Jump to content

Dung beetle

From Wikipedia, the free encyclopedia
(Redirected from Dung-beetle)

Dung beetle
Scarabaeus viettei (syn. Madateuchus viettei, Scarabaeidae) in dry spiny forest close to Mangily, western Madagascar
Scarabaeus viettei [sv] (syn. Madateuchus viettei, Scarabaeidae) in dry spiny forest close to Mangily, western Madagascar
Scientific classificationEdit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Coleoptera
Infraorder: Scarabaeiformia
Superfamily: Scarabaeoidea
Groups included
Cladistically included but traditionally excluded taxa

Dung beetles are beetles that feed on feces. Some species of dung beetles can bury dung 250 times their own mass in one night.[1]

Many dung beetles, known as rollers, roll dung into round balls, which are used as a food source or breeding chambers. Other dung beetles like Euoniticellus intermedius, known as tunnelers, bury the dung wherever they find it. A third group, the dwellers, neither roll nor burrow: they simply live in dung. They are often attracted by the feces collected by burrowing owls. There are dung beetle species of various colors and sizes, and some functional traits such as body mass (or biomass) and leg length can have high levels of variability.[2]

All the species belong to the superfamily Scarabaeoidea, most of them to the subfamilies Scarabaeinae and Aphodiinae of the family Scarabaeidae (scarab beetles). As most species of Scarabaeinae feed exclusively on feces, that subfamily is often dubbed true dung beetles. There are dung-feeding beetles which belong to other families, such as the Geotrupidae (the earth-boring dung beetle). The Scarabaeinae alone comprises more than 5,000 species.[3]

The nocturnal African dung beetle Scarabaeus satyrus is one of the few known invertebrate animals that navigate and orient themselves using the Milky Way.[4][5] The daily dung of one elephant can support 2,000,000 beetles.[6]

Taxonomy

[edit]

Dung beetles are not a single taxonomic group; dung feeding is found in a number of families of beetles, so the behaviour cannot be assumed to have evolved only once.

Ecology and behavior

[edit]
Dung beetle rolling a ball of dung in the Addo Elephant National Park, South Africa

Dung beetles live in many habitats, including desert, grasslands and savannas,[10] farmlands, and native and planted forests.[11] They are highly influenced by the environmental context,[2] and do not prefer extremely cold or dry weather. They are found on all continents except Antarctica. They eat the dung of herbivores and omnivores, and prefer that produced by the latter.[12] Many of them also feed on mushrooms and decaying leaves and fruits. The Neotropical Deltochilum valgum, D. kolbei and D. viridescens are carnivores with a strong preference for preying upon millipedes.[13] Two other species from Brazil, Canthon dives and Canthon virens, prey on queens and other winged forms of leafcutter ants.[14] One species from the Iberian Peninsula, Thorectes lusitanicus, feeds on acorns.[15] Dung beetles do not necessarily have to eat or drink anything else, because the dung provides all the necessary nutrients.[citation needed]

Most dung beetles search for dung using their sensitive sense of smell. Some smaller species simply attach themselves to the dung-providers to wait for the dung. After capturing the dung, a dung beetle rolls it, following a straight line despite all obstacles. Sometimes, dung beetles try to steal the dung ball from another beetle, so the dung beetles have to move rapidly away from a dung pile once they have rolled their ball to prevent it from being stolen. Dung beetles can roll up to 10 times their weight. Male Onthophagus taurus beetles can pull 1,141 times their own body weight: the equivalent of an average person pulling six double-decker buses full of people.[16]

A species of dung beetle (the African Scarabaeus zambesianus) navigates by polarization patterns in moonlight,[17] the first animal known to do so.[18][19][20][21] Dung beetles can also navigate when only the Milky Way or clusters of bright stars are visible,[22] making them the only insects known to orient themselves by the Milky Way.[23][22] Research using 1 kg bolus of elephant dung found that a larger number exploit it during the night (13,700) than during the day (3,330).[6] The eyes of dung beetles are superposition compound eyes typical of many scarabaeid beetles;[24][25] The sequence of images shows a sequence of the beetle rolling a dung ball. It does this to navigate.

