Production of riboflavin and related cofactors by biotechnological processes

Liu, Shuang; Hu, Wenya; Wang, Zhiwen; Chen, Tao

doi:10.1186/s12934-020-01302-7

Cited by 84 publications

(85 citation statements)

References 139 publications

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“…The formation of reduced compounds such as lactic acid, ethanol, and butanol, among others, is evidence of the occurrence of metabolic pathways shifting from acidgenesis to solventogenesis [ 43 ]. One intermediate (I-1), a primary α-hydroxy ketone with butan-2-one substituted by a hydroxy group at positions 1 and 3 or a secondary α-hydroxy ketone, has a close structural analogue of 3,4-dihydroxybutan-2-one, whose phosphorylated form ( l -3,4-dihydroxybutan-2-one 4-phosphate) is a precursor for the synthesis of riboflavin [ 47 ]. Formyl 7 E -hexadecenoate, an effective nitrogen removal stimulant found in aquatic duckweed, was reported in lactic acid bacteria enhanced fermented milk [ 48 , 49 ].…”

Section: Discussionmentioning

confidence: 99%

Fermentation Enhanced Biotransformation of Compounds in the Kernel of Chrysophyllum albidum

et al. 2020

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Chrysophyllum albidum Linn (African star apple) is a fruit with extensive nutritional and medicinal benefits. The fruit and kernel in the seed are both edible. Strains of lactic acid bacteria (LAB) were isolated from fermented seeds and assessed for probiotic characteristics. The extracts in both the unfermented and the fermented aqueous extracts from the kernels obtained from the seeds of C. albidum were subjected to analysis using the gas chromatography/mass spectrometry (GC-MS) method. This analysis identified the bioactive compounds present as possible substrate(s) for the associated organisms inducing the fermentation and the resultant biotransformed products formed. Three potential probiotic LAB strains identified as Lactococcus raffinolactis (ProbtA1), Lactococcus lactis (ProbtA2a), and Pediococcus pentosaceus (ProbtA2b) were isolated from the fermented C. albidum seeds. All strains were non hemolytic, which indicated their safety, Probt (A1, A2a, and A2b) grew in an acidic environment (pH 3.5) during the 48-h incubation time, and all three strains grew in 1% bile, and exhibited good hydrophobicity and auto-aggregation properties. Mucin binding proteins was not detected in any strain, and bile salt hydrolase was detected in all the strains. l-lactic acid (28.57%), norharman (5.07%), formyl 7E-hexadecenoate (1.73%), and indole (1.51%) were the four major constituents of the fermented kernel of the C. albidum, while 2,5-dimethylpyrazine (C1, 1.27%), 3,5-dihydroxy-6-methyl-2,3-dihydropyran-4-one (C2, 2.90%), indole (C3, 1.31%), norharman (C4, 3.01%), and methyl petroselinate (C5, 4.33%) were the five major constituents of the unfermented kernels. The isolated LAB are safe for consumption. The fermenting process metabolized C1, C2, and C5, which are possible starter cultures for the growth of probiotics. Fermentation is an essential tool for bioengineering molecules in foods into safe and health beneficial products.

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Section: Discussionmentioning

confidence: 99%

Fermentation Enhanced Biotransformation of Compounds in the Kernel of Chrysophyllum albidum

et al. 2020

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“…Metabolic engineering strategies based on the riboflavin metabolic pathway of B. subtilis are usually based on optimization of the central carbon metabolism, overexpression and deregulation of the RF synthesis and purine biosynthesis pathways, as well as blocking the synthesis of by-products [ 52 ]. The precursor supply in the RF biosynthesis pathway can be enhanced by redirecting the carbon flux through the PPP (pentose phosphate pathway) from the EMP (Embden-Meyerhof-Parnas) pathway, and increasing the expression of purine biosynthesis genes ( pur operon), thus increasing GTP production [ 53 , 54 ]. The yield of riboflavin in fed-batch fermentation using B. subtilis reached up to 826.52 mg/L [ 54 ].…”

Section: Vitamins As High-value Productsmentioning

confidence: 99%

Bacillus subtilis: a universal cell factory for industry, agriculture, biomaterials and medicine

Chuan²,

Fang³

et al. 2020

Microb Cell Fact

255

142

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Due to its clear inherited backgrounds as well as simple and diverse genetic manipulation systems, Bacillus subtilis is the key Gram-positive model bacterium for studies on physiology and metabolism. Furthermore, due to its highly efficient protein secretion system and adaptable metabolism, it has been widely used as a cell factory for microbial production of chemicals, enzymes, and antimicrobial materials for industry, agriculture, and medicine. In this mini-review, we first summarize the basic genetic manipulation tools and expression systems for this bacterium, including traditional methods and novel engineering systems. Secondly, we briefly introduce its applications in the production of chemicals and enzymes, and summarize its advantages, mainly focusing on some noteworthy products and recent progress in the engineering of B. subtilis . Finally, this review also covers applications such as microbial additives and antimicrobials, as well as biofilm systems and spore formation. We hope to provide an overview for novice researchers in this area, offering them a better understanding of B. subtilis and its applications.

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“…Riboflavin biosynthesis begins from two major substrates, GTP and Ribu5P, derived from purine biosynthesis or/and the pentose phosphate pathway, containing seven enzymatic steps generating the final product ( Liu et al, 2020 ). Research on riboflavin biosynthesis demonstrated that characteristic features of most enzymes and steps involved in the riboflavin pathway are mostly similar between prokaryotes and plants, whereas fungi use a somewhat different pathway and enzymes ( Abbas and Sibirny, 2011 ).…”

Section: Biosynthesis Of Riboflavin and Its Derivativesmentioning

confidence: 99%

Production of Vitamin B2 (Riboflavin) by Microorganisms: An Overview

Averianova

Balabanova

Son

et al. 2020

Front. Bioeng. Biotechnol.

125

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Riboflavin is a crucial micronutrient that is a precursor to coenzymes flavin mononucleotide and flavin adenine dinucleotide, and it is required for biochemical reactions in all living cells. For decades, one of the most important applications of riboflavin has been its global use as an animal and human nutritional supplement. Being well-informed of the latest research on riboflavin production via the fermentation process is necessary for the development of new and improved microbial strains using biotechnology and metabolic engineering techniques to increase vitamin B2 yield. In this review, we describe well-known industrial microbial producers, namely, Ashbya gossypii , Bacillus subtilis , and Candida spp. and summarize their biosynthetic pathway optimizations through genetic and metabolic engineering, combined with random chemical mutagenesis and rational medium components to increase riboflavin production.

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Production of riboflavin and related cofactors by biotechnological processes

Cited by 84 publications

References 139 publications

Fermentation Enhanced Biotransformation of Compounds in the Kernel of Chrysophyllum albidum

Fermentation Enhanced Biotransformation of Compounds in the Kernel of Chrysophyllum albidum

Bacillus subtilis: a universal cell factory for industry, agriculture, biomaterials and medicine

Production of Vitamin B2 (Riboflavin) by Microorganisms: An Overview

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