Basic concepts '', an
intestinal parasite, has hooks and
suckers to attach to its
host Parasitism is a kind of
symbiosis, a close and persistent long-term biological interaction between a parasite and its host. Unlike
saprotrophs, parasites feed on living hosts, though some parasitic fungi, for instance, may continue to feed on hosts they have killed. Unlike
commensalism and
mutualism, the parasitic relationship harms the host, either feeding on it or, as in the case of intestinal parasites, consuming some of its food. Because parasites interact with other species, they can readily act as
vectors of pathogens, causing
disease.
Predation is by definition not a symbiosis, as the interaction is brief, but the entomologist
E. O. Wilson has characterised parasites as "predators that eat prey in units of less than one". Within that scope are many possible strategies.
Taxonomists classify parasites in a variety of overlapping schemes, based on their interactions with their hosts and on their
life cycles, which can be complex. An
obligate parasite depends completely on the host to complete its life cycle, while a
facultative parasite does not. Parasite life cycles involving only one host are called "direct"; those with a definitive host (where the parasite reproduces sexually) and at least one intermediate host are called "indirect". An endoparasite lives inside the host's body; an ectoparasite lives outside, on the host's surface. Mesoparasites—like some
copepods, for example—enter an opening in the host's body and remain partly embedded there. Some parasites can be generalists, feeding on a wide range of hosts, but many parasites, and the majority of protozoans and
helminths that parasitise animals, are specialists and extremely host-specific. Much of the thinking on types of parasitism has focused on terrestrial animal parasites of animals, such as helminths. Those in other environments and with other hosts often have analogous strategies. For example, the
snubnosed eel is probably a facultative endoparasite (i.e., it is semiparasitic) that opportunistically burrows into and eats sick and dying fish.
Plant-eating insects such as
scale insects,
aphids, and
caterpillars closely resemble ectoparasites, attacking much larger plants; they serve as vectors of bacteria, fungi and viruses which cause
plant diseases. As female scale insects cannot move, they are obligate parasites, permanently attached to their hosts. exhaled
carbon dioxide, skin odours, visual and heat signatures, and moisture. Parasitic plants can use, for example, light, host physiochemistry, and volatiles to recognize potential hosts.
Major strategies There are six major parasitic
strategies, namely
parasitic castration; directly transmitted parasitism;
trophically-transmitted parasitism;
vector-transmitted parasitism;
parasitoidism; and micropredation. These apply to parasites whose hosts are plants as well as animals. These strategies represent
adaptive peaks; intermediate strategies are possible, but organisms in many different groups have consistently
converged on these six, which are evolutionarily stable.
Parasitic castrators '' (highlighted) attached to
its crab host Parasitic castrators partly or completely destroy their host's ability to reproduce, diverting the energy that would have gone into reproduction into host and parasite growth, sometimes causing gigantism in the host. The host's other systems remain intact, allowing it to survive and to sustain the parasite. of host
crabs. In the case of
Sacculina, the testes of over two-thirds of their crab hosts degenerate sufficiently for these male crabs to develop female
secondary sex characteristics such as broader abdomens, smaller
claws and egg-grasping appendages. Various species of helminth castrate their hosts (such as insects and snails). This may happen directly, whether mechanically by feeding on their gonads, or by secreting a chemical that destroys reproductive cells; or indirectly, whether by secreting a hormone or by diverting nutrients. For example, the
trematode Zoogonus lasius, whose
sporocysts lack mouths, castrates the intertidal marine snail
Tritia obsoleta chemically, developing in its gonad and killing its reproductive cells.
Directly transmitted are directly transmitted
obligate ectoparasites Directly transmitted parasites, not requiring a vector to reach their hosts, include such parasites of terrestrial vertebrates as lice and mites; marine parasites such as
copepods and
cyamid amphipods;
monogeneans; and many species of nematodes, fungi, protozoans, bacteria, and viruses. Whether endoparasites or ectoparasites, each has a single host-species. Within that species, most individuals are free or almost free of parasites, while a minority carry a large number of parasites; this is known as an
aggregated distribution.
Autoinfection, where (by exception) the whole of the parasite's
life cycle takes place in a single primary host, can sometimes occur in helminths such as
Strongyloides stercoralis.
Vector-transmitted protozoan endoparasite
Trypanosoma among human
red blood cells
Vector-transmitted parasites rely on a third party, an intermediate host, where the parasite does not reproduce sexually, For example, the deer tick
Ixodes scapularis acts as a vector for diseases including
Lyme disease,
babesiosis, and
anaplasmosis. Protozoan endoparasites, such as the
malarial parasites in the genus
Plasmodium and sleeping-sickness parasites in the genus
Trypanosoma, have infective stages in the host's blood which are transported to new hosts by biting insects.
Parasitoids Parasitoids are insects which sooner or later kill their hosts, placing their relationship close to predation. Most parasitoids are
parasitoid wasps or other
hymenopterans; others include
dipterans such as
phorid flies. They can be divided into two groups, idiobionts and koinobionts, differing in their treatment of their hosts.
