,
Iris oratoria, attempting to startle a predator with
deimatic behaviour Many species make use of behavioral strategies to deter predators.
Startling the predator Many weakly-defended animals, including
moths,
butterflies,
mantises,
phasmids, and
cephalopods such as octopuses, make use of patterns of threatening or
startling behaviour, such as suddenly displaying conspicuous
eyespots, so as to scare off or momentarily distract a predator, thus giving the prey animal an opportunity to escape. In the absence of toxins or other defences, this is essentially bluffing, in contrast to aposematism which involves honest signals.
Pursuit-deterrent signals stotting,
signalling honestly to the predator that the chase will be unprofitable Pursuit-deterrent signals are behavioral signals used by prey to convince predators not to pursue them. For example,
gazelles
stot, jumping high with stiff legs and an arched back. This is thought to signal to predators that they have a high level of fitness and can outrun the predator. As a result, predators may choose to pursue a different prey that is less likely to outrun them.
White-tailed deer and other prey mammals flag with conspicuous (often black and white) tail markings when alarmed, informing the predator that it has been detected. Warning calls given by birds such as the
Eurasian jay are similarly
honest signals, benefiting both predator and prey: the predator is informed that it has been detected and might as well save time and energy by giving up the chase, while the prey is protected from attack.
Playing dead playing dead Another pursuit-deterrent signal is
thanatosis or playing dead. Thanatosis is a form of bluff in which an animal mimics its own dead body,
feigning death to avoid being attacked by predators seeking live prey. Thanatosis can also be used by the predator in order to lure prey into approaching. An example of this is seen in
white-tailed deer fawns, which experience a drop in heart rate in response to approaching predators. This response, referred to as "alarm
bradycardia", causes the fawn's heart rate to drop from 155 to 38 beats per minute within one beat of the heart. This drop in heart rate can last up to two minutes, causing the fawn to experience a depressed breathing rate and decrease in movement, called tonic immobility. Tonic immobility is a reflex response that causes the fawn to enter a low body position that simulates the position of a corpse. Upon discovery of the fawn, the predator loses interest in the "dead" prey. Other symptoms of alarm bradycardia, such as salivation, urination, and defecation, can also cause the predator to lose interest.
Distraction plover,
distracting a predator from its nest by feigning a broken wing Marine
molluscs such as
sea hares,
cuttlefish,
squid and
octopuses give themselves a last chance to escape by distracting their attackers. To do this, they eject a mixture of chemicals, which may
mimic food or otherwise confuse predators. In response to a predator, animals in these groups release
ink, creating a cloud, and
opaline, affecting the predator's feeding senses, causing it to attack the cloud.
Distraction displays attract the attention of predators away from an object, typically the nest or young, that is being protected, as when some birds feign a broken wing while hopping about on the ground.
Mimicry and aposematism and
monarch are
Müllerian mimics, similar in appearance, unpalatable to predators.
Mimicry occurs when an organism (the mimic) simulates signal properties of another organism (the model) to confuse a third organism. This results in the mimic gaining protection, food, and mating advantages. There are two classical types of defensive mimicry: Batesian and Müllerian. Both involve
aposematic coloration, or warning signals, to avoid being attacked by a predator. This form of mimicry is seen in many
insects. The idea behind Batesian mimicry is that predators that have tried to eat the unpalatable species learn to associate its colors and markings with an unpleasant taste. This results in the predator learning to avoid species displaying similar colours and markings, including Batesian mimics, which are in effect parasitic on the chemical or other defences of the unprofitable models. Some species of octopus can mimic a selection of other animals by changing their skin color, skin pattern and body motion. When a
damselfish attacks an
octopus, the octopus mimics a banded
sea snake. The model chosen varies with the octopus's predator and habitat. Most of these octopuses use Batesian mimicry, selecting an organism repulsive to predators as a model. In
Müllerian mimicry, two or more aposematic forms share the same warning signals, as in
viceroy and
monarch butterflies. Birds avoid eating both species because their wing patterns honestly signal their unpleasant taste. '' combines sharp
spines with
warning coloration Defensive structures Many animals are protected against predators with armour in the form of hard shells (such as most
molluscs and
turtles), leathery or scaly skin (as in
reptiles), or tough chitinous exoskeletons (as in
arthropods). A
spine is a sharp, needle-like structure used to inflict pain on predators. An example of this seen in nature is in the
sohal surgeonfish. These fish have a sharp scalpel-like spine on the front of each of their tail fins, able to inflict deep wounds. The area around the spines is often brightly colored to advertise the defensive capability; predators often avoid the Sohal surgeonfish. Defensive spines may be detachable, barbed or poisonous.
Porcupine spines are long, stiff, break at the tip, and in some species are barbed to stick into a would-be predator. In contrast, the
hedgehog's short spines, which are modified hairs, readily bend, and are barbed into the body, so they are not easily lost; they may be jabbed at an attacker. ==Safety in numbers==