In the fascinating world of Penicillium chrysogenum, there are endless aspects that deserve to be explored and analyzed. Whether on a personal, professional or academic level, Penicillium chrysogenum exerts a significant influence that directly impacts our lives. In this article, we will delve into the depths of Penicillium chrysogenum to unravel its mysteries and discover what makes it so relevant in today's society. Through detailed and comprehensive analysis, we will seek to understand the importance and impact that Penicillium chrysogenum has in different contexts, as well as examine its evolution over time. Additionally, we will explore the implications that Penicillium chrysogenum has for the future and how it may influence the course of events to come. Get ready to embark on a journey of discovery and knowledge about Penicillium chrysogenum!
Penicillium chrysogenum (formerly known as Penicillium notatum) is a species of fungus in the genus Penicillium. It is common in temperate and subtropical regions and can be found on salted food products, but it is mostly found in indoor environments, especially in damp or water-damaged buildings. It has been recognised as a species complex that includes P. notatum, P. meleagrinum, and P. cyaneofulvum. Molecular phylogeny has established that Alexander Fleming's first discovered penicillin producing strain is of a distinct species, P. rubens, and not of P. notatum. It has rarely been reported as a cause of human disease. It is the source of several β-lactam antibiotics, most significantly penicillin. Other secondary metabolites of P. chrysogenum include roquefortine C, meleagrin,chrysogine,6-MSA YWA1/melanin, andrastatin A,fungisporin,secalonic acids, sorbicillin, and PR-toxin.
Like the many other species of the genus Penicillium, P. chrysogenum usually reproduces by forming dry chains of spores (or conidia) from brush-shaped conidiophores. The conidia are typically carried by air currents to new colonisation sites. In P. chrysogenum, the conidia are blue to blue-green, and the mold sometimes exudes a yellow pigment. However, P. chrysogenum cannot be identified based on colour alone. Observations of morphology and microscopic features are needed to confirm its identity and DNA sequencing is essential to distinguish it from closely related species such as P. rubens. The sexual stage of P. chrysogenum was discovered in 2013 by mating cultures in the dark on oatmeal agar supplemented with biotin, after the mating types (MAT1-1 or MAT1-2) of the strains had been determined using PCR amplification.
The airborne asexual spores of P. chrysogenum are important human allergens. Vacuolar and alkaline serine proteases have been implicated as the major allergenic proteins.
The discovery of penicillin ushered in a new age of antibiotics derived from microorganisms. Penicillin is an antibiotic isolated from growing Penicillium mold in a fermenter. The mold is grown in a liquid culture containing sugar and other nutrients including a source of nitrogen. As the mold grows, it uses up the sugar and starts to make penicillin only after using up most of the nutrients for growth.
The ability to produce penicillin appears to have evolved over millions of years, and is shared with several other related fungi. It is believed to confer a selective advantage during competition with bacteria for food sources.[citation needed] Some bacteria have consequently developed the counter-ability to survive penicillin exposure by producing penicillinases, enzymes that degrade penicillin.[citation needed] Penicillinase production is one mechanism by which bacteria can become penicillin resistant.
The principal genes responsible for producing penicillin, pcbAB, pcbC, and penDE are closely linked, forming a cluster on chromosome I. Some high-producing Penicillium chrysogenum strains used for the industrial production of penicillin contain multiple tandem copies of the penicillin gene cluster.
Similar to other filamentous fungi, CRISPR/Cas9-mediated genome editing techniques are available for editing the genome of Penicillium chrysogenum.
References
^Samson RA, Houbraken J, Thrane U, Frisvad JC, Andersen B (2010). Food and Indoor Fungi. Utrecht, the Netherlands: CBS-KNAW- Fungal Biodiversity Centre. pp. 1–398.
^Samson RA, Hadlok R, Stolk AC (1977). "A taxonomic study of the Penicillium chrysogenum series". Antonie van Leeuwenhoek. 43 (2): 169–75. doi:10.1007/BF00395671. PMID413477. S2CID41843432.
^Lyratzopoulos, G.; Ellis, M.; Nerringer, R.; Denning, D. W. (October 2002). "Invasive infection due to penicillium species other than P. marneffei". The Journal of Infection. 45 (3): 184–195. doi:10.1053/jinf.2002.1056. ISSN0163-4453. PMID12387776.
^Shen HD, Chou H, Tam MF, Chang CY, Lai HY, Wang SR (October 2003). "Molecular and immunological characterization of Pen ch 18, the vacuolar serine protease major allergen of Penicillium chrysogenum". Allergy. 58 (10): 993–1002. doi:10.1034/j.1398-9995.2003.00107.x. PMID14510716. S2CID28229046.
^Raper KB, Thom C (1949). A manual of the Penicillia. Williams & Wilkins Company (Baltimore).
^Martín JF, Gutiérrez S, Fernández FJ, Velasco J, Fierro F, Marcos AT, Kosalkova K (1994). "Expression of genes and processing of enzymes for the biosynthesis of penicillins and cephalosporins". Antonie van Leeuwenhoek. 65 (3): 227–43. doi:10.1007/BF00871951. PMID7847890. S2CID25327312.