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Target Concepts:
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Query: KEGG:D02011 (
FAD
)
5,530
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The alternative NADH:ubiquinone oxidoreductase (NDH-2) from Escherichia coli is a membrane protein playing a prominent role in respiration by linking the reduction of NADH to the quinone pool. Remote sequence similarity reveals an evolutionary relation between alternative NADH:quinone oxidoreductases and the
SCOP
-family "FAD/NAD-linked reductases". We have created a structural model for NDH-2 from E. coli through comparative modelling onto a template from this family. Combined analysis of our model and sequence conservation allowed us to include the cofactor
FAD
and the substrate NADH in atomic detail. Furthermore, we propose the most plausible orientation of NDH-2 relative to the membrane and specify a region of the protein potentially involved in ubiquinone binding.
...
PMID:Functional properties of the alternative NADH:ubiquinone oxidoreductase from E. coli through comparative 3-D modelling. 1558 35
Structure motifs are amino acid packing patterns that occur frequently within a set of protein structures. We define a labeled graph representation of protein structure in which vertices correspond to amino acid residues and edges connect pairs of residues and are labeled by (1) the Euclidian distance between the C(alpha) atoms of the two residues and (2) a boolean indicating whether the two residues are in physical/chemical contact. Using this representation, a structure motif corresponds to a labeled clique that occurs frequently among the graphs representing the protein structures. The pairwise distance constraints on each edge in a clique serve to limit the variation in geometry among different occurrences of a structure motif. We present an efficient constrained subgraph mining algorithm to discover structure motifs in this setting. Compared with contact graph representations, the number of spurious structure motifs is greatly reduced. Using this algorithm, structure motifs were located for several
SCOP
families including the Eukaryotic Serine Proteases, Nuclear Binding Domains, Papain-like Cysteine Proteases, and
FAD
/NAD-linked Reductases. For each family, we typically obtain a handful of motifs within seconds of processing time. The occurrences of these motifs throughout the PDB were strongly associated with the original
SCOP
family, as measured using a hyper-geometric distribution. The motifs were found to cover functionally important sites like the catalytic triad for Serine Proteases and co-factor binding sites for Nuclear Binding Domains. The fact that many motifs are highly family-specific can be used to classify new proteins or to provide functional annotation in Structural Genomics Projects.
...
PMID:Distance-based identification of structure motifs in proteins using constrained frequent subgraph mining. 1736 41
