Amycolatopsis mediterranei: A Sixty-Year Journey from Strain Isolation to Unlocking Its Potential of Rifamycin Analogue Production by Combinatorial Biosynthesis

Utkarsh Sood; Moritz Müller; Tian Lan; Gauri Garg; Nirjara Singhvi; Princy Hira; Priya Singh; Aeshna Nigam; Mansi Verma; Pushp Lata; Hardeep Kaur; Abhilash Kumar; Charu Dogra Rawat; Sukanya Lal; Courtney Aldrich; Andreas Bechthold; Rup Lal

doi:10.1021/acs.jnatprod.3c00686

Amycolatopsis mediterranei: A Sixty-Year Journey from Strain Isolation to Unlocking Its Potential of Rifamycin Analogue Production by Combinatorial Biosynthesis

Utkarsh Sood, Moritz Müller, Tian Lan, Gauri Garg, Nirjara Singhvi, Princy Hira, Priya Singh, Aeshna Nigam, Mansi Verma, Pushp Lata, Hardeep Kaur, Abhilash Kumar, Charu Dogra Rawat, Sukanya Lal, Courtney Aldrich, Andreas Bechthold, Rup Lal

Medicinal Chemistry

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Ever since the isolation of Amycolatopsis mediterranei in 1957, this strain has been the focus of research worldwide. In the last 60 years or more, our understanding of the taxonomy, development of cloning vectors and conjugation system, physiology, genetics, genomics, and biosynthetic pathway of rifamycin B production in A. mediterranei has substantially increased. In particular, the development of cloning vectors, transformation system, characterization of the rifamycin biosynthetic gene cluster, and the regulation of rifamycin B production by the pioneering work of Heinz Floss have made the rifamycin polyketide biosynthetic gene cluster (PKS) an attractive target for extensive genetic manipulations to produce rifamycin B analogues which could be effective against multi-drug-resistant tuberculosis. Additionally, a better understanding of the regulation of rifamycin B production and the application of newer genomics tools, including CRISPR-assisted genome editing systems, might prove useful to overcome the limitations associated with low production of rifamycin analogues.

Original language	English (US)
Pages (from-to)	424-438
Number of pages	15
Journal	Journal of Natural Products
Volume	87
Issue number	2
DOIs	https://doi.org/10.1021/acs.jnatprod.3c00686
State	Published - Feb 23 2024

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Publisher Copyright:
© 2024 American Chemical Society and American Society of Pharmacognosy.

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Sood, U., Müller, M., Lan, T., Garg, G., Singhvi, N., Hira, P., Singh, P., Nigam, A., Verma, M., Lata, P., Kaur, H., Kumar, A., Rawat, C. D., Lal, S., Aldrich, C., Bechthold, A., & Lal, R. (2024). Amycolatopsis mediterranei: A Sixty-Year Journey from Strain Isolation to Unlocking Its Potential of Rifamycin Analogue Production by Combinatorial Biosynthesis. Journal of Natural Products, 87(2), 424-438. https://doi.org/10.1021/acs.jnatprod.3c00686

Sood, U, Müller, M, Lan, T, Garg, G, Singhvi, N, Hira, P, Singh, P, Nigam, A, Verma, M, Lata, P, Kaur, H, Kumar, A, Rawat, CD, Lal, S, Aldrich, C, Bechthold, A & Lal, R 2024, 'Amycolatopsis mediterranei: A Sixty-Year Journey from Strain Isolation to Unlocking Its Potential of Rifamycin Analogue Production by Combinatorial Biosynthesis', Journal of Natural Products, vol. 87, no. 2, pp. 424-438. https://doi.org/10.1021/acs.jnatprod.3c00686

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abstract = "Ever since the isolation of Amycolatopsis mediterranei in 1957, this strain has been the focus of research worldwide. In the last 60 years or more, our understanding of the taxonomy, development of cloning vectors and conjugation system, physiology, genetics, genomics, and biosynthetic pathway of rifamycin B production in A. mediterranei has substantially increased. In particular, the development of cloning vectors, transformation system, characterization of the rifamycin biosynthetic gene cluster, and the regulation of rifamycin B production by the pioneering work of Heinz Floss have made the rifamycin polyketide biosynthetic gene cluster (PKS) an attractive target for extensive genetic manipulations to produce rifamycin B analogues which could be effective against multi-drug-resistant tuberculosis. Additionally, a better understanding of the regulation of rifamycin B production and the application of newer genomics tools, including CRISPR-assisted genome editing systems, might prove useful to overcome the limitations associated with low production of rifamycin analogues.",

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Amycolatopsis mediterranei: A Sixty-Year Journey from Strain Isolation to Unlocking Its Potential of Rifamycin Analogue Production by Combinatorial Biosynthesis

Abstract

Bibliographical note

PubMed: MeSH publication types

UN SDGs

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