Abstract
Background3D domain swapping is a novel structural phenomenon observed in diverse set of protein structures in oligomeric conformations. A distinct structural feature, where structural segments in a protein dimer or higher oligomer were shared between two or more chains of a protein structure, characterizes 3D domain swapping. 3D domain swapping was observed as a key mediator of numerous functional mechanisms and play pathogenic role in various diseases including conformational diseases like amyloidosis, Alzheimer's disease, Parkinson's disease and prion diseases. We report the first study with a focus on identifying functional classes, pathways and diseases mediated by 3D domain swapping in the human proteome.MethodsWe used a panel of four enrichment tools with two different ontologies and two annotations database to derive biological and clinical relevant information associated with 3D domain swapping. Protein domain enrichment analysis followed by Gene Ontology (GO) term enrichment analysis revealed the functional repertoire of proteins involved in swapping. Pathway analysis using KEGG annotations revealed diverse pathway associations of human proteins involved in 3D domain swapping. Disease Ontology was used to find statistically significant associations with proteins in swapped conformation and various disease categories (P-value < 0.05).ResultsWe report meta-analysis results of a literature-curated dataset of human gene products involved in 3D domain swapping and discuss new insights about the functional repertoire, pathway associations and disease implications of proteins involved in 3D domain swapping.ConclusionsOur integrated bioinformatics pipeline comprising of four different enrichment tools, two ontologies and two annotations revealed new insights into the functional and disease correlations with 3D domain swapping. GO term enrichment were used to infer terms associated with three different GO categories. Protein domain enrichment was used to identify conserved domains enriched in swapped proteins. Pathway enrichment analysis using KEGG annotations revealed that proteins with swapped conformations are present in all six classes of KEGG BRITE hierarchy and significantly enriched KEGG pathways were observed in five classes. Five major classes of disease were found to be associated with 3D domain swapping using functional disease ontology based enrichment analysis. Five classes of human diseases: cancer, diseases of the respiratory or pulmonary system, degenerative diseases of the central nervous system, vascular disease and encephalitis were found to be significant. In conclusion, our study shows that bioinformatics based analytical approaches using curated data can enhance the understanding of functional and disease implications of 3D domain swapping.
Highlights
3D domain swapping is a novel structural phenomenon observed in diverse set of protein structures in oligomeric conformations
Two proteins with high degree of similarity could interact and form a homodimer, where as two distantly related proteins could form a heterodimer [8,9]. 3D domain swapping is a unique protein structural mechanism observed in homodimers or higher order oligomers with a specific type of interaction, where a segment of two protein chains are mutually swapped. 3D domain swapping was observed in protein structures in heteroligomer conformations. 3D domain swapping was associated with several proteins that were involved in diverse functional events and disease pathways
3D domain swapping is a structural mechanism employed by a variety of protein structures to form oligomeric assemblies
Summary
3D domain swapping is a novel structural phenomenon observed in diverse set of protein structures in oligomeric conformations. Efficient classification, annotation and prediction algorithms are rapidly improving our understanding of protein sequence-structure-function relationships Analysis of such relationships often helps in our understanding of novel sequence or structural features in the regulation of a particular function including molecular pathways and various disease mechanisms. 3D domain swapping is a unique protein structural mechanism observed in homodimers or higher order oligomers with a specific type of interaction, where a segment of two protein chains are mutually swapped. We used complete set of human proteins from 3DSwap database and examined statistically significant domains, biological process, cellular component, molecular function, biological pathways and diseases using enrichment methods. This manuscript is a case study that leverage application of robust bioinformatics methods to gain new functional and therapeutic insights from a protein structural mechanism
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