Cannibalism




Cannibalism is the act of one individual of a species consuming all or part of another individual of the same species as food. To consume the same species, or show cannibalistic behavior, is a common ecological interaction in the animal kingdom, and has been recorded for more than 1,500 species.[1]Human cannibalism is well-documented, both in ancient and recent times.[2]


The rate of cannibalism increases in nutritionally poor environments as individuals turn to other conspecific individuals as an additional food source.[3] Cannibalism regulates population numbers, whereby resources such as food, shelter and territory become more readily available with the decrease of potential competition. Although it may benefit the individual, it has been shown that the presence of cannibalism decreases the expected survival rate of the whole population and increases the risk of consuming a relative.[3] Other negative effects may include the increased risk of pathogen transmission as the encounter rate of hosts increases.[4] Cannibalism, however, does not—as once believed—occur only as a result of extreme food shortage or artificial/unnatural conditions, but could also occur under natural conditions in a variety of species.[1][5][6]


Cannibalism seems to be especially prevalent in aquatic ecosystems, in which up to approximately 90% of the organisms[vague] engage in cannibalistic activity at some point in their life cycle.[vague] Cannibalism is also not restricted to carnivorous species, as it can be found in herbivores and detritivores.[vague][5] Sexual cannibalism normally involves the consumption of the male by the female individual before, during or after copulation.[3] Other forms of cannibalism include size-structured cannibalism and intrauterine cannibalism.


Behavioural, physiological and morphological adaptations have evolved to decrease the rate of cannibalism in individual species.[3]




Contents





  • 1 Benefits


  • 2 Cost


  • 3 Diseases transmitted through cannibalism


  • 4 Foraging dynamics


  • 5 Sexual cannibalism


  • 6 Size-structured cannibalism

    • 6.1 Filial cannibalism


    • 6.2 Infanticide



  • 7 Intrauterine cannibalism


  • 8 Protection against cannibalism


  • 9 See also


  • 10 References


  • 11 Further reading




Benefits


In environments where food availability is constrained, individuals can receive extra nutrition and energy if they use other conspecific individuals as an additional food source. This would, in turn, increase the survival rate of the cannibal and thus provide an evolutionary advantage in environments where food is scarce.[7] A study conducted on wood frog tadpoles showed that those that exhibited cannibalistic tendencies had faster growth rates and higher fitness levels than non-cannibals.[8] An increase of size and growth would give them the added benefit of protection from potential predators such as other cannibals and give them an advantage when competing for resources [3]


The nutritional benefits of cannibalism may allow for the more efficient conversion of a conspecific diet into reusable resources than fully herbaceous diet; as herbaceous diets may consist of excess elements which the animal has to expend energy to get rid of.[9] This facilitates for faster development; however, a trade-off may occur as there may be less time to ingest these acquired resources. Studies have shown that there is a noticeable size difference between animals fed on a high conspecific diet which were smaller compared to those fed on a low conspecific diet.[9] Hence, individual fitness could only be increased if the balance between developmental rate and size is balanced out, with studies showing that this is achieved in low conspecific diets.[9]


Cannibalism regulates population numbers and benefits the cannibalistic individual and its kin as resources such as extra shelter, territory and food are freed; thereby increasing the fitness of the cannibal;[7] by lowering crowding effects.[10] However, this is only the case if the cannibal recognizes its own kin as this won't hinder any future chances of perpetuating its genes in future generations. The elimination of competition can also increase mating opportunities, allowing further spread of an individual's genes.



Cost


Animals which have diets consisting of mostly conspecific prey (a prey that belongs to the same species) expose themselves to a greater risk of injury and use more energy foraging, while there could be other alternative food sources available in their habitat, which could eventually entail less risk.[3]


In order to combat the risk of personal injury, a predator often targets younger or more vulnerable prey[citation needed]. However, this predator's behavior may result -in some cases- in an increase to the cost associated with the time required to forage for a suitable prey, and consequently could result in a failure to meet the predator's self-set nutritional requirements.[11] In addition, the consumption of conspecific prey may also involve the ingestion of defence compounds and hormones which may impact the developmental growth of the cannibal[9] Hence, predators normally partake in a cannibalistic diet in conditions where alternative food sources are absent or not as readily available.


