Learning a peptide-protein binding affinity predictor with kernel ridge regression

The cellular function of a vast majority of proteins is performed through physical interactions with other biomolecules, which, most of the time, are other proteins. Peptides represent templates of choice for mimicking a secondary structure in order to modulate protein-protein interaction. They are...

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Bibliographic Details
Published in:BMC bioinformatics 2013-03, Vol.14 (1), p.82-82, Article 82
Main Authors: Giguère, Sébastien, Marchand, Mario, Laviolette, François, Drouin, Alexandre, Corbeil, Jacques
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Alleles
Analysis
Antibodies
Artificial Intelligence
Binding Sites
Biochemistry
Computer Simulation
Dynamic programming
Histocompatibility Antigens Class II - chemistry
Histocompatibility Antigens Class II - genetics
Histocompatibility Antigens Class II - metabolism
Homeopathy
Kernels
Machine learning
Materia medica and therapeutics
Methods
Peptides
Peptides - chemistry
Peptides - immunology
Peptides - metabolism
Pharmaceuticals
Protein binding
Protein Interaction Domains and Motifs
Protein Interaction Mapping - methods
Protein-protein interactions
Proteins
Studies
Therapeutics
Viral antibodies
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Summary:The cellular function of a vast majority of proteins is performed through physical interactions with other biomolecules, which, most of the time, are other proteins. Peptides represent templates of choice for mimicking a secondary structure in order to modulate protein-protein interaction. They are thus an interesting class of therapeutics since they also display strong activity, high selectivity, low toxicity and few drug-drug interactions. Furthermore, predicting peptides that would bind to a specific MHC alleles would be of tremendous benefit to improve vaccine based therapy and possibly generate antibodies with greater affinity. Modern computational methods have the potential to accelerate and lower the cost of drug and vaccine discovery by selecting potential compounds for testing in silico prior to biological validation. We propose a specialized string kernel for small bio-molecules, peptides and pseudo-sequences of binding interfaces. The kernel incorporates physico-chemical properties of amino acids and elegantly generalizes eight kernels, comprised of the Oligo, the Weighted Degree, the Blended Spectrum, and the Radial Basis Function. We provide a low complexity dynamic programming algorithm for the exact computation of the kernel and a linear time algorithm for it's approximation. Combined with kernel ridge regression and SupCK, a novel binding pocket kernel, the proposed kernel yields biologically relevant and good prediction accuracy on the PepX database. For the first time, a machine learning predictor is capable of predicting the binding affinity of any peptide to any protein with reasonable accuracy. The method was also applied to both single-target and pan-specific Major Histocompatibility Complex class II benchmark datasets and three Quantitative Structure Affinity Model benchmark datasets. On all benchmarks, our method significantly (p-value ≤ 0.057) outperforms the current state-of-the-art methods at predicting peptide-protein binding affinities. The proposed approach is flexible and can be applied to predict any quantitative biological activity. Moreover, generating reliable peptide-protein binding affinities will also improve system biology modelling of interaction pathways. Lastly, the method should be of value to a large segment of the research community with the potential to accelerate the discovery of peptide-based drugs and facilitate vaccine development. The proposed kernel is freely available at http://graal.ift.ulaval.ca/downlo
ISSN:1471-2105
1471-2105
DOI:10.1186/1471-2105-14-82