An electrostatic basis for the stability of thermophilic proteins

Dominy, Brian N.; Minoux, Hervé; Brooks, Charles L.

doi:10.1002/prot.20190

Cited by 137 publications

(139 citation statements)

References 74 publications

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“…Here, all stabilizing structural factors act in concert, pointing to enhanced compactness as the most probable original cause for higher stability. In the second case, on the contrary, we found a strong sequence bias that can explain dominating role of some of the stabilizing interactions, e.g., electrostatics (19,20), but not of others. The high level of sequence variation compared with mesophilic orthologs and the significant bias toward charged residues in their sequences point to a key role of sequence selection in adaptation of T. maritima proteins (1TMY and 1VJW) to extreme conditions of the environment, in contrast to other (hyper)thermophilic proteins (1CAA, 1IQZ, 2CJN, and 2PRD) where structural bias is more pronounced.…”

Section: Resultsmentioning

confidence: 56%

“…3 and Table 5), in turn, uncovers another possible mechanism of thermostability in T. maritima's proteins. The stability of these proteins under extremely high temperatures is apparently provided by significant modifications of their sequences toward enrichment by charged residues (19,20), which can be an effective sequence-based method of adaptation to extreme specific conditions. van der Waals interactions (29), number of H-bonds (12,30), and number of residues involved into elements of secondary structure in groups of proteins under consideration.…”

Section: Resultsmentioning

confidence: 99%

“…The increase of the number of charged residues in hyperthermophilic proteomes appears to be much greater than would have been necessary for stability purposes alone. Indeed, enhanced stability can be achieved by the addition of only a few ion pairs (4,19,20). This points to the possibility of alternative reasons (unrelated to protein stabilization) for this specific compositional bias toward charged residues, which should be thoroughly explored.…”

Section: Discussionmentioning

confidence: 99%

“…1a) and structural analysis (Table 1), it points to compactness as a key factor in the structure-based strategy of thermophilic adaptation in archaea. At the same time, lower packing density in proteins from A. aeolicus and T. maritima and a higher (compared with mesophilic E. coli, as well as with hyperthermophilic P. furiosus) content of charged residues suggest that these organisms follow mostly sequence-based stabilization, possibly, with a key role of ionic interactions (19,20).…”

Section: From Physical Mechanism Of Thermal Stabilization To Strategimentioning

confidence: 99%

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Physics and evolution of thermophilic adaptation

Berezovsky

Shakhnovich

2005

Proc. Natl. Acad. Sci. U.S.A.

245

213

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Analysis of structures and sequences of several hyperthermostable proteins from various sources reveals two major physical mechanisms of their thermostabilization. The first mechanism is ''structure-based,'' whereby some hyperthermostable proteins are significantly more compact than their mesophilic homologues, while no particular interaction type appears to cause stabilization; rather, a sheer number of interactions is responsible for thermostability. Other hyperthermostable proteins employ an alternative, ''sequence-based'' mechanism of their thermal stabilization. They do not show pronounced structural differences from mesophilic homologues. Rather, a small number of apparently strong interactions is responsible for high thermal stability of these proteins. High-throughput comparative analysis of structures and complete genomes of several hyperthermophilic archaea and bacteria revealed that organisms develop diverse strategies of thermophilic adaptation by using, to a varying degree, two fundamental physical mechanisms of thermostability. The choice of a particular strategy depends on the evolutionary history of an organism. Proteins from organisms that originated in an extreme environment, such as hyperthermophilic archaea (Pyrococcus furiosus), are significantly more compact and more hydrophobic than their mesophilic counterparts. Alternatively, organisms that evolved as mesophiles but later recolonized a hot environment (Thermotoga maritima) relied in their evolutionary strategy of thermophilic adaptation on ''sequence-based'' mechanism of thermostability. We propose an evolutionary explanation of these differences based on physical concepts of protein designability.thermostability ͉ structure͞sequence ͉ molecular evolution ͉ molecular packing ͉ genomes͞proteomes T he importance of various factors contributing to protein thermostability remains a subject of intense study (1). The most frequently reported trends include increased van der Waals interactions (2), higher core hydrophobicity (3), additional networks of hydrogen bonds (1), enhanced secondary structure propensity (4), ionic interactions (5), increased packing density (6), and decreased length of surface loops (7). It was shown recently that proteins use various combinations of these mechanisms. However, no general physical mechanism for increased thermostability was found. The diversity of the ''recipes'' for thermostability immediately raises two important questions: (i) What are possible physical mechanisms to increase thermostability of proteins, and (ii) how did evolution use possible physical mechanisms of thermal stabilization to develop strategies of adaptation to high temperature and other possible demands of the environment?In this work, we first analyze in great detail several proteins from various hyperthermophilic organisms and show that some of them draw their thermostability from structural factors such as increased compactness. Furthermore, direct analysis of interactions as well as sequence comparison with mesophilic orthologues i...

