Comparative Study of the Pharmacological Properties of Luteolin and Its 7,3'-Disulfate.

The global spread of the metabolic syndrome, oncological and viral diseases forces researchers to pay increased attention to the secondary metabolites of marine hydrobionts, which often have a high therapeutic potential in the treatment of these pathologies and are effective components of functional food. The flavone luteolin (LT), as one of the most widely distributed and studied plant metabolites, is distinguished by a diverse spectrum of biological activity and a pleiotropic nature of the mechanism of action at the molecular, cellular and organismal levels. However, there is still practically no information on the spectrum of biological activity of its sulfated derivatives, which are widely represented in seagrasses of the genus Zostera. In the present work, a comparative study of the pharmacological properties of LT and its 7,3'-disulfate was carried out with a brief analysis of the special role of sulfation in the pharmacological activity of flavonoids.

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

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.

Development of host strains and vector system for an efficient genetic transformation of filamentous fungi.

An ability to synthesize extracellular enzymes degrading a wide spectrum of plant and algae polymeric substrates makes many fungi relevant for biotechnology. The terrestrial thermophilic and marine fungal isolates capable of plant and algae degradation have been tested for antibiotic resistance for their possible use in a new genetic transformation system. Plasmids encoding the hygromycin B phosphotransferase (hph) under the control of the cauliflower mosaic virus 35S promoter, the trpC gene promoter of Aspergillus nidulans, and the Aureobasidium pullulans TEF gene promoter were delivered into the fungal cells by electroporation. The effectiveness of different promoters was compared by transformation and growth of Thermothelomyces thermophila (formerly Myceliophthora thermophila) on the selective medium and by real-time PCR analysis. A highly efficient transformation was observed at an electric-pulse of 8.5 kV/cm by using 10 µg of DNA per 1 × 105 conidia. Although all promoters were capable of hph expression in the Th. thermophila cells, the trpC promoter provided the highest level of hygromycin resistance. We further successfully applied plant binary vector pPZP for co-transformation of hph gene and enhanced green fluorescent protein gene that confirmed this transformation system could be used as an appropriate tool for gene function studies and the expression of heterologous proteins in micromycetes.