L2 Intermediate Filaments PDF

Summary

This document provides information about intermediate filaments, including their structure, function, and types. It also covers several microscopy techniques and properties, like resistance to stretching. It appears to be a study document rather than an exam paper.

Full Transcript

BS31004
The Cell Shape
dynamic and Movement
cytoskeleton

L2 : Intermediate filaments
Dr Alan Prescott
[email protected]
Immunofluorescence microscopy
Electron microscopy

actin intermediate
filaments filaments

microtubules
 Intermediate filaments
Most resilient structures in the cell
Can withstand large stresses and strains
Cell type-specific expression patterns
Large multigene family
All similar secondary structure -
-helical, coiled-coils
Some cytoplasmic and others nuclear
Network through cell from plasma membrane
to nucleus
The Intermediate Filament Multigene Family

TYPE V TYPE VI
lamins: filensin
A-type=A,C CP49 TYPE I
B-type=B1,B2,B3
keratins 9-20
trichocyte keratins
TYPE IV Ha1-4, Hax, others
neurofilaments:
NF-L, NF-M
NF-H
-internexin
nestin

TYPE III
vimentin
desmin TYPE II
GFAP keratins 1-8
peripherin trichocyte keratins
Hb1-4, Hbx, others
 Intermediate filament proteins
Robust proteins - need denaturants to dissolve them
– Removal of denaturant (eg. Urea) by dialysis initiates protein assembly
No energy source required
– In-vitro: Di- and monovalent cations, physiological pH, reducing agents at
room temperature
Assembly = dimer - tetramer - higher oligomers
– Heptad repeats in -helices: form coiled coils
– Sequence motifs at either end of rod domain important in assembly
Small soluble pool
Filaments are apolar
– Subunit exchange along whole filament
 Structure of intermediate
filaments
assembles in
parallel dimers
then antiparallel
tetramers

alpha-helical rod domain
L1 L12 L2

1A 1B 2A 2B
E1 V1 H1 H2 V2 E2
head domain tail domain
“stutter”
- another linker?

essential for
filament contributes
assembly to filament
assembly
 Heptad repeats visualised as a
helical wheel

Heptad repeats
are the basis e g
of coiled-coil b c
formation in a d
intermediate
filament f f
protein
dimers c d a
g e b

The -helix is the most common protein structure in
nature
The intermediate filament multigene family

Type I keratin epithelia
Type II keratin epithelia
Type III vimentin-like mesenchyme
Type IV neurofilaments neurones
Type V lamins all nuclei
Type VI (variable)

At least 65 genes in the human genome
Tissue-specific expression
Usefulness in diagnostic pathology
 Visualisation of intermediate filament
protein tetramers by electron microscopy
Intermediate
filaments
polymerise
spontaneously
and rapidly in
vitro

(no ATP/GTP,
cofactors or
associated
proteins
required)
 Intermediate filaments resist stretching but are easily bent

Figure 16-9 Molecular Biology of the Cell (© Garland Science 2008)
Physical properties of the major
cytoskeletal filaments
Structure and assembly of intermediate filaments.
Figure 16-19 Molecular Biology of the Cell (© Garland Science 2008)
Figure 16-8 (part 2 of 2) Molecular Biology of the Cell (© Garland Science 2008)
Keratin intermediate filament
proteins
Type I Proteins
– Acidic isoelectric points / Lower Mr
Type II proteins
– Neutral or basic isolelectric points / Higher Mr

Obligate heteropolymers
Equimolar association of Type I and II required
for assembly
Specific paired expression in tissues
Position of keratins on 2D gels
Type I

Type II
Types I & II: Two families of keratin filament protein

Type II Type I

K2p K9
K1 K10 cornified, dry
K2e
stratified, barrier

K3 K12 corneal

K4 K13 mucosal, wet

K6a K16 fast turnover
K6b
K17
K5 K14 K15 basal
K19
K8 K18 simple
K7 K20
Mirjana Liovic
Keratin intermediate filaments are dynamic, as soluble keratin is incorporated into filaments.
 Immunoperoxidase staining of
keratin K5 in epidermis (basal cells)
in skin
Immunoperoxidase staining of K13 in
buccal epithelium
K10 fluorescence staining
in epidermis
(skin): suprabasal cells
positive, basal cells
are negative
Purification and in vitro assembly of
bovine muzzle keratins
In vitro assembled keratin filaments
 Intermediate filament
attachment sites
KERATINS
– Desmosomes
– Hemidesomosomes

Type III IF proteins
– Desmosomes - GFAP/Desmin
– Ankyrin - plasma membrane
Keratins and desmosomes seen by immunofluorescence
Desmosomes and Intermediate filaments
Intermediate filament - desmosome
networks link cell to cell in tissues
Epidermolysis bullosa simplex
Blistering skin
Dominant inheritance
Basal keratinocytes
are fragile
Faults in keratin
filament formation
caused by mutations in
basal cell keratins
K5 or K14
When intermediate skin blistering
filaments fail... disorders arise
Transgenic mice carrying a mutant keratin gene exhibit blistering similar to that in the human
disease epidermolysis bullosa simplex.
The intermediate filament multigene family

Type I keratin epithelia
Type II keratin epithelia
Type III vimentin-like mesenchyme
Type IV neurofilaments neurones
Type V lamins all nuclei
Type VI (variable)
Different filament networks can coexist in the
same cell

keratin vimentin
Muscle: distinct
locations for
different
intermediate
filaments
 Desmin surrounds the
sarcomere in skeletal muscle
The intermediate filament multigene family

Type I keratin epithelia
Type II keratin epithelia
Type III vimentin-like mesenchyme
Type IV neurofilaments neurones
Type V lamins all nuclei
Type VI (variable)
Lamin intermediate filaments are all
intranuclear

extra piece in helix 1B CaaX
Box (B lamins)

nuclear localization signal

Long c-term
Tail domain
 Intermediate filaments in the
nucleus
A- and B-type lamins,form framework of nuclear lamina
 -helical/coiled coils ~ 55nm long (~350 amino acids):
longer than cytoplasmic rod domains
B-lamins in all nuclei; A-type lamins in differentiated cells
Lamins cannot co-assemble with cytoplasmic filaments
(due to length and sequence characteristics of -helix)
Disassembly/reassembly of the nuclear lamina by
phosphorylation at mitosis
Interconnect nuclear pores; docking sites on nuclear
membrane via LAPs
Lamin meshwork in oocyte nuclei
 GFP-lamin B in live cells

Frans Ramaekers
Nuclear lamina is linked to the cytoplasmic cytoskeleton
The intermediate filament multigene family

Type I keratin epithelia
Type II keratin epithelia
Type III vimentin-like mesenchyme
Type IV neurofilaments neurones
Type V lamins all nuclei
Type VI (variable)
 Cross-linked IFs Less cross-links
in axon (NF-H non- in Glial cells
helical extension)

Figure 16-22 Molecular Biology of the Cell (© Garland Science 2008)
 Neurofilament protein
structure
NF-L

NF-H.. KSP KSP KSP KSP..
Quick-freeze deep etch preparation for EM,
showing cross bridges between neurofilaments
consisting of extended tail domains (Chen et al.,
J Cell Sci. 113, 2000)
 Type VI ?
Lens specific IFproteins:CP49,filensin
Filensin+ CP49+crystallin
Human lens 5 weeks
CP49 Filensin
The intermediate filament multigene family

Type I keratin epithelia
Type II keratin epithelia
Type III vimentin-like mesenchyme
Type IV neurofilaments neurones
Type V lamins all nuclei
Type VI (variable)