Microscopy of keratin filaments inside cells.
'Keratins' are a family of
fibrous structural proteins; tough and insoluble, they form the hard but
nonmineralized structures found in
reptiles,
birds,
amphibians and
mammals. They are rivaled as
biological materials in toughness only by
chitin.
There are various types of keratins, even within a single
animal.
Variety of animal uses
Keratins are the main constituent of structures that grow from the skin:
★ the ''α-keratins'' in the
hair (including
wool),
horns,
nails,
claws and
hooves of mammals
★ the harder ''
β-keratins'' in the
scales and claws of
reptiles, their
shells (
chelonians, such as
tortoise,
turtle,
terrapin), and in the
feathers,
beaks, and claws of
birds. (These keratins are formed primarily in
beta sheets. However, beta sheets are also found in α-keratins.)
[1]
Arthropods such as
crustaceans often have parts of their
armor or
exoskeleton made of keratin, sometimes in combination with
chitin.
The
baleen plates of filter-feeding
whales are made of them.
They can be integrated in the chitinophosphatic material that makes up the
shell and
setae in many
brachiopods.
Keratins are also found in the
gastrointestinal tracts of many animals, including
roundworms (who also have an outer layer made of keratin).
Although it is now difficult to be certain, the scales, claws, some
protective armour and the beaks of
dinosaurs would, almost certainly, have been composed of a type of keratin.
In
Crossopterygian fish, the outer layer of
cosmoid scales was keratin.
Cornification
In mammals there are soft
epithelial keratins, the
cytokeratins, and harder
hair keratins. As certain skin cells
differentiate and become
cornified, pre-keratin
polypeptides are incorporated into
intermediate filaments. Eventually the
nucleus and
cytoplasmic
organelles disappear,
metabolism ceases and cells undergo a
programmed death as they become fully keratinized.
Cells in the
epidermis contain a structural matrix of keratin which makes this outermost layer of the
skin almost waterproof, and along with
collagen and
elastin, gives skin its strength. Rubbing and pressure cause keratin to proliferate with the formation of protective
calluses — useful for athletes and on the fingertips of musicians who play stringed instruments. Keratinized epidermal cells are constantly shed and replaced (see
dandruff).
These hard,
integumentary structures are formed by intercellular cementing of fibers formed from the dead, cornified cells generated by
specialized beds deep within the skin. Hair grows continuously and feathers
moult and regenerate. The constituent
proteins may be
phylogenetically homologous but differ somewhat in
chemical structure and super
molecular organization. The
evolutionary relationships are complex and only partially known. Multiple
genes have been identified for the β-keratins in feathers, and this is probably characteristic of all keratins.
Molecular biology and biochemistry
The properties which make structural proteins like keratins useful depend on their supermolecular aggregation. These depend on the properties of the individual
polypeptide strands, which depend in turn on their
amino acid composition and sequence. The
α-helix and
β-sheet motifs, and disulfide bridges, are crucial to the
conformations of
globular, functional proteins like
enzymes, many of which operate semi-independently, but they take on a completely dominant role in the architecture and aggregation of keratins.
Glycine and alanine
Keratins contain a high proportion of the smallest of the 20 amino acids,
glycine, whose "
side group" is a single
hydrogen atom; also the next smallest,
alanine, with a small and uncharged
methyl group. In the case of β-sheets, this allows
sterically-unhindered hydrogen bonding between the
amino and
carboxyl groups of
peptide bonds on adjacent protein chains, facilitating their close alignment and strong binding. Fibrous keratin molecules can twist around each other to form
helical intermediate filaments.
Limited interior space is the reason why the triple helix of the (unrelated) structural protein
collagen, found in skin,
cartilage and
bone, likewise has a high percentage of glycine. The connective tissue protein
elastin also has a high percentage of both glycine and alanine. Silk
fibroin, considered a β-keratin, can have these two as 75–80% of the total, with 10–15% serine, with the rest having bulky side groups. The chains are antiparallel, with an alternating C → N orientation.
[1] A preponderance of amino acids with small,
unreactive side groups is characteristic of structural proteins, for which H-bonded close packing is more important than
chemical specificity.
Disulfide bridges
In addition to intra- and intermolecular hydrogen bonds, keratins have large amounts of the
sulfur-containing amino acid
cysteine, required for the
disulfide bridges that confer additional strength and rigidity by permanent, thermally-stable
crosslinking—a role sulfur bridges also play in
vulcanized rubber. Human hair is approximately 14% cysteine. The pungent smells of burning hair and rubber are due to the sulfur compounds formed. Extensive disulfide bonding contributes to the in
solubility of keratins, except in
dissociating or
reducing agents such as
urea.
The more flexible and elastic keratins of hair have fewer interchain disulfide bridges than the keratins in mammalian
fingernails, hooves and claws (homologous structures), which are harder and more like their analogs in other vertebrate classes. Hair and other α-keratins consist of
α-helically-coiled single protein strands (with regular intra-chain
H-bonding), which are then further twisted into superhelical ropes that may be further coiled. The β-keratins of reptiles and birds have β-pleated sheets twisted together, then stabilized and hardened by disulfide bridges.
Silk
The
silk fibroins produced by
insects and
spiders are often classified as keratins, though it is unclear whether they are phylogenetically related to vertebrate keratins.
Silk found in insect
pupae, and in
spider webs and egg casings, also has twisted β-pleated sheets incorporated into fibers wound into larger supermolecular aggregates. The structure of the
spinnerets on spiders’ tails, and the contributions of their interior
glands, provide remarkable control of fast
extrusion. Spider silk is typically about 1 to 2 micrometres (µm) thick, compared with about 60 µm for human hair, and more for some mammals. (Hair, or
fur, occurs only in mammals.) The
biologically and
commercially useful properties of
silk fibers depend on the organization of multiple adjacent protein chains into hard,
crystalline regions of varying size, alternating with flexible,
amorphous regions where the chains are
randomly coiled.
[2] A somewhat analogous situation occurs with
synthetic polymers such as
nylon, developed as a silk substitute. Silk from the
hornet cocoon contains doublets about 10 µm across, with cores and coating, and may be arranged in up to 10 layers; also in plaques of variable shape. Adult hornets also use silk as a
glue, as do spiders.
Pairing
Clinical significance
Some
infectious fungi, such as those which cause
athlete's foot and
ringworm, feed on keratin.
Diseases caused by mutations in the keratin genes include:
★
Epidermolysis bullosa simplex
★
Ichthyosis bullosa of Siemens
★
Epidermolytic hyperkeratosis
See also
★
Acne
★
Keratosis pilaris
★
Intermediate filament
★
Desmosome
★
Tinea Versicolor
Additional images
References
1. New aspects of the alpha-helix to beta-sheet transition in stretched hard alpha-keratin fibers, Kreplak L, Doucet J, Dumas P, Briki F, , , Biophys J, 2004
2. http://www.amonline.net.au/spiders/toolkit/silk/structure.htm
External links
★
Composition and β-sheet structure of silk
★
Spider silk fiber structure
★
Hair-Science.com's entry on the miroscopic elements of hair
★
keratin antibody review
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