Showing total 28 results

1. SFPEL-LPI: Sequence-based feature projection ensemble learning for predicting LncRNA-protein interactions.

Author

Zhang, Wen, Tang, Guifeng, Huang, Feng, Zhang, Xining, Yue, Xiang, and Wu, Wenjian

Subjects

RNA-protein interactions, GENETIC regulation, RNA interference, RNA splicing, ADENYLATION (Biochemistry)

Abstract

LncRNA-protein interactions play important roles in post-transcriptional gene regulation, poly-adenylation, splicing and translation. Identification of lncRNA-protein interactions helps to understand lncRNA-related activities. Existing computational methods utilize multiple lncRNA features or multiple protein features to predict lncRNA-protein interactions, but features are not available for all lncRNAs or proteins; most of existing methods are not capable of predicting interacting proteins (or lncRNAs) for new lncRNAs (or proteins), which don’t have known interactions. In this paper, we propose the sequence-based feature projection ensemble learning method, “SFPEL-LPI”, to predict lncRNA-protein interactions. First, SFPEL-LPI extracts lncRNA sequence-based features and protein sequence-based features. Second, SFPEL-LPI calculates multiple lncRNA-lncRNA similarities and protein-protein similarities by using lncRNA sequences, protein sequences and known lncRNA-protein interactions. Then, SFPEL-LPI combines multiple similarities and multiple features with a feature projection ensemble learning frame. In computational experiments, SFPEL-LPI accurately predicts lncRNA-protein associations and outperforms other state-of-the-art methods. More importantly, SFPEL-LPI can be applied to new lncRNAs (or proteins). The case studies demonstrate that our method can find out novel lncRNA-protein interactions, which are confirmed by literature. Finally, we construct a user-friendly web server, available at . [ABSTRACT FROM AUTHOR]

Published

2018

2. Predicting B cell receptor substitution profiles using public repertoire data.

Author

Dhar, Amrit, Davidsen, Kristian, IVMatsen, Frederick A., and Minin, Vladimir N.

Subjects

B cell receptors, AMINO acids, GENETIC mutation, CLONING, GERMINAL centers, IMMUNOTECHNOLOGY

Abstract

B cells develop high affinity receptors during the course of affinity maturation, a cyclic process of mutation and selection. At the end of affinity maturation, a number of cells sharing the same ancestor (i.e. in the same “clonal family”) are released from the germinal center; their amino acid frequency profile reflects the allowed and disallowed substitutions at each position. These clonal-family-specific frequency profiles, called “substitution profiles”, are useful for studying the course of affinity maturation as well as for antibody engineering purposes. However, most often only a single sequence is recovered from each clonal family in a sequencing experiment, making it impossible to construct a clonal-family-specific substitution profile. Given the public release of many high-quality large B cell receptor datasets, one may ask whether it is possible to use such data in a prediction model for clonal-family-specific substitution profiles. In this paper, we present the method “Substitution Profiles Using Related Families” (SPURF), a penalized tensor regression framework that integrates information from a rich assemblage of datasets to predict the clonal-family-specific substitution profile for any single input sequence. Using this framework, we show that substitution profiles from similar clonal families can be leveraged together with simulated substitution profiles and germline gene sequence information to improve prediction. We fit this model on a large public dataset and validate the robustness of our approach on two external datasets. Furthermore, we provide a command-line tool in an open-source software package () implementing these ideas and providing easy prediction using our pre-fit models. [ABSTRACT FROM AUTHOR]

Published

2018

3. SARNAclust: Semi-automatic detection of RNA protein binding motifs from immunoprecipitation data.

Author

Dotu, Ivan, Adamson, Scott I., Coleman, Benjamin, Fournier, Cyril, Ricart-Altimiras, Emma, Eyras, Eduardo, and Chuang, Jeffrey H.

