V P Bulgakov 1,2 , Y V Vereshchagina 1 , G N Veremeichik 1 Show Affiliations »
Abstract
BACKGROUND: For many years, anticancer polyphenols have attracted significant attention as substances that prevent tumor growth and progression. These compounds are simple phenolic acids, complex phenolic acids, such as caffeoylquinic acids, rosmarinic acid and its derivatives, stilbenes, flavones, isoflavones, and anthocyanins. Some compounds, such as tea and coffee polyphenols, can be produced in large quantities by traditional methods, while many others cannot. METHODS: We reviewed the available literature regarding the biotechnological aspects of polyphenol production by cultured plant cells and described approaches that have been used to obtain high levels of anticancer polyphenols (resveratrol, podophyllotoxin, genistein, lithospermic acid B, and others). Additionally, we provide our view on bioengineering strategies that could be important for the further improvement of cell biosynthetic characteristics. RESULTS: The main trend in the field is the activation of entire biosynthetic pathways based on a comprehensive knowledge of protein-protein interaction networks involved in the regulation of polyphenol biosynthesis. As an example, we consider the jasmonate subnetwork, which will be increasingly used by plant biotechnologists. The next-generation technologies to sustained polyphenol production involve manipulations with microRNAs and reproduction of rol-gene effects. CONCLUSION: Plant polyphenols play an important role in maintaining human health, and their role in the prevention of cancer will continue to grow. Targeting mechanisms involved in uncontrolled cancer cell proliferation will increasingly become the standard for cancer patients. Plant biotechnological studies aiming at producing anticancer compounds will be developed in parallel with these studies to provide a wider range of metabolites for each particular case. Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.org.
BACKGROUND: For many years, anticancer polyphenols have attracted significant attention as substances that prevent tumor growth and progression. These compounds are simple phenolic acids , complex phenolic acids , such as caffeoylquinic acids , rosmarinic acid and its derivatives, stilbenes , flavones , isoflavones , and anthocyanins . Some compounds, such as tea and coffee polyphenols , can be produced in large quantities by traditional methods, while many others cannot. METHODS: We reviewed the available literature regarding the biotechnological aspects of polyphenol production by cultured plant cells and described approaches that have been used to obtain high levels of anticancer polyphenols (resveratrol , podophyllotoxin , genistein , lithospermic acid B , and others). Additionally, we provide our view on bioengineering strategies that could be important for the further improvement of cell biosynthetic characteristics. RESULTS: The main trend in the field is the activation of entire biosynthetic pathways based on a comprehensive knowledge of protein-protein interaction networks involved in the regulation of polyphenol biosynthesis. As an example, we consider the jasmonate subnetwork, which will be increasingly used by plant biotechnologists. The next-generation technologies to sustained polyphenol production involve manipulations with microRNAs and reproduction of rol-gene effects. CONCLUSION: Plant polyphenols play an important role in maintaining human health, and their role in the prevention of cancer will continue to grow. Targeting mechanisms involved in uncontrolled cancer cell proliferation will increasingly become the standard for cancer patients . Plant biotechnological studies aiming at producing anticancer compounds will be developed in parallel with these studies to provide a wider range of metabolites for each particular case. Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.org.
Entities: Chemical
Disease
Species
Keywords:
Anticancer polyphenols; bioengineering strategies; biosynthesis; biotechnology; plant cell culture; secondaryzzm321990metabolism; systems biology.
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Year: 2018
PMID: 28595545 DOI: 10.2174/0929867324666170609080357
Source DB: PubMed Journal: Curr Med Chem ISSN: 0929-8673 Impact factor: 4.530