Furmaniak Magda A, Misztak Agnieszka E, Franczuk Martyna D, Wilmotte Annick, Waleron Małgorzata, Waleron Krzysztof F
Chair and Department of Pharmaceutical Microbiology, Medical University of Gdańsk, Gdańsk, Poland.
Department of Biotechnology, Intercollegiate Faculty of Biotechnology of University of Gdańsk and Medical University of Gdańsk, Gdańsk, Poland.
Front Microbiol. 2017 Dec 18;8:2541. doi: 10.3389/fmicb.2017.02541. eCollection 2017.
The cyanobacterial genus appears very conserved and has been divided into five main genetic clusters on the basis of molecular taxonomy markers. Genetic studies of seven strains, including genome sequencing, have enabled a better understanding of those photosynthetic prokaryotes. Even though genetic manipulations have not yet been performed with success, many genomic and proteomic features such as stress adaptation, nitrogen fixation, or biofuel production have been characterized. Many of above-mentioned studies aimed to optimize the cultivation conditions. Factors like the light intensity and quality, the nitrogen source, or different modes of growth (auto-, hetero-, or mixotrophic) have been studied in detail. The scaling-up of the biomass production using photobioreactors, either closed or open, was also investigated to increase the production of useful compounds. The richness of nutrients contained in the genus can be used for promising applications in the biomedical domain. Ingredients such as the calcium spirulan, immulina, C-phycocyanin, and γ-linolenic acid (GLA) show a strong biological activity. Recently, its use in the fight against cancer cells was documented in many publications. The health-promoting action of "Spirulina" has been demonstrated in the case of cardiovascular diseases and age-related conditions. Some compounds also have potent immunomodulatory properties, promoting the growth of beneficial gut microflora, acting as antimicrobial and antiviral. Products derived from were shown to successfully replace biomaterial scaffolds in regenerative medicine. Supplementation with the cyanobacterium also improves the health of livestock and quality of the products of animal origin. They were also used in cosmetic preparations.
蓝藻菌属看起来非常保守,并且基于分子分类学标记已被分为五个主要的基因簇。对七种蓝藻菌株的遗传学研究,包括基因组测序,使得人们对这些光合原核生物有了更好的理解。尽管尚未成功进行基因操作,但许多基因组和蛋白质组特征,如应激适应、固氮或生物燃料生产,已得到表征。上述许多研究旨在优化培养条件。光照强度和质量、氮源或不同生长模式(自养、异养或混合营养)等因素已被详细研究。还研究了使用封闭式或开放式光生物反应器扩大生物质产量,以增加有用化合物的产量。蓝藻菌属所含营养物质的丰富性可用于生物医学领域的有前景的应用。诸如钙螺旋藻多糖、免疫蛋白、C-藻蓝蛋白和γ-亚麻酸(GLA)等成分具有很强的生物活性。最近,许多出版物都记载了其在对抗癌细胞方面有应用。“螺旋藻”对心血管疾病和与年龄相关病症的健康促进作用已得到证实。一些化合物还具有强大的免疫调节特性,促进有益肠道微生物群的生长,具有抗菌和抗病毒作用。源自蓝藻菌属的产品已被证明能成功替代再生医学中的生物材料支架。补充蓝藻菌也能改善牲畜健康和动物源性产品的质量。它们还被用于化妆品制剂中。
