Parental care is the investment a parent puts into their offspring—which includes protecting and feeding the young, preparing burrows or nests, and providing eggs with yolk. There is great variation in parental care in the animal kingdom. In some species, the parents may not care for their offspring at all, while in others the parents exhibit single-parental or even bi-parental care. As with other topics in behavioral ecology, interactions within a family involve conflicts. These conflicts can be broken down into three general types: sexual (male–female) conflict, parent–offspring conflict, and sibling conflict.
Types of parental care There are many different patterns of
parental care in the animal kingdom. The patterns can be explained by physiological constraints or ecological conditions, such as mating opportunities. In invertebrates, there is no parental care in most species because it is more favorable for parents to produce a large number of eggs whose fate is left to chance than to protect a few individual young. In other cases, parental care is indirect, manifested via actions taken before the offspring is produced, but nonetheless essential for their survival; for example, female
Lasioglossum figueresi sweat bees excavate a nest, construct brood cells, and stock the cells with pollen and nectar before they lay their eggs, so when the larvae hatch they are sheltered and fed, but the females die without ever interacting with their brood. In birds, biparental care is the most common, because reproductive success directly depends on the parents' ability to feed their chicks. Two parents can feed twice as many young, so it is more favorable for birds to have both parents delivering food. In mammals, female-only care is the most common. This is most likely because females are internally fertilized and so are holding the young inside for a prolonged period of
gestation, which provides males with the opportunity to desert. Females also feed the young through
lactation after birth, so males are not required for feeding. Male parental care is only observed in species where they contribute to feeding or carrying of the young, such as in
marmosets. In fish there is no parental care in 79% of
bony fish. In fish with parental care, it usually limited to selecting, preparing, and defending a nest, as seen in
sockeye salmon, for example. Also, parental care in fish, if any, is primarily done by males, as seen in
gobies and
redlip blennies. In species with internal fertilization, the female is usually the one to take care of the young. In cases where fertilization is external the male becomes the main caretaker.
Familial conflict Familial conflict is a result of trade-offs as a function of lifetime
parental investment. Parental investment was defined by
Robert Trivers in 1972 as "any investment by the parent in an individual offspring that increases the offspring's chance of surviving (and hence reproductive success) at the cost of the parent's ability to invest in other offspring". Parental investment includes behaviors like guarding and feeding. Each parent has a limited amount of parental investment over the course of their lifetime. Investment trade-offs in offspring quality and quantity within a brood and trade offs between current and future broods leads to conflict over how much parental investment to provide and to whom parents should invest in. There are three major types of familial conflict: sexual, parent–offspring, and sibling–sibling conflict. This cued parental response is a type of behavioral negotiation between parents that leads to stabilized compensation. Sexual conflicts can give rise to antagonistic co-evolution between the sexes to try to get the other sex to care more for offspring. For example, in the waltzing fly
Prochyliza xanthostoma, ejaculate feeding maximizes female reproductive success and minimizes the female's chance of mating multiply. Evidence suggests that the sperm evolved to prevent female waltzing flies from mating multiply in order to ensure the male's paternity. We also see sex-ratio conflict between the queen and her workers in social
hymenoptera. Because of
haplodiploidy, the workers (offspring) prefer a 3:1 female to male sex allocation while the queen prefers a 1:1 sex ratio. Both the queen and the workers try to bias the sex ratio in their favor. In some species, the workers gain control of the sex ratio, while in other species, like
B. terrestris, the queen has a considerable amount of control over the colony sex ratio. Lastly, there has been recent evidence regarding
genomic imprinting that is a result of parent–offspring conflict. Paternal genes in offspring demand more maternal resources than maternal genes in the same offspring and vice versa. This has been shown in imprinted genes like
insulin-like growth factor-II.
Parent–offspring conflict resolution Parents need an honest signal from their offspring that indicates their level of hunger or need, so that the parents can distribute resources accordingly. Offspring want more than their fair share of resources, so they exaggerate their signals to wheedle more parental investment. However, this conflict is countered by the cost of excessive begging. Not only does excessive begging attract predators, but it also retards chick growth if begging goes unrewarded. Thus, the cost of increased begging enforces offspring honesty. Another resolution for parent–offspring conflict is that parental provisioning and offspring demand have actually coevolved, so that there is no obvious underlying conflict.
Cross-fostering experiments in
great tits (
Parus major) have shown that offspring beg more when their biological mothers are more generous. Therefore, it seems that the willingness to invest in offspring is co-adapted to offspring demand.
Sibling–sibling conflict The lifetime
parental investment is the fixed amount of parental resources available for all of a parent's young, and an offspring wants as much of it as possible. Siblings in a brood often compete for parental resources by trying to gain more than their fair share of what their parents can offer. Nature provides numerous examples in which sibling rivalry escalates to such an extreme that one sibling tries to kill off broodmates to maximize parental investment (
See Siblicide). In the
Galápagos fur seal, the second pup of a female is usually born when the first pup is still suckling. This competition for the mother's milk is especially fierce during periods of food shortage such as an
El Niño year, and this usually results in the older pup directly attacking and killing the younger one. In some bird species, sibling rivalry is also abetted by the
asynchronous hatching of eggs. In the
blue-footed booby, for example, the first egg in a nest is hatched four days before the second one, resulting in the elder chick having a four-day head start in growth. When the elder chick falls 20-25% below its expected weight threshold, it attacks its younger sibling and drives it from the nest. Sibling relatedness in a brood also influences the level of sibling–sibling conflict. In a study on
passerine birds, it was found that chicks begged more loudly in species with higher levels of
extra-pair paternity.
Brood parasitism feeding a common cuckoo chick Some animals
deceive other species into providing all parental care. These brood parasites selfishly exploit their hosts' parents and host offspring. The
common cuckoo is a well known example of a brood parasite. Female cuckoos lay a single egg in the nest of the host species and when the cuckoo chick hatches, it ejects all the host eggs and young. Other examples of brood parasites include
honeyguides,
cowbirds, and the
large blue butterfly. Brood parasite offspring have many strategies to induce their host parents to invest parental care. Studies show that the common cuckoo uses vocal mimicry to reproduce the sound of multiple hungry host young to solicit more food. Other cuckoos use visual deception with their wings to exaggerate the begging display. False gapes from brood parasite offspring cause host parents to collect more food. Another example of a brood parasite is
Phengaris butterflies such as
Phengaris rebeli and
Phengaris arion, which differ from the cuckoo in that the butterflies do not oviposit directly in the nest of the host, an ant species
Myrmica schencki. Rather, the butterfly larvae release chemicals that deceive the ants into believing that they are ant larvae, causing the ants to bring the butterfly larvae back to their own nests to feed them. as well as
Bombus bohemicus, a bumblebee that relies on host workers of various other
Bombus species. Similarly, in
Eulaema meriana, some Leucospidae wasps exploit the brood cells and nest for shelter and food from the bees.
Vespula austriaca is another wasp in which the females force the host workers to feed and take care of the brood. In particular,
Bombus hyperboreus, an Arctic bee species, is also classified as a brood parasite in that it attacks and enslaves other species within their subgenus,
Alpinobombus to propagate their population. ==Mating systems==