Subjects

IMMUNOPRECIPITATION, RNA-binding proteins, PROTEIN-protein interactions, NUCLEOTIDE sequence, RNA splicing

Abstract

RNA-protein binding is critical to gene regulation, controlling fundamental processes including splicing, translation, localization and stability, and aberrant RNA-protein interactions are known to play a role in a wide variety of diseases. However, molecular understanding of RNA-protein interactions remains limited; in particular, identification of RNA motifs that bind proteins has long been challenging, especially when such motifs depend on both sequence and structure. Moreover, although RNA binding proteins (RBPs) often contain more than one binding domain, algorithms capable of identifying more than one binding motif simultaneously have not been developed. In this paper we present a novel pipeline to determine binding peaks in crosslinking immunoprecipitation (CLIP) data, to discover multiple possible RNA sequence/structure motifs among them, and to experimentally validate such motifs. At the core is a new semi-automatic algorithm SARNAclust, the first unsupervised method to identify and deconvolve multiple sequence/structure motifs simultaneously. SARNAclust computes similarity between sequence/structure objects using a graph kernel, providing the ability to isolate the impact of specific features through the bulge graph formalism. Application of SARNAclust to synthetic data shows its capability of clustering 5 motifs at once with a V-measure value of over 0.95, while GraphClust achieves only a V-measure of 0.083 and RNAcontext cannot detect any of the motifs. When applied to existing eCLIP sets, SARNAclust finds known motifs for SLBP and HNRNPC and novel motifs for several other RBPs such as AGGF1, AKAP8L and ILF3. We demonstrate an experimental validation protocol, a targeted Bind-n-Seq-like high-throughput sequencing approach that relies on RNA inverse folding for oligo pool design, that can validate the components within the SLBP motif. Finally, we use this protocol to experimentally interrogate the SARNAclust motif predictions for protein ILF3. Our results support a newly identified partially double-stranded UUUUUGAGA motif similar to that known for the splicing factor HNRNPC. [ABSTRACT FROM AUTHOR]

Published

2018

4. PCSF: An R-package for network-based interpretation of high-throughput data.

Author

Akhmedov, Murodzhon, Kedaigle, Amanda, Chong, Renan Escalante, Montemanni, Roberto, Bertoni, Francesco, Fraenkel, Ernest, and Kwee, Ivo

Subjects

BIOINFORMATICS software, DATA analysis software, MATHEMATICAL optimization, COMPUTATIONAL biology, PROTEIN-protein interactions

Abstract

With the recent technological developments a vast amount of high-throughput data has been profiled to understand the mechanism of complex diseases. The current bioinformatics challenge is to interpret the data and underlying biology, where efficient algorithms for analyzing heterogeneous high-throughput data using biological networks are becoming increasingly valuable. In this paper, we propose a software package based on the Prize-collecting Steiner Forest graph optimization approach. The PCSF package performs fast and user-friendly network analysis of high-throughput data by mapping the data onto a biological networks such as protein-protein interaction, gene-gene interaction or any other correlation or coexpression based networks. Using the interaction networks as a template, it determines high-confidence subnetworks relevant to the data, which potentially leads to predictions of functional units. It also interactively visualizes the resulting subnetwork with functional enrichment analysis. [ABSTRACT FROM AUTHOR]

Published

2017

5. Accurate De Novo Prediction of Protein Contact Map by Ultra-Deep Learning Model.

Author

Wang, Sheng, Sun, Siqi, Li, Zhen, Zhang, Renyu, and Xu, Jinbo

Subjects

PROTEIN structure, ARTIFICIAL neural networks, PROTEIN folding, PAIRED comparisons (Mathematics), AMINO acid sequence

