Identification of potentially safe promising fungal cell factories for the production of polyketide natural food colorants using chemotaxonomic rationale

<p>Abstract</p> <p>Background</p> <p>Colorants derived from natural sources look set to overtake synthetic colorants in market value as manufacturers continue to meet the rising demand for clean label ingredients – particularly in food applications. Many ascomycetous fu...

Full description

Bibliographic Details
Main Authors: Frisvad Jens C, Thrane Ulf, Meyer Anne S, Mapari Sameer AS
Format: Article
Language:English
Published: BMC 2009-04-01
Series:Microbial Cell Factories
Online Access:http://www.microbialcellfactories.com/content/8/1/24
Description
Summary:<p>Abstract</p> <p>Background</p> <p>Colorants derived from natural sources look set to overtake synthetic colorants in market value as manufacturers continue to meet the rising demand for clean label ingredients – particularly in food applications. Many ascomycetous fungi naturally synthesize and secrete pigments and thus provide readily available additional and/or alternative sources of natural colorants that are independent of agro-climatic conditions. With an appropriately selected fungus; using in particular chemotaxonomy as a guide, the fungal natural colorants could be produced in high yields by using the optimized cultivation technology. This approach could secure efficient production of pigments avoiding use of genetic manipulation.</p> <p>Results</p> <p>Polyketide pigment producing ascomycetous fungi were evaluated for their potential as production organisms based on <it>a priori </it>knowledge on species-specific pigment and potential mycotoxin production and BioSafety level (BSL) classification. Based on taxonomic knowledge, we pre-selected ascomycetous fungi belonging to <it>Penicillium </it>subgenus <it>Biverticillium </it>that produced yellow, orange or red pigments while deselecting <it>Penicillium marneffei</it>; a well known human pathogen in addition to other mycotoxigenic fungi belonging to the same group. We identified 10 strains belonging to 4 species; <it>viz</it>. <it>P. purpurogenum, P. aculeatum, P. funiculosum</it>, and <it>P. pinophilum </it>as potential pigment producers that produced <it>Monascus</it>-like pigments but no known mycotoxins. The selection/deselection protocol was illustrated in the pigment extracts of <it>P. aculeatum </it>IBT 14259 and <it>P. crateriforme </it>IBT 5015 analysed by HPLC-DAD-MS. In addition, extracellular pigment producing ability of some of the potential pigment producers was evaluated in liquid media with a solid support and N-glutarylmonascorubramine was discovered in the partially purified pigment extract of <it>P. purpurogenum </it>IBT 11181 and IBT 3645.</p> <p>Conclusion</p> <p>The present work brought out that the use of chemotaxonomic tools and <it>a priori </it>knowledge of fungal extrolites is a rational approach towards selection of fungal polyketide pigment producers considering the enormous chemical diversity and biodiversity of ascomycetous fungi. This rationale could be very handy for the selection of potentially safe fungal cell factories not only for polyketide pigments but also for the other industrially important polyketides; the molecular and genetic basis for the biosynthesis of which has not yet been examined in detail. In addition, 4 out of the 10 chemotaxonomically selected promising <it>Penicillium </it>strains were shown to produce extracellular pigments in the liquid media using a solid support indicating future cell factory possibilities for polyketide natural food colorants.</p>
ISSN:1475-2859