Contribution of mechanosensitive channels to osmoadaptation and ectoine excretion in Halomonas elongata

Vandrich, Jasmina; Pfeiffer, Friedhelm; Alfaro-Espinoza, Gabriela; Kunte, Hans-Jörg

doi:10.1007/s00792-020-01168-y

Cited by 21 publications

(14 citation statements)

References 82 publications

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“…By adopting the “bacterial milking” process, a final ectoine titer of 7.4 g/L was achieved after repeatedly performing this process at least nine times, with a productivity of 0.22 g/L/h. Mechanosensitive channels (MSC), which are responsible for the excretion of compatible solutes in many halophilic microorganisms when suffering hypoosmotic shock, only make a small contribution to the ectoine excretion in H. elongata [ 37 , 38 ]. Therefore, H. elongata should have an efflux system either as a universal compatible solute transporter or as a specific ectoine exporter [ 38 ].…”

Section: Microbial Production Of Ectoine/hydroxyectoine In Halophilicmentioning

confidence: 99%

Microbial production of ectoine and hydroxyectoine as high-value chemicals

Liu

Shi

et al. 2021

Microb Cell Fact

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Ectoine and hydroxyectoine as typical representatives of compatible solutes are not only essential for extremophiles to survive in extreme environments, but also widely used in cosmetic and medical industries. Ectoine was traditionally produced by Halomonas elongata through a “bacterial milking” process, of which the marked feature is using a high-salt medium to stimulate ectoine biosynthesis and then excreting ectoine into a low-salt medium by osmotic shock. The optimal hydroxyectoine production was achieved by optimizing the fermentation process of Halomonas salina. However, high-salinity broth exacerbates the corrosion to fermenters, and more importantly, brings a big challenge to the subsequent wastewater treatment. Therefore, increasing attention has been paid to reducing the salinity of the fermentation broth but without a sacrifice of ectoine/hydroxyectoine production. With the fast development of functional genomics and synthetic biology, quite a lot of progress on the bioproduction of ectoine/hydroxyectoine has been achieved in recent years. The importation and expression of an ectoine producing pathway in a non-halophilic chassis has so far achieved the highest titer of ectoine (~ 65 g/L), while rational flux-tuning of halophilic chassis represents a promising strategy for the next-generation of ectoine industrial production. However, efficient conversion of ectoine to hydroxyectoine, which could benefit from a clearer understanding of the ectoine hydroxylase, is still a challenge to date.

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Section: Microbial Production Of Ectoine/hydroxyectoine In Halophilicmentioning

confidence: 99%

Microbial production of ectoine and hydroxyectoine as high-value chemicals

Liu

Shi

et al. 2021

Microb Cell Fact

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“…Compatible solutes are released into the environment through the transient opening of mechanosensitive channels when producer cells are subjected to a rapid osmotic down-shift (Booth 2014). Microorganisms also excrete compatible solutes under steady-state high osmolarity growth conditions, perhaps in an effort to finetune turgor (Czech et al 2016(Czech et al , 2018bGrammann et al 2002;Hoffmann et al 2012;Lamark et al 1992;Vandrich et al 2020). An ecophysiologically important process for the release of compatible solutes into the environment is also cell lysis; e.g., after the attack of ectoine producers by lytic phages (Van Goethem et al 2019).…”

Section: Catabolism Of Ectoine and 5-hydroxyectoine Ecophysiological mentioning

confidence: 99%

“…EhuB and UehA, the periplasmic high-affinity substrate-binding proteins have been crystalized in the presence of ectoines, thereby revealing the molecular determinants for the efficient capturing of environmental ectoines by transporters (Hanekop et al 2007;Lecher et al 2009) (Supplementary Figure S6). The osmotically inducible TeaABC transporter form H. elongata, a system closely related to the TRAP-T UehABC system from Ruegeria pomeroyi, not only serves for the import of ectoines as osmostress protectants and as a recycling systems for newly synthesized and excreted ectoines (Grammann et al 2002;Kuhlmann et al 2008b;Vandrich et al 2020) but it might also be used for their acquisition as nutrients (Schwibbert et al 2011).…”