Abstract

Motivation: Protein contacts contain key information for the understanding of protein structure and function and thus, contact prediction from sequence is an important problem. Recently exciting progress has been made on this problem, but the predicted contacts for proteins without many sequence homologs is still of low quality and not very useful for de novo structure prediction. Method: This paper presents a new deep learning method that predicts contacts by integrating both evolutionary coupling (EC) and sequence conservation information through an ultra-deep neural network formed by two deep residual neural networks. The first residual network conducts a series of 1-dimensional convolutional transformation of sequential features; the second residual network conducts a series of 2-dimensional convolutional transformation of pairwise information including output of the first residual network, EC information and pairwise potential. By using very deep residual networks, we can accurately model contact occurrence patterns and complex sequence-structure relationship and thus, obtain high-quality contact prediction regardless of how many sequence homologs are available for proteins in question. Results: Our method greatly outperforms existing methods and leads to much more accurate contact-assisted folding. Tested on 105 CASP11 targets, 76 past CAMEO hard targets, and 398 membrane proteins, the average top L long-range prediction accuracy obtained by our method, one representative EC method CCMpred and the CASP11 winner MetaPSICOV is 0.47, 0.21 and 0.30, respectively; the average top L/10 long-range accuracy of our method, CCMpred and MetaPSICOV is 0.77, 0.47 and 0.59, respectively. Ab initio folding using our predicted contacts as restraints but without any force fields can yield correct folds (i.e., TMscore>0.6) for 203 of the 579 test proteins, while that using MetaPSICOV- and CCMpred-predicted contacts can do so for only 79 and 62 of them, respectively. Our contact-assisted models also have much better quality than template-based models especially for membrane proteins. The 3D models built from our contact prediction have TMscore>0.5 for 208 of the 398 membrane proteins, while those from homology modeling have TMscore>0.5 for only 10 of them. Further, even if trained mostly by soluble proteins, our deep learning method works very well on membrane proteins. In the recent blind CAMEO benchmark, our fully-automated web server implementing this method successfully folded 6 targets with a new fold and only 0.3L-2.3L effective sequence homologs, including one β protein of 182 residues, one α+β protein of 125 residues, one α protein of 140 residues, one α protein of 217 residues, one α/β of 260 residues and one α protein of 462 residues. Our method also achieved the highest F1 score on free-modeling targets in the latest CASP (Critical Assessment of Structure Prediction), although it was not fully implemented back then. Availability: [ABSTRACT FROM AUTHOR]

Published

2017

6. SFPEL-LPI: Sequence-based feature projection ensemble learning for predicting LncRNA-protein interactions

Author

Wenjian Wu, Wen Zhang, Xining Zhang, Guifeng Tang, Xiang Yue, and Feng Huang

Subjects

Proteomics, 0301 basic medicine, Protein Extraction, Computer science, Biochemistry, Machine Learning, Database and Informatics Methods, Mathematical and Statistical Techniques, 0302 clinical medicine, Protein sequencing, Feature (machine learning), RNA Processing, Post-Transcriptional, Biology (General), Databases, Protein, Projection (set theory), Peptide sequence, Extraction Techniques, Sequence, Ecology, Gene Ontologies, Statistics, RNA-Binding Proteins, Genomics, Genomic Databases, Nucleic acids, Computational Theory and Mathematics, 030220 oncology & carcinogenesis, Modeling and Simulation, Physical Sciences, Protein Interaction Networks, RNA, Long Noncoding, Identification (biology), Databases, Nucleic Acid, Network Analysis, Algorithms, Research Article, Protein Binding, Computer and Information Sciences, QH301-705.5, Computational biology, Research and Analysis Methods, Protein–protein interaction, 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, Humans, Amino Acid Sequence, Statistical Methods, Non-coding RNA, Protein Interactions, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Biology and life sciences, Base Sequence, Proteins, Computational Biology, Genome Analysis, Ensemble learning, Biological Databases, 030104 developmental biology, Protein-Protein Interactions, Long non-coding RNAs, RNA, Mathematics, Forecasting