Cambefort and Hanski (1991) classified dung beetles into three functional types based on their feeding and nesting strategies such as – Rollers, Tunnelers and Dwellers. The "rollers" roll and bury a dung ball either for food storage or for making a brooding ball. In the latter case, two beetles, one male and one female, stay around the dung ball during the rolling process. Usually it is the male that rolls the ball, while the female hitch-hikes or simply follows behind. In some cases, the male and the female roll together. When a spot with soft soil is found, they stop and bury the ball, then mate underground. After the mating, one or both of them prepares the brooding ball. When the ball is finished, the female lays eggs inside it, a form of mass provisioning.

Some species do not leave after this stage, but remain to safeguard their offspring. The dung beetle goes through a complete metamorphosis. The larvae live in brood balls made with dung prepared by their parents. During the larval stage, the beetle feeds on the dung surrounding it.

The behavior of the beetles was poorly understood until the studies of Jean Henri Fabre in the late 19th century. For example, Fabre corrected the myth that a dung beetle would seek aid from other dung beetles when confronted by obstacles. By observation and experiment, he found the seeming helpers were in fact awaiting an opportunity to steal the roller's food source.[26]

They are widely used in ecological research as a good bioindicator group to examine the impacts of climate disturbances, such as extreme droughts[27] and associated fires,[28] and human activities on tropical biodiversity[29][30] and ecosystem functioning,[31] such as seed dispersal, soil bioturbation and nutrient cycling.[28]

Benefits and uses

[edit]
Caution sign showing the importance of dung beetles in South Africa

Dung beetles play a role in agriculture and tropical forests. By burying and consuming dung, they improve nutrient recycling and soil structure.[32][33] Dung beetles have been further shown to improve soil conditions and plant growth on rehabilitated coal mines in South Africa.[34] They are also important for the dispersal of seeds present in animals' dung,[35] influencing seed burial and seedling recruitment in tropical forests.[36] They can protect livestock, such as cattle, by removing the dung which, if left, could provide habitat for pests such as flies. Therefore, many countries have introduced the creatures for the benefit of animal husbandry. The American Institute of Biological Sciences reports that dung beetles save the United States cattle industry an estimated US$380 million annually through burying above-ground livestock feces.[37]

In Australia, the Commonwealth Scientific and Industrial Research Organisation (CSIRO) commissioned the Australian Dung Beetle Project (1965–1985) which, led by George Bornemissza, sought to introduce species of dung beetles from South Africa and Europe. The successful introduction of 23 species was made, most notably Digitonthophagus gazella and Euoniticellus intermedius, which has resulted in improvement of the quality and fertility of Australian cattle pastures, along with a reduction in the population of pestilent Australian bush flies by around 90%.[38][39] In 1995 it was reported that dung beetles were being trialled in the Sydney beach suburb of Curl Curl to deal with dog droppings.[40]

An application made by Landcare Research to import up to 11 species of dung beetle into New Zealand[41] was approved in 2011.[42] As well as improving pasture soils the Dung Beetle Release Strategy Group said that it would result in a reduction in emissions of nitrous oxide (a greenhouse gas) from agriculture.[43] There was, however, strong opposition from some at the University of Auckland, and a few others, based on the risks of the dung beetles acting as vectors of disease.[44][45] There were public health researchers at the University of Auckland who agreed with the Environmenal Protection Authority's risk assessment.[46] Several Landcare programmes in Australia involved schoolchildren collecting dung beetles.[47]

The African dung beetle (D. gazella) was introduced in several locations in North and South America and has been spreading its distribution to other regions by natural dispersal and accidental transportation, and is now probably naturalized in most countries between México and Argentina. The exotic species might be useful for controlling diseases of livestock in commercial areas, and might displace native species in modified landscapes; however, data is not conclusive about its effect on native species in natural environments and further monitoring is required.[48]

Like many other insects, (dried) dung beetle, called qiāngláng (蜣蜋) in Chinese, is used in Chinese herbal medicine. It is recorded in the "Insect section" (蟲部) of the Compendium of Materia Medica, where it is recommended for the cure of 10 diseases.[citation needed]

In Isan, Northeastern Thailand, the local people eat many different kinds of insects, including the dung beetle. There is an Isan song กุดจี่หายไปใหน "Where Did the Dung Beetle Go", which relates the replacement of water buffalo with the "metal" buffalo, which does not provide the dung needed for the dung beetle and has led to the increasing rarity of the dung beetle in the agricultural region.[citation needed]

