Description '', showing the difference in shape of the abdomen Brachyuran crabs are generally covered with a thick
exoskeleton, composed primarily of highly mineralized
chitin. Behind their pair of
chelae (claws) are six walking legs and then two swimming legs. The crab
breathes through
gills on its underside; gills must be at least moist to work. True crabs vary in size from the
pea crab, a few millimeters wide, to the
Japanese spider crab, with a leg span up to . Several other groups of crustaceans with similar appearances – such as
king crabs and
porcelain crabs have
convergently evolved similar features to true crabs, making them good examples of
carcinisation. Brachyuran crabs are often markedly
sexually dimorphic. Males of many species have larger
claws, a tendency that is particularly pronounced in the
fiddler crabs of the genus
Uca (
Ocypodidae). In fiddler crabs, males have one greatly enlarged claw used for communication, particularly for attracting a mate. Another conspicuous difference is the form of the pleon (
abdomen); in most male crabs, this is narrow and triangular in form, while females have a broader, rounded abdomen. This is because female crabs brood fertilised eggs on their
pleopods.
Life cycle '') on Istrian coast,
Adriatic Sea True crabs attract a mate through chemical (
pheromones), visual, acoustic, or vibratory means. Pheromones are used by most fully aquatic species, while
terrestrial and semiterrestrial crabs often use visual signals, such as
fiddler crab males waving their large claws to attract females. The vast number of brachyuran crabs have
internal fertilisation and mate belly-to-belly. For many aquatic species, mating takes place just after the female has moulted and is still soft. Females can store the
sperm for a long time before using it to fertilise their
eggs. When fertilisation has taken place, the eggs are released onto the female's abdomen, below the tail flap, secured with a sticky material. In this location, they are protected during embryonic development. Females carrying eggs are called "berried" since the eggs resemble round berries. When development is complete, the female releases the newly hatched
larvae into the water, where they are part of the
plankton. The release is often timed with the
tidal and light/dark
diurnal cycle. The free-swimming tiny
zoea larvae can float and take advantage of water currents. They have a spine, which probably reduces the rate of predation by larger animals. The zoea of most species must find food, but some crabs provide enough
yolk in the eggs that the larval stages can continue to live off the yolk. '' at spawning time in the
Black Sea, carrying eggs under her abdomen '' climbing up a rock in
Hawaii Each species has a particular number of zoeal stages, separated by
moults, before they change into a
megalopa stage, which resembles an adult crab, except for having the abdomen (tail) sticking out behind. After one more moult, the crab is a
juvenile, living on the bottom rather than floating in the water. This last moult, from megalopa to juvenile, is critical, and it must take place in a habitat that is suitable for the juvenile to survive. Most terrestrial crabs must
migrate down to the ocean to release their larvae; in some cases, this entails very extensive migrations. After living for a short time as larvae in the ocean, the juveniles must do this migration in reverse. In many tropical areas with land crabs, these migrations often result in considerable
roadkill of migrating crabs. Once crabs have become juveniles, they still have to keep moulting many more times to become adults. They are covered with a hard shell, which would otherwise prevent growth. The moult cycle is coordinated by
hormones. When preparing for moult, the old shell is softened and partly eroded away, while the rudimentary beginnings of a new shell form under it. At the time of moulting, the crab takes in a lot of water to expand and crack open the old shell at a line of weakness along the back edge of the
carapace. The crab must then extract all of itself – including its legs,
mouthparts,
eyestalks, and even the lining of the front and back of the digestive tract – from the old shell. This is a difficult process that takes many hours, and if a crab gets stuck, it will die. After freeing itself from the old shell (now called an
exuvia), the crab is extremely soft and hides until its new shell has hardened. While the new shell is still soft, the crab can expand it to make room for future growth.
Behaviour consuming Heterocentrotus trigonarius'' in Hawaii True crabs typically walk sideways (hence the term
crabwise), because of the articulation of the legs which makes a sidelong gait more efficient. Some crabs walk forward or backward, including
raninids,
Libinia emarginata and
Mictyris platycheles. the
Portunidae especially so as their last pair of walking legs are flattened into swimming paddles. Brachyuran crabs are mostly active animals with complex behaviour patterns such as communicating by drumming or waving their
pincers. Crabs tend to be aggressive toward one another, and males often fight to gain access to females. On rocky
seashores, where nearly all caves and crevices are occupied, crabs may also fight over hiding holes.
Fiddler crabs (genus
Uca) dig burrows in sand or mud, which they use for resting, hiding, and mating, and to defend against intruders. True crabs are
omnivores, feeding primarily on
algae, and taking any other food, including
molluscs,
worms, other
crustaceans,
fungi,
bacteria, and
detritus, depending on their availability and the crab species. For many crabs, a mixed diet of plant and animal matter results in the fastest growth and greatest
fitness. Some species are more specialised in their diets, based in plankton, clams or fish. True crabs work together to provide food and protection for their family, and during mating season to find a comfortable spot for the female to release her eggs. Brachyurans are
durophagous, characterised by the high closing force they can exert with their claws. The
Florida stone crab generates the highest muscle force per unit area reported for animals, at 2000 kiloNewtons/m2, while other animals generate 100–300 kN/m2. Crabs of the family Cancridae,
Romaleon antennarium,
R. branneri,
Metacarcinus gracilis,
M. magister,
Glebocarcinus oregonensis, and
Cancer productus, generate closing forces that exceed the force/weight ratio threshold determined for most animals by allometric equations, of 20 body masses1/3; this exceptional muscle strength could be due to greater resting
sarcomere length than those of other animals at 10–18
micrometres, compared to 2.7 micrometres in mammals. == Evolution ==