Chapter 9.2 PDF - Cytoskeleton and Cell Motility

Summary

This document provides an overview of cytoskeletal components, specifically focusing on intermediate filaments and actin filaments. It details their structure, function, and the processes of assembly and disassembly, along with discussing their roles in cell function. It also highlights the importance of these elements in maintaining cellular integrity and mechanical strength. This material is suited for higher-level biology and cell biology courses.

Full Transcript

CHAPTER 9-part 2
The Cytoskeleton and Cell Motility:
Actin and Intermediate Filaments
Required reading: relevant sections of Chapter 9

9.2-1
9.1 | Overview of the Major Functions of the Cytoskeleton
Properties of cytoskeletal components

9.2-2
 9.7 | Intermediate Filaments

Intermediate filaments have only
been identified in animal cells

Intermediate filaments are strong,
flexible, ropelike fibers that
provide mechanical strength to
cells that are subjected to
physical stress

Unlike actin filaments and
microtubules, IFs are a chemically
heterogeneous group of
structures that are encoded by
approximately 70 different genes

IFs can be divided into five major
classes based on the type of cell
in which they are found (as well
as biochemical, genetic, and
immunologic criteria)
9.2-3

Intermediate filament assembly does not involve ATP or GTP hydrolysis
9.7 | Intermediate Filaments

IFs radiate through the
cytoplasm of a wide variety of
animal cells and are often
interconnected to other
cytoskeletal filaments by thin,
wispy cross-bridges

In many cells, these cross-
bridges consist of an
elongated dimeric protein
called plectin

Each plectin molecule has a
binding site for an
intermediate filament at one
end and, depending on the
isoform, a binding site for
another intermediate filament,
microfilament, or microtubule
at the other end 9.2-4
 9.7 | Intermediate Filaments
Intermediate Assembly and Disassembly

The basic building block of IF assembly is
thought to be a rodlike tetramer
Eight tetramers associate with one
another in a lateral arrangement to form a
filament that is one unit in length (about
60 nm)
Unit lengths of filaments associate with
one another in an end-to-end fashion to
form the highly elongated intermediate
filament
None of these assembly steps require the
direct involvement of either ATP or GTP
The tetrameric building blocks lack
polarity as does the assembled filament,
which distinguishes IFs from other
cytoskeletal elements

9.2-5
 9.7 | Intermediate Filaments
Intermediate Assembly and Disassembly
Intermediate filaments are less
sensitive to chemical agents
than other types of cytoskeletal
elements and more difficult to
solubilize Localization of
injected
When labeled keratin subunits
biotinylated
are injected cells, they are keratin during a
rapidly incorporated into 20-minute label
existing IFs period
The subunits are not
incorporated at the ends of the
filament but into the filament’s
Distribution of
interior
intermediate
Unlike the other two major filaments in the
cytoskeletal elements, cell as revealed
by anti-keratin
assembly and disassembly of
antibodies
IFs are controlled primarily by
subunit phosphorylation and
dephosphorylation 9.2-6
Example of intermediate filaments: keratins
Keratins:
Provide strength to epithelial cells
The most diverse IF family
~ 20 found in different types of
human epithelial cells
~ 10 more specific to hair and nails
Disulfide bonded keratin structures
survive even in cell death
(hair, nails, claws,scales)
Keratins tend to be rich in cyteines

9.2-7
 14.2 | Prophase
The Dissolution of the Nuclear Envelope and Partitioning of Cytoplasmic Organelles
at the end of prophase

The three major components of the
nuclear envelope are disassembled
nuclear pores
Nuclear membranes
nuclear lamina composed of
intermediate filaments (lamin)
and membrane associated proteins
The integrity of the nuclear membranes is
first disrupted mechanically as holes are
torn into the nuclear envelope by
cytoplasmic dynein molecules associated
with the outer nuclear membrane

Phosphorylation of human lamin causes
de-polymerization and subsequent
disassembly of the lamina

9.2-8
Pathologies of intermediate filaments
epidermolysis bullosa simplex (EBS), is from mutations in the
gene that encodes a keratin polypeptide

9.2-9
Pathologies of intermediate filaments

Example: desmin-related myopathy -mutations in the gene that encodes desmin
Desmin integrates the various components of a muscle cell
Leads to skeletal muscle weakness, cardiac
arrhythmias, and eventual congestive heart failure

