Application of Biolog FF MicroPlate for substrate utilization and metabolite profiling of closely related fungi

Filamentous fungi are known to have unique biochemical pathways to assimilate a vast array of simple and complex nutrients available to them and to produce a variety of metabolites. Morphological and biochemical uniqueness of these organisms are commonly used for their identification, but differenti...

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Bibliographic Details
Published in:Journal of microbiological methods 2009-04, Vol.77 (1), p.102-108
Main Author: Singh, Maya Prakash
Format: Article
Language:English
Subjects:
Biolog FF Microplate
Biological and medical sciences
Culture Media - chemistry
Culture Media - metabolism
Culture profiling
Fermentation
Fundamental and applied biological sciences. Psychology
Fungi - chemistry
Fungi - classification
Fungi - growth & development
Fungi - metabolism
Growth, nutrition, metabolism, transports, enzymes. Molecular biology
Microbiological Techniques - methods
Microbiology
Mycological methods and techniques used in mycology
Mycological Typing Techniques - methods
Mycology
Natural products
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Summary:Filamentous fungi are known to have unique biochemical pathways to assimilate a vast array of simple and complex nutrients available to them and to produce a variety of metabolites. Morphological and biochemical uniqueness of these organisms are commonly used for their identification, but differentiation of closely related cultures requires extensive phenotypic and genomic investigations. The Biolog FF MicroPlate was recently introduced for rapid identification of common filamentous fungi based on their abilities to utilize 95 discrete substrates. We used the FF MicroPlate for substrate utilization, growth, secondary metabolite and antimicrobial profiles of some fungal cultures important to our microbial drug discovery program. Culture growth was monitored by change in absorbance in each well, and the presence of secondary metabolites and their corresponding bioactivities was detected by LCMS analyses and antimicrobial assays of the extracts of each well, respectively. Fingerprints were created with Spotfire visualization software, and data were analyzed in various ways. The substrate utilization fingerprints were useful in selecting media components for media optimization of secondary metabolite production for the various cultures. In general, a strong correlation was found among substrate utilization, growth, antimicrobial activity and presence of the responsible secondary metabolites. The method was used for dereplication of isolated fungi and in the differentiation of closely related variants within one species.
ISSN:0167-7012
1872-8359
DOI:10.1016/j.mimet.2009.01.014