Muscardine is a disease of insects. It is caused by many species of entomopathogenic fungus. Many muscardines are known for affecting silkworms. Muscardine may also be called calcino.
While studying muscardine in silkworms in the 19th century, Agostino Bassi found that the causal agent was a fungus. This was the first demonstration of the germ theory of disease, the first time a microorganism was recognized as an animal pathogen. There are many types of muscardine. They are often named for the color of the conidial layer each fungus leaves on its host.
Black muscardine
Black muscardine is caused by Beauveria brongniartti and Metarhizium anisopliae.
Metarhizium species such as M. anisopliae can cause fatal disease in over 200 species of insect.
Brown muscardine
Aspergillosis of insects can be called brown muscardine. Over 10 Aspergillus species can cause the disease, such as A. flavus and A. tamari. The conidial layer may be brownish or greenish yellow.
Grassy muscardine
Grassy muscardine is caused by Hirsutella necatrix. This fungus produces an enzyme that breaks down the chitin in its host's body.
Gray muscardine
Gray muscardine is caused by Isaria javanica.
Green muscardine
Green muscardine disease is the presentation of a fungal infection of insects caused by members of the Metarhizium genus (now including Nomuraea rileyi), because of the green colour of their spores. Once the fungus has killed its host, mycelia invade the host's body and, under humid conditions, the insect cuticle becomes covered with a layer of green spores, hence the name of the disease. It was originally discovered as a pest of silk worms, upon which it was highly lethal. To insect mycologists and microbial control specialists, "green muscardine" refers to fungal infection caused by Metarhizium spp., whereas in sericulture, "green muscardine" refers to a similar fungal infection caused by Nomuraea rileyi. Green muscardine has been identified as disease of over 200 known insect species.
Orange muscardine
Orange muscardine is caused by Sterigmatocystis japonica.
Penicillosis
Penicillosis of insects is considered a type of muscardine, particularly when caused by Penicillium citrinum and P. granulatum.
Red muscardine
Red muscardine is caused by Sporosporella uvella and Isaria fumosoroseus.
White muscardine
One of the best known forms is white muscardine, which is caused by Beauveria bassiana.
When suffering from white muscardine, an insect larva may become inactive and stop eating. The elasticity of its cuticle is lost and it may experience vomiting and diarrhea. As it dies it hardens. The fungus leaves the body of its host covered in powdery white conidia. The fungal layer is tough due to oxalate crystals, and this slows the decay of the body. When a pupa is infected, it often mummifies. It shrinks and wrinkles before growing a fungal coating. In an adult moth, the body hardens and the wings drop off.
During infection, the fungus absorbs water and nutrients from the host. The hemolymph of the insect crystallizes and thickens. The fungus usually produces toxins, as well. After it kills the host, the fungus continues to absorb water from the body, causing it to harden further.
Other insects prone to white muscardine include the brown planthopper and the diaprepes root weevil.
Yellow muscardine
Yellow muscardine is caused by Isaria farinosa.
Yellow red muscardine
Yellow red muscardine is caused by Isaria fumosoroseus. It can produce reddish patches on the external body and powdery masses of spores internally.
Control
Fungicidal agents such as azadirachtin and phytoallexin have been used against some muscardine pathogens. Silkworm breeders dust their cages with slaked lime to discourage fungal growth. In India a dust of chaff soaked in formalin is applied to the larvae.
References
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- Mahr, S. Know Your Friends: The Entomopathogen Beauveria bassiana. Midwest Biological Control News October, 1997. Volume IV, Number 10.
- Wang, C. and Y. Xia. Cover photo. PLoS Genetics, January, 2011.
- ^ Vega, F. E. and H. K. Kaya. Insect Pathology. Academic Press. 2012. pg. 433.
- Chernin, L., et al. (1997). Chitinolytic activity of the acaropathogenic fungi Hirsutella thompsonii and Hirsutella necatrix. Canadian Journal of Microbiology 43(5) 440-46.
- Vladimir V. Gouli; Svetlana Y. Gouli; Jose A.P. Marcelino (6 November 2015). Concise Illustrated Dictionary of Biocontrol Terms. Elsevier Science. p. 71. ISBN 978-0-12-849898-9.
- R. W. Glaser (1 June 1926). "The Green Muscardine Disease in Silkworms and Its Control". Annals of the Entomological Society of America. 19 (2): 180–192. doi:10.1093/aesa/19.2.180.
- Fernando E. Vega; Harry K. Kaya (14 December 2011). Insect Pathology. Academic Press. p. 432. ISBN 978-0-12-384985-4.
- Richard Calderone (12 October 2001). Fungal Pathogenesis: Principles and Clinical Applications. CRC Press. p. 139. ISBN 978-0-8247-0568-8.
- ^ White Muscardine Fungus. Archived 2013-07-04 at archive.today Rice Knowledge Bank. International Rice Research Institute (IRRI). 2009.
- Beavers, J. B., et al. (1972). Two Muscardine fungi pathogenic to Diaprepes abbreviatus. The Florida Entomologist 55(2) 117-120.
- Vyas, R. V., et al. (1992). Effect of some natural pesticides on entomogenous muscardine fungi. Indian J Exp Biol. 30(5) 435-6.
- Ravikumar, J., et al. Muscardine: a menace to silkworm in winter. The Hindu. January 7, 2010.
- Veeranna, G., et al. (1985). Muscardine Disease – Precautionary Measures and Its Control. Karnataka State Sericulture Research and Development Institute, Bangalore, Karnataka.