Abstract

LncRNA-protein interactions play important roles in post-transcriptional gene regulation, poly-adenylation, splicing and translation. Identification of lncRNA-protein interactions helps to understand lncRNA-related activities. Existing computational methods utilize multiple lncRNA features or multiple protein features to predict lncRNA-protein interactions, but features are not available for all lncRNAs or proteins; most of existing methods are not capable of predicting interacting proteins (or lncRNAs) for new lncRNAs (or proteins), which don’t have known interactions. In this paper, we propose the sequence-based feature projection ensemble learning method, “SFPEL-LPI”, to predict lncRNA-protein interactions. First, SFPEL-LPI extracts lncRNA sequence-based features and protein sequence-based features. Second, SFPEL-LPI calculates multiple lncRNA-lncRNA similarities and protein-protein similarities by using lncRNA sequences, protein sequences and known lncRNA-protein interactions. Then, SFPEL-LPI combines multiple similarities and multiple features with a feature projection ensemble learning frame. In computational experiments, SFPEL-LPI accurately predicts lncRNA-protein associations and outperforms other state-of-the-art methods. More importantly, SFPEL-LPI can be applied to new lncRNAs (or proteins). The case studies demonstrate that our method can find out novel lncRNA-protein interactions, which are confirmed by literature. Finally, we construct a user-friendly web server, available at http://www.bioinfotech.cn/SFPEL-LPI/., Author summary LncRNA-protein interactions play important roles in post-transcriptional gene regulation, poly-adenylation, splicing and translation. Identification of lncRNA-protein interactions helps to understand lncRNA-related activities. In this paper, we propose a novel computational method “SFPEL-LPI” to predict lncRNA-protein interactions. SFPEL-LPI makes use of lncRNA sequences, protein sequences and known lncRNA-protein associations to extract features and calculate similarities for lncRNAs and proteins, and then combines them with a feature projection ensemble learning frame. SFPEL-LPI can predict unobserved interactions between lncRNAs and proteins, and also can make predictions for new lncRNAs (or proteins), which have no interactions with any proteins (or lncRNAs). SFPEL-LPI produces high-accuracy performances on the benchmark dataset when evaluated by five-fold cross validation, and outperforms state-of-the-art methods. The case studies demonstrate that SFPEL-LPI can find out novel associations, which are confirmed by literature. To facilitate the lncRNA-protein interaction prediction, we develop a user-friendly web server, available at http://www.bioinfotech.cn/SFPEL-LPI/.

Published

2018

7. DART-ID increases single-cell proteome coverage.

Author

Chen, Albert Tian, Franks, Alexander, and Slavov, Nikolai

Subjects

TANDEM mass spectrometry, MONOCYTES, RF values (Chromatography), LEUCOCYTES, STATISTICAL power analysis, LIQUID chromatography

Abstract

Analysis by liquid chromatography and tandem mass spectrometry (LC-MS/MS) can identify and quantify thousands of proteins in microgram-level samples, such as those comprised of thousands of cells. This process, however, remains challenging for smaller samples, such as the proteomes of single mammalian cells, because reduced protein levels reduce the number of confidently sequenced peptides. To alleviate this reduction, we developed Data-driven Alignment of Retention Times for IDentification (DART-ID). DART-ID implements principled Bayesian frameworks for global retention time (RT) alignment and for incorporating RT estimates towards improved confidence estimates of peptide-spectrum-matches. When applied to bulk or to single-cell samples, DART-ID increased the number of data points by 30–50% at 1% FDR, and thus decreased missing data. Benchmarks indicate excellent quantification of peptides upgraded by DART-ID and support their utility for quantitative analysis, such as identifying cell types and cell-type specific proteins. The additional datapoints provided by DART-ID boost the statistical power and double the number of proteins identified as differentially abundant in monocytes and T-cells. DART-ID can be applied to diverse experimental designs and is freely available at . [ABSTRACT FROM AUTHOR]

Published

2019

8. Pathogenicity and functional impact of non-frameshifting insertion/deletion variation in the human genome.

Author

Pagel, Kymberleigh A., Antaki, Danny, Lian, AoJie, Mort, Matthew, Cooper, David N., Sebat, Jonathan, Iakoucheva, Lilia M., Mooney, Sean D., and Radivojac, Predrag

Subjects

HUMAN genome, AUTISM spectrum disorders, MICROBIAL virulence, RECURRENT neural networks, POST-translational modification, PHYSICAL sciences