Failure to recognize kin preys would also be a disadvantage if cannibals were to consume younger individuals. For example, a male stickleback fish may often mistake their own "eggs" for their competitor's eggs, and hence would inadvertently eliminate some of its own genes from the available gene pool.[3] Kin recognition has been observed in tadpoles of the spadefoot toad, whereby cannibalistic tadpoles of the same clutch tended to avoid consuming and harming siblings, while eating other non-siblings.[12]


The act of cannibalism may also encourage the spread of diseases within a population which could negatively impact on the cannibal's fitness levels.[4]



Diseases transmitted through cannibalism


Cannibalism can potentially reduce the prevalence of parasites in the population by decreasing the number of susceptible hosts and indirectly killing the parasite in the host.[13] It has been shown in some studies that the risk of encountering an infected victim increases when there is a higher cannibalism rate, though this risk drops as the number of available hosts decreases.[13] However, this is only the case if the risk of disease transmission is low.[4] Cannibalism is an ineffective method of disease spread as cannibalism in the animal kingdom is normally a one-on-one interaction, and the spread of disease requires group cannibalism; thereby it is rare for a disease to have evolved to rely solely on cannibalism to spread. Usually there are different means of transmission, such as with direct contact, maternal transmission, coprophagy, and necrophagy with different species.[4] Infected individuals are more likely to be consumed than non-infected individuals, thus some research has suggested that the spread of disease may be a limiting factor to the prevalence of cannibalism in the population.[13]


Some examples of diseases transmitted by cannibalism in mammals include Kuru which is a prion disease that degenerates the brain.[4] This disease is prevalent in Papua New Guinea whereby tribes practice endocannibalism in cannibalistic funeral rituals and consume the brains infected by these prions.[14] It is a cerebellar dysfunctional disease which has symptoms including a broad-based gait and decreased motor activity control; however, the disease has a long incubation rate and symptoms may not appear until years later.[14]


Bovine spongiform encephalopathy, or mad cow disease is another prion disease which is usually caused by feeding contaminated bovine tissue to other cattle.[15] It is a neurodegenerative disease and could be spread to humans if the individual were to consume contaminated beef. The spread of parasites such as nematodes may also be facilitated by cannibalism as eggs from these parasites are transferred more easily from one host to another.[4]


Other forms of diseases include sarcocystis and iridovirus in reptiles and amphibians; granulosus virus, chagas disease, and microsporidia in insects; stained prawn disease, white pot syndrome, helminthes and tapeworms in crustaceans and fish.[4]



Foraging dynamics


Cannibalism may become apparent when direct competition for limited resources forces individuals to use other conspecific individuals as an additional resource to maintain their metabolic rates.[3] Hunger drives individuals to increase their foraging rates, which in turn decreases their attack threshold and tolerance to other conspecific individuals. As resources dwindle, individuals are forced to change their behaviour which may lead to animal migration,[16] confrontation, or cannibalism.[3]


Cannibalism rates increase with increasing population density as it becomes more advantageous to prey on conspecific organisms than to forage in the environment.[3] This is because the encounter rate between predator and prey increases, making cannibalism more convenient and beneficial than foraging within the environment. Over time, the dynamics within the population changes as those with cannibalistic tendencies may receive additional nutritional benefits and increase the size ratio of predator to prey.[17] The presence of smaller prey, or prey which are at a vulnerable stage of their life cycle, increases the chances of cannibalism occurring due to the reduced risk of injury.[18] A feedback loop occurs when increasing rates of cannibalism decreases population densities, leading to an increased abundance of alternative food sources; making it more beneficial to forage within the environment than for cannibalism to occur.[3] When population numbers and foraging rates increase, the carrying capacity for that resource in the area may be reached, thus forcing individuals to look for other resources such as conspecific prey.



Sexual cannibalism



Sexual cannibalism is present largely in spiders and other invertebrates, including gastropods.[3] This refers to the killing and consumption of conspecific sexual partners during courtship, and during or after copulation. Normally, it is the female which consumes the conspecific male organism, though there have been some reported cases of the male consuming the adult female, however, this has only been recorded under laboratory conditions.[3][19][20] Sexual cannibalism has been recorded in the female redback spider, black widow spider, praying mantis, and scorpion, among others.


