19.1: Actin Structures

Actin is a huge part of the cytoskeleton and is abundantly found in eukaryotic cells
Though the isoforms of actin have minor differences, they all have very different functions
Globular G-actin and F-actin are both subunits oriented in the same direction
The (-) end of actin filaments is polarized and has an exposed ATP binding site
The filaments of actin are organized into networks and bundles divided by cross-linked proteins
The CH domain family is the main housing of many actin cross-linked proteins

19.2: The Dynamics of Actin Assembly

The actin cytoskeleton is dynamic within cells and the filaments can grow and shrink at a rapid rate
Polymerization of G-actin and nucleation occur at the same time in cells, and once polymerization stabilizes the rates for the addition and loss of subunits becomes equal
Critical concentration (Cc) is the equilibrium of actin monomers and actin filaments
When G-actin is above Cc, filaments grow and when it is below Cc, then filaments depolymerize
The (+) side of actin grows faster than the (-) side, and there is more Cc monomer on the (-) side than there is on the (+) side
Specialized actin building proteins control the length, assembly, and stability of actin filaments
Bacteria and viruses can be moved and the shape of a cell can be changed through the regulated polymerization of actin

Actin filaments interact with myosin isoforms through the actins head domains, though their cellular roles can differ depending on their tail domains
The sliding filament assay can monitor the movement of actin filaments by myosin
Intracellular translocation of various membrane limited vesicles along actin filaments are powered by myosins I, V, and VI
Contractile bundles with primitive sarcomere like organization can be formed by actin filaments and myosin II in nonmuscle cells
A transient bundle of myosin II and actin, known as the contractile ring, is formed through the dividing of the cell, which later pinches into two halves through cytokinesis
Sarcomeres are what the organization of actin thin filaments and myosin thick filaments in skeletal muscle cells are called

Events of migrating cells
- Pseudopodium or lamellipodium extension
- Extended leading edges adhesion to the substratum
- Streaming of the cytosol; forward flow
- Retraction of cells body
Cell locomotion occurs through actin polymerization and branching generated movement, adhesion structures assembly, and myosin II-mediated cortical contraction
The organization and assembly of the cytoskeleton can be induced through external signals, and the internal of both G proteins and calcium can be induced as well
When these are all polarized, the result is cell locomotion

Only cells that show multicellular organization have intermediate filaments in them
Intermediate filaments are grouped into IF proteins, which based on their sequences and tissue distribution, are organized into four different types
Intermediate structures proceed with the assembly of intermediate filaments
Intermediate filaments organization is mediated by various IFAPs and provide cells with structural stability

Actin is a huge part of the cytoskeleton and is abundantly found in eukaryotic cells
Though the isoforms of actin have minor differences, they all have very different functions
Globular G-actin and F-actin are both subunits oriented in the same direction
The (-) end of actin filaments is polarized and has an exposed ATP binding site
The filaments of actin are organized into networks and bundles divided by cross-linked proteins
The CH domain family is the main housing of many actin cross-linked proteins

The actin cytoskeleton is dynamic within cells and the filaments can grow and shrink at a rapid rate
Polymerization of G-actin and nucleation occur at the same time in cells, and once polymerization stabilizes the rates for the addition and loss of subunits becomes equal
Critical concentration (Cc) is the equilibrium of actin monomers and actin filaments
When G-actin is above Cc, filaments grow and when it is below Cc, then filaments depolymerize
The (+) side of actin grows faster than the (-) side, and there is more Cc monomer on the (-) side than there is on the (+) side
Specialized actin building proteins control the length, assembly, and stability of actin filaments
Bacteria and viruses can be moved and the shape of a cell can be changed through the regulated polymerization of actin

Actin filaments interact with myosin isoforms through the actins head domains, though their cellular roles can differ depending on their tail domains
The sliding filament assay can monitor the movement of actin filaments by myosin
Intracellular translocation of various membrane limited vesicles along actin filaments are powered by myosins I, V, and VI
Contractile bundles with primitive sarcomere like organization can be formed by actin filaments and myosin II in nonmuscle cells
A transient bundle of myosin II and actin, known as the contractile ring, is formed through the dividing of the cell, which later pinches into two halves through cytokinesis
Sarcomeres are what the organization of actin thin filaments and myosin thick filaments in skeletal muscle cells are called

Events of migrating cells
- Pseudopodium or lamellipodium extension
- Extended leading edges adhesion to the substratum
- Streaming of the cytosol; forward flow
- Retraction of cells body
Cell locomotion occurs through actin polymerization and branching generated movement, adhesion structures assembly, and myosin II-mediated cortical contraction
The organization and assembly of the cytoskeleton can be induced through external signals, and the internal of both G proteins and calcium can be induced as well
When these are all polarized, the result is cell locomotion

Only cells that show multicellular organization have intermediate filaments in them
Intermediate filaments are grouped into IF proteins, which based on their sequences and tissue distribution, are organized into four different types
Intermediate structures proceed with the assembly of intermediate filaments
Intermediate filaments organization is mediated by various IFAPs and provide cells with structural stability