Section: Catabolism Of Ectoine and 5-hydroxyectoine Ecophysiological mentioning

confidence: 99%

“…Shown are the systems that mediate cellular import of K + under acute osmotic stress as an immediate adjustment response and those that allow it extrusion once the cell begins with the import and/or synthesis of compatible solutes (e.g., ectoine and its derivative 5-hydroxyectoine) (Bremer and Krämer 2019;Wood 2011). Cells also seem to possess efflux systems for compatible solutes, probably a measure to fine-tune turgor when the cell elongates and doubles its volume prior to division (Czech et al 2016;Vandrich et al 2020). Cells maintain very low intracellular Na + concentration through dedicated export systems as this ion, in contrast to K + , is cytotoxic (Danchin and Nikel 2019).…”

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confidence: 99%

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The ups and downs of ectoine: structural enzymology of a major microbial stress protectant and versatile nutrient

Hermann

Mais

Czech

et al. 2020

Biological Chemistry

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Ectoine and its derivative 5-hydroxyectoine are compatible solutes and chemical chaperones widely synthesized by Bacteria and some Archaea as cytoprotectants during osmotic stress and high- or low-growth temperature extremes. The function-preserving attributes of ectoines led to numerous biotechnological and biomedical applications and fostered the development of an industrial scale production process. Synthesis of ectoines requires the expenditure of considerable energetic and biosynthetic resources. Hence, microorganisms have developed ways to exploit ectoines as nutrients when they are no longer needed as stress protectants. Here, we summarize our current knowledge on the phylogenomic distribution of ectoine producing and consuming microorganisms. We emphasize the structural enzymology of the pathways underlying ectoine biosynthesis and consumption, an understanding that has been achieved only recently. The synthesis and degradation pathways critically differ in the isomeric form of the key metabolite N-acetyldiaminobutyric acid (ADABA). γ-ADABA serves as preferred substrate for the ectoine synthase, while the α-ADABA isomer is produced by the ectoine hydrolase as an intermediate in catabolism. It can serve as internal inducer for the genetic control of ectoine catabolic genes via the GabR/MocR-type regulator EnuR. Our review highlights the importance of structural enzymology to inspire the mechanistic understanding of metabolic networks at the biological scale.

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“…For example, the halophilic bacterium Spiribacter salinus M19-40 produces enhanced levels of compatible solutes such as ectoine and trehalose when they are exposed to a high NaCl concentration [ 45 ]. These organic solutes have a critical role in reducing the thermodynamic activity of water to compensate for the external osmotic pressure [ 47 ].…”

Section: Survival Strategies Of Extremophilic Microorganisms Undermentioning

confidence: 99%

Extremophilic Microorganisms for the Treatment of Toxic Pollutants in the Environment

Jeong

Choi

2020

Molecules

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As concerns about the substantial effect of various hazardous toxic pollutants on the environment and public health are increasing, the development of effective and sustainable treatment methods is urgently needed. In particular, the remediation of toxic components such as radioactive waste, toxic heavy metals, and other harmful substances under extreme conditions is quite difficult due to their restricted accessibility. Thus, novel treatment methods for the removal of toxic pollutants using extremophilic microorganisms that can thrive under extreme conditions have been investigated during the past several decades. In this review, recent trends in bioremediation using extremophilic microorganisms and related approaches to develop them are reviewed, with relevant examples and perspectives.

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Contribution of mechanosensitive channels to osmoadaptation and ectoine excretion in Halomonas elongata

Cited by 21 publications

References 82 publications

Microbial production of ectoine and hydroxyectoine as high-value chemicals

Microbial production of ectoine and hydroxyectoine as high-value chemicals

The ups and downs of ectoine: structural enzymology of a major microbial stress protectant and versatile nutrient

Extremophilic Microorganisms for the Treatment of Toxic Pollutants in the Environment

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