摘要
Representing and recognizing protein active sites sequence motif (1D motif) and structural motif (3D motif) is an important topic for predicting and designing protein function. Prevalent methods for extracting and searching 3D motif always consider residue as the minimal unit, which have limited sensitivity. Here we present a new spatial representation of protein active sites, called 'functional-group 3D motif', based on the fact that the functional groups inside a residue contribute mostly to its function. Relevant algorithm and computer program are developed, which could be widely used in the function prediction and the study of structural-function relationship of proteins. As a test, we defined a functional-group 3D motif of the catalytic triad and oxyanion hole with the structure of porcine trypsin (PDB code: 1mct) as the template. With our motif-searching program, we successfully found similar sub-structures in trypsins, subtilisins and α/β hydrolases, which show distinct folds but share
Representing and recognizing protein active sites sequence motif (1D motif) and structural motif (3D motif) is an important topic for predicting and designing protein function. Prevalent methods for extracting and searching 3D motif always consider residue as the minimal unit, which have limited sensitivity. Here we present a new spatial representation of protein active sites, called “functional-group 3D motif”, based on the fact that the functional groups inside a residue contribute mostly to its function. Relevant algorithm and computer program are developed, which could be widely used in the function prediction and the study of structural-function relationship of proteins. As a test, we defined a functional-group 3D motif of the catalytic triad and oxyanion hole with the structure of porcine trypsin (PDB code: 1mct) as the template. With our motif-searching program, we successfully found similar sub-structures in trypsins, subtilisins and α/β hydrolases, which show distinct folds but share similar catalytic mechanism. Moreover, this motif can be used to elucidate the structural basis of other proteins with variant catalytic triads by comparing it to those proteins. Finally, we scanned this motif against a non-redundant protein structure database to find its matches, and the results demonstrated the potential application of functional group 3D motif in function prediction. Above all, compared with the other 3D-motif representations on residues, the functional group 3D motif achieves better representation of protein active region, which is more sensitive for protein function prediction.
