Megascolecidae
Megascolecidae | |
---|---|
Megascolecidae found in Sai Kung West Country Park, Hong Kong belonging to genus Amynthas | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Annelida |
Clade: | Pleistoannelida |
Clade: | Sedentaria |
Class: | Clitellata |
Order: | Opisthopora |
Suborder: | Crassiclitellata |
Family: | Megascolecidae Rosa, 1891[1] |
Genera | |
Over 65, see text |
Megascolecidae is a family of earthworms native to Madagascar, Australia, New Zealand, Asia, and North America.[2] At up to 2 meters in length,[3] their large size distinguishes the Megascolecidae from other earthworm families. They are an essential part of maintaining soil structure, minor carbon sequestration, and maintaining terrestrial ecosystems.
Physiological features
[edit]Different species of the Megascolecidae have different physiological features, but some similarities of physiological features can be found between species.[4] The family contains relatively large individuals. The length of earthworms can vary from 1.0 cm (0.39 in) to 2 m (6 ft 7 in).[3] The number of spermathecal pores is normally paired, but multiples can be present in some species. The location of spermathecal pores and how they are positioned in different segmental locations is used in the identification of different megascolecidids.[5]
Earthworms ingest a variety of organic materials in the soil since they live in terrestrial environments.[6] Earthworms in this family have the ability to decompose lignocellulose, which requires assistance from microorganisms in their digestive system.[7] Aside from microorganisms, digestive enzymes such as amylase and cellulase, and proteins can be found in different regions of the gut. Chemical digestion mainly occurs in the intestinal caeca of earthworms, which have higher protease activity than other parts of the gut.[6]
Genital markings in the Megascolecidae family can be used to distinguish species.[8]
Reproductive system
[edit]The Megascolecidae are oviparous, laying eggs to reproduce. They are biparental.[9] The ideal condition of reproduction for the megascolecidids is 25 °C, where the eggs hatch the quickest and have the highest cocoon production.[10]
The male reproductive organ of the Megascolecidae includes testes, seminal vesicles, spermathecae, prostate glands,[11] and spermathecal pores.[12] The sperm can be found in testes and seminal vesicles, but cannot be found in spermathecae.[9] The female reproductive organ consists of female pores, which normally occur in pairs.[8] Both male and female reproductive organs are present in earthworms because they are monoecious. To breed, two earthworms exchange sperm. Long after they are separated, the egg case is secreted. It forms a ring around the worm, then the worm removes the ring from its body and injects its own eggs and the other worm's sperm into it. Afterwards, the egg case is sealed and ready to hatch, grow, and become a cocoon.[13]
Lifecycle
[edit]The Megascolecidae lifecycle takes around 50–57 days, depending on the external environments and habitat. The rate of growth during the first 14 days is very low, however; after 21 – 28 days, the rate of growth increases and then cycles up and down throughout the worm's life with no pattern.[14] The growth rate of these worms is correlated to the temperature of their environment. As temperatures increase from 30 °C, a significant growth rate and decreasing the time to sexual maturity are seen. The ideal living temperature of megascolecidids is around 15 to 30 °C.[15] Overall mean growth is 1.79 mg/day, 1.57 mg/day, and 1.34 mg/day depending on the abundance of worms and environment condition and size.[14] The cocoon production of Megascolecidae species also is correlated with the temperature of the environment.[16]