In most species of spiders, the consumption of the male individual occurs before copulation and the male fails to transfer his sperm into the female.[3] This may be due to mistaken identity such as in the case of the orb weaving spider which holds little tolerance to any spider which are present in its web and may mistake the vibrations to be that of a prey item.[3] Other reasons for male consumption before mating may include female choice and the nutritional advantages of cannibalism.[21] The size of the male spider may play a part in determining its reproductive success as smaller males are less likely to be consumed during pre-copulation; however, larger males may be able to prevent the smaller ones from gaining access to the female.[21]
There exists a conflict of interest between males and females, as females may be more inclined to turn to cannibalism as a source of nutritional intake while the male's interest is mostly focused on ensuring paternity of the future generations.[3] It was found that cannibalistic females produced offspring with greater survival rates than non-cannibalistic females, as cannibals produced greater clutches and larger egg sizes.[22] Hence, species such as the male dark fishing spider of the family dolomedes self-sacrifice and spontaneously die during copulation to facilitate for their own consumption by the female, thereby increasing the chance of survivorship of future offspring.[23]


Sexual dimorphism has been theorised to have arisen from sexual selection as smaller males were captured more easily than larger males; however, it is also possible that sexual cannibalism only occurs due to the difference in size between male and females.[3] Data comparing female and male spider body length shows that there is little support for the prior theory as there is not much correlation between body size and the presence of sexual cannibalism. Not all species of spiders which partake in sexual cannibalism exhibit size dimorphism.[3]


The avoidance of sexual cannibalism is present in many male species to increase their rate of survival, whereby the male uses cautionary methods to lower the risk of his consumption.[3] Male orb weaving spiders would often wait for females to moult or to finish eating before attempting to initiate mating, as the females are less likely to attack.[3] Males which are vulnerable to post copulation consumption may gather mating thread to generate a mechanical tension which they could use to spring away after insemination, while other spiders such as the crab spider may tangle the female legs in webs to reduce the risk of the female capturing him.[3] Male choice is common in mantids whereby males were observed to choose fatter females due to the reduced risk of attack and were more hesitant to approach starved females.[24]



Size-structured cannibalism





Nematode Mononchidae eating another Mononchidae.


Size-structured cannibalism is cannibalism in which older, larger, more mature individuals consume smaller, younger conspecifics. In size-structured populations, (where populations are made of individuals of various sizes, ages, and maturities), cannibalism can be responsible for 8% (Belding's ground squirrel) to 95% (dragonfly larvae) of the total mortality,[25] making it a significant and important factor for population[26] and community dynamics.[27]


Size-structured cannibalism has commonly been observed in the wild for a variety of taxa. Vertebrate examples include chimpanzees, where groups of adult males have been observed to attack and consume infants.[28][29][30]



Filial cannibalism



Filial cannibalism is a specific type of size-structured cannibalism in which adults eat their own offspring.[31] Although most often thought of as parents eating live young, filial cannibalism includes parental consumption of stillborn infants and miscarried fetuses as well as infertile and still-incubating eggs. Vertebrate examples include pigs, where savaging accounts for a sizable percentage of total piglet deaths, and cats.[32]


Filial cannibalism is particularly common in teleost fishes, appearing in at least seventeen different families of teleosts.[33] Within this diverse group of fish, there have been many, variable explanations of the possible adaptive value of filial cannibalism. One of these is the energy-based hypothesis, which suggests that fish eat their offspring when they are low on energy as an investment in future reproductive success.[31] This has been supported by experimental evidence, showing that male three-spined sticklebacks,[31][34][35] male tessellated darters,[36] and male sphinx blenny fish[37] all consume or absorb their own eggs to maintain their physical conditions. In other words, when males of a fish species are low on energy, it might sometimes be beneficial for them to feed on their own offspring to survive and invest in future reproductive success.


Another hypothesis as to the adaptive value of filial cannibalism in teleosts is that it increases density-dependent egg survivorship. In other words, filial cannibalism simply increases overall reproductive success by helping the other eggs make it to maturity by thinning out the numbers. Possible explanations as to why this is so include increasing oxygen availability to the remaining eggs,[38] the negative effects of accumulating embryo waste,[39] and predation.[39]


In some species of eusocial wasps, such as Polistes chinensis, the reproducing female will kill and feed younger larvae to her older brood. This occurs under food stressed conditions in order to ensure that the first generation of workers emerges without delay.[40]
Further evidence also suggests that occasionally filial cannibalism might be the unfortunate by-product of cuckoldry in fish. Males consume broods, which may include their own offspring, when they believe a certain percentage of the brood contains genetic material that is not theirs.[34][41]


The dinosaur Coelophysis was once suspected to practice this form of cannibalism but this turned out to be wrong, although Deinonychus may have done. Skeletal remains from subadults with missing parts are suspected of having been eaten by other Deinonychus, mainly full-grown adults.



