Abstract
BackgroundFungal perylenequinonoid (PQ) pigments from Shiraia fruiting body have been well known as excellent photosensitizers for medical and agricultural uses. The fruiting bodies are colonized by a diverse bacterial community of unknown function. We screened the companion bacteria from the fruiting body of Shiraia sp. S9 and explored the bacterial elicitation on fungal PQ production.ResultsA bacterium Pseudomonas fulva SB1 isolated from the fruiting body was found to stimulate the production of fungal PQs including hypocrellins A, C (HA and HC), and elsinochromes A–C (EA, EB and EC). After 2 days of co-cultures, Shiraia mycelium cultures presented the highest production of HA (325.87 mg/L), about 3.20-fold of that in axenic culture. The co-culture resulted in the induction of fungal conidiation and the formation of more compact fungal pellets. Furthermore, the bacterial treatment up-regulated the expression of polyketide synthase gene (PKS), and activated transporter genes of ATP-binding cassette (ABC) and major facilitator superfamily transporter (MFS) for PQ exudation.ConclusionsWe have established a bacterial co-culture with a host Shiraia fungus to induce PQ biosynthesis. Our results provide a basis for understanding bacterial–fungal interaction in fruiting bodies and a practical co-culture process to enhance PQ production for photodynamic therapy medicine.
Highlights
Fungal perylenequinonoid (PQ) pigments from Shiraia fruiting body have been well known as excellent photosensitizers for medical and agricultural uses
Perylenequinones (PQs) comprise a family of natural pigments characterized by 3,10-dihydroxy-4,9-perylenequinone chromophore, which are being explored as a group of reactive oxygen species (ROS)-generating photosensitizers for medical and agricultural uses [1]
We investigated the interaction between the bacterium and Shiraia sp
Summary
The screening of the associated bacteria A total of 31 bacterial isolates were obtained from the fresh fruiting body of S. bambusicola (Additional file 1: Table S1). After 2-day treatment of SB1 at 400 cells/mL, total HA production in cultures was enhanced to its peak value 325.87 mg/L, about 3.20-fold of that of control group (Fig. 10). Ncbi.nlm.nih.gov/geo/) including polyketide synthase (PKS, CL954Contig1), O-methyltransferase (Omef, CL6443Contig1), FAD/FMN-dependent oxidoreductase (FAD, CL2000Contig1), monooxygenase (Mono, CL1046Contig1), multicopper oxidase (MCO, CL4891Contig1), major facilitator superfamily (MFS, CL13Contig3) and ATP-binding cassette transporter (ABC, CL1803Contig1) were analyzed by using qRTPCR after 48 h of the co-culture The expression of those PQ biosynthesis-related unigenes were up-regulated by SB1 in the co-culture, about 4.2-, 2.1-, 2.0-, 2.6-, 2.0-, Discussion Owing to the unique structures and the conspicuous biological activities of the PQs such as anticancer [2, 23], antiviral [24] and antimicrobial activities [25], biotechnological production of the PQs using mycelium cultures of Shiraia sp. A bacterium P. fulva SB1 isolated from Shiraia fruiting body could elicit both PQ accumulation in hyphal cells and the excretion to the medium (Table 1 and Fig. 2). The correlation between fungal morphology and metabolite production in co-cultures needed to be further elucidated for understanding the role of live bacterium in bacterial–fungal interactions
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