Deep Neural Network Based Predictions of Protein Interactions Using Primary Sequences

Li, Hang; Gong, Xiujun; Yu, Hua; Zhou, Chang

doi:10.3390/molecules23081923

Cited by 109 publications

(69 citation statements)

References 38 publications

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“…These methods have included the Support Vector Machine [15], Random Forests [29] and autoencoders [6]. More recently, studies such as DPPI [31], DNN-PPI [32], and PIPR [33] have explored deep learning frameworks for PPI prediction. Note that these newer deep learning-based approaches are end-to-end classification models and do not specifically focus on the feature construction technique.…”

Section: Previous Workmentioning

confidence: 99%

“…For the human dataset, it is not the best among the machine learning based methods. In these experiments, we compare the results of our methods (M9 and M10) on Guo's yeast dataset with baseline approaches SVM-AC [15], kNN-CTD [17], EELM-PCA [46], SVM-MCD [27], MLP [47], RF-LPQ [28], SAE [6], DNN-PPI [32], DPPI [31] and SRGRU, SCNN and PIPR from [33]. The results for the baseline approaches are taken from [33].…”

Section: Comparison With Deep Learning Approach -Piprmentioning

confidence: 99%

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Sequence representations and their utility for predicting protein-protein interactions

Kimothi

Biyani

Hogan

2019

Preprint

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Protein-Protein Interactions (PPIs) are a crucial mechanism underpinning the function of the cell. Predicting the likely relationship between a pair of proteins is thus an important problem in bioinformatics, and a wide range of machine-learning based methods have been proposed for this task. Their success is heavily dependent on the construction of the feature vectors, with most using a set of physico-chemical properties derived from the sequence. Few work directly with the sequence itself.Recent works on embedding sequences in a low dimensional vector space has shown the utility of this approach for tasks such as protein classification and sequence search. In this paper, we extend these ideas to the PPI task, making inferences from the pair instead of for the individual sequences. We evaluate the method on human and yeast PPI datasets, benchmarking against the established methods. These results demonstrate that we can obtain sequence encodings for the PPI task which achieve similar levels of performance to existing methods without reliance on complex physico-chemical feature sets.

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Section: Previous Workmentioning

confidence: 99%

Section: Comparison With Deep Learning Approach -Piprmentioning

confidence: 99%

Sequence representations and their utility for predicting protein-protein interactions

Kimothi

Biyani

Hogan

2019

Preprint

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“…Neural networks are also gaining popularity in their application to biological systems. Some examples of these in the context of biological sequences are DNNs trained to identify lab origin given a DNA sequence (15), identify whether a sequence of DNA is plasmid or chromosomal in origin (16), and predicting protein-protein interactions between two proteins (17). In this study, I explore whether DNN architectures successful in image and text classifiers are suitable for the problem of identifying putative PPs.…”

Section: Introductionmentioning

confidence: 99%

NeuRiPP: Neural network identification of RiPP precursor peptides

Santos

2019

Preprint

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Significant progress has been made in the past few years on the computational identification biosynthetic gene clusters (BGCs) that encode ribosomally synthesized and posttranslationally modified peptides (RiPPs). This is done by identifying both RiPP tailoring enzymes (RTEs) and RiPP precursor peptides (PPs). However, identification of PPs, particularly for novel RiPP classes remains challenging. To address this, machine learning has been used to accurately identify PP sequences. However, current machine learning tools have limitations, since they are specific to the RiPP-class they are trained for, and are contextdependent, requiring information about the surrounding genetic environment of the putative PP sequences. NeuRiPP overcomes these limitations. It does this by leveraging the rich data set of high-confidence putative PP sequences from existing programs, along with experimentally verified PPs from RiPP databases. NeuRiPP uses neural network models that are suitable for peptide classification with weights trained on PP datasets. It is able to identify known PP sequences, and sequences that are likely PPs. When tested on existing RiPP BGC datasets, NeuRiPP is able to identify PP sequences in significantly more putative RiPP clusters than current tools, while maintaining the same HMM hit accuracy. Finally, NeuRiPP was able to successfully identify PP sequences from novel RiPP classes that are recently characterized experimentally, highlighting its utility in complementing existing bioinformatics tools.

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“…Recently, deep learning methods show the potential of automatically extracting comprehensive features from protein sequences, and gain unprecedented success in PPI tasks. Corresponding methods, including DNN-PPI [28], DPPI [18], and PIPR [8] employ various neural sequence pair models to predict PPI information based on protein sequences. In the application of predicting the structural properties of a protein complex, NetSurfp-2.0 [25] employs a neural sequence model to predict the solvent accessible surface area (ASA) of a protein.…”

Section: Introductionmentioning

confidence: 99%

“…Such mechanisms deploy fixed representations, e.g. one-hot vectors [28], physicochemical property-aware encoding [8] or static amino acid embeddings [8]. However, these representations face several indispensable problems for PPI property predictions upon mutations.…”

Section: Introductionmentioning

confidence: 99%

Mutation effect estimation on protein-protein interactions using deep contextualized representation learning

Zhou

Chen

et al. 2019

Preprint

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The functional impact of protein mutations is reflected on the alteration of conformation and thermodynamics of protein-protein interactions (PPIs). Quantifying the changes of two interacting proteins upon mutations are commonly carried out by computational approaches. Hence, extensive research efforts have been put to the extraction of energetic or structural features on proteins, followed by statistical learning methods to estimate the effects of mutations to PPI properties. Nonetheless, such features require extensive human labors and expert knowledge to obtain, and have limited abilities to reflect point mutations. We present an end-to-end deep learning framework, , to estimate the effects of mutations on PPIs. incorporates a contextualized representation mechanism of amino acids to propagate the effects of a point mutation to surrounding amino acid representations, therefore amplifying the subtle change in a long protein sequence. On top of that, leverages a Siamese residual recurrent convolutional neural encoder to encode a wildtype protein pair and its mutation pair. Multiple-layer perceptron regressors are applied to the protein pair representations to predict the quantifiable changes of PPI properties upon mutations. Experimental evaluations show that outperforms various state-of-the-art systems on the change of binding affinity prediction and the buried surface area prediction. The software implementation is available at https://github.com/guangyu-zhou/MuPIPR

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Deep Neural Network Based Predictions of Protein Interactions Using Primary Sequences

Cited by 109 publications

References 38 publications

Sequence representations and their utility for predicting protein-protein interactions

Sequence representations and their utility for predicting protein-protein interactions

NeuRiPP: Neural network identification of RiPP precursor peptides

Mutation effect estimation on protein-protein interactions using deep contextualized representation learning

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