Macrotermes natalensis

Macrotermes natalensis
	Cross-section of mound
Scientific classification
Kingdom:	Animalia
Phylum:	Arthropoda
Class:	Insecta
Order:	Blattodea
Infraorder:	Isoptera
Family:	Termitidae
Genus:	Macrotermes
Species:	M. natalensis
Binomial name
	Macrotermes natalensis; (Haviland, 1898)

Macrotermes natalensis is a fungus-growing termite species that belongs to the genus Macrotermes. This species is associated with the Termitomyces fungal genus. M. natalensis has domesticated Termitomyces to produce food for the colony. Both termite species- fungal genus- are obligate and mutually beneficial where termite relies on the fungus to break down for plant materiel and nutrient resource. In contrast, the fungal species obtain plant material and optimal conditions for growth. This is relationship also inhibits competitors and antagonistic fungi to termites mounds.

Habitat: This fungal-termite species reported in South Africa.

Genome data size: M. natalensis has become a well-studied fungus-growing termite species, and its genomic sequence reads generate 1.3 gigabytes of data, making it the largest termite genome to date.^[2]

Colony caste system[]

All the fungus-growing termite colonies similar caste systems. Each caste plays a different roles in the colony, but it is not yet known how caste selection occurs. The primary reproductive caste or royal pair is made up of a king and a queen. The winged alates make up the secondary reproductive caste. Sterile castes do not possess any reproductive capacity and include workers and soldiers, both major and minor.

Termitomyces in a colony[]

Termitomyces fungi play a major role in termite nutrition. They also influence termite survival and caste development. The fungal garden is managed by the worker caste.

In a mature M. natalensis colony, older workers collect dead plant material along with Termitomyces asexual spores from their habitat and pass these on to the younger workers. The young workers only stay in the nest. They receive the plant material and ingest it along with the Termitomyces spores. Later, young workers defecate this blended plant material, along with fungal spores, somewhere in the colony nest. It forms a "comb", where the fungal mycelium establishes a dense network. The Termitomyces fungi use the nutrients from the comb and complete their life cycle with fruiting bodies or fungal nodules.

References[]

^ Bignell, D. E.; Jones, D. T. (2014). "A Taxonomic Index, with Names of Descriptive Authorities of Termite Genera and Species: An Accompaniment to Biology of Termites: A Modern Synthesis". Journal of Insect Science. 14 (81): 34. doi:10.1673/031.014.81. PMC 4212872. PMID 25368037.
^ Poulsen, Michael; Hu, Haofu; Li, Cai; Chen, Zhensheng; Xu, Luohao; Otani, Saria; Nygaard, Sanne; Nobre, Tania; Klaubauf, Sylvia (7 October 2014). "Complementary symbiont contributions to plant decomposition in a fungus-farming termite". Proceedings of the National Academy of Sciences of the United States of America. 111 (40): 14500–14505. doi:10.1073/pnas.1319718111. PMC 4209977. PMID 25246537.

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[BignJone-1] Bignell, D. E.; Jones, D. T. (2014). "A Taxonomic Index, with Names of Descriptive Authorities of Termite Genera and Species: An Accompaniment to Biology of Termites: A Modern Synthesis". Journal of Insect Science. 14 (81): 34. doi:10.1673/031.014.81. PMC 4212872. PMID 25368037.

[PoulHuLiChen14-2] Poulsen, Michael; Hu, Haofu; Li, Cai; Chen, Zhensheng; Xu, Luohao; Otani, Saria; Nygaard, Sanne; Nobre, Tania; Klaubauf, Sylvia (7 October 2014). "Complementary symbiont contributions to plant decomposition in a fungus-farming termite". Proceedings of the National Academy of Sciences of the United States of America. 111 (40): 14500–14505. doi:10.1073/pnas.1319718111. PMC 4209977. PMID 25246537.

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