Penicillium expansum versus antagonist yeasts and patulin degradation in vitro

Coelho, Alexandre Rodrigo; Celli, Marcos Giovani; Ono, Elisabete Yurie Sataque; Wosiacki, Gilvan; Hoffmann, Fernando Leite; Pagnocca, Fernando Carlos; Hirooka, Elisa Yoko

doi:10.1590/s1516-89132007000400019

Cited by 43 publications

(43 citation statements)

References 35 publications

(33 reference statements)

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“…In the last decade, a few studies investigated the effect on patulin accumulation by BCAs that are effective against P. expansum. Pichia ohmeri (11), Candida sake and Pantoea agglomerans (12), and several Lactobacillus species (13) were able to reduce patulin accumulation in vitro. These studies excluded the metabolism of patulin by these microorganisms, and the observed reduction was attributed to the protection of fruits from infection by patulin-producing P. expansum and/or to the decrease of mycotoxin production.…”

mentioning

confidence: 98%

Searching for Genes Responsible for Patulin Degradation in a Biocontrol Yeast Provides Insight into the Basis for Resistance to This Mycotoxin

Ianiri

Idnurm

Wright

et al. 2013

Appl Environ Microbiol

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f Patulin is a mycotoxin that contaminates pome fruits and derived products worldwide. Basidiomycete yeasts belonging to the subphylum Pucciniomycotina have been identified to have the ability to degrade this molecule efficiently and have been explored through different approaches to understand this degradation process. In this study, Sporobolomyces sp. strain IAM 13481 was found to be able to degrade patulin to form two different breakdown products, desoxypatulinic acid and (Z)-ascladiol. To gain insight into the genetic basis of tolerance and degradation of patulin, more than 3,000 transfer DNA (T-DNA) insertional mutants were generated in strain IAM 13481 and screened for the inability to degrade patulin using a bioassay based on the sensitivity of Escherichia coli to patulin. Thirteen mutants showing reduced growth in the presence of patulin were isolated and further characterized. Genes disrupted in patulin-sensitive mutants included homologs of Saccharomyces cerevisiae YCK2, PAC2, DAL5, and VPS8. The patulin-sensitive mutants also exhibited hypersensitivity to reactive oxygen species as well as genotoxic and cell wall-destabilizing agents, suggesting that the inactivated genes are essential for tolerating and overcoming the initial toxicity of patulin. These results support a model whereby patulin degradation occurs through a multistep process that includes an initial tolerance to patulin that utilizes processes common to other external stresses, followed by two separate pathways for degradation.

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confidence: 98%

Searching for Genes Responsible for Patulin Degradation in a Biocontrol Yeast Provides Insight into the Basis for Resistance to This Mycotoxin

Ianiri

Idnurm

Wright

et al. 2013

Appl Environ Microbiol

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“…Walker et al (1995) reported the susceptibility of yeast and filamentous fungi caused by the killer positive strains of S. cerevisiae, P. anomala and Williopsis mrakii. Studies by Coelho et al (2006Coelho et al ( , 2007 showed 58.15% inhibition of spore germination of P. expansum with supernatant of C. guilliermondii cultivate obtained after 72 h of incubation at 25 o C, whereas Pichia ohmeri (25 o C/48 h) inhibited the hyphal length development in 64.37%, both associated with the killer factor. Although there had not been any reports on the action of killer toxins produced by Kluyveromyces sp.…”

Section: Antifungal Assaymentioning

confidence: 95%

“…The antifungal assay in solid medium was used for screening the yeasts with potential activity against the fungal strains. This method allowed observing two types of inhibition, i.e., competition for the nutrients, identified by yeast growth pumping through the edge of the well and/or extra-cellular compound production by antibiosis, characterized by the inhibition zone with no growth of spoilage mould (Coelho et al 2007). …”

Section: Antifungal Assay In Solid Mediummentioning

confidence: 99%

Role of killer factors in the inhibitory activity of bio-control yeasts against Penicillium expansum and Aspergillus ochraceus

Portes

Oliveira

Simer

et al. 2013

Braz. arch. biol. technol.

