Construction of the advanced flavin mononucleotide producers in the flavinogenic yeast Candida famata.

Flavin mononucleotide (FMN, riboflavin-5'-phosphate) is flavin coenzyme synthesized in all living organisms from riboflavin (vitamin B2 ) after phosphorylation in the reaction catalyzed by riboflavin kinase. FMN has several applications mostly as yellow colorant in food industry due to 200 times better water solubility as compared to riboflavin. Currently, FMN is produced by chemical phosphorylation of riboflavin, however, final product contains up to 25% of flavin impurities. Microbial overproducers of FMN are known, however, they accumulate this coenzyme in glucose medium. Current work shows that the recombinant strains of the flavinogenic yeast Candida famata with overexpressed FMN1 gene coding for riboflavin kinase in the recently isolated by us advanced riboflavin producers due to overexpression of the structural and regulatory genes of riboflavin synthesis and of the putative exporter of riboflavin from the cell, synthesized elevated amounts of FMN in the media not only with glucose but also in lactose and cheese whey. Activation of FMN accumulation on lactose and cheese whey was especially strong in the strains which expressed the gene of transcription activator SEF1 under control of the lactose-induced LAC4 promoter. The accumulation of this coenzyme by the washed cells of the best recombinant strain achieved 540 mg/L in the cheese whey supplemented only with ammonium sulfate during 48 h in shake flask experiments.

Cheese whey supports high riboflavin synthesis by the engineered strains of the flavinogenic yeast Candida famata.

BACKGROUND: Riboflavin is a precursor of FMN and FAD which act as coenzymes of numerous enzymes. Riboflavin is an important biotechnological commodity with annual market sales exceeding nine billion US dollars. It is used primarily as a component of feed premixes, a food colorant, a component of multivitamin mixtures and medicines. Currently, industrial riboflavin production uses the bacterium, Bacillus subtilis, and the filamentous fungus, Ashbya gossypii, and utilizes glucose and/or oils as carbon substrates. RESULTS: We studied riboflavin biosynthesis in the flavinogenic yeast Candida famata that is a genetically stable riboflavin overproducer. Here it was found that the wild type C. famata is characterized by robust growth on lactose and cheese whey and the engineered strains also overproduce riboflavin on whey. The riboflavin synthesis on whey was close to that obtained on glucose. To further enhance riboflavin production on whey, the gene of the transcription activator SEF1 was expressed under control of the lactose-induced promoter of the native ß-galactosidase gene LAC4. These transformants produced elevated amounts of riboflavin on lactose and especially on whey. The strain with additional overexpression of gene RIB6 involved in conversion of ribulose-5-phosphate to riboflavin precursor had the highest titer of accumulated riboflavin in flasks during cultivation on whey. Activation of riboflavin synthesis was also obtained after overexpression of the GND1 gene that is involved in the synthesis of the riboflavin precursor ribulose-5-phosphate. The best engineered strains accumulated 2.5 g of riboflavin/L on whey supplemented only with (NH4)2SO4 during batch cultivation in bioreactor with high yield (more than 300 mg/g dry cell weight). The use of concentrated whey inhibited growth of wild-type and engineered strains of C. famata, so the mutants tolerant to concentrated whey were isolated. CONCLUSIONS: Our data show that the waste of dairy industry is a promising substrate for riboflavin production by C. famata. Possibilities for using the engineered strains of C. famata to produce high-value commodity (riboflavin) from whey are discussed.