Distribution and habitat
[edit]Megascolecidae species can be in Australia, New Zealand, Asia, North America, South America, and Europe.[17] The intercontinental presence of Megascolecidae species can be explained by the Permanence of Continent Theory, which provides the explanation of most Cenozoic distributions; this theory,though, does not explain the presence of European Megascolecidae in North America. The intercontinental distribution of Megascolecidae has two different theories that explains its phenomenon -land bridges and continental drift.[18]
The Megascolecidae family originated in Australia.[19] Australia has number of species that are native to different parts of the country; Anisochaeta sebastiani is an example. This species can be found from Queensland to Tasmania.[20] Fifty-three known species of these earthworms can be found in Western Australia; Graliophilus georgei and G. secundus are some examples.[21] G. zeilensis can be found in the Northern Territory, specifically in Mount Zeil, West MacDonnell Ranges. G. zeilensis also can be found on the highest point of the mountain where average rainfall of the region is 250 mm annually. This distinguishes them from other species from Graliophilus.[22]
Metaphire and Amynthas are two common genera belonging to the Megascolecidae family. They can be found in different countries in Asia.[23]
Eight different species of Metaphire can be found in Malaysia: M. sedimensis, M. hijaunensis, M..e songkhlaensis, M. pulauensis, M. pulauensis, M. fovella, M. balingensis, and M. strellana. These species are commonly found in soil containing medium to high organic material. such as loamy soil.[24]
In Indonesia, 9 different genera can be found; Amynthas, Archipheretima, Metaphire, Metapheretima, Pheretima, Pithemera, Planapheretima, Pleinogaster, and Polypheretima. Pheretimoid is the biggest group of species, which consists of 65 species. Some intrageneric groups are restricted to mainland Asia, but others are native to Indo-Australian Archipelago.[25]
The ideal habitat for Megascolecidae is a terrestrial environment with soil with a high content of organic material, such as loamy soil,[14] cattlebor pig manure, and aerobically digested sewage sludge.[10] Megascolecidae species grow and produce more cocoons during the summer than the winter, because their lifecycle is highly correlated to the temperature and humidity of the environment.[14] Some Megascolecidae species have adapted to colder temperatures and drier areas, though, which enables them to live in higher-altitude regions of the land.[22]
Ecology
[edit]Megascolecidae form an important part of the soil ecosystem, in that they indicate soil health and maintain soil productivity. The abundance of earthworms is highly correlated to soil pH, texture, water content, and temperature.[26] Earthworms have the ability to biomonitor soil pollutants.[27] This is because of earthworms' burrowing habit serves to facilitate water flow and agrochemicals through the soil profile, so are able to perform carbon sequestration and reduce soil pollutants].[26] Invasive earthworms can have a significant impact causing changes in soil profiles, nutrient and organic matter content and other soil organisms or plant communities. In most cases the disturbed areas includes agricultural systems or previously areas that are lacking of earthworms would see the biggest impact of the invasive earthworms.[28] The impact of earthworms on soil structure is due to the rate of net nitrogen mineralization.[29]
Genera
[edit]- Aceeca Blakemore, 2000
- Aridulodrilus Dyne, 2021[30]
- Amphimiximus Blakemore, 2000
- Amynthas Kinberg, 1867
- Anisochaeta Beddard, 1890
- Anisogogaster Blakemore, 2010