Other diseases related to
pathology of intermediate filaments

9.2-10
Ovrview of
Cytoskeletalal
organization

9.2-11
 9.10 | Actin

Microfilaments: (actin)

Motility
Shape
Structural support
Muscle contraction

9.2-12
 9.8 | Actin and Myosin
Actin Structure

Minus (- ) end of G-actin

The most abundant protein in cells
G actin = globular
F actin = filamentous
In the presence of ATP actin monomers
Plus (+) end of G-actin
polymerize into a flexible helical filament
The ATP binding cleft is oriented in the same direction in all actin subunits
(monomers)in the filament
Minus (-) end: the end of the filament with an exposed binding cleft
(also called pointed end) binds to the plus end in a filament
Plus (+) end: the other end (also called barbed end) is where the minus
9.2-13
end of an G actin binds
 9.8 | Actin
Actin Filament Assembly and Disassembly

In-vitro: plus and minus ends have
different polymerization rates

In vivo:
polymerization only
occurs at the plus
end by ATP-actin

Minus end of G-actin

The minus end
may be anchored

Only ADP-actin
dissociates
9.2-14
Microfilaments form various structures
(in accordance with their function)

Actin polymerization and organization is
regulated by Actin Binding Proteins

9.2-15
Actin binds to many, many accessory proteins in eukaryotic cells
Myosins are actin-based motor proteins
All share a characteristic “head” or
“motor” domain (ATP-ase activity)
Grouped into conventional and
unconventional myosins
Move towards + end (except myosin VI)
Type II (conventional) myosins are best
studied, responsible for muscle
contraction, cytokinesis, cell migration

Note the possibly confusing
terminology: The type II
myosins have subclasses,
one of which is Myosin II

One of the
Unconventional
myosins are
associated with
transport vesicles
9.2-16
and organelles
 9.8 | Myosin: The Molecular Motor of Actin
Conventional (Type II) Myosins
Each myosin II molecule is composed
of six polypeptide chains:
one pair of heavy chains
two pairs of light chains
organized in such a way as to produce
a highly asymmetric protein.

Myosin II consists of
(1) a pair of globular heads that
contain the catalytic site of the
molecule
(2) a pair of necks, each consisting of
a single, uninterrupted α helix and
two associated light chains
(3) a single, long, rod-shaped tail
formed by the intertwining of long
a-helical sections of the two heavy
chains
Assembles into fibers with
the ends of the tails pointing toward the 9.2-17
center, and the globular heads pointing away
9.9 | Muscle Organization and Contraction
Skeletal muscle: voluntary movement
Muscle: bundles of parallel muscle
fibers (cells) joined by tendons to the
bones that the muscle must move
Fibers: each fiber is a multinucleate
cell formed during embryogenesis
and specialized for contraction

Myofibril: thinner cylindrical strands that
make up a muscle fiber and consist of
repeating units of sarcomeres 9.2-18

Sarcomere: the contractile unit of myofibrils
each of which has a very specific organization
9.9 | Muscle Organization and Contraction
Organization of Sarcomeres

Each sarcomere extends from
one Z line to the next Z line
Thin filaments (actin)
Thick filaments (myosin)

9.2-19
Sarcomere organization Actin has an orientation:
Plus ends are anchored at Z-lines
CapZ caps actin at plus end
Tropomodulin caps the (-) end and
regulates the length of actin filaments
Nebulin: repeating actin binding motifs
that binds actin filament to Z line
Myomesin: bundles the myosin filaments
Titin: extends through the myosin (thick)
filament and attaches to the Z line – helps
to prevent tearing of muscle

9.2-20
9.9 | Muscle Organization and Contraction
The Sliding Filament Model
of Muscle Contraction

During contraction, the myosin
molecules pull the surrounding thin
filaments (actin), forcing them to slide
toward the center of the sarcomere
Individual myosins work
asynchronously, so that only a fraction
are active at any given instant
The “neck” acts as a lever, amplifying
the conformational change caused by
ATP hydrolysis

9.2-21
Contractile cycle
Conformational changes (mechanical) in the myosin
head couple ATP hydrolysis (chemical) to movement
1) ATP binds to the cleft in the myosin head,
releasing myosin from actin
2 and 3) ATP hydrolysis to ADP+Pi causes
weak binding to actin
4) Pi release causes tighter binding and the
power stroke that moves the thin filament
toward the center of the sarcomere
5) ADP is released, freeing the ATP binding
cleft
1) ATP binds to the cleft in the myosin head,
releasing myosin
9.2-22

