Secondary metabolism in simulated microgravity

Demain, Arnold L.; Fang, Aiqi

doi:10.1002/tcr.1018

Cited by 54 publications

(47 citation statements)

References 65 publications

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“…Microbes sense their environment through a variety of sensors and receptors which serve to integrate the different signals into the appropriate cellular response(s) that is optimal for survival. While numerous environmental stimuli have been examined for their effect on microorganisms, effects due to changes in mechanical and/or physical forces are also becoming increasingly apparent (6,21,50,82,97). Recently, several important studies have demonstrated a key role for microgravity and the low fluid shear dynamics associated with microgravity in the regulation of microbial gene expression, physiology, and pathogenesis (22,54,60,78,82).…”

Section: Introductionmentioning

confidence: 99%

Microbial Responses to Microgravity and Other Low-Shear Environments

Nickerson

Ott

Wilson

et al. 2004

Microbiol Mol Biol Rev

328

348

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Microbial adaptation to environmental stimuli is essential for survival. While several of these stimuli have been studied in detail, recent studies have demonstrated an important role for a novel environmental parameter in which microgravity and the low fluid shear dynamics associated with microgravity globally regulate microbial gene expression, physiology, and pathogenesis. In addition to analyzing fundamental questions about microbial responses to spaceflight, these studies have demonstrated important applications for microbial responses to a ground-based, low-shear stress environment similar to that encountered during spaceflight. Moreover, the low-shear growth environment sensed by microbes during microgravity of spaceflight and during ground-based microgravity analogue culture is relevant to those encountered during their natural life cycles on Earth. While no mechanism has been clearly defined to explain how the mechanical force of fluid shear transmits intracellular signals to microbial cells at the molecular level, the fact that cross talk exists between microbial signal transduction systems holds intriguing possibilities that future studies might reveal common mechanotransduction themes between these systems and those used to sense and respond to low-shear stress and changes in gravitation forces. The study of microbial mechanotransduction may identify common conserved mechanisms used by cells to perceive changes in mechanical and/or physical forces, and it has the potential to provide valuable insight for understanding mechanosensing mechanisms in higher organisms. This review summarizes recent and future research trends aimed at understanding the dynamic effects of changes in the mechanical forces that occur in microgravity and other low-shear environments on a wide variety of important microbial parameters

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Section: Introductionmentioning

confidence: 99%

Microbial Responses to Microgravity and Other Low-Shear Environments

Nickerson

Ott

Wilson

et al. 2004

Microbiol Mol Biol Rev

328

348

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“…On hypergravity up to ~20×g these Eukaryotes only significantly decrease proliferation rate and population density accordingly data by Kato, Mogami and Baba [24]. On the contrary, growth of Unicellular Prokaryotes and Eukaryotes on microgravity enhance their growth, gene expression, virulence and secondary metabolism accordingly data by Demain and Fang [25], Nickerson et al [26], Purevdorj-Gage et al [27], and Horneck, Klaus and Mancinelli [28].…”

Section: Resultsmentioning

confidence: 89%

Scaling of Total Metabolic, Gravitational and Heat Energy of Living Organisms, Earth and Sun

Atanasov¹

2015

EJB

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Abstract:The gravitational energy, total metabolic energy and heat energy of living organisms, Earth and Sun are scaled.Statistical analyses have shown that nearly a linear relationship between the total metabolic energy per lifespan of Poikilothermic organisms (P ls , kJ), total heat energy (THE E , kJ) of the Earth and the body mass (M, kg) of Poikilotherms and Earth (M E , kg) in log-log plots holds: P ls = 1.696×10 5 M 0.949 with R 2 = 0.996. A similar relationship between the total metabolic energy of Homoitherms Mammals and Aves (P ls , kJ), the total heat energy of Sun (emitted over Earth surface per Earth's lifespan) (THE S , kJ), and body mass (M, kg) of Mammals, Aves and Earth (M E , kg) holds: P ls = 10.2×10 5 M 1.023 with R 2 = 0.996. The metabolic potential of living organisms, gravitational and heat potential of Earth and Sun are scaled too. The gravitational and 'heat' potential of Earth are emerging as a lower limit of lifespan metabolic potentials of unicellular organisms, while the gravitational and 'heat' potential of Sun are emerging as an upper limit of lifespan metabolic potentials of multicellular organisms (Poikilotherms, Mammals and Aves). The relationships between mass-energy characteristics of living organisms, Earth and Sun show that gravitational and heat energy of Earth and Sun determine maximum and minimum total metabolic energy (per lifespan) of living organisms, while the gravitational and 'heat' potentials of Earth and Sun determine their maximum and minimum lifespan metabolic potentials.

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“…An attempt to reduce the pellet formation by adding Teflon beads to the rotatingwall bioreactor proved to be unsuccessful as regards increasing the rapamycin production. 56,57 A number of regulatory protein families, as well as physical and chemical factors including nutritional sources and microgravity, can affect a broad range of physiological processes involved in secondary metabolite production. Therefore, targeted genetic engineering of the regulatory system can be an alternative approach to improve the productivity of useful natural products.…”

Section: Biological Activities Of Rapamycin and Its Analogsmentioning

confidence: 99%

Biosynthesis of rapamycin and its regulation: past achievements and recent progress

et al. 2010

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Rapamycin and its analogs are clinically important macrolide compounds produced by Streptomyces hygroscopicus. They exhibit antifungal, immunosuppressive, antitumor, neuroprotective and antiaging activities. The core macrolactone ring of rapamycin is biosynthesized by hybrid type I modular polyketide synthase (PKS)/nonribosomal peptide synthetase systems primed with 4,5-dihydrocyclohex-1-ene-carboxylic acid. The linear polyketide chain is condensed with pipecolate by peptide synthetase, followed by cyclization to form the macrolide ring and modified by a series of post-PKS tailoring steps. The aim of this review was to outline past and recent advances in the biosynthesis and regulation of rapamycin, with an emphasis on the distinguished contributions of Professor Demain to the study of rapamycin. In addition, this article describes the biological activities as well as mechanism of action of rapamycin and its derivatives. Recent attempts to improve the productivity of rapamycin and generate diverse rapamycin analogs through mutasynthesis and mutagenesis are also introduced, along with some future perspectives.

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Secondary metabolism in simulated microgravity

Cited by 54 publications

References 65 publications

Microbial Responses to Microgravity and Other Low-Shear Environments

Microbial Responses to Microgravity and Other Low-Shear Environments

Scaling of Total Metabolic, Gravitational and Heat Energy of Living Organisms, Earth and Sun

Biosynthesis of rapamycin and its regulation: past achievements and recent progress

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