Idiobiont parasitoids sting their often-large prey on capture, either killing them outright or paralysing them immediately. The immobilised prey is then carried to a nest, sometimes alongside other prey if it is not large enough to support a parasitoid throughout its development. An
egg is laid on top of the prey and the nest is then sealed. The parasitoid develops rapidly through its larval and pupal stages,
feeding on the provisions left for it. Most micropredators are
hematophagic, feeding on blood. They include annelids such as
leeches, crustaceans such as
branchiurans and
gnathiid isopods, various
dipterans such as mosquitoes and
tsetse flies, other arthropods such as fleas and ticks, vertebrates such as
lampreys, and mammals such as
vampire bats. Examples to illustrate some of the many possible combinations are given in the table.
Variations Among the many variations on parasitic strategies are hyperparasitism, or facultative or obligate parasitoids whose hosts are either conventional parasites or parasitoids. Hyperparasites can control their hosts' populations, and are used for this purpose
in agriculture and to some extent in
medicine. The controlling effects can be seen in the way that the
CHV1 virus helps to control the damage that
chestnut blight,
Cryphonectria parasitica, does to
American chestnut trees, and in the way that
bacteriophages can limit bacterial infections. It is likely, though little researched, that most pathogenic microparasites have hyperparasites which may prove widely useful in both agriculture and medicine.
Social parasitism Social parasites take advantage of interspecific interactions between members of
eusocial animals such as
ants,
termites, and
bumblebees. Examples include the large blue butterfly,
Phengaris arion, its larvae employing
ant mimicry to parasitise certain ants,
Bombus bohemicus, a bumblebee which invades the hives of other bees and takes over reproduction while their young are raised by host workers, and
Melipona scutellaris, a eusocial bee whose virgin queens escape killer workers and invade another colony without a queen. An extreme example of interspecific social parasitism is found in the ant
Tetramorium inquilinum, an obligate parasite which lives exclusively on the backs of other
Tetramorium ants. A mechanism for the evolution of social parasitism was first proposed by Carlo Emery in 1909. Now known as "
Emery's rule", it states that social parasites tend to be closely related to their hosts, often being in the same genus. Intraspecific social parasitism occurs in parasitic nursing, where some individual young take milk from unrelated females. In
wedge-capped capuchins, higher ranking females sometimes take milk from low ranking females without any reciprocation.
Brood parasitism In
brood parasitism, the hosts suffer increased parental investment and energy expenditure to feed parasitic young, which are commonly larger than host young. The growth rate of host nestlings is slowed, reducing the host's fitness. Brood parasites include birds in different families such as
cowbirds,
whydahs,
cuckoos, and
black-headed ducks. These do not build nests of their own, but leave their eggs in nests of other
species. In the family
Cuculidae, over 40% of cuckoo species are obligate brood parasites, while others are either facultative brood parasites or provide parental care. The eggs of some brood parasites
mimic those of their hosts, while some cowbird eggs have tough shells, making them hard for the hosts to kill by piercing, both mechanisms implying selection by the hosts against parasitic eggs. The adult female
European cuckoo further mimics a predator, the
European sparrowhawk, giving her time to lay her eggs in the host's nest unobserved. Host species often combat parasitic egg mimicry through egg
polymorphism, having two or more egg phenotypes within a single population of a species. Multiple phenotypes in host eggs decrease the probability of a parasitic species accurately "matching" their eggs to host eggs.
Kleptoparasitism In
kleptoparasitism (from Greek κλέπτης (
kleptēs), "thief"), parasites steal food gathered by the host. The parasitism is often on close relatives, whether within the same species or between species in the same genus or family. For instance, the many lineages of
cuckoo bees lay their eggs in the nest cells of other
bees in the same family. Kleptoparasitism is uncommon generally but conspicuous in birds; some such as
skuas are specialised in pirating food from other seabirds, relentlessly chasing them down until they disgorge their catch.
Sexual parasitism A unique approach is seen in some species of
anglerfish, such as
Ceratias holboelli, where the males are reduced to tiny
sexual parasites, wholly dependent on females of their own species for survival, permanently attached below the female's body, and unable to fend for themselves. The female nourishes the male and protects him from predators, while the male gives nothing back except the sperm that the female needs to produce the next generation.
Adelphoparasitism Adelphoparasitism, (from Greek
ἀδελφός (
adelphós), brother), also known as sibling-parasitism, occurs where the host species is closely related to the parasite, often in the same family or genus. In the citrus blackfly parasitoid,
Encarsia perplexa, unmated females may lay
haploid eggs in the fully developed larvae of their own species, producing male offspring, while the marine worm
Bonellia viridis has a similar reproductive strategy, although the larvae are planktonic.
Illustrations Examples of the major variant strategies are illustrated. File:Pteromalid hyperparasitoid.jpg|A hyperparasitoid
pteromalid wasp on the cocoons of its host, itself a parasitoid
braconid wasp File:Maculinea arion Large Blue Upperside SFrance 2009-07-18.jpg|The
large blue butterfly is an
ant mimic and social parasite. File:Eastern Phoebe-nest-Brown-headed-Cowbird-egg.jpg|In
brood parasitism, the host raises the young of another species: here a
cowbird's egg in an
Eastern phoebe's nest. File:Great Skua (cropped).jpg|The
great skua is a powerful
kleptoparasite, relentlessly pursuing other seabirds until they disgorge their catches of food. File:Северная церапия (cropped).jpg|The male of the
anglerfish species
Ceratias holboelli lives as a tiny
sexual parasite permanently attached below the female's body. File:Encarsia perplexa.jpg|
Encarsia perplexa (centre), a parasitoid of
citrus blackfly (lower left), is also an adelphoparasite, laying eggs in larvae of its own species == Taxonomic range ==