63 research outputs found
Binding Leverage and Leverage Coupling as Determinants of Allosteric Regulation and Communication
A geometry-based generic predictor for catalytic and allosteric sites
An important aspect of understanding protein allostery, and of artificial effector design, is the characterization and prediction of substrate- and effector-binding sites. To find binding sites in allosteric enzymes, many of which are oligomeric with allosteric sites at domain interfaces, we devise a local centrality measure for residue interaction graphs, which behaves well for both small/monomeric and large/multimeric proteins. The measure is purely structure based and has a clear geometrical interpretation and no free parameters. It is not biased towards typically catalytic residues, a property that is crucial when looking for non-catalytic effector sites, which are potent drug targets.Norwegian Research Council/FUGE IIacceptedVersio
Coherent Conformational Degrees of Freedom as a Structural Basis for Allosteric Communication
Conformational changes in allosteric regulation can to a large extent be described as motion along one or a few coherent degrees of freedom. The states involved are inherent to the protein, in the sense that they are visited by the protein also in the absence of effector ligands. Previously, we developed the measure binding leverage to find sites where ligand binding can shift the conformational equilibrium of a protein. Binding leverage is calculated for a set of motion vectors representing independent conformational degrees of freedom. In this paper, to analyze allosteric communication between binding sites, we introduce the concept of leverage coupling, based on the assumption that only pairs of sites that couple to the same conformational degrees of freedom can be allosterically connected. We demonstrate how leverage coupling can be used to analyze allosteric communication in a range of enzymes (regulated by both ligand binding and post-translational modifications) and huge molecular machines such as chaperones. Leverage coupling can be calculated for any protein structure to analyze both biological and latent catalytic and regulatory sites
Flowering Buds of Globular Proteins: Transpiring Simplicity of Protein Organization
Structural and functional complexity of proteins is dramatically reduced to a simple linear picture when the laws of polymer physics are considered. A basic unit of the
protein structure is a nearly standard closed loop of 25–35 amino acid residues, and
every globular protein is built of consecutively connected closed loops. The physical
necessity of the closed loops had been apparently imposed on the early stages of
protein evolution. Indeed, the most frequent prototype sequence motifs in prokaryotic
proteins have the same sequence size, and their high match representatives are found
as closed loops in crystallized proteins. Thus, the linear organization of the closed
loop elements is a quintessence of protein evolution, structure and folding
Protein and DNA sequence determinants of thermophilic adaptation
Prokaryotes living at extreme environmental temperatures exhibit pronounced
signatures in the amino acid composition of their proteins and nucleotide
compositions of their genomes reflective of adaptation to their thermal
environments. However, despite significant efforts, the definitive answer of
what are the genomic and proteomic compositional determinants of Optimal Growth
Temperature of prokaryotic organisms remained elusive. Here the authors
performed a comprehensive analysis of amino acid and nucleotide compositional
signatures of thermophylic adaptation by exhaustively evaluating all
combinations of amino acids and nucleotides as possible determinants of Optimal
Growth Temperature for all prokaryotic organisms with fully sequences genomes..
