Strain Improvement of Streptomyces xanthochromogenes RIA 1098 for Enhanced Pravastatin Production at High Compactin Concentrations

Dzhavakhiya, V. V.; Voinova, T. M.; Глаголева, Е. В.; Petukhov, D. V.; Ovchinnikov, A. I.; Карташов, М. Ю.; Кузнецов, Б. Б.; Skryabin, K. G.

doi:10.1007/s12088-015-0537-5

Cited by 7 publications

(6 citation statements)

References 13 publications

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“…After optimizing the fermentation medium, the maximum bioconversion rate of this strain reached 91% at a daily compactin dose of 1 g L −1 , and remained high (83%) even at a doubled dose of 2 g L −1 (Figure 3G). [ 82 ]…”

Section: Genetic Strategies Improving Statins Productionmentioning

confidence: 99%

Improving statins production: From non‐genetic strategies to genetic strategies

Fan

Tang

Yang

et al. 2023

Biotechnology Journal

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Statins are lipid‐lowering drugs that selectively inhibit 3‐hydroxy‐3‐methylglutaryl coenzyme A (HMG‐CoA) reductase, effectively reducing cholesterol synthesis. With improved nutritional conditions, the demand for statins is increasing in the global market. The use of microbial cell factories for statin biosynthesis has become advantageous due to the rapid advancements in biotechnology. These approaches offer simple operation and easy separation of products. This review provides an overview the strategies for statins production via microbial cell factories, including both traditional fermentation culture (non‐genetic) and modern synthetic biology manufacture (genetic). Firstly, the complex fermentation parameters and process control technology on submerged fermentation (SmF) and solid‐state fermentation (SSF) are introduced in detail. The potential use of recoverable agricultural wastes/(biomass) as a fermentation substrate in SSF for statin production is emphasized. Additionally, metabolic engineering strategies for constructing robust engineering strains and directed evolution are also discussed. The review highlights the potential and challenges of using microbial cell factories for statin production, and aims to promote greener production modes for statins.This article is protected by copyright. All rights reserved

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Section: Genetic Strategies Improving Statins Productionmentioning

confidence: 99%

Improving statins production: From non‐genetic strategies to genetic strategies

Fan

Tang

Yang

et al. 2023

Biotechnology Journal

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“… Immobilization on silane modified iron (II, III) oxide magnetic nanoparticles (MNP) Cholesterol → 4-cholesten-3-one Oxidation → cholesterol oxidase Immobilized cholesterol oxidase activity was 2 times higher than its free form; it could be reused for up to 10 cycles Not reported Ghosh et al 2018 Streptomyces sp. Immobilization on silicon dioxide-coated magnetite biosensor Cholesterol → 4-cholesten-3-one Oxidation → cholesterol oxidase Immobilized enzyme was more than 2 times efficient than its free form; enzyme concentration was 20 mg·mL -1 , substrate concentration was 6.46 mM; it could be reused for up to 30 days 90.0% in 180 min Perdani et al 2020 Streptomyces strain(s) Mutated, genetically modified, or heterologous expressed enzymes bioconversion Substrate(s) → product(s) Reaction → enzyme(s) Bioconversion conditions Bioconversion rate/yield/productivity References Streptomyces xanthochromogenes RIA 1098 Multi-step random UV mutagenesis Compactin → pravastatin - Mutagenesis was performed in order to obtain mutants resistant for high compactin concentrations; 50 h of reaction time 91.0 % Dzhavakhiya et al 2015 Streptomyces coelicolor CR1 Structure-guided engineering and directed evolution Ethyl-4-chloro-3-oxobutyrate → ethyl-(S)-4-chloro-3-hydroxylbutyrate Reduction → carbonyl reductase Mutagenesis was performed to improve both thermal stability and catalytic activity; substrate concentration = 100 g·L -1 ; bioreactor = 300 mL; reaction time = 9 h 255 g· L −1 day -1 Li et al 2017 Streptomyces halstedii Heterologous expression in Pichia pastoris and displaying on its membrane surface Phosphatidylcholine + l -serine → phosphatidylserine Transphosphatidylation → phospholipase D Repeated batch conditions up to 4 cycles: 8 h reaction; 200 mL of 0.2 M sodium acetate buffer; 40 °C, pH 5,5; 3 U·mL -1 biocatalyst; 1:3 phosphatidylcholine: l -serine ratio 53.0% Liu et al 2019 Streptomyces sp. NRRL F-4489 Heterologous expression in E. coli BL21 (DE3) ...…”