Infanticide



Infanticide is the killing of a non-adult animal by an adult of the same species. Infanticide is often, but not always, accompanied by cannibalism. It is often displayed in lions; a male lion encroaching on the territory of a rival pride will often kill any existing cubs fathered by other males; this brings the lionesses into heat more quickly, enabling the invading lion to sire his own young. This is a good example of cannibalistic behavior in a genetic context.


In many species of Lepidoptera, such as Cupido minimus and the Indian mealmoth, the first larvae to hatch will consume the other eggs or smaller larvae on the host plant to decrease competition.[42][43]



Intrauterine cannibalism



Intrauterine cannibalism is a behaviour in some carnivorous species, in which multiple embryos are created at impregnation, but only one or two are born. The larger or stronger ones consume their less-developed siblings as a source of nutrients.


In adelphophagy or embryophagy, the fetus eats sibling embryos, while in oophagy it feeds on eggs.[44][45]


Adelphophagy occurs in some marine gastropods (calyptraeids, muricids, vermetids, and buccinids) and in some marine annelids (Boccardia proboscidia in Spionidae).[46]


Intrauterine cannibalism is known to occur in lamnoid sharks[47] such as the sand tiger shark, and in the fire salamander,[48] as well as in some teleost fishes.[45] The Carboniferous period chimaera, Delphyodontos dacriformes, is suspected of having practiced intrauterine cannibalism, also, due to the sharp teeth of the recently born (or possibly aborted) juveniles, and the presence of fecal matter in the juveniles' intestines.[49]



Protection against cannibalism


Animals have evolved protection to prevent and deter potential predators such as those from their own kind.[3] Many amphibian eggs are gelatinous and toxic to decrease edibility. Often, adults would lay their eggs in crevices, holes, or empty nesting sites to hide their eggs from potential conspecific predators which tend to ingest the eggs for an additional nutritional benefit or to get rid of genetic competition. In amphibians, the development of non-aquatic egg deposition has helped increase the survival rates of their young by the evolution of viviparity or direct development.[3] In bees, worker policing occurs to prohibit worker reproduction, whereby workers cannibalize other worker laid eggs.[50] Queen laid eggs have a different scent than worker laid eggs, allowing workers differentiate between the two, allowing them to nurture and protect queen laid eggs rather than cannibalising them.[50] Parental presence at nesting sites is also a common method of protection against infanticide committed by conspecific individuals, whereby the parent exhibit defensive displays to ward off potential predators. Parental investment in newborns are generally higher during their early stages of development whereby behaviours such as aggression, territorial behaviour, and pregnancy blocking become more apparent.[3]


Morphological plasticity helps an individual account for different predation stresses, thereby increasing individual survival rates.[51] Japanese brown frog tadpoles have been shown to exhibit morphological plasticity when they are in a high stress environment where cannibalism between tadpoles and more developed individuals were present. Shifting their morphology plays a key role in their survival, creating bulkier bodies when put into environments where more developed tadpoles were present, to make it difficult for the individuals to swallow them whole.[51] Diet shifts between different stages of development have also evolved to decrease competition between each stage, thereby increasing the amount of food availability so that there is a decreased chance that the individuals will turn to cannibalism as an additional food source.[3]



See also


  • Anthropophage

  • Cannibalism in poultry

  • Cannibalism in China

  • Man-eater

  • Fall armyworm § Cannibalism

  • Uruguayan Air Force Flight 571


References




  1. ^ ab G. A. Polis, The evolution and dynamics of intraspecific predation, Annual Review of Ecology and Systematics 12, 225-251 (1981)


  2. ^ Goldman, Laurence, ed. (1999). The Anthropology of Cannibalism. Greenwood Publishing Group. ISBN 978-0-89789-596-5..mw-parser-output cite.citationfont-style:inherit.mw-parser-output qquotes:"""""""'""'".mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-lock-limited a,.mw-parser-output .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em


  3. ^ abcdefghijklmnopqrstuvwxy Elgar, M.A. & Crespi, B.J. 1992, Cannibalism: ecology and evolution among diverse taxa, Oxford University Press, Oxford [England]; New York.


