Topic
Byssochlamys
About: Byssochlamys is a research topic. Over the lifetime, 100 publications have been published within this topic receiving 6987 citations.
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13 Nov 2012
TL;DR: The Ecology of Fungal Food Spoilage: Naming and Classifying Fungi and Methods for Isolation, Enumeration and Identification is presented.
Abstract: Introduction. The Ecology of Fungal Food Spoilage. Naming and Classifying Fungi. Methods for Isolation, Enumeration and Identification. Primary Keys and Miscellaneous Fungi. Zygomycetes. Penicillium and Related Genera. Aspergillus and Relataed Teleomorphs. Xerophiles. Yeast. Spoilage of Fresh and Perishable Foods. Spoilage of Stored, Processed and Preserved Foods. Media Appendix. Glossary. Index
3,461 citations
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TL;DR: It was concluded that chitosan was worthy of further study as a natural preservative for foods prone to fungal spoilage and was concentration-, pH- and temperature-dependent.
488 citations
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TL;DR: Information on the current understanding of the mechanisms of patulin toxinogenesis is included, and its toxicological effects are summarized.
Abstract: Patulin is a toxic chemical contaminant produced by several species of mold, especially within Aspergillus, Penicillium and Byssochlamys. It is the most common mycotoxin found in apples and apple-derived products such as juice, cider, compotes and other food intended for young children. Exposure to this mycotoxin is associated with immunological, neurological and gastrointestinal outcomes. Assessment of the health risks due to patulin consumption by humans has led many countries to regulate the quantity in food. A full understanding of the molecular genetics of patulin biosynthesis is incomplete, unlike other regulated mycotoxins (aflatoxins, trichothecenes and fumonisins), although the chemical structures of patulin precursors are now known. The biosynthetic pathway consists of approximately 10 steps, as suggested by biochemical studies. Recently, a cluster of 15 genes involved in patulin biosynthesis was reported, containing characterized enzymes, a regulation factor and transporter genes. This review includes information on the current understanding of the mechanisms of patulin toxinogenesis and summarizes its toxicological effects.
444 citations
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TL;DR: More research is needed to elucidate the mechanism(s) of thermoresistance and develop new methods for the complete inactivation of resistant ascospores, which results in great economic losses.
Abstract: Spoilage of pasteurized and canned fruit and fruit products caused by heat-resistant molds have been reported repeatedly in recent years. Species most commonly implicated in fruit and fruit product disintegration are Byssochlamys fulva, Byssochlamys nivea, Neosartorya fischeri, Talaromyces flavus, and Eupenicillium brefeldianum. These organisms are saprophytic rather than parasitic and usually contaminate fruits on or near the ground. They can survive heat treatments used for fruit processing and can grow and spoil the products during storage at room temperature, which results in great economic losses. Mold heat resistance is attributed to the formation of sexual spores, ascospores. Ascospores have a wide range of heat resistance, depending on species, strain, age of organism, heating medium, pH, presence of sugars, fats, and acids in heating medium, growth conditions, etc. The mechanism(s) of thermoresistance are not clear; probably some very stable compound(s) critical to germination and outgrowth are present in the heat-resistant ascospores. Besides spoilage, the heat-resistant molds produce a number of toxic secondary metabolites, such as byssotoxin A; byssochlamic acid; the carcinogen, patulin, the tremorgenic substances, fumitremorgin A and C, and verruculogen; fischerin, which caused fatal peritonitis in mice; and eupenifeldin, a compound possessing cytotoxicity as well as in vivo antitumor activity. Growth of heat-resistant fungi can be controlled by lowering the water activity, adding sulfur dioxide, sorbate, or benzoate; washing of fruits in hypochlorite solution before heat treatment reduces the number of ascospores and makes the heat destruction more successful. More research is needed to elucidate the mechanism(s) of thermoresistance and develop new methods for the complete inactivation of resistant ascospores.
182 citations