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“…Métodos alternativos são desenvolvidos para o controle do bolor azul como a utilização de microrganismos antagônicos (COELHO et al, 2007;LEVY et al, 2000) As leveduras e seus metabólitos também vêm sendo estudados para utilização no controle biológico. Levy et al (2000) analisaram o potencial antagônico de 18 leveduras contra Penicillium spp produtor de patulina, avaliando o potencial e a estabilidade dos compostos ativos produzidos, utilizando o sobrenadante do meio de leveduras para realização de antibiograma.…”

Section: Dombrink-kurtzman E Blackburnunclassified

“…Ao considerar o efeito antagônico e degradador de Pichia membranifaciens e Sporobolomyces roseus na degradação de 588,4 para 290,0 µg de patulina (25ºC/15 dias) em estudos preliminares (COELHO et al, 2004;LEVY et al, 2002), Coelho et al (2007) avaliaram o efeito degradador de Pichia ohmeri 158 isolada de ecossistema natural (formigueiro) sobre toxina produzida por P. expansum toxigênico (107 µg/mL). Para tanto, foi adicionado simultaneamente 223 µg de patulina e 3,0 x 10 6 células de P. ohmeri 158 em 25 mL de Caldo Extrato de Malte, seguido de quantificação aos 2, 5, 10 e 15 dias de incubação a 25ºC por Cromatografia Líquida de Alta Eficiência.…”

Section: Lai Fuh E Shihunclassified

Patulina: incidência e controle em derivados de maçã

et al. 2009

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ResumoA patulina, 4hidroxi-4furo[3,2-c] pirano(6H)-1, micotoxina termo-resistente, é produzida por várias espécies de fungos, comuns em vegetais, produtos derivados e principalmente em maçãs. Estudos sobre a toxicidade em animais demonstraram esta micotoxina possui caráter teratogênico, cancerígeno e imunotóxico em camundongos. Sua biossíntese é bem compreendida envolvendo uma série de reações de condensação e de oxiredução, muitas catalisadas por enzimas. O perigo da contaminação de alimentos com patulina, alerta sobre a necessidade de um controle mais rigoroso. Pesquisas recentes objetivam sua remoção e degradação, bem como aumentar a sensibilidade das análises, tornando-as mais rápidas e com menores custos. A remoção de patulina de alimentos é feita com compostos adsorventes, com inconveniente de diminuir a qualidade do produto por adsorver outros componentes desejáveis. A degradação é feita com compostos sulfurados, os quais não são permitidos em alimentos em muitos países, e pelo crescimento de leveduras, como no caso da produção de sidras. Muitas leveduras apresentam resistência contra a patulina e produzem compostos capazes de degradá-la. Aqui, foram revisadas pesquisas sobre patulina com ênfase sobre sua influência na indústria de alimentos, incidência de patulina em suco de maçã e outros alimentos, concentrações máximas permitidas, efeitos na saúde, biossíntese, remoção, degradação e métodos mais utilizados para sua detecção e quantificação. Palavras-chave: Micotoxinas, Penicillium expansum, maçã AbstractThe patulin, (4hydroxy-4furo[3,2-c]pyran(6H)-1),, is a thermal resistent mycotoxin produced by several species of fungi are common in plants, mainly in derivatives and apples. Studies on the toxicity in animals have shown that mycotoxin has character teratogenic, and carcinogenic in mice immunotoxic. Its biosynthesis is well understood involving a series of reactions of condensation and oxiredução, many catalyzed by enzymes. The danger of contamination of food with patulin, warning about the need for a more rigorous control. Recent research aimed their removal and degradation as well as increase the sensitivity of the tests, making them faster and at less cost. The removal of patulin of food is made with composite adsorbents, with inconvenience to diminish the quality of the product by adsorbs other components desirable. The degradation is made with sulfur compounds, which are not allowed in food in many countries, and the growth of yeasts, such as the production of cider. Many yeasts have resistance against patulin and produce compounds capable degrade it. Here, we reviewed research on patulin with emphasis on its influence in food industry, incidence of patulin in apple juice and other foods, maximum permissible concentrations, health effects, biosynthesis, removal, degradation and most widely used methods for its detection and quantification.

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Penicillium expansum versus antagonist yeasts and patulin degradation in vitro

Abstract: Taking into account the preliminary antagonistic/biodegradation property showed by Pichia membranifaciens and

Cited by 43 publications

References 35 publications

Searching for Genes Responsible for Patulin Degradation in a Biocontrol Yeast Provides Insight into the Basis for Resistance to This Mycotoxin

Searching for Genes Responsible for Patulin Degradation in a Biocontrol Yeast Provides Insight into the Basis for Resistance to This Mycotoxin

Role of killer factors in the inhibitory activity of bio-control yeasts against Penicillium expansum and Aspergillus ochraceus

Patulina: incidência e controle em derivados de maçã

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