2022
DOI: 10.1007/s42995-022-00140-3
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Solutions: how adaptive changes in cellular fluids enable marine life to cope with abiotic stressors

Abstract: The seas confront organisms with a suite of abiotic stressors that pose challenges for physiological activity. Variations in temperature, hydrostatic pressure, and salinity have potential to disrupt structures, and functions of all molecular systems on which life depends. During evolution, sequences of nucleic acids and proteins are adaptively modified to “fit” these macromolecules for function under the particular abiotic conditions of the habitat. Complementing these macromolecular adaptations are alteration… Show more

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Cited by 20 publications
(34 citation statements)
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“…However, not only mutations of the amino acid sequence of proteins but also the composition of the cytoplasm of the extremophile in the context of its geological environment has a significant impact on protein stability and function. The cellular milieu is fairly crowded and contains a rather complex aqueous solution with a variety of different cosolutes (organic osmolytes). Organisms living under extreme conditions are able to accumulate certain cosolvents such as sorbitol or TMAO in their cells to protect their proteins from unfolding and denaturation. Interestingly, TMAO, one of the most potent cosolvents discovered to date, was found to be upregulated in deep sea organisms up to high levels and acts as a chemical chaperone to counteract the deteriorating effect of pressure (hence also denoted “piezolyte”) not only on proteins but also on noncanonical DNA and RNA structures. ,,,, Genome sequencing of a snailfish from the Yap Trench (at ∼7000 m depth) revealed the presence of five copies of a gene encoding a flavin-containing monooxygenase that catalyzes the reaction of trimethylamine (TMA) to TMAO, with TMA supplied by gut bacteria .…”
Section: Resultsmentioning
confidence: 99%
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“…However, not only mutations of the amino acid sequence of proteins but also the composition of the cytoplasm of the extremophile in the context of its geological environment has a significant impact on protein stability and function. The cellular milieu is fairly crowded and contains a rather complex aqueous solution with a variety of different cosolutes (organic osmolytes). Organisms living under extreme conditions are able to accumulate certain cosolvents such as sorbitol or TMAO in their cells to protect their proteins from unfolding and denaturation. Interestingly, TMAO, one of the most potent cosolvents discovered to date, was found to be upregulated in deep sea organisms up to high levels and acts as a chemical chaperone to counteract the deteriorating effect of pressure (hence also denoted “piezolyte”) not only on proteins but also on noncanonical DNA and RNA structures. ,,,, Genome sequencing of a snailfish from the Yap Trench (at ∼7000 m depth) revealed the presence of five copies of a gene encoding a flavin-containing monooxygenase that catalyzes the reaction of trimethylamine (TMA) to TMAO, with TMA supplied by gut bacteria .…”
Section: Resultsmentioning
confidence: 99%
“…Also, macromolecular crowding can help stabilize biomolecular systems such as proteins against unfolding. 12,40,121,125 Temperature-and pressure-induced unfolding of SNase is shifted to higher temperatures and drastically to higher pressures in 30 wt % polysaccharide solution, mimicking intracellular crowding conditions. 125 An ∼1.5 kbar increase of pressure stability at ambient temperature has also been observed for the protein RNase A upon addition of 30 wt % dextran crowder.…”
Section: Cosolvent Effectsmentioning
confidence: 99%
“…Organisms living under extreme conditions accumulate protein-stabilizing organic cosolvents (also referred to as compatible cosolutes or osmolytes) in their cells, such as glycerol, sorbitol, glycine betaine, or the deep-sea osmolyte trimethylamine-N-oxide (TMAO). [19][20][21]43,53,54 In addition to genetically based adaptations of the structural stability of proteins via mutations of amino-acids (denoted as intrinsic adaptations), extrinsic adaptations using such particular cosolvents are required to achieve the required adaptive changes in the stability and hence function of the proteins. [19][20][21]43,53,54 Remarkably, a given organic osmolyte often shows similar effects on proteins, nucleic acids, and membranes, suggesting common stabilization effects.…”
Section: Volume-sensitive Conformational Changes Phase Transitions An...mentioning
confidence: 99%
“…In addition to this physicochemical interest in the pressure variable, pressure is also a well-known parameter in the biological and biotechnological context. , Although high hydrostatic pressure (HHP) of several hundred to thousand bar (1 bar = 0.1 MPa ≈ 1 atm) significantly affects the structural and dynamical properties and thus the function of cellular components, this has not banned life from occupying high-pressure habitats in the ocean depths and subseafloor crust. Life itself may even have been created under pressure, such as in black smoker environments in the deep sea.…”
mentioning
confidence: 99%
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