Abstract

Differentiation between phenotypically neutral and disease-causing genetic variation remains an open and relevant problem. Among different types of variation, non-frameshifting insertions and deletions (indels) represent an understudied group with widespread phenotypic consequences. To address this challenge, we present a machine learning method, MutPred-Indel, that predicts pathogenicity and identifies types of functional residues impacted by non-frameshifting insertion/deletion variation. The model shows good predictive performance as well as the ability to identify impacted structural and functional residues including secondary structure, intrinsic disorder, metal and macromolecular binding, post-translational modifications, allosteric sites, and catalytic residues. We identify structural and functional mechanisms impacted preferentially by germline variation from the Human Gene Mutation Database, recurrent somatic variation from COSMIC in the context of different cancers, as well as de novo variants from families with autism spectrum disorder. Further, the distributions of pathogenicity prediction scores generated by MutPred-Indel are shown to differentiate highly recurrent from non-recurrent somatic variation. Collectively, we present a framework to facilitate the interrogation of both pathogenicity and the functional effects of non-frameshifting insertion/deletion variants. The MutPred-Indel webserver is available at . [ABSTRACT FROM AUTHOR]

Published

2019

9. DeepConv-DTI: Prediction of drug-target interactions via deep learning with convolution on protein sequences.

Author

Lee, Ingoo, Keum, Jongsoo, and Nam, Hojung

Subjects

AMINO acid sequence, DEEP learning, MATHEMATICAL convolutions, CARRIER proteins, BINDING sites, PROTEIN models

Abstract

Identification of drug-target interactions (DTIs) plays a key role in drug discovery. The high cost and labor-intensive nature of in vitro and in vivo experiments have highlighted the importance of in silico-based DTI prediction approaches. In several computational models, conventional protein descriptors have been shown to not be sufficiently informative to predict accurate DTIs. Thus, in this study, we propose a deep learning based DTI prediction model capturing local residue patterns of proteins participating in DTIs. When we employ a convolutional neural network (CNN) on raw protein sequences, we perform convolution on various lengths of amino acids subsequences to capture local residue patterns of generalized protein classes. We train our model with large-scale DTI information and demonstrate the performance of the proposed model using an independent dataset that is not seen during the training phase. As a result, our model performs better than previous protein descriptor-based models. Also, our model performs better than the recently developed deep learning models for massive prediction of DTIs. By examining pooled convolution results, we confirmed that our model can detect binding sites of proteins for DTIs. In conclusion, our prediction model for detecting local residue patterns of target proteins successfully enriches the protein features of a raw protein sequence, yielding better prediction results than previous approaches. Our code is available at . [ABSTRACT FROM AUTHOR]

Published

2019

10. Prediction of VRC01 neutralization sensitivity by HIV-1 gp160 sequence features.

Author

Magaret, Craig A., Benkeser, David C., Williamson, Brian D., Borate, Bhavesh R., Carpp, Lindsay N., Georgiev, Ivelin S., Setliff, Ian, Dingens, Adam S., Simon, Noah, Carone, Marco, Simpkins, Christopher, Montefiori, David, Alter, Galit, Yu, Wen-Han, Juraska, Michal, Edlefsen, Paul T., Karuna, Shelly, Mgodi, Nyaradzo M., Edugupanti, Srilatha, and Gilbert, Peter B.

Subjects

BIOLOGICAL databases, HIV-positive persons, AMINO acid analysis, GLYCOSYLATION, TITERS