  4. ^ abcdefg Rudolf, V.H.W. & Antonovics, J. 2007, "Disease transmission by cannibalism: rare event or common occurrence?", Proceedings of the Royal Society B: Biological Sciences, vol. 274, no. 1614, pp. 1205-1210.


  5. ^ ab Laurel R. Fox, Cannibalism in natural populations, Annual Review of Ecology and Systematics 6, 87-106 (1975)


  6. ^ M. A. Elgar and B. J. Crespi (eds), Cannibalism: Ecology and evolution among diverse taxa. (Oxford University Press, New York, 1992)


  7. ^ ab Snyder, W.E., Joseph, S.B., Preziosi, R.F. & Moore, A.J. 2000, "Nutritional Benefits of Cannibalism for the Lady BeetleHarmonia axyridis(Coleoptera: Coccinellidae) When Prey Quality is Poor", Environmental Entomology, vol. 29, no. 6, pp. 1173-1179.


  8. ^ Jefferson, D.M., Hobson, K.A., Demuth, B.S., Ferrari, M.C.O. & Chivers, D.P. 2014, "Frugal cannibals: how consuming conspecific tissues can provide conditional benefits to wood frog tadpoles (Lithobates sylvaticus)", Naturwissenschaften, vol. 101, no. 4, pp. 291-303.


  9. ^ abcd . Simpson, J., Joncour, B. & Nelson, W.A. 2018, "Low levels of cannibalism increase fitness in an herbaceous tortrix moth", Behavioral Ecology and
    Sociobiology, vol. 72, no. 2, pp.
    1-11.



  10. ^ Nishimura, K. & Isoda, Y. 2004, "Evolution of cannibalism: referring to costs of cannibalism", Journal of Theoretical Biology, vol. 226, no. 3, pp. 293-302.


  11. ^ Chapman, J.W. 1999, "Fitness consequences of cannibalism in Spodoptera frugiperda (fall armyworm), Behavioral Ecology, vol. 10, no. 3, pp. 298-303.


  12. ^ . Pfennig, D.W., Reeve, H.K. & Sherman, P.W. 1993, "Kin recognition and cannibalism in spadefoot toad tadpoles", Animal Behaviour, vol. 46, no. 1, pp. 87-94.


  13. ^ abc . Benjamin G Van Allen, Dillemuth, F.P., Flick, A.J., Faldyn, M.J., Clark, D.R., Volker H W Rudolf & Elderd, B.D. 2017, "Cannibalism and Infectious Disease: Friends or Foes?", The American Naturalist, vol. 190, no. 3, pp. 299-312.


  14. ^ ab . Prusiner, S.B. 2008, "Reflections on Kuru", Philosophical Transactions: Biological Sciences, vol. 363, no. 1510, pp. 3654-3656.


  15. ^ . Finberg, K.E. 2004, "Mad cow disease in the United States: an update on bovine spongiform encephalopathy and variant Creutzfeldt-Jakob disease", Clinical
    Microbiology Newsletter, vol. 26,
    no. 15, pp. 113-118.



  16. ^ Milner-Gulland, E.J., Fryxell, J.M. & Sinclair, A.R.E. 2011, Animal migration: a synthesis, Oxford University Press, Oxford.


  17. ^ Brose, U., Ehnes, R.B., Rall, B.C., Vucic-Pestic, O., Berlow, E.L. & Scheu, S. 2008, "Foraging Theory Predicts Predator-Prey Energy Fluxes", Journal of Animal Ecology, vol. 77, no. 5, pp. 1072-1078.


  18. ^ Daly, B. & Long, W.C. 2014, "Inter-cohort cannibalism of early benthic phase blue king crabs (Paralithodes platypus): alternate foraging strategies in different habitats lead to different functional responses", PLOS One, vol. 9, no. 2, pp. e88694.


  19. ^ Kenwyn Blake Suttle (1999). "The Evolution of Sexual Cannibalism". University of California, Berkeley.


  20. ^ Min-Li Tsai & Chang-Feng Dai (2003). "Cannibalism within mating pairs of the parasitic isopod Ichthyoxenus fushanensis" (abstract page). Journal of Crustacean Biology. 23 (3): 662–668. doi:10.1651/C-2343.


  21. ^ ab Elgar, M.A. & Fahey, B.F. 1996, "Sexual cannibalism, competition, and size dimorphism in the orb-weaving spider Nephila plumipes Latreille (Araneae: Araneoidea)", Behavioral
    Ecology, vol. 7, no. 2, pp.
    195-198.