The authors discovered that total concentration of seven amino acids in
proteomes, IVYWREL, serves as a universal proteomic predictor of Optimal Growth
Temperature in prokaryotes. Resolving the old-standing controversy the authors
determined that the variation in nucleotide composition (increase of purine
load, or A+G content with temperature) is largely a consequence of thermal
adaptation of proteins. However, the frequency with which A and G nucleotides
appear as nearest neighbors in genome sequences is strongly and independently
correlated with Optimal Growth Temperature. as a result of codon bias in
corresponding genomes. Together these results provide a complete picture of
proteomic and genomic determinants of thermophilic adaptation.Comment: in press PLoS Computational Biology; revised versio
Representation of amino acid sequences in terms of interaction energy in protein globules
AbstractWe suggest a new simple approach for comparing the primary structure of proteins and their spatial structure. It relies on the one-to-one correspondence between each residue of the polypeptide chain and the energy of van der Waals interactions between the regions of the native globule flanking this residue. The method obviates the sophisticated geometrical criteria for estimating similarity between spatial structures. Besides, it permits one to analyze structural units of different scale
Positive and Negative Design in Stability and Thermal Adaptation of Natural Proteins
The aim of this work is to elucidate how physical principles of protein design are reflected in natural sequences that evolved in response to the thermal conditions of the environment. Using an exactly solvable lattice model, we design sequences with selected thermal properties. Compositional analysis of designed model sequences and natural proteomes reveals a specific trend in amino acid compositions in response to the requirement of stability at elevated environmental temperature: the increase of fractions of hydrophobic and charged amino acid residues at the expense of polar ones. We show that this “from both ends of the hydrophobicity scale” trend is due to positive (to stabilize the native state) and negative (to destabilize misfolded states) components of protein design. Negative design strengthens specific repulsive non-native interactions that appear in misfolded structures. A pressure to preserve specific repulsive interactions in non-native conformations may result in correlated mutations between amino acids that are far apart in the native state but may be in contact in misfolded conformations. Such correlated mutations are indeed found in TIM barrel and other proteins
Entropic stabilization of proteins and its proteomic consequences
We report here a new entropic mechanism of protein thermostability due to
residual dynamics of rotamer isomerization in native state. All-atom
simulations show that Lysines have much greater number of accessible rotamers
than Arginines in folded states of proteins. This finding suggests that Lysines
would preferentially entropically stabilize the native state. Indeed we show in
computational experiments that Arginine-to-Lysine amino acid substitutions
result in noticeable stabilization of proteins. We then hypothesize that if
evolution uses this physical mechanisms in its strategies of thermophilic
adaptation then hyperthermostable organisms would have much greater content of
Lysines in their proteomes than of comparable in size and similarly charged
Arginines.. Consistent with that, high-throughput comparative analysis of
complete proteomes shows extremely strong bias towards Arginine-to-Lysine
replacement in hyperthermophilic organisms and overall much greater content of
Lysines than Arginines in hyperthermophiles. This finding cannot be explained
by GC compositional biases. Our study provides an example of how analysis of a
delicate physical mechanism of thermostability helps to resolve a puzzle in
comparative genomics as to why aminoacid compositions of hyperthermophilic
proteomes are significantly biased towards Lysines but not Arginine
Synergistic Allostery in Multiligand-Protein Interactions
Amide hydrogen-deuterium exchange mass spectrometry is powerful for describing combinatorial coupling effects of a cooperative ligand pair binding at noncontiguous sites: adenosine at the ATP-pocket and a docking peptide (PIFtide) at the PIF-pocket, on a model protein kinase PDK1. Binding of two ligands to PDK1 reveal multiple hotspots of synergistic allostery with cumulative effects greater than the sum of individual effects mediated by each ligand. We quantified this synergism and ranked these hotspots using a difference in deuteration-based approach, which showed that the strongest synergistic effects were observed at three of the critical catalytic loci of kinases: the αB-αC helices, and HRD-motif loop, and DFG-motif. Additionally, we observed weaker synergistic effects at a distal GHI-subdomain locus. Synergistic changes in deuterium exchange observed at a distal site but not at the intermediate sites of the large lobe of the kinase reveals allosteric propagation in proteins to operate through two modes. Direct electrostatic interactions between polar and charged amino acids that mediate targeted relay of allosteric signals, and diffused relay of allosteric signals through soft matter-like hydrophobic core amino acids. Furthermore, we provide evidence that the conserved β-3 strand lysine of protein kinases (Lys111 of PDK1) functions as an integrator node to coordinate allosteric coupling of the two ligand-binding sites. It maintains indirect interactions with the ATP-pocket and mediates a critical salt bridge with a glutamate (Glu130) of αC helix, which is conserved across all kinases. In summary, allosteric propagation in cooperative, dual-liganded enzyme targets is bidirectional and synergistic and offers a strategy for combinatorial drug development.Fil: Ghode, Abhijeet. National University Of Singapore; SingapurFil: Gross, Lissy Zoe Florens. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Parque Centenario. Instituto de Investigación en Biomedicina de Buenos Aires - Instituto Partner de la Sociedad Max Planck; ArgentinaFil: Tee, Wei Ven. National University Of Singapore; SingapurFil: Guarnera, Enrico. Agency For Science, Technology And Research; SingapurFil: Berezovsky, Igor N.. Agency For Science, Technology And Research; SingapurFil: Biondi, Ricardo Miguel. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Parque Centenario. Instituto de Investigación en Biomedicina de Buenos Aires - Instituto Partner de la Sociedad Max Planck; ArgentinaFil: Anand, Ganesh S.. National University Of Singapore; Singapu
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