No ATP = rigor mortis
Calcium ions trigger contraction via troponin and tropomyosin
Tropomyosin masks the myosin Troponin complex (3 subunits): binds to
binding sites on the actin filament tropomyosin Both have regulatory roles
in contraction

Calcium binding to troponin relieves the
tropomyosin blockages of the interaction
between actin and myosin head

1) Motor neuron excitation signal
2) Signal transduction pathway leads to
Ca2+ release from the SR
3) Ca2+ binds to troponin (TnC subunit),
causing conformation shift
4) Troponin conformation shift moves
tropomyosin out of place
5) Myosin binding site on actin is exposed
6) When excitation signaling ceases, Ca2+
9.2-23 are pumped back into SR, muscle relaxes
Pathologies associated with myosins

Familial hypertrophic cardiomyopathy:
Genetically dominant inherited mutation in
myosin (~2 per 1000 people)

Over 40 different point mutations can lead to:
Heart enlargement
Abnormally small coronary vessels
Cardiac arrhythmias

9.2-24
9.11 Actin-Binding Proteins Myosins are actin-based
Actin polymerization and organization motor proteins
is regulated by Actin Binding Proteins

9.2-25
 9.11: Actin polymerization is regulated by G-actin binding proteins

There is a (large) pool of soluble actin
monomers generated in a cell whose
polymerization is controlled by actin binding
proteins

Cofilin: binds ADP actin and severs filaments
promoting depolymerization (at minus end)
Profilin
functions as an adenine nucleotide
exchange factor
Binds to ADP actin (at the plus end),
changing the conformation and allowing
binding of ATP
Binding results in dissociation of profilin Minus end of an
ATP actin then either joins a growing actin monomer
filament at the plus end OR is bound by:
Thymosin:
sequesters G- actin preventing
polymerization 9.2-26
Displacement of thymosin allows binding
of G-actin to the plus end
9.11: Capping proteins stabilize F-actinCapping the plus end of the
filament prevents further growth

Capping the minus end prevents
loss of subunits

In muscle both ends of an actin
filament are capped stabilizing the
sarcomere and preventing either
addition or loss of actin subunits

plus end

9.2-27
9.11 Proteins that crosslink actin filaments
Actin can be linked to other actin filaments
Actin can be linked to the cell membrane (indirectly)

Cell cortex: network of actin filaments and
accessory proteins that underlies the
plasma membrane in most eukaryotic cells

9.-26
9.2-28
9.11 Proteins that promote actin branching and growth
Minus end of
Plus end
G-actin

Arp2/3 complex:
(actin related proteins)
nucleates new branches off
the sides of existing filaments

Arps are activated by WASPs
(Wiskott-Aldrich syndrome
protein)

Note orientation of minus and
9.2-29
plus ends and that G-actin is
added to the plus end
9.12: Cell Motiity -growing filaments can push the cell membrane forward

1-2)Extracellular signal recognized and signal
transduction cascade initiated
3-4) WASP activates Arp complex and Arp
nucleate new actin filaments
5) result is branch formation at plus end
6) Membrane is pushed forward
7) Caps terminate elongation
8) Oldest part of filament at the minus end
9) F-actin servered and depolymerized at
minus end
10) Profilin exchanges GDP to GTP 9.2-30
Regulation of the actin skeleton by Rho family of small GTPases

Rho family GTPases often are bound to a guanine
nucleotide dissociation inhibitor (GDI) in the cytosol
9.2-31
The GDI prevents Rho from interacting with it’s GEF at the
plasma membrane
The role of actin in endocytosis

9.2-32
 Learning objectives
Know the general characteristics of intermediate filaments
Understand the role of plectins and lamins
Know what regulates the assembly and disassembly of intermediate filaments
Understand the structure of G-actin and F-actin and always be clear on polarity
Know what myosins are, that there are two classes and the role of myosin II in muscle contraction
Be clear on the role of the following structures and proteins in muscle and be clear on the polarity
of skeletal muscle contraction

Cap Z
tropomodulin
myomesin
nebulin
titan
troponin
tropomyosin
Understand the structure of G-actin and assembly of F-actin in vivo
(this includes the profilin, cofilin and thymosin cycle)
Understand the role of the Arp complex and the fundamentals of branching and elongation and how
this relates to cell motility

Know what Rho is
Know what a GDI is and it’s role
Be able to compare and contrast microtubules, intermediate filaments and actin 9.2-33