The Mediterranean dung beetle (Bubas bison) has been used in conjunction with biochar stock fodder to reduce emissions of nitrous oxide and carbon dioxide, which are both greenhouse gases. The beetles work the biochar-enriched dung into the soil without the use of machines.[49]

Scientists in Canberra in 1965 discovered that Dung beetles (Scarabaeids), specifically Onthophagus australis Guérin-Méneville, improve plant yields using their dung. Japanese millet was studied and data on nutrient uptake. These plants were placed in pots lacking nitrogen, phosphorus, and sulfur. Cow-dung was then added in treatment groups with or without O. australis. Some treatment groups even had two out of the three nutrients supplemented in the pots. Comparisons of the treatment and control groups were made to show that top growth and roots significantly increased when the dung was mixed well into the soil in the pots. Results showed that dung beetle activity greatly improved plant life. The dung has little impact alone, but in combination with the dung beetle, the nutritional value for the plants increases greatly. This suggests that dung beetles have many positive implications for the environment, including a beneficial role with plant life.[50]

In culture

[edit]

Some dung beetles are used as food in South East Asia and a variety of dung beetle species have been used therapeutically (and are still being used in traditionally living societies) in potions and folk medicines to treat a number of illnesses and disorders.[51]

Ancient Egypt

[edit]
A scarab statue at the Karnak temple complex

Several species of the dung beetle, most notably the species Scarabaeus sacer (often referred to as the sacred scarab), enjoyed a sacred status among the ancient Egyptians.

xpr
ḫpr
in hieroglyphs

Egyptian hieroglyphic script uses the image of the beetle to represent a triliteral phonetic that Egyptologists transliterate as xpr or ḫpr and translate as "to come into being", "to become" or "to transform". The derivative term xprw or ḫpr(w) is variously translated as "form", "transformation", "happening", "mode of being" or "what has come into being", depending on the context. It may have existential, fictional, or ontologic significance. The scarab was linked to Khepri ("he who has come into being"), the god of the rising sun. The ancients believed that the dung beetle was only male-sexed, and reproduced by depositing semen into a dung ball. The supposed self-creation of the beetle resembles that of Khepri, who creates himself out of nothing. Moreover, the dung ball rolled by a dung beetle resembles the sun. Plutarch wrote:

The race of beetles has no female, but all the males eject their sperm into a round pellet of material which they roll up by pushing it from the opposite side, just as the sun seems to turn the heavens in the direction opposite to its own course, which is from west to east.[52]

The ancient Egyptians believed that Khepri renewed the sun every day before rolling it above the horizon, then carried it through the other world after sunset, only to renew it, again, the next day. Some New Kingdom royal tombs exhibit a threefold image of the sun god, with the beetle as symbol of the morning sun. The astronomical ceiling in the tomb of Ramses VI portrays the nightly "death" and "rebirth" of the sun as being swallowed by Nut, goddess of the sky, and re-emerging from her womb as Khepri.

The image of the scarab, conveying ideas of transformation, renewal, and resurrection, is ubiquitous in ancient Egyptian religious and funerary art.

Excavations of ancient Egyptian sites have yielded images of the scarab in bone, ivory, stone, Egyptian faience, and precious metals, dating from the Sixth Dynasty and up to the period of Roman rule. They are generally small, bored to allow stringing on a necklace, and the base bears a brief inscription or cartouche. Some have been used as seals. Pharaohs sometimes commissioned the manufacture of larger images with lengthy inscriptions, such as the commemorative scarab of Queen Tiye. Massive sculptures of scarabs can be seen at Luxor Temple, at the Serapeum in Alexandria (see Serapis) and elsewhere in Egypt.

A scarab, depicted on the walls of Tomb KV6 in the Valley of the Kings

The scarab was of prime significance in the funerary cult of ancient Egypt. Scarabs, generally, though not always, were cut from green stone, and placed on the chest of the deceased. Perhaps the most famous example of such "heart scarabs" is the yellow-green pectoral scarab found among the entombed provisions of Tutankhamen. It was carved from a large piece of Libyan desert glass. The purpose of the "heart scarab" was to ensure that the heart would not bear witness against the deceased at judgement in the Afterlife. Other possibilities are suggested by the "transformation spells" of the Coffin Texts, which affirm that the soul of the deceased may transform (xpr) into a human being, a god, or a bird and reappear in the world of the living.

