the middle of the sarcomere and prevents overstretching (thick filaments remain interdigitated b/w the thin filaments)

Question 56

What do mutations in titin cause?

Answer 56

Cardiomyopathies

Question 57

What are the cytosolic Ca concentrations in skeletal muscle under resting conditions?

Answer 57

Low due to the activity of SERCA that pumps them from the cytosol into the SR

Question 58

What does SERCA establish in skeletal muscle?

Answer 58

Reservoir of Ca in the SR

Question 59

Describe contraction of skeletal muscle

Answer 59

1. Nerve impulse at a NMJ triggers an AP in the plasma membrane
2. AP travels down T-tubules
3. Depolarization stimulates opening of voltage gated Ca channels in the SR membrane
4. Extracellular Ca is brought into the cell and causes the release of Ca from the SR and subsequent elevation of cytosolic Ca concentration occurs
5. Elevated Ca induces conformational changes in tropomyosin and troponin which permit the myosin-actin interactions and hence contraction

Question 60

What does the phosphorylation of myosin LC by MLCK cause?

Answer 60

Unfolds the myosin II which is now active and can assemble into bipolar fragments to participate in contraction

Question 61

Describe non-muscle cell contraction

Answer 61

Non-muscle cells contain several types of actin-myosin structures similar to skeletal muscle fibers
Formed in a transient manner as needed by the cell
Ex. Cytokinesis

Question 62

What is dystrophin?

Answer 62

Part of a protein complex that links the cytoskeleton of muscle fibers to the surrounding of CT (basal lamina)

Question 63

Dystrophin is a long protein with numerous redundant coils that provides what?

Answer 63

A structural link between the cytoskeleton of the muscle cell and the ECM
Acts like a shock absorber during contraction and stabilizes the sarcolemma

Question 64

What is Duchenne’s muscular dystrophy associated with?

Answer 64

Loss of dystrophin

Question 65

What is Duchenne’s muscular dystrophy?

Answer 65

An x-linked recessive disorder caused by an abnormal dystrophin gene
Cause progressive muscle wasting
Pts are confined to wheelchairs by 12 and die by respiratory failure by age 22

Question 66

What is Becker’s muscular dystrophy?

Answer 66

A milder form of DMD with a later onset

Question 67

Defects in dystrophin weaken what?

Answer 67

Muscle cells and muscle fibers

Question 68

In those with DMD, eventually the body cant keep up with repair which leads to what?

Answer 68

Death of skeletal muscle cells and muscle degeneration

Question 69

What mutation do DMD pts have?

Answer 69

Out of frame mutations -> little to no expression of dystrophin

Question 70

Pts with BMD have which mutation?

Answer 70

In frame mutation -> smaller protein with partial function of dystrophin

Question 71

What are some treatments for DMD?

Answer 71

Gene therapy, dystrophin replacement, drugs to prevent exon skipping