Please use this identifier to cite or link to this item: http://repositorio.ufla.br/jspui/handle/1/30903
metadata.artigo.dc.title: Optimizing the mass production of Clonostachys rosea by liquid-state fermentation
metadata.artigo.dc.creator: Carvalho, André Luiz de Andrade
Rezende, Larissa Castro de
Costa, Lúcio Bertoldo
Halfeld-Vieira, Bernardo de Almeida
Pinto, Zayame Vegette
Morandi, Marcelo Augusto Boechat
Medeiros, Flávio Henrique Vasconcelos de
Bettiol, Wagner
metadata.artigo.dc.subject: Clonostachys rosea
Mass production
Liquid media
Bioreactor
Fungal production
metadata.artigo.dc.publisher: Elsevier
metadata.artigo.dc.date.issued: Mar-2018
metadata.artigo.dc.identifier.citation: CARVALHO, A. L. de A. et al. Optimizing the mass production of Clonostachys rosea by liquid-state fermentation. Biological Control, [S.l.], v. 118, p. 16-25, Mar. 2018.
metadata.artigo.dc.description.abstract: Optimization of the culture medium and the entire mass production process for various fungi in liquid medium has been studied. However, the technology is not well developed for Clonostachys rosea, a biocontrol agent against various plant pathogens due to its antagonistic capacity to act as a hyperparasite, compete for nutrients and space, and induce plant resistance to pathogens. In this study, we aimed to optimize the culture medium and to standardize parameters that may interfere with the production of C. rosea conidia in a liquid-state fermentation system. Culturing was performed in 250-mL Erlenmeyer flasks shaken for 7 days, followed by planned experimental methodology to reduce the number of analyses and consumable costs. Benchtop bioreactor tests with the optimized medium were performed. Glucose and sucrose were evaluated as carbon sources. Initially, the effects of temperature, pH, photoperiod, carbon:nitrogen ratio and water activity on inoculum production were evaluated, with the pH and photoperiod being factors that contributed to conidial production. Optimization of the fermentation conditions was performed using a central composite rotational design (CCD) with a wider range of pH values and photoperiods. The remaining variables were fixed according to the previous assay. Colony-forming unit (CFUs), biomass production and conidial viability were evaluated, and glucose was used as a carbon source to enhance conidial production. The optimized conditions that resulted in a maximum yield of conidia (1.78 × 107 conidia mL−1), dried biomass (0.558 g) and CFUs (5.15 × 106 CFUs mL−1) were a pH value of 4 and a photoperiod of 12 h.
metadata.artigo.dc.identifier.uri: https://www.sciencedirect.com/science/article/pii/S1049964417302505#!
http://repositorio.ufla.br/jspui/handle/1/30903
metadata.artigo.dc.language: en_US
Appears in Collections:DFP - Artigos publicados em periódicos

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