  22. ^ Welke, K.W. & Schneider, J.M. 2012, "Sexual cannibalism benefits offspring survival", Animal Behaviour, vol. 83, no. 1, pp. 201-207.


  23. ^ Schwartz, S., Wagner, W. & Hebets, E. 2016, "Males Can Benefit from Sexual Cannibalism Facilitated by Self-Sacrifice", Current
    Biology, vol. 26, no. 20, pp.
    2794-2799.



  24. ^ Kadoi, M., Morimoto, K. & Takami, Y. 2017, “Male mate choice in a sexually cannibalistic species: male escapes from hungry females in the praying mantid Tenodera angustipennis”, Journal of Ethology, vol. 35, no. 2, pp. 177-185.


  25. ^ G. A. Polis, The evolution and dynamics of intraspecific predation. Annual Review of Ecology and Systematics 12, 225-251 (1981)


  26. ^ David Claessen, A. M. De Roos, and L. Persson, Population dynamic theory of size-dependent cannibalism. Proceedings of the Royal Society of London Series B-Biological Sciences 271 (1537), 333-340 (2004)


  27. ^ V. H. W. Rudolf, Consequences of stage-structured predators: Cannibalism, behavioral effects and trophic cascades. Ecology 88, 2991-3003 (2007)


  28. ^ A. C. Arcadi and R. W. Wrangham, Infanticide in chimpanzees: Review of cases and a new within-group observation from the Kanyawara study group in Kibale National Park. Primates 40 (2), 337-351 (1999).


  29. ^ M. L. Wilson, W. R. Wallauer, and A. E. Pusey, New cases of intergroup violence among chimpanzees in Gombe National Park, Tanzania. International Journal of Primatology 25 (3), 523-549 (2004).


  30. ^ D. P. Watts, J. C. Mitani, and H. M. Sherrow, New cases of inter-community infanticide by male chimpanzees at Ngogo, Kibale National Park, Uganda. Primates 43 (4), 263-270 (2002)


  31. ^ abc Rohwer, S. 1978. Parent Cannibalism of Offspring and Egg Raiding as a Courtship Strategy. American Naturalist 112:429-440.


  32. ^ Hartwell, S, Cats that kill kittens


  33. ^ Manica, A. 2002. Filial cannibalism in teleost fish. Biological Reviews 77:261-277.


  34. ^ ab Mehlis, M., T. C. M. Bakker, L. Engqvist, and J. G. Frommen. 2010. To eat or not to eat: egg-based assessment of paternity triggers fine-tuned decisions about filial cannibalism. Proceedings of the Royal Society B-Biological Sciences 277:2627-2635.


  35. ^ Mehlis, M., T. C. M. Bakker, and J. G. Frommen. 2009. Nutritional benefits of filial cannibalism in three-spined sticklebacks (Gasterosteus aculeatus). Naturwissenschaften 96:399-403.


  36. ^ DeWoody, J. A., D. E. Fletcher, S. D. Wilkins, and J. C. Avise. 2001. Genetic documentation of filial cannibalism in nature. Proceedings of the National Academy of Sciences of the United States of America 98:5090-5092.


  37. ^ Kraak, S. B. M. 1996. Female preference and filial cannibalism in Aidablennius sphynx (Teleostei, Blenniidae); a combined field and laboratory study. Behavioural Processes 36:85-97.


  38. ^ Payne, A. G., C. Smith, and A. C. Campbell. 2002. Filial cannibalism improves survival and development of beaugregory damselfish embryos. Proceedings of the Royal Society of London Series B-Biological Sciences 269:2095-2102.


  39. ^ ab Klug, H., K. Lindstrom, and C. M. S. Mary. 2006. Parents benefit from eating offspring: density-dependent egg survivorship compensates for filial cannibalism. Evolution 60:2087-2095.


  40. ^ Kudo, K.; Shirai, A. (5 January 2012). "Effect of food availability on larval cannibalism by foundresses of the paper wasp Polistes chinensis antennalis". Insect Soc. 59: 279–284.


  41. ^ Gray, S. M., L. M. Dill, and J. S. McKinnon. 2007. Cuckoldry incites cannibalism: male fish turn to cannibalism when perceived certainty of paternity decreases. American Naturalist 169:258-263.


  42. ^ Eeles, Peter. "Small Blue". UK Butterflies.


