Abstract
A considerable proportion of protein-protein interactions (PPIs) in the cell are estimated to be mediated by very short peptide segments that approximately conform to specific sequence patterns known as linear motifs (LMs), often present in the disordered regions in the eukaryotic proteins. These peptides have been found to interact with low affinity and are able bind to multiple interactors, thus playing an important role in the PPI networks involving date hubs. In this work, PPI data and de novo motif identification based method (MEME) were used to identify such peptides in three cancer-associated hub proteins—MYC, APC and MDM2. The peptides corresponding to the significant LMs identified for each hub protein were aligned, the overlapping regions across these peptides being termed as overlapping linear peptides (OLPs). These OLPs were thus predicted to be responsible for multiple PPIs of the corresponding hub proteins and a scoring system was developed to rank them. We predicted six OLPs in MYC and five OLPs in MDM2 that scored higher than OLP predictions from randomly generated protein sets. Two OLP sequences from the C-terminal of MYC were predicted to bind with FBXW7, component of an E3 ubiquitin-protein ligase complex involved in proteasomal degradation of MYC. Similarly, we identified peptides in the C-terminal of MDM2 interacting with FKBP3, which has a specific role in auto-ubiquitinylation of MDM2. The peptide sequences predicted in MYC and MDM2 look promising for designing orthosteric inhibitors against possible disease-associated PPIs. Since these OLPs can interact with other proteins as well, these inhibitors should be specific to the targeted interactor to prevent undesired side-effects. This computational framework has been designed to predict and rank the peptide regions that may mediate multiple PPIs and can be applied to other disease-associated date hub proteins for prediction of novel therapeutic targets of small molecule PPI modulators.
Highlights
There has been a gradual shift of focus in cancer research from the study of individual proteins to edgetic perturbations of highly connected nodes in intra-cellular signaling networks, known as hub nodes, which are considered essential for maintaining the network topology [1,2,3]
The transient and low-affinity protein-protein interactions (PPIs) mediated by these short, flexible peptide segments help many date hub proteins to employ the same interfaces for binding multiple interactors at different time or locations [10,11]
Recent studies have shown that small chemical inhibitors can target PPIs, including the ones mediated by short peptides, and have the potential to act as new therapeutic agents against complex diseases including cancer [13]
Summary
There has been a gradual shift of focus in cancer research from the study of individual proteins to edgetic perturbations of highly connected nodes (proteins) in intra-cellular signaling networks, known as hub nodes, which are considered essential for maintaining the network topology [1,2,3]. The transient and low-affinity PPIs mediated by these short, flexible peptide segments help many date hub proteins to employ the same interfaces for binding multiple interactors at different time or locations [10,11]. Recent studies have shown that small chemical inhibitors can target PPIs, including the ones mediated by short peptides, and have the potential to act as new therapeutic agents against complex diseases including cancer [13]. Identification of such short peptides that may mediate multiple protein interactions in essential cancer-associated hub proteins can help in targeting peptide-mediated PPIs for therapeutic intervention with structural analogues
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