Physics and evolution of thermophilic adaptation

Berezovsky, Igor N.; Shakhnovich, Eugene I.

doi:10.1073/pnas.0503890102

Cited by 240 publications

(229 citation statements)

References 30 publications

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“…Our result is in agreement with the previous findings to define the minimal pharmacophore in moenomycin, in which the EF-ring phosphoglycerate portion together with either the C or the D ring forms critical interactions with proteins (8). Although A. aeolicus (11), like E. coli, was classified as Gram-negative bacterium, the interaction pattern with moenomycin in AaPGT showed differences from our structure and SaPBP2 ( Fig. 2 B and C).…”

Section: Resultssupporting

confidence: 82%

Crystal structure of the membrane-bound bifunctional transglycosylase PBP1b from Escherichia coli

Sung

Lai²,

Huang³

et al. 2009

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

157

180

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Drug-resistant bacteria have caused serious medical problems in recent years, and the need for new antibacterial agents is undisputed. Transglycosylase, a multidomain membrane protein essential for cell wall synthesis, is an excellent target for the development of new antibiotics. Here, we determined the X-ray crystal structure of the bifunctional transglycosylase penicillin-binding protein 1b (PBP1b) from Escherichia coli in complex with its inhibitor moenomycin to 2.16-Å resolution. In addition to the transglycosylase and transpeptidase domains, our structure provides a complete visualization of this important antibacterial target, and reveals a domain for protein-protein interaction and a transmembrane helix domain essential for substrate binding, enzymatic activity, and membrane orientation.antibacterial development ͉ antibiotic resistance ͉ membrane protein structure ͉ peptidoglycan synthesis ͉ protein-protein interaction I n the last decade, the prevalence and occasional outbreaks of drug-resistant bacteria, such as methicillin-resistant Staphylococcus aureus (MRSA) and vancomycin-resistant enterococci (VRE), have posed appalling hurdles in the treatment of bacterial infections (1, 2). New antibacterial agents are, as a result, in desperate demand to combat these pernicious antibiotic-resistant problems that can otherwise cause life-or-death struggles.Bacteria cell wall is a mesh-like structure of cross-linked peptidoglycan, which is essential to scaffold the cytoplasmic membrane and to maintain structural integrity of the cell (3). Cell wall synthesis at the membrane surface is mainly carried out by the membrane-bound enzymes, transpeptidases and transglycosylases, and inhibitors of the transpeptidase are among the most popular antibiotics in clinical use today (3).Escherichia coli PBP1b is a bifunctional transglycosylase, also known as peptidoglycan glycosyltransferase or murein synthase. It contains a transmembrane (TM) helix, 2 enzymatic domains [transglycosylase (TG) and transpeptidase (TP)] (4), and a domain composed of Ϸ100 aa residues between TM and TG with unknown structure and functionality (Fig. 1B). For Ͼ50 years, TP has been the main target for 2 most important classes of antibiotics: ␤-lactams (e.g., penicillin and methicillin) and glycopeptides (e.g., vancomycin). Not too long after they were introduced, resistant bacteria had emerged rapidly and caused serious medical problems. In contrast, resistant strains against moenomycin, the only natural inhibitor to TG from Streptomyces, have rarely been found. The development of new antibiotics against TG has been highly anticipated (5), and not until recently have the molecular structures of TG been available, even with the TM structure undefined.Two crystal structures of transglycosylase, a bifunctional transglycosylase from S. aureus (referred to as SaPBP2) and a transglycosylase domain from Aquifex aeolicus (referred to as AaPGT), have been determined recently with their TM domain or TM and TP domains removed, respectively (6-8). These structur...

