THEMATICS: A simple computational predictor of enzyme function from structure

Ondrechen, Mary Jo; Clifton, James R; Ringe, Dagmar

doi:10.1073/pnas.211436698

Cited by 215 publications

(218 citation statements)

References 38 publications

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“…Electrostatic effects would provide an important contribution to enzyme catalysis [15]. These general considerations are confirmed by a number of theoretical and biochemical studies of individual protein enzymes [16,17,18,19,20,21,22] and can be summarized as follows: Relative physicochemical properties of the functional residues of the enzymes are very distinct from the other residues in a molecule. Now, this is the central idea of the present method: If some relative physicochemical property can be calculated from a structure of a ribozyme, then the bases involved in catalytic site can be identified.…”

Section: Torshin: Computed Energetics Of Ribozymesmentioning

confidence: 87%

“…Functional residues destabilize proteins/enzymes [16,17,18,19] and the energetic contribution of individual residues can be reliably calculated ( [14,20,21] and unpublished data). It is also known that catalytic residues in enzymes also have unusual regions on theoretical microscopic titration curves [22]. Thus, once again, catalytic residues are distinct from all of the remaining residues in an enzyme [22].…”

Section: Torshin: Computed Energetics Of Ribozymesmentioning

confidence: 99%

“…Thus, once again, catalytic residues are distinct from all of the remaining residues in an enzyme [22]. For proteins with known spatial structure, the functional residues can be predicted using these theoretical methods [21,22].…”

Section: Torshin: Computed Energetics Of Ribozymesmentioning

confidence: 99%

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Computed Energetics of Nucleotides in Spatial Ribozyme Structures: An Accurate Identification of Functional Regions from Structure

Torshin¹

2004

The Scientific World JOURNAL

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Ribozymes are functionally diverse RNA molecules with intrinsic catalytic activity. Multiple structural and biochemical studies are required to establish which nucleotide bases are involved in the catalysis. The relative energetic properties of the nucleotide bases have been analyzed in a set of the known ribozyme structures. It was found that many of the known catalytic nucleotides can be identified using only the structure without any additional biochemical data. The results of the calculations compare well with the available biochemical data on RNA stability. Extensive in silico mutagenesis suggests that most of the nucleotides in ribozymes stabilize the RNA. The calculations show that relative contribution of the catalytic bases to RNA stability observably differs from contributions of the noncatalytic bases. Distinction between the concepts of "relative stability" and "mutational stability" is suggested. As results of prediction for several models of ribozymes appear to be in agreement with the published data on the potential active site regions, the method can potentially be used for prediction of functional nucleotides from nucleic sequence.

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Section: Torshin: Computed Energetics Of Ribozymesmentioning

confidence: 87%

Section: Torshin: Computed Energetics Of Ribozymesmentioning

confidence: 99%

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Computed Energetics of Nucleotides in Spatial Ribozyme Structures: An Accurate Identification of Functional Regions from Structure

Torshin¹

2004

The Scientific World JOURNAL

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“…Approaches based on preexisting structure may be grouped broadly into those using energetics, [12][13][14][15] and others using structural and geometric analysis. [16][17][18][19] Here, we focus on comparative, or evolutionary approaches, [20][21][22][23][24][25][26] and specifically on the evolutionary trace (ET).…”

Section: Introductionmentioning

confidence: 99%

Sequence and structure continuity of evolutionary importance improves protein functional site discovery and annotation

et al. 2010

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Protein functional sites control most biological processes and are important targets for drug design and protein engineering. To characterize them, the evolutionary trace (ET) ranks the relative importance of residues according to their evolutionary variations. Generally, top-ranked residues cluster spatially to define evolutionary hotspots that predict functional sites in structures. Here, various functions that measure the physical continuity of ET ranks among neighboring residues in the structure, or in the sequence, are shown to inform sequence selection and to improve functional site resolution. This is shown first, in 110 proteins, for which the overlap between top-ranked residues and actual functional sites rose by 8% in significance. Then, on a structural proteomic scale, optimized ET led to better 3D structure-function motifs (3D templates) and, in turn, to enzyme function prediction by the Evolutionary Trace Annotation (ETA) method with better sensitivity of (40% to 53%) and positive predictive value (93% to 94%). This suggests that the similarity of evolutionary importance among neighboring residues in the sequence and in the structure is a universal feature of protein evolution. In practice, this yields a tool for optimizing sequence selections for comparative analysis and, via ET, for better predictions of functional site and function. This should prove useful for the efficient mutational redesign of protein function and for pharmaceutical targeting.

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“…Some effort has also been made to pursue more "informatics"-based approaches to the interpretation of electrostatic properties. Much of this work includes identification of functionally-relevant residues in biomolecules by looking at electrostatic destabilization of conserved residues [18], highly shifted pK a values [44], clusters of charged residues [59], protein-membrane interactions [40], and other structural characteristics [55]. Other research has focused on comparisons of electrostatic potentials including global analyses of the biomolecular structure [38,9,40,51,37,30,36,47,43,8,53,34,46,35,52] both in threedimensional space over the entire biomolecular structure and at localized regions such as active sites [52,6,22].…”

Section: Introductionmentioning

confidence: 99%

Application of New Multiresolution Methods for the Comparison of Biomolecular Electrostatic Properties in the Absence of Global Structural Similarity

Zhang¹,

Bajaj²,

Kwon³

et al. 2006

Multiscale Model. Simul.

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In this paper we present a method for the multi-resolution comparison of biomolecular electrostatic potentials without the need for global structural alignment of the biomolecules. The underlying computational geometry algorithm uses multi-resolution attributed contour trees (MACTs) to compare the topological features of volumetric scalar fields. We apply the MACTs to compute electrostatic similarity metrics for a large set of protein chains with varying degrees of sequence, structure, and function similarity. For calibration, we also compute similarity metrics for these chains by a more traditional approach based upon 3D structural alignment and analysis of Carbo similarity indices. Moreover, because the MACT approach does not rely upon pairwise structural alignment, its accuracy and efficiency promises to perform well on future large-scale classification efforts across groups of structurally-diverse proteins. The MACT method discriminates between protein chains at a level comparable to the Carbo similarity index method; i.e., it is able to accurately cluster proteins into functionally-relevant groups which demonstrate strong dependence on ligand binding sites. The results of the analyses are available from the linked web databases

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THEMATICS: A simple computational predictor of enzyme function from structure

Cited by 215 publications

References 38 publications

Computed Energetics of Nucleotides in Spatial Ribozyme Structures: An Accurate Identification of Functional Regions from Structure

Computed Energetics of Nucleotides in Spatial Ribozyme Structures: An Accurate Identification of Functional Regions from Structure

Sequence and structure continuity of evolutionary importance improves protein functional site discovery and annotation

Application of New Multiresolution Methods for the Comparison of Biomolecular Electrostatic Properties in the Absence of Global Structural Similarity

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