Exploring fungal biodiversity: organic acid production by 66 strains of filamentous fungi

Liaud, Nadège; Giniès, Christian; Navarro, David; Fabre, Nicolás; Crapart, Sylvaine; Gimbert, Isabelle; Levasseur, Anthony; Raouche, Sana; Sigoillot, Jean‐Claude

doi:10.1186/s40694-014-0001-z

Cited by 134 publications

(82 citation statements)

References 33 publications

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“…The decrease in pH may be attributed to the organic acid production by the fungal strains. 41 The pH increase was higher in flasks which have higher growth of algae, especially in the 50× CDS medium. In a 5 L airlift reactor with a Rhizopus sp.…”

Section: Glycerol Acetic Acid and Biomass Lipid Profilementioning

confidence: 93%

Nutrient recovery from ethanol co-products by a novel mycoalgae biofilm: attached cultures of symbiotic fungi and algae

Rajendran

Fox

2017

J. Chem. Technol. Biotechnol

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BACKGROUND Fungal and algae treatment of food‐industry waste opens a new avenue for valorizing waste to valuable products through the production of desirable cell biomass. A novel mycoalgae biofilm (symbiotic growth of algae and fungi) was developed in ethanol co‐products, the profuse remains from the ethanol distillation process. RESULTS The mycoalgae biofilm flasks produced more biomass compared with pure fungal cultures under all the conditions tested. The total microbial biomass concentration in mycoalgae biofilm increased from 5.998 g L−1 at 4 d (98.81% fungal biomass and 1.19% algae biomass) to 9.358 g L−1 at 12 d (97.2% fungal biomass and 2.8% algae biomass) with a drop in attached residual solids from 6.304 g L−1 at 4 d to 3.349 g L−1 at 12 d in 10× condensed distillers solubles medium. The high nutrient concentration of P (818 mg L−1) and N (924 mg L−1) in the samples was recovered in the attached mycoalgae biomass at 55.7% and 74%, respectively, with a reduction in COD of up to 65.6%. CONCLUSION The results show that ethanol co‐products support excellent mycoalgae biofilm growth. The nutrients in ethanol co‐products can be efficiently recovered and recycled for agricultural applications and better nutrient management. © 2016 Society of Chemical Industry

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Section: Glycerol Acetic Acid and Biomass Lipid Profilementioning

confidence: 93%

Nutrient recovery from ethanol co-products by a novel mycoalgae biofilm: attached cultures of symbiotic fungi and algae

Rajendran

Fox

2017

J. Chem. Technol. Biotechnol

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“…In particular, succinic, fumaric, malic and lactic acids are determined which are known to be secreted in variable proportions by various fungi species 15,16 . Moreover, among them, glycerol was also determined; glycerol can be produced by some species of fungi when stressed by water shortage 2 .…”

Section: Resultsmentioning

confidence: 99%

Low molecular weight organic acid salts, markers of old fungi activity in wall paintings

et al. 2016

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Micro Infrared Spectroscopy (µSR-FTIR) and X-Ray diffraction (µSR-XRD) with synchrotron light, Gas Chromatography/Mass Spectrometry (CG/MS), Optical Microscopy (OM) and Scanning Electron Microscopy (SEM/EDS) were used to identify and obtain the distribution of complex mixtures of calcium salts of low molecular weight organic acids (LMWOA) in micro-layered micro-samples. Filamentous fungi produce LMWOA that can react with metal cations producing stable salts. These substances were found in the dark spots covering the surfaces of Saint Michael's Chapel wall paintings of the Royal Monastery of Pedralbes in Barcelona linking them to old fungi activity. The presence of glycerol likewise related to the fungi activity is also identified in the layers.

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“…Physiologically active compounds such as antibiotics, antitumor drugs, antibodies, hypocholesterolemic drugs, anticancer drugs, immunosuppressants, plant hormones, growth promoters for livestock, alkaloids, statins (Vieira et al 2008;Demain 2014;Khan et al 2014), phenolic compounds, terpenes, steroids (Hasnat et al 2015), and antioxidants (Borderes et al 2011) are obtained by fungal culture in bioprocess. Fungi are also recognized by their wide potential in enzyme production of commercial scale (Demain 2014;Hansen et al 2015), biotransformation process (Aguirre-Pranzoni et al 2011), and synthesis of organic acids (Liaud et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Fungi as a source of natural coumarins production

Costa

Tavares

Oliveira

2016

Appl Microbiol Biotechnol

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Natural coumarins and derivatives are compounds that occur naturally in several organisms (plant, bacteria, and fungi) consisting of fused benzene and α-pyrone rings. These compounds show high technological potential applications in agrochemical, food, pharmaceuticals, and cosmetics industries. Therefore, the need for bulk production of coumarins and the advancement of the chemical and pharmaceutical industries led to the development of synthetic coumarin. However, biotransformation process, synthetic bioengineering, metabolic engineering, and bioinformatics have proven effective in the production of natural products. Today, these biological systems are recognized as green chemistry innovation and business strategy. This review article aims to report the potential of fungi for synthesis of coumarin. These microorganisms are described as a source of natural products capable of synthesizing many bioactive metabolites. The features, classification, properties, and industrial applications of natural coumarins as well as new molecules obtained by basidiomycetes and ascomycetes fungi are reported in order to explore a topic not yet discussed in the scientific literature.

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Exploring fungal biodiversity: organic acid production by 66 strains of filamentous fungi

Cited by 134 publications

References 33 publications

Nutrient recovery from ethanol co-products by a novel mycoalgae biofilm: attached cultures of symbiotic fungi and algae

Nutrient recovery from ethanol co-products by a novel mycoalgae biofilm: attached cultures of symbiotic fungi and algae

Low molecular weight organic acid salts, markers of old fungi activity in wall paintings

Fungi as a source of natural coumarins production

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