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Section: Resultssupporting

confidence: 82%

Crystal structure of the membrane-bound bifunctional transglycosylase PBP1b from Escherichia coli

Sung

Lai²,

Huang³

et al. 2009

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

157

180

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“…at the earliest (prebiotic) stages of evolution. It seems therefore likely that emergence of wonderfolds dominated the physical selection and design of first thermostable proteins in the course of prebiotic evolution (36).…”

Section: Resultsmentioning

confidence: 99%

Physical Origins of Protein Superfamilies

Zeldovich

Berezovsky

Shakhnovich

2006

Journal of Molecular Biology

Self Cite

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In this work, we discovered a fundamental connection between selection for protein stability and emergence of preferred structures of proteins. Using standard exact 3-dimensional lattice model we evolve sequences starting from random ones and determining exact native structure after each mutation. Acceptance of mutations is biased to select for stable proteins. We found that certain structures, "wonderfolds", are independently discovered numerous times as native states of stable proteins in many unrelated runs of selection. Diversity of sequences that fold into wonderfold structures gives rise to superfamilies, i.e. sets of dissimilar sequences that fold into the same or very similar structures. Wonderfolds appear to be the most designable structures out of complete set of compact lattice proteins. Furthermore, proteins having wondefolds as their native structure tend to be most thermostable among all evolved proteins. This effect is purely due to the favorable geometric properties of wonderfolds and, thus, dominates any dependence on sequences. The present work establishes a model of prebiotic structure selection, which identifies dominant structural patterns emerging upon optimization of proteins for survival in hot environment. Convergently discovered prebiotic initial superfamilies with ''wonderfold'' structures could have served as a seed for subsequent biological evolution involving gene duplications and divergence.3

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“…[8][9][10][11][12] Although most hydrogen-bonded sidechain interactions that have been experimentally measured in membrane proteins appear to make relatively modest contributions, [21][22][23][24][25][26][27] some have been measured as high as 1.8 kcal/mol and in theory it is possible that they could be made even stronger. 26,28 Thus, it seems reasonable to expect that the number of transmembrane interhelical hydrogen bonds might increase in thermophiles.…”

Section: Interhelical Hydrogen Bonding In Thermophiles and Mesophilesmentioning

confidence: 99%

“…As a result, the stabilizing mechanisms have been extensively explored for water-soluble proteins. The mechanisms observed include an increase in secondary structure propensity; 1,2 changes that decrease unfolded state entropy such as the introduction of Pro residues, reduction of Gly residues, 3 smaller loops, 4 and the addition of disulfide bonds; [5][6][7] an increase of hydrogen bonds and salt bridges; [8][9][10][11][12] and better optimized hydrophobicity. 13 Szilagyi and Zavodszky 3 made an extensive study of many protein families and found that few of these mechanisms were general, except an increase in salt bridges.…”

Section: Introductionmentioning

confidence: 99%

Structural differences between thermophilic and mesophilic membrane proteins

Meruelo¹,

Han

Kim

et al. 2012

Protein Science

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The evolutionary adaptations of thermophilic water-soluble proteins required for maintaining stability at high temperature have been extensively investigated. Little is known about the adaptations in membrane proteins, however. Here, we compare many properties of mesophilic and thermophilic membrane protein structures, including side-chain burial, packing, hydrogen bonding, transmembrane kinks, loop lengths, hydrophobicity, and other sequence features. Most of these properties are quite similar between mesophiles and thermophiles although we observe a slight increase in side-chain burial and possibly a slight decrease in the frequency of transmembrane kinks in thermophilic membrane protein structures. The most striking difference is the increased hydrophobicity of thermophilic transmembrane helices, possibly reflecting more stringent hydrophobicity requirements for membrane partitioning at high temperature. In agreement with prior work examining transmembrane sequences, we find that thermophiles have an increase in small residues (Gly, Ala, Ser, and Val) and a strong suppression of Cys. We also find a relative dearth of most strongly polar residues (Asp, Asn, Glu, Gln, and Arg). These results suggest that in thermophiles, there is significant evolutionary pressure to offload destabilizing polar amino acids, to decrease the entropy cost of side chain burial, and to eliminate thermally sensitive amino acids.

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Physics and evolution of thermophilic adaptation

Cited by 240 publications

References 30 publications

Crystal structure of the membrane-bound bifunctional transglycosylase PBP1b from Escherichia coli

Crystal structure of the membrane-bound bifunctional transglycosylase PBP1b from Escherichia coli

Physical Origins of Protein Superfamilies

Structural differences between thermophilic and mesophilic membrane proteins

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