  43. ^ Boots, Michael (1998-05-01). "Cannibalism and the stage-dependent transmission of a viral pathogen of the Indian meal moth, Plodia interpunctella". Ecological Entomology. 23 (2): 118–122. doi:10.1046/j.1365-2311.1998.00115.x. ISSN 1365-2311.


  44. ^ Thierry Lodé 2001. Les stratégies de reproduction des animaux (reproduction strategies in animal kingdom). Eds Dunod Sciences, Paris


  45. ^ ab Crespi, Bernard; Christina Semeniuk (2004). "Parent-Offspring Conflict in the Evolution of Vertebrate Reproductive Mode". The American Naturalist. 163 (5): 635–654. doi:10.1086/382734. PMID 15122484.


  46. ^ Thomsen O., Collin R. & Carrillo-Baltodano A. (2014). "The Effects of Experimentally Induced Adelphophagy in Gastropod Embryos". PLOS One 9(7): e103366. doi:10.1371/journal.pone.0103366.


  47. ^ Hamlett, William C.; Allison M. Eulitt; Robert L. Jarrell; Matthew A. Kelly (1993). "Uterogestation and placentation in elasmobranchs". Journal of Experimental Zoology. 266 (5): 347–367. doi:10.1002/jez.1402660504.


  48. ^ Stebbins, Robert C.; Nathan W. Cohen (1995). A Natural History of Amphibians. Princeton, NJ: Princeton University Press. p. 9. ISBN 978-0-691-10251-1.


  49. ^ Lund, R. 1980. Viviparity and intrauterine feeding in a new holocephalan fish from the Lower Carboniferous of Montana. Science, 209: 697‑699.


  50. ^ ab Santomauro, G., Oldham, N.J., Boland, W. & Engels, W. 2004, "Cannibalism of diploid drone larvae in the honey bee (Apis mellifera) is released by odd pattern of cuticular substances", Journal of Apicultural Research, vol. 43, no. 2, pp. 69-74.


  51. ^ ab Kishida, O., Trussell, G.C., Nishimura, K. & Ohgushi, T. 2009, "Inducible Defenses in Prey Intensify Predator Cannibalism", Ecology, vol. 90, no. 11, pp. 3150-3158.




Further reading




  • M. A. Elgar and Bernard J. Crespi (eds.). 1992. Cannibalism: Ecology and Evolution of Cannibalism among Diverse Taxa Oxford University Press, New York. (361pp)
    ISBN 0-19-854650-5







Popular posts from this blog

𛂒𛀶,𛀽𛀑𛂀𛃧𛂓𛀙𛃆𛃑𛃷𛂟𛁡𛀢𛀟𛁤𛂽𛁕𛁪𛂟𛂯,𛁞𛂧𛀴𛁄𛁠𛁼𛂿𛀤 𛂘,𛁺𛂾𛃭𛃭𛃵𛀺,𛂣𛃍𛂖𛃶 𛀸𛃀𛂖𛁶𛁏𛁚 𛂢𛂞 𛁰𛂆𛀔,𛁸𛀽𛁓𛃋𛂇𛃧𛀧𛃣𛂐𛃇,𛂂𛃻𛃲𛁬𛃞𛀧𛃃𛀅 𛂭𛁠𛁡𛃇𛀷𛃓𛁥,𛁙𛁘𛁞𛃸𛁸𛃣𛁜,𛂛,𛃿,𛁯𛂘𛂌𛃛𛁱𛃌𛂈𛂇 𛁊𛃲,𛀕𛃴𛀜 𛀶𛂆𛀶𛃟𛂉𛀣,𛂐𛁞𛁾 𛁷𛂑𛁳𛂯𛀬𛃅,𛃶𛁼

Crossroads (UK TV series)

ữḛḳṊẴ ẋ,Ẩṙ,ỹḛẪẠứụỿṞṦ,Ṉẍừ,ứ Ị,Ḵ,ṏ ṇỪḎḰṰọửḊ ṾḨḮữẑỶṑỗḮṣṉẃ Ữẩụ,ṓ,ḹẕḪḫỞṿḭ ỒṱṨẁṋṜ ḅẈ ṉ ứṀḱṑỒḵ,ḏ,ḊḖỹẊ Ẻḷổ,ṥ ẔḲẪụḣể Ṱ ḭỏựẶ Ồ Ṩ,ẂḿṡḾồ ỗṗṡịṞẤḵṽẃ ṸḒẄẘ,ủẞẵṦṟầṓế