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Section: Resultsmentioning

confidence: 56%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: From Physical Mechanism Of Thermal Stabilization To Strategimentioning

confidence: 99%

See 2 more Smart Citations

Physics and evolution of thermophilic adaptation

Berezovsky

Shakhnovich

2005

Proc. Natl. Acad. Sci. U.S.A.

245

213

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“…Moreover, the stabilizing contribution of salt-bridges partially buried in the protein matrix depends on the local polarity 5,13,14 while the presence of internal water molecules could alleviate the associated desolvation penalty 15,16 . In this regard, it was proposed that (hyper)thermophiles could benefit from dense ion-pairing because of a higher internal dielectric constant 17 . Finally, the presence of water molecules inside internal cavities or superficial pockets also improves the molecular packing and extends the HB connectivity with potential effects on local kinetic stability 18 .…”

Section: Introductionmentioning

confidence: 99%

Role of Internal Water on Protein Thermal Stability: The Case of Homologous G Domains

et al. 2014

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In this work we address the question whether the enhanced stability of thermophilic proteins has a direct connection with internal hydration. Our model systems are two homologues G-domains of different stability: the mesophilic G domain of the Elongation-Factor thermal unstable protein from E. coli and the hyperthermophilic G domain of the EF-α protein from S. solfataricus. Using molecular dynamics simulation at the microsecond time-scale we show that both proteins host water molecules in internal cavities and that these molecules exchange with the external solution in the nanosecond time scale. The hydration free energy of these sites evaluated via extensive calculations is found to be favourable for both systems, with the hyperthermophilic protein offering a slightly more favourable environment to host water molecules. We estimate that under ambient conditions, the free energy gain due to internal hydration is about 1.3 kcal/mol in favor of the hyperthermophilic variant. However, we also find that at the high working temperature of the hyperthermophile, the cavities are rather dehydrated, meaning that at extreme conditions other molecular factors secure the stability of the protein. Interestingly, we detect a clear correlation between the hydration of internal cavities and the protein conformational landscape. The emerging picture is that internal hydration is an effective observable to probe the conformational landscape of proteins. In the specific context of our investigation, the analysis confirms that the hyperthermophilic G-domain is characterized by multiple states and it has a more flexible structure than its mesophilic homologue.

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A polyextremophilic alcohol dehydrogenase from the Atlantis II Deep Red Sea brine pool

et al. 2018

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Enzymes originating from hostile environments offer exceptional stability under industrial conditions and are therefore highly in demand. Using single‐cell genome data, we identified the alcohol dehydrogenase (ADH) gene, adh/a1a, from the Atlantis II Deep Red Sea brine pool. ADH/A1a is highly active at elevated temperatures and high salt concentrations (optima at 70 °C and 4 mKCl) and withstands organic solvents. The polyextremophilic ADH/A1a exhibits a broad substrate scope including aliphatic and aromatic alcohols and is able to reduce cinnamyl‐methyl‐ketone and raspberry ketone in the reverse reaction, making it a possible candidate for the production of chiral compounds. Here, we report the affiliation of ADH/A1a to a rare enzyme family of microbial cinnamyl alcohol dehydrogenases and explain unique structural features for halo‐ and thermoadaptation.

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An electrostatic basis for the stability of thermophilic proteins

Cited by 137 publications

References 74 publications

Physics and evolution of thermophilic adaptation

Physics and evolution of thermophilic adaptation

Role of Internal Water on Protein Thermal Stability: The Case of Homologous G Domains

A polyextremophilic alcohol dehydrogenase from the Atlantis II Deep Red Sea brine pool

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