Abstract

The broadly neutralizing antibody (bnAb) VRC01 is being evaluated for its efficacy to prevent HIV-1 infection in the Antibody Mediated Prevention (AMP) trials. A secondary objective of AMP utilizes sieve analysis to investigate how VRC01 prevention efficacy (PE) varies with HIV-1 envelope (Env) amino acid (AA) sequence features. An exhaustive analysis that tests how PE depends on every AA feature with sufficient variation would have low statistical power. To design an adequately powered primary sieve analysis for AMP, we modeled VRC01 neutralization as a function of Env AA sequence features of 611 HIV-1 gp160 pseudoviruses from the CATNAP database, with objectives: (1) to develop models that best predict the neutralization readouts; and (2) to rank AA features by their predictive importance with classification and regression methods. The dataset was split in half, and machine learning algorithms were applied to each half, each analyzed separately using cross-validation and hold-out validation. We selected Super Learner, a nonparametric ensemble-based cross-validated learning method, for advancement to the primary sieve analysis. This method predicted the dichotomous resistance outcome of whether the IC50 neutralization titer of VRC01 for a given Env pseudovirus is right-censored (indicating resistance) with an average validated AUC of 0.868 across the two hold-out datasets. Quantitative log IC50 was predicted with an average validated R2 of 0.355. Features predicting neutralization sensitivity or resistance included 26 surface-accessible residues in the VRC01 and CD4 binding footprints, the length of gp120, the length of Env, the number of cysteines in gp120, the number of cysteines in Env, and 4 potential N-linked glycosylation sites; the top features will be advanced to the primary sieve analysis. This modeling framework may also inform the study of VRC01 in the treatment of HIV-infected persons. [ABSTRACT FROM AUTHOR]

Published

2019

11. CoPhosK: A method for comprehensive kinase substrate annotation using co-phosphorylation analysis.

Author

Ayati, Marzieh, Wiredja, Danica, Schlatzer, Daniela, Maxwell, Sean, Li, Ming, Koyutürk, Mehmet, and Chance, Mark R.

Subjects

KINASES, MASS spectrometry, PHOSPHORYLATION, CANCER, PHOSPHOPEPTIDES

Abstract

We present CoPhosK to predict kinase-substrate associations for phosphopeptide substrates detected by mass spectrometry (MS). The tool utilizes a Naïve Bayes framework with priors of known kinase-substrate associations (KSAs) to generate its predictions. Through the mining of MS data for the collective dynamic signatures of the kinases’ substrates revealed by correlation analysis of phosphopeptide intensity data, the tool infers KSAs in the data for the considerable body of substrates lacking such annotations. We benchmarked the tool against existing approaches for predicting KSAs that rely on static information (e.g. sequences, structures and interactions) using publically available MS data, including breast, colon, and ovarian cancer models. The benchmarking reveals that co-phosphorylation analysis can significantly improve prediction performance when static information is available (about 35% of sites) while providing reliable predictions for the remainder, thus tripling the KSAs available from the experimental MS data providing to a comprehensive and reliable characterization of the landscape of kinase-substrate interactions well beyond current limitations. [ABSTRACT FROM AUTHOR]

Published

2019

12. Identifying individual risk rare variants using protein structure guided local tests (POINT).

Author

Marceau West, Rachel, Lu, Wenbin, Rotroff, Daniel M., Kuenemann, Melaine A., Chang, Sheng-Mao, Wu, Michael C., Wagner, Michael J., Buse, John B., Motsinger-Reif, Alison A., Fourches, Denis, and Tzeng, Jung-Ying

Subjects

PROTEIN structure, PROTEOMICS, OPERATOR theory, QUANTITATIVE research, KERNEL functions, BIOLOGICAL databases

Abstract

Rare variants are of increasing interest to genetic association studies because of their etiological contributions to human complex diseases. Due to the rarity of the mutant events, rare variants are routinely analyzed on an aggregate level. While aggregation analyses improve the detection of global-level signal, they are not able to pinpoint causal variants within a variant set. To perform inference on a localized level, additional information, e.g., biological annotation, is often needed to boost the information content of a rare variant. Following the observation that important variants are likely to cluster together on functional domains, we propose a rte structure guided local est (POINT) to provide variant-specific association information using structure-guided aggregation of signal. Constructed under a kernel machine framework, POINT performs local association testing by borrowing information from neighboring variants in the 3-dimensional protein space in a data-adaptive fashion. Besides merely providing a list of promising variants, POINT assigns each variant a p-value to permit variant ranking and prioritization. We assess the selection performance of POINT using simulations and illustrate how it can be used to prioritize individual rare variants in PCSK9, ANGPTL4 and CETP in the Action to Control Cardiovascular Risk in Diabetes (ACCORD) clinical trial data. [ABSTRACT FROM AUTHOR]