One scholar comments on other traits of the scarab connected with the theme of death and rebirth:

It may not have gone unnoticed that the pupa, whose wings and legs are encased at this stage of development, is very mummy-like. It has even been pointed out that the egg-bearing ball of dung is created in an underground chamber which is reached by a vertical shaft and horizontal passage curiously reminiscent of Old Kingdom mastaba tombs."[53]

In contrast to funerary contexts, some of ancient Egypt's neighbors adopted the scarab motif for seals of varying types. The best-known of these being Judean LMLK seals (8 of 21 designs contained scarab beetles), which were used exclusively to stamp impressions on storage jars during the reign of Hezekiah.

The scarab remains an item of popular interest thanks to modern fascination with the art and beliefs of ancient Egypt. Scarab beads in semiprecious stones or glazed ceramics can be purchased at most bead shops, while at Luxor Temple a massive ancient scarab has been roped off to discourage visitors from rubbing the base of the statue "for luck".

In literature

[edit]

In Aesop's fable "The Eagle and the Beetle", the eagle kills a hare that has asked for sanctuary with a beetle. The beetle then takes revenge by twice destroying the eagle's eggs. The eagle, in despair, flies up to Olympus and places her latest eggs in Zeus's lap, beseeching the god to protect them. When the beetle finds out what the eagle has done, it stuffs itself with dung, goes straight up to Zeus and flies right into his face. Zeus is startled at the sight of the unpleasant creature, jumping to his feet so that the eggs are broken. Learning of the origin of their feud, Zeus attempts to mediate and, when his efforts to mediate fail, he changes the breeding season of the eagle to a time when the beetles are not above ground.

Aristophanes alluded to Aesop's fable several times in his plays. In Peace, the hero rides up to Olympus to free the goddess Peace from her prison. His steed is an enormous dung beetle which has been fed so much dung that it has grown to monstrous size.

Hans Christian Andersen's "The Dung Beetle" tells the story of a dung beetle who lives in the stable of the king's horses in an imaginary kingdom. When he demands golden shoes like those the king's horse wears and is refused, he flies away and has a series of adventures, which are often precipitated by his feeling of superiority to other animals. He finally returns to the stable having decided (against all logic) that it is for him that the king's horse wears golden shoes.[54]

In Franz Kafka's The Metamorphosis, the transformed character of Gregor Samsa is called an "old dung beetle" (alter Mistkäfer) by a charwoman.

See also

[edit]

References

[edit]
  1. ^ "Some Less Known Fascinating Facts about Dung Beetle". IANS. news.biharprabha.com. Retrieved 21 April 2014.
  2. ^ a b Griffiths, Hannah M.; Louzada, Julio; Bardgett, Richard D.; Barlow, Jos (2016-03-03). "Assessing the Importance of Intraspecific Variability in Dung Beetle Functional Traits". PLOS ONE. 11 (3): e0145598. Bibcode:2016PLoSO..1145598G. doi:10.1371/journal.pone.0145598. ISSN 1932-6203. PMC 4777568. PMID 26939121.
  3. ^ Frolov, A.V. "Subfamily Scarabaeinae: atlas of representatives of the tribes (Scarabaeidae)". Retrieved on 2007-08-02.
  4. ^ Jonathan Amos (24 January 2013). "Dung beetles guided by Milky Way". BBC News. Retrieved 28 January 2013.
  5. ^ Dacke, M.; Baird, E.; Byrne, M.; Scholtz, C. H.; Warrant, E. J. (2013). "Dung Beetles Use the Milky Way for Orientation". Current Biology. 23 (4): 298–300. doi:10.1016/j.cub.2012.12.034. PMID 23352694.
  6. ^ a b Krell, Frank-Thorsten; Krell-Westerwalbesloh, Sylvia (2024). "One elephant may sustain 2 million dung beetles in East African savannas on any given day". The Science of Nature. 111 (1). doi:10.1007/s00114-024-01894-9. ISSN 0028-1042.
  7. ^ "Geotrupidae (earth-boring dung beetles)". kerbtier.de. Retrieved 28 March 2015.
  8. ^ "Scarabaeinae dung beetles". Archived from the original on 2015-03-19. Retrieved 28 March 2015.
  9. ^ Skelley, P. E. Aphodiinae. Archived 2018-02-14 at the Wayback Machine Generic Guide to New World Scarab Beetles. University of Nebraska State Museum. 2008 Version.
  10. ^ França, Filipe M.; Korasaki, Vanesca; Louzada, Julio; Vaz-de-Mello, Fernando Z. (2016). "First report on dung beetles in intra-Amazonian savannahs in Roraima, Brazil". Biota Neotropica. 16 (1). doi:10.1590/1676-0611-BN-2015-0034. ISSN 1676-0603.
  11. ^ Beiroz, Wallace; Slade, Eleanor M.; Barlow, Jos; Silveira, Juliana M.; Louzada, Julio; Sayer, Emma (2017-01-01). "Dung beetle community dynamics in undisturbed tropical forests: implications for ecological evaluations of land-use change" (PDF). Insect Conservation and Diversity. 10 (1): 94–106. doi:10.1111/icad.12206. ISSN 1752-4598. S2CID 88666069.
  12. ^ Dell'Amore, Christine. "Dung Beetles' Favorite Poop Revealed". National Geographic. National Geographic Society. Archived from the original on 2016-09-23. Retrieved 22 September 2016.
  13. ^ Silva, F.A.B.; Vidaurre, T.; Vaz-de-Mello, F.; Louzada, J. (2012). "Predatory behavior in Deltochilum: convergent evolution or a primitive character within this clade". Journal of Natural History. 46 (21–22): 1359–1367. doi:10.1080/00222933.2012.658584. S2CID 85229138.
  14. ^ Forti, Luiz Carlos; Rinaldi, Isabela Maria Piovesan; Camargo, Roberto da Silva; Fujihara, Ricardo Toshio (2012-03-06). "Predatory Behavior of Canthon virens (Coleoptera: Scarabaeidae): A Predator of Leafcutter Ants". Psyche: A Journal of Entomology. 2012: 1–5. doi:10.1155/2012/921465. hdl:11449/73288.
  15. ^ PéRez-Ramos, Ignacio M.; MarañóN, Teodoro; Lobo, Jorge M.; Verdú, José R. (August 2007). "Acorn removal and dispersal by the dung beetle Thorectes lusitanicus : ecological implications". Ecological Entomology. 32 (4): 349–356. doi:10.1111/j.1365-2311.2007.00874.x. hdl:10261/47760. ISSN 0307-6946.
  16. ^ Khaleeli, Homa (24 March 2010). "Just how strong is a dung beetle?". The Guardian. London.
  17. ^ Tills 2013, p. 123.
  18. ^ Dacke, M.; Nilsson, D. E.; Scholtz, C. H.; Byrne, M.; Warrant, E. J. (2003). "Animal behaviour: Insect orientation to polarized moonlight". Nature. 424 (6944): 33. Bibcode:2003Natur.424...33D. doi:10.1038/424033a. PMID 12840748. S2CID 52859195.
  19. ^ Milius, Susan (2003). "Moonlighting: Beetles navigate by lunar polarity". Science News. 164 (1): 4–5. doi:10.2307/3981988. JSTOR 3981988.
  20. ^ Roach, John (2003). "Dung Beetles Navigate by the Moon, Study Says", National Geographic News. Retrieved on 2007-08-02.
  21. ^ Milius, S. (2003). "Moonlighting". Science News. 164 (1): 4–5. doi:10.2307/3981988. JSTOR 3981988.
  22. ^ a b Dacke, Marie; Baird, Emily; Byrne, Marcus; Scholtz, Clarke H.; Warrant, Eric J. (2013). "Dung Beetles Use the Milky Way for Orientation". Current Biology. 23 (4): 298–300. doi:10.1016/j.cub.2012.12.034. PMID 23352694.
  23. ^ Wits University (24 January 2013). "Dung Beetles Follow the Milky Way: Insects Found to Use Stars for Orientation". ScienceDaily. Retrieved 25 January 2013.
  24. ^ Meyer-Rochow, V.B. (1978). "Retina and dioptric apparatus of the dung beetle ( Euoniticellus africanus ; Scarabaeidae)". Journal of Insect Physiology. 24 (2): 165–179. doi:10.1016/0022-1910(78)90114-2.
  25. ^ Meyer-Rochow, V.B.; Gokan, N. (1990). "The eye of the dung beetle Onthophagus posticus (Coleoptera, Scarabaeidae)". New Zealand Journal of Entomology. 13: 7–15. doi:10.1080/00779962.1990.9722582.
  26. ^ Fabre, J. Henri (1949). The Insect World of J. Henri Fabre. De Mattos, Alexander Teixeira (translator). Dodd, Mead & Company. p. 99. I ask myself in vain what Proudhon introduced into Scarabaean morality the daring paradox that 'property means plunder', or what diplomatist taught the Dung-beetle the savage maxim that 'might is right'.
  27. ^ França, FM; Benkwitt, CE; Peralta, G; Robinson, JPW; Graham, NAJ; Tylianakis, JM; Berenguer, E; Lees, AC; Ferreira, J; Louzada, J; Barlow, J (2020). "Climatic and local stressor interactions threaten tropical forests and coral reefs". Philosophical Transactions of the Royal Society B. 375 (1794): 20190116. doi:10.1098/rstb.2019.0116. PMC 7017775. PMID 31983328.
  28. ^ a b França, Filipe; Ferreira, J; Vaz-de-Mello, FZ; Maia, LF; Berenguer, E; Palmeira, A; Fadini, R; Louzada, J; Braga, R; Oliveira, VH; Barlow, J (10 February 2020). "El Niño impacts on human-modified tropical forests: Consequences for dung beetle diversity and associated ecological processes". Biotropica. 52 (1): 252–262. doi:10.1111/btp.12756.
  29. ^ França, Filipe; Louzada, Julio; Korasaki, Vanesca; Griffiths, Hannah; Silveira, Juliana; Barlow, Jos (2016). "Do space-for-time assessments underestimate the impacts of logging on tropical biodiversity? An Amazonian case study using dung beetles". Journal of Applied Ecology. 53 (4): 1098–1105. doi:10.1111/1365-2664.12657.
  30. ^ França, Filipe; Barlow, Jos; Araújo, Bárbara; Louzada, Julio (4 November 2016). "Does selective logging stress tropical forest invertebrates? Using fat stores to examine sublethal responses in dung beetles". Ecology and Evolution. 6 (23): 8526–8533. doi:10.1002/ece3.2488. PMC 5167030. PMID 28031804.
  31. ^ França, Filipe M.; Frazão, Fábio S.; Korasaki, Vanesca; Louzada, Júlio; Barlow, Jos (2017-12-01). "Identifying thresholds of logging intensity on dung beetle communities to improve the sustainable management of Amazonian tropical forests" (PDF). Biological Conservation. 216 (Supplement C): 115–122. doi:10.1016/j.biocon.2017.10.014.
  32. ^ Brown, J.; Scholtz, C. H.; Janeau, J. L.; Grellier, S.; Podwojewski, P. (2010). "Dung beetles (Coleoptera: Scarabaeidae) can improve soil hydrological properties" (PDF). Applied Soil Ecology. 46: 9–16. doi:10.1016/j.apsoil.2010.05.010. hdl:2263/14419.
  33. ^ Nichols, E.; Spector, S.; Louzada, J.; Larsen, T.; Amezquita, S.; Favila, M.E. (2008). "Ecological functions and ecosystem services provided by Scarabaeinae dung beetles". Biological Conservation. 141 (6): 1461–1474. doi:10.1016/j.biocon.2008.04.011.
  34. ^ Badenhorst, J.; Dabrowski, J.; Scholtz, C. H.; Truter, W. F. (2018). "Dung beetle activity improves herbaceous plant growth and soil properties on confinements simulating reclaimed mined land in South Africa". Applied Soil Ecology. 132: 53–59. doi:10.1016/j.apsoil.2018.08.011. hdl:2263/67268. S2CID 91863191.
  35. ^ França, Filipe; Louzada, Julio; Barlow, Jos (2018-02-15). "Selective logging effects on 'brown world' faecal-detritus pathway in tropical forests: A case study from Amazonia using dung beetles" (PDF). Forest Ecology and Management. 410: 136–143. doi:10.1016/j.foreco.2017.12.027. ISSN 0378-1127.
  36. ^ Griffiths, Hannah M.; Bardgett, Richard D.; Louzada, Julio; Barlow, Jos (2016-12-14). "The value of trophic interactions for ecosystem function: dung beetle communities influence seed burial and seedling recruitment in tropical forests". Proc. R. Soc. B. 283 (1844): 20161634. doi:10.1098/rspb.2016.1634. ISSN 0962-8452. PMC 5204146. PMID 27928036.
  37. ^ Losey, J. E.; Vaughan, M. (2006). "The Economic Value of Ecological Services Provided by Insects". BioScience. 56 (4): 311–23. doi:10.1641/0006-3568(2006)56[311:TEVOES]2.0.CO;2.
  38. ^ Bornemissza, G. F. (1976). "The Australian dung beetle project 1965–1975". Australian Meat Research Committee Review. 30: 1–30.
  39. ^ Ward, Colin (21 February 2011). "Dung beetle program". CSIROpedia. Archived from the original on 24 November 2020.
  40. ^ Brady Halls (4 November 1995). "CNN - Dung beetles devour 'poo-lution' Down Under". CNN.
  41. ^ "Application summary – ERMA200599" (PDF). ERMA. Retrieved 12 December 2010.[permanent dead link]
  42. ^ "HSNO Application". www.epa.govt.nz. 2 February 2011. Retrieved 21 October 2024.
  43. ^ Ihaka, James (24 September 2010). "Let's roll... dung beetle to combat global warming". The New Zealand Herald. Retrieved 12 December 2010.
  44. ^ 17 Aug 2014, 01:09 am (2012-05-07). "Experts dump on dung beetle". Fwplus.co.nz. Archived from the original on 2013-04-14. Retrieved 2014-08-16.{{cite web}}: CS1 maint: numeric names: authors list (link)
  45. ^ Guilford, Grant (2013-02-18). "Grant Guilford: Dung beetle plan a risky gamble". NZ Herald. Nzherald.co.nz. Retrieved 2014-08-16.
  46. ^ drj9 (2013-03-17). "'Fickle thy name is' vox populi : puzzle over dung beetles and science reporting". Journal of Outrageous Speculation. Retrieved 2014-04-22.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  47. ^ "Release Programme | Dung Beetles in New Zealand". Dungbeetle.org.nz. 2013-09-26. Retrieved 2014-04-22.
  48. ^ Ferrer-Paris, José R. (2014). "El escarabajo estercolero africano, Digitonthophagus gazella, (Coleoptera: Scarabaeidae) en la región Neotropical, ¿beneficioso o perjudicial?". Boletín de la Red Latinoamericana Para el Estudio de Especies Invasoras. 4 (1): 41–48.
  49. ^ Daly, Jon (18 October 2019). "Poo-eating beetles and charcoal used by WA farmer to combat climate change". ABC News. Australian Broadcasting Corporation. Retrieved 18 October 2019. Mr Pow said his innovative farming system could help livestock producers become more profitable while helping to address the impact of climate change.
  50. ^ BORNEMISSZA, G.F.; WILLIAMS, C.H. (January 1970). "An effect of dung beetle activity on plant yield". Pedobiologia. 10 (1): 1–6. doi:10.1016/s0031-4056(23)00394-3. ISSN 0031-4056.
  51. ^ Meyer-Rochow, V.B. (January 2017). "Therapeutic arthropods and other, largely terrestrial, folk-medicinally important invertebrates: a comparative survey and review". Journal of Ethnobiology and Ethnomedicine. 13 (9): 9. doi:10.1186/s13002-017-0136-0. PMC 5296966. PMID 28173820.
  52. ^ "Isis and Osiris", Moralia, in volume V of the Loeb Classical Library edition, 1936, now in the public domain. Retrieved on 2007-08-02.
  53. ^ Andrews, Carol (1994). Amulets of Ancient Egypt. Texas: University of Texas Press. ISBN 0-292-70464-X. p. 51.
  54. ^ Andersen, Hans Christian; James, M. R. (trans.) (1930). The Beetle. Faber and Faber. {{cite book}}: |work= ignored (help)

Bibliography

[edit]
[edit]