Section: Biotechnological Biotransformation Processes For Drug Producmentioning

confidence: 99%

“…For example, multi-step random UV mutagenesis has been recently applied to Streptomyces xanthochromogenes strain RIA 1098 for the production of pravastatin, one of the most popular cholesterol-lowering drugs (Dzhavakhiya et al 2015 ). The traditional industrial two-stage process includes the microbial synthesis of compactin by Penicillium citrinum and then its further conversion to pravastatin by S. xanthochromogenes strain RIA 1098, which is capable of hydroxylating the compactin on the C6 position (Dzhavakhiya et al 2015 ). A high compactin content is required to increase the rate of conversion, but at the same time high compactin concentrations could inhibit microbial growth.…”

Section: Biotechnological Biotransformation Processes For Drug Producmentioning

confidence: 99%

“…Thus, improvement of the strain resistance to compactin is a desirable goal. In this recent study, S. xanthochromogenes mutants, obtained through UV irradiation, were tested for pravastatin bioconversion in the presence of a daily dose of 1.0 or 2.0 g· L −1 of compactin; with this strategy, 91.0% or 83.0% of bioconversion rates was reported, respectively, after medium optimization (Dzhavakhiya et al 2015 ). A different approach was applied for the synthesis of another cholesterol-lowering drug, the Lipitor, and in particular of its key intermediate ethyl-(S)-4-chloro-3-hydroxylbutyrate from ethyl-4-chloro-3-oxobutyrate using a recombinant carbonyl reductase from Streptomyces coelicolor CR1 (Li et al 2017 ).…”

Section: Biotechnological Biotransformation Processes For Drug Producmentioning

confidence: 99%

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Streptomycetes as platform for biotechnological production processes of drugs

Ferraiuolo

Cammarota

Schiraldi

et al. 2021

Appl Microbiol Biotechnol

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“…Statins are mainly derived from secondary metabolites of microbial fermentation and chemical synthesis. One study of various microorganisms revealed some fungi and bacteria that can convert compactin to pravastatin, in addition to strain improvement of Streptomyces xanthochromogenes RIA 1098 for enhanced pravastatin production ( 7 ). Pravastatin is mainly used to reduce cholesterol levels in patients, and it has been confirmed to promote angiogenesis and resistance to oxidative stress ( 8 , 9 ), but its role in intestinal I/R injury has not been elucidated.…”

Section: Introductionmentioning

confidence: 99%

Gut Microbial Metabolite Pravastatin Attenuates Intestinal Ischemia/Reperfusion Injury Through Promoting IL-13 Release From Type II Innate Lymphoid Cells via IL−33/ST2 Signaling

Deng

Yang

et al. 2021

Front. Immunol.

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Intestinal ischemia/reperfusion (I/R) injury is a grave condition with high morbidity and mortality. We previously confirmed that intestinal I/R induces intestinal flora disorders and changes in metabolites, but the role of different metabolites in intestinal I/R injury is currently unclear. Based on targeted metabolic sequencing, pravastatin (PA) was determined to be a metabolite of the gut microbiota. Further, intestinal I/R model mice were established through superior mesenteric artery obstruction. In addition, a co-culture model of small intestinal organoids and type II innate lymphoid cells (ILC2s) was subjected to hypoxia/reoxygenation (H/R) to simulate an intestinal I/R model. Moreover, correlation analysis between the PA level in preoperative feces of patients undergoing cardiopulmonary bypass and the indices of postoperative intestinal I/R injury was carried out. IL-33-deficient mice, ILC2-deleted mice, and anti-IL-13 neutralizing antibodies were also used to explore the potential mechanism through which PA attenuates intestinal I/R injury. We demonstrated that PA levels in the preoperative stool of patients undergoing cardiopulmonary bypass were negatively correlated with the indices of postoperative intestinal I/R injury. Furthermore, PA alleviated intestinal I/R injury and improved the survival of mice. We further showed that PA promotes IL-13 release from ILC2s by activating IL-33/ST2 signaling to attenuate intestinal I/R injury. In addition, IL-13 promoted the self-renewal of intestinal stem cells by activating Notch1 and Wnt signals. Overall, results indicated that the gut microbial metabolite PA can attenuate intestinal I/R injury by promoting the release of IL-13 from ILC2s via IL-33/ST2 signaling, revealing a novel mechanism of and therapeutic strategy for intestinal I/R injury.

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Strain Improvement of Streptomyces xanthochromogenes RIA 1098 for Enhanced Pravastatin Production at High Compactin Concentrations

Cited by 7 publications

References 13 publications

Improving statins production: From non‐genetic strategies to genetic strategies

Improving statins production: From non‐genetic strategies to genetic strategies

Streptomycetes as platform for biotechnological production processes of drugs

Gut Microbial Metabolite Pravastatin Attenuates Intestinal Ischemia/Reperfusion Injury Through Promoting IL-13 Release From Type II Innate Lymphoid Cells via IL−33/ST2 Signaling

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