Published

2019

13. Inferring interaction partners from protein sequences using mutual information.

Author

Bitbol, Anne-Florence

Subjects

PROTEIN-protein interactions, CELLULAR signal transduction, COEVOLUTION, FAMILIES, AMINO acid sequence

Abstract

Functional protein-protein interactions are crucial in most cellular processes. They enable multi-protein complexes to assemble and to remain stable, and they allow signal transduction in various pathways. Functional interactions between proteins result in coevolution between the interacting partners, and thus in correlations between their sequences. Pairwise maximum-entropy based models have enabled successful inference of pairs of amino-acid residues that are in contact in the three-dimensional structure of multi-protein complexes, starting from the correlations in the sequence data of known interaction partners. Recently, algorithms inspired by these methods have been developed to identify which proteins are functional interaction partners among the paralogous proteins of two families, starting from sequence data alone. Here, we demonstrate that a slightly higher performance for partner identification can be reached by an approximate maximization of the mutual information between the sequence alignments of the two protein families. Our mutual information-based method also provides signatures of the existence of interactions between protein families. These results stand in contrast with structure prediction of proteins and of multi-protein complexes from sequence data, where pairwise maximum-entropy based global statistical models substantially improve performance compared to mutual information. Our findings entail that the statistical dependences allowing interaction partner prediction from sequence data are not restricted to the residue pairs that are in direct contact at the interface between the partner proteins. [ABSTRACT FROM AUTHOR]

Published

2018

14. Systematically benchmarking peptide-MHC binding predictors: From synthetic to naturally processed epitopes.

Author

Zhao, Weilong and Sher, Xinwei

Subjects

MACHINE learning, EPITOPES, T cells, CLINICAL immunology, HLA histocompatibility antigens

Abstract

A number of machine learning-based predictors have been developed for identifying immunogenic T-cell epitopes based on major histocompatibility complex (MHC) class I and II binding affinities. Rationally selecting the most appropriate tool has been complicated by the evolving training data and machine learning methods. Despite the recent advances made in generating high-quality MHC-eluted, naturally processed ligandome, the reliability of new predictors on these epitopes has yet to be evaluated. This study reports the latest benchmarking on an extensive set of MHC-binding predictors by using newly available, untested data of both synthetic and naturally processed epitopes. 32 human leukocyte antigen (HLA) class I and 24 HLA class II alleles are included in the blind test set. Artificial neural network (ANN)-based approaches demonstrated better performance than regression-based machine learning and structural modeling. Among the 18 predictors benchmarked, ANN-based mhcflurry and nn_align perform the best for MHC class I 9-mer and class II 15-mer predictions, respectively, on binding/non-binding classification (Area Under Curves = 0.911). NetMHCpan4 also demonstrated comparable predictive power. Our customization of mhcflurry to a pan-HLA predictor has achieved similar accuracy to NetMHCpan. The overall accuracy of these methods are comparable between 9-mer and 10-mer testing data. However, the top methods deliver low correlations between the predicted versus the experimental affinities for strong MHC binders. When used on naturally processed MHC-ligands, tools that have been trained on elution data (NetMHCpan4 and MixMHCpred) shows better accuracy than pure binding affinity predictor. The variability of false prediction rate is considerable among HLA types and datasets. Finally, structure-based predictor of Rosetta FlexPepDock is less optimal compared to the machine learning approaches. With our benchmarking of MHC-binding and MHC-elution predictors using a comprehensive metrics, a unbiased view for establishing best practice of T-cell epitope predictions is presented, facilitating future development of methods in immunogenomics. [ABSTRACT FROM AUTHOR]

Published

2018

15. Co-evolution networks of HIV/HCV are modular with direct association to structure and function.

Author

Quadeer, Ahmed Abdul, Morales-Jimