Short Co-occurring Polypeptide Regions Can Predict Global Protein Interaction Maps

Pitre, Sylvain; Hooshyar, M. A.; Schoenrock, Andrew; Samanfar, Bahram; Jessulat, Matthew; Green, James R.; Dehne, Frank; Golshani, Ashkan

doi:10.1038/srep00239

Cited by 59 publications

(63 citation statements)

References 24 publications

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“…Our new methods and new predictions 57 at least double the number of organisms for which sequence-based PPI predictions are 58 available, and they do this in a more consistent way than other method [24]. On top,…”

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confidence: 84%

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ProfPPIdb: pairs of physical protein-protein interactions predicted for entire proteomes

Tran

Hamp

Rost

2018

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confidence: 84%

“…As before in [20], [23], we obtained Many advanced sequence-based PPI prediction methods have been developed. Park and 112 Marcotte [22] showed that PIPE2 [24], AutoCorrelation [31], and SigProd [32] 113 performed well compared to other methods. We showed a profile-kernel SVM to improve 114 over these methods for human and yeast [23].…”

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confidence: 98%

ProfPPIdb: pairs of physical protein-protein interactions predicted for entire proteomes

Tran

Hamp

Rost

2018

Preprint

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“…Thus, there is a longstanding interest in using sequence-based methods to model and predict protein interactions (Hashemifar, et al, 2018). Several sequence-based methods have been developed to predict PPIs, such as SigProd (Martin, et al, 2005), AutoCorrelation (Guo, et al, 2008), Yang's work (Yang, et al, 2010), Zhou's work (Zhou, et al, 2011), PIPE2 (Pitre, et al, 2012), You's work (You, et al, 2014), PPI-PK (Hamp and Rost, 2015), Wong's work (Wong, et al, 2015), Sun's work (Sun, et al, 2017), and DPPI (Hashemifar, et al, 2018). The main limitation of these sequence-based methods is only the amino acid compositions of a sequence were considered.…”

Section: Introductionmentioning

confidence: 99%

A deep learning framework for improving protein interaction prediction using sequence properties

Guo

Chen

2019

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Motivation: Almost all critical functions and processes in cells are sustained by the cellular networks of protein-protein interactions (PPIs), understanding these is therefore crucial in the investigation of biological systems. Despite all past efforts, we still lack high-quality PPI data for constructing the networks, which makes it challenging to study the functions of association of proteins. High-throughput experimental techniques have produced abundant data for systematically studying the cellular networks of a biological system and the development of computational method for PPI identification. Results:We have developed a deep learning-based framework, named iPPI, for accurately predicting PPI on a proteome-wide scale depended only on sequence information. iPPI integrates the amino acid properties and compositions of protein sequence into a unified prediction framework using a hybrid deep neural network. Extensive tests demonstrated that iPPI can greatly outperform the state-of-the-art prediction methods in identifying PPIs. In addition, the iPPI prediction score can be related to the strength of protein-protein binding affinity and further showed the biological relevance of our deep learning framework to identify PPIs. Availability and Implementation: iPPI is available as an open-source software and can be downloaded from https://github.com/model-lab/

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“…PIPE has been used to identify novel protein interactions, to discover new protein complexes, to predict novel protein functions [32–36], and to produce proteome-wide predicted interaction networks for S . cerevisiae [34], Schizosaccharomyces pombe [33], Caenorhabditis elegans [35] and Homo sapiens [36], among others.…”

Section: Introductionmentioning

confidence: 99%

“…We do note that interactions from one species can be used to predict interactions in another, even using distant relatives such as human and yeast. However, within-species interactions have been found to be more accurate [33]. …”

Section: Introductionmentioning

confidence: 99%

Evolution of protein-protein interaction networks in yeast

et al. 2017

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Interest in the evolution of protein-protein and genetic interaction networks has been rising in recent years, but the lack of large-scale high quality comparative datasets has acted as a barrier. Here, we carried out a comparative analysis of computationally predicted protein-protein interaction (PPI) networks from five closely related yeast species. We used the Protein-protein Interaction Prediction Engine (PIPE), which uses a database of known interactions to make sequence-based PPI predictions, to generate high quality predicted interactomes. Simulated proteomes and corresponding PPI networks were used to provide null expectations for the extent and nature of PPI network evolution. We found strong evidence for conservation of PPIs, with lower than expected levels of change in PPIs for about a quarter of the proteome. Furthermore, we found that changes in predicted PPI networks are poorly predicted by sequence divergence. Our analyses identified a number of functional classes experiencing fewer PPI changes than expected, suggestive of purifying selection on PPIs. Our results demonstrate the added benefit of considering predicted PPI networks when studying the evolution of closely related organisms.

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Short Co-occurring Polypeptide Regions Can Predict Global Protein Interaction Maps

Cited by 59 publications

References 24 publications

ProfPPIdb: pairs of physical protein-protein interactions predicted for entire proteomes

ProfPPIdb: pairs of physical protein-protein interactions predicted for entire proteomes

A deep learning framework for improving protein interaction prediction using sequence properties

Evolution of protein-protein interaction networks in yeast

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