- Aporodrilus Blakemore, 2000
- Archipheretima Michaelsen, 1928
- Arctiostrotus McKey-Fender, 1982
- Argilophilus Eisen, 1893
- Austrohoplochaetella Jamieson, 1971
- Begemius Easton, 1982
- Caecadrilus Blakemore, 2000
- Chetcodrilus Fender & McKey-Fender, 1990
- Comarodrilus Stephenson, 1915
- Cryptodrilus Fletcher, 1886
- Dendropheretima James, 2005
- Deodrilus Beddard, 1890
- Didymogaster Fletcher, 1886
- Digaster Perrier, 1872
- Diporochaeta Beddard, 1890
- Drilochaera Fender & McKey-Fender, 1990
- Driloleirus Fender & McKey-Fender, 1990
- Duplodicodrilus Blakemore, 2008
- Eastoniella Jamieson, 1977
- Fletcherodrilus Michaelsen, 1891
- Gastrodrilus Blakemore, 2000
- Gemascolex Edmonds & Jamieson, 1973
- Geofdyneia Jamieson, 2000
- Graliophilus Jamieson, 1971
- Haereodrilus Dyne, 2000
- Healesvillea Jamieson, 2000
- Heteroporodrilus Jamieson, 1970
- Hiatidrilus Blakemore, 1997
- Hickmaniella Jamieson, 1974
- Hypolimnus Blakemore, 2000
- Isarogoscolex James, 2005
- Kincaidodrilus McKey-Fender, 1982
- Lampito Kinberg, 1867
- Macnabodrilus Fender & McKey-Fender, 1990
- Megascolex Templeton, 1844
- Megascolides McCoy, 1878
- Metapheretima Michaelsen, 1928
- Metaphire Sims & Easton, 1972
- Nelloscolex Gates, 1939
- Nephrallaxis Fender & McKey-Fender, 1990
- Notoscolex Fletcher, 1886
- Oreoscolex Jamieson, 1973
- Paraplutellus Jamieson, 1972[31]
- Pericryptodrilus Jamieson, 1977
- Perionychella Michaelsen, 1907
- Perionyx Perrier, 1872
- Perissogaster Fletcher, 1887
- Pheretima Kinberg, 1867
- Pithemera Sims & Easton, 1972
- Planapheretima Michaelsen, 1934
- Pleionogaster Michaelsen, 1892
- Plutelloides Jamieson, 2000
- Plutellus Perrier, 1873
- Polypheretima Michaelsen, 1934
- Pontodrilus Perrier, 1874
- Propheretima Jamieson, 1995
- Provescus Blakemore, 2000
- Pseudocryptodrilus Jamieson, 1972
- Pseudonotoscolex Jamieson, 1971
- Retrovescus Blakemore, 1998
- Scolecoidea Blakemore, 2000
- Sebastianus Blakemore, 1997
- Simsia Jamieson, 1972[31]
- Spenceriella Michaelsen, 1907
- Tassiedrilus Blakemore, 2000
- Terrisswalkerius Jamieson, 1994
- Tonoscolex Gates, 1933
- Torresiella Dyne, 1997
- Toutellus Fender & McKey-Fender, 1990
- Troyia Jamieson, 1977
- Vesiculodrilus Jamieson, 1973
- Woodwardiella Stephenson, 1925
- Zacharius Blakemore, 1997
References
[edit]- ^ Rosa, D. (1891). "Die exotischen terricolen des k. k. naturhistorischen Hofmuseums". Annalen des K.K. Naturhistorischen Hofmuseums. 6: 379–406.
- ^ "The geographic distribution of the genera in the Pheretima complex (Megascolecidae) in eastern Asia and the Pacific region (English translation)". ResearchGate. Retrieved 2021-05-20.
- ^ a b Fahri, Fahri; Amaliah, Rizki; Suryobroto, Bambang; Atmowidi, Tri; Nguyen, Anh D. (2018-12-11). "Three new "caecate" earthworm species from Sulawesi, Indonesia (Oligochaeta, Megascolecidae)". ZooKeys (805): 1–14. doi:10.3897/zookeys.805.24834. PMC 6299058. PMID 30584390.
- ^ Zhao, Qi; Zhang, Minghuan; Dong, Yan; Qiu, Jiangping (June 2017). "New Species of Megascolecidae (Oligochaeta) from Hainan Island, China". Annales Zoologici. 67 (2): 221–227. doi:10.3161/00034541ANZ2017.67.2.003. S2CID 89825577.
- ^ Hutchings, P. (2007-06-01). "Reproductive Biology and Phylogeny of Annelida * Volume edited by Greg Rouse and Fredrik Pleijel Series edited by Barrie G.M. Jamieson". Integrative and Comparative Biology. 47 (5): 788–789. doi:10.1093/icb/icm008.
- ^ a b Nozaki, Mana; Ito, Katsutoshi; Miura, Chiemi; Miura, Takeshi (September 2013). "Examination of Digestive Enzyme Distribution in Gut Tract and Functions of Intestinal Caecum, in Megascolecid Earthworms (Oligochaeta: Megascolecidae) in Japan". Zoological Science. 30 (9): 710–715. doi:10.2108/zsj.30.710. ISSN 0289-0003. PMID 24004076. S2CID 24831606.
- ^ Fujii, Katsuhiko; Ikeda, Kana; Yoshida, Seo (2012). "Isolation and characterization of aerobic microorganisms with cellulolytic activity in the gut of endogeic earthworms". International Microbiology. 15 (15): 121–130. doi:10.2436/20.1501.01.165. PMID 23847816.
- ^ a b Wang, Yu-Hsi; Shih, Hsi-Te (2017-07-12). "Four new species of earthworms (Oligochaeta: Megascolecidae: Amynthas) from Taiwan based on morphological and molecular evidence". Zoological Studies. 56 (56): e18. doi:10.6620/ZS.2017.56-18. PMC 6517727. PMID 31966217.
- ^ a b Vanpraagh, Bd (1995). "Reproductive biology of Megascolides australis Mccoy (Oligochaeta, Megascolecidae)". Australian Journal of Zoology. 43 (5): 489. doi:10.1071/ZO9950489.
- ^ a b Edwards, C. A.; Dominguez, J.; Neuhauser, E. F. (1998-06-19). "Growth and reproduction of Perionyx excavatus (Perr.) (Megascolecidae) as factors in organic waste management". Biology and Fertility of Soils. 27 (2): 155–161. doi:10.1007/s003740050414. S2CID 12479260.
- ^ "Parthenogenesis, polyploidy and reproductive seasonality in the Taiwanese mountain earthworm Amynthas catenus (Oligochaeta, Megascolecidae) | Request PDF". ResearchGate. Retrieved 2021-05-21.
- ^ Minamiya, Yukio; Hayakawa, Hiroshi; Ohga, Kyohei; Shimano, Satoshi; Ito, Masamichi T.; Fukuda, Tatsuya (2011). "Variability of sexual organ possession rates and phylogenetic analyses of a parthenogenetic Japanese earthworm, Amynthas vittatus (Oligochaeta: Megascolecidae)". Genes & Genetic Systems. 86 (1): 27–35. doi:10.1266/ggs.86.27. PMID 21498920.
- ^ "Natural history". www.biologicaldiversity.org. Retrieved 2021-05-21.
- ^ a b c d Karmegam, Natchimuthu; Daniel, Thilagavathy (October 2009). "Growth, reproductive biology and life cycle of the vermicomposting earthworm, Perionyx ceylanensis Mich. (Oligochaeta: Megascolecidae)". Bioresource Technology. 100 (20): 4790–4796. doi:10.1016/j.biortech.2009.05.004. PMID 19467590.
- ^ Edwards, C. A.; Dominguez, J.; Neuhauser, E. F. (1998-06-01). "Growth and reproduction of Perionyx excavatus (Perr.) (Megascolecidae) as factors in organic waste management". Biology and Fertility of Soils. 27 (2): 155–161. doi:10.1007/s003740050414. S2CID 12479260.
- ^ Bhattacharjee, Gautam; Chaudhuri, P. S. (2002-06-01). "Cocoon production, morphology, hatching pattern and fecundity in seven tropical earthworm species — a laboratory-based investigation". Journal of Biosciences. 27 (3): 283–294. doi:10.1007/BF02704917. PMID 12089477. S2CID 24522967.
- ^ Buckley, Thomas R.; James, Sam; Allwood, Julia; Bartlam, Scott; Howitt, Robyn; Prada, Diana (2011). "Phylogenetic analysis of New Zealand earthworms (Oligochaeta: Megascolecidae) reveals ancient clades and cryptic taxonomic diversity". Molecular Phylogenetics and Evolution. 58 (1): 85–96. doi:10.1016/j.ympev.2010.09.024. PMID 20951218.
- ^ Reynolds, J.W. 1995. The distribution of earthworms (Annelida, Oligochaeta) in North America. Pp. 133- 153 In: Mishra, P.C., N. Behera, B.K. Senapati and B.C. Guru (eds.). Advances in Ecology and Environmental Sciences. New Delhi: Ashish Publishing House, 651 pp.
- ^ Jamieson, B. G. M. (1977-04-06). "The indigenous earthworms (Megascolecidae: Oligochaeta) of Lord Howe Island". Records of the Australian Museum. 30 (12): 272–308. doi:10.3853/j.0067-1975.30.1977.390. Retrieved 2021-05-20.
- ^ Blakemore, R. J. (1997-12-01). "Two new genera and some new species of Australian earthworms (Acanthodrilidae, Megascolecidae: Oligochaeta)". Journal of Natural History. 31 (12): 1785–1848. doi:10.1080/00222939700770951.
- ^ Jamieson, B. G. M. (2009-08-20). "Earthworms (Megascolecidae: Oligochaeta) from Western Australia and their zoogeography". Journal of Zoology. 165 (4): 471–504. doi:10.1111/j.1469-7998.1971.tb02200.x.
- ^ a b Dyne, Geoffrey R. (2019-11-18). "A new relictual species of earthworm (Oligochaeta: Megascolecidae) from central Australia". Zootaxa. 4700 (1): 146–150. doi:10.11646/zootaxa.4700.1.9. PMID 32229997. S2CID 209564871.
- ^ Zhao, Qi; Cluzeau, Daniel; Briard, Charlène; Sun, Jing; Jiang, Jibao; Guernion, Muriel; Qiu, Jiang-Ping (2012-01-01). "Hainan earthworm community and the comparison with other East and Southeast Asia countries for geographic distribution and endemic rate". Zoology in the Middle East. 58 (Suppl. 4): 141–150. doi:10.1080/09397140.2012.10648996. S2CID 84500164.
- ^ Ng, Beewah; Bantaowong, Ueangfa; Tongkerd, Piyoros; Panha, Somsak (8 March 2018). "Description of two new species of the earthworm genus, Metaphire (Clitellata: Megascolecidae), from Kedah, Peninsular Malaysia" (PDF). Raffles Bulletin of Zoology. 66: 132–141.
- ^ Nugroho, Hari (2010). "A taxonomical review on pheretimoid earthworms (Ollgochaeta: Megascolecidae) from Indonesian archipelago". Indonesia Zoo. 19 (2): 93–108.
- ^ a b Martin Shipitalo; Tayfun Korucu (2017-01-11), "Structure: Earthworms", Encyclopedia of Soil Science (3 ed.), CRC Press, pp. 2212–2215, doi:10.1081/e-ess3-120053787 (inactive 23 December 2024), ISBN 978-1-315-16186-0, retrieved 2021-05-20
{{citation}}
: CS1 maint: DOI inactive as of December 2024 (link) - ^ Hirano, Takeshi; Tamae, Kazuyoshi (2011-11-28). "Earthworms and Soil Pollutants". Sensors. 11 (12): 11157–11167. Bibcode:2011Senso..1111157H. doi:10.3390/s111211157. PMC 3251976. PMID 22247659.
- ^ Hendrix, P. F.; Baker, G. H.; Callaham, M. A.; Damoff, G. A.; Fragoso, C.; González, G.; James, S. W.; Lachnicht, S. L.; Winsome, T.; Zou, X. (September 2006). "Invasion of exotic earthworms into ecosystems inhabited by native earthworms". Biological Invasions. 8 (6): 1287–1300. doi:10.1007/s10530-006-9022-8. S2CID 18494778.
- ^ Willems, J. J. G. M.; Marinissen, J. C. Y.; Blair, J. (July 1996). "Effects of earthworms on nitrogen mineralization". Biology and Fertility of Soils. 23 (1): 57–63. doi:10.1007/BF00335819. S2CID 23836511.
- ^ Records of the Australian Museum (2021) vol. 73, issue no. 4, pp. 123–129 https://doi.org/10.3853/j.2201-4349.73.2021.1769
- ^ a b Jamieson, B. G. M. (1972). "The australian earthworm genus Spenceriella and description of two new genera (Megascolecidae: Oligochaeta)". Memoirs of the National Museum of Victoria. 33: 73–87. doi:10.24199/j.mmv.1972.33.10.
External links
[edit]- Bleiman, Andrew (May 22, 2008). "Giant Blue Earthworms and Friends". Zooillogix. ScienceBlogs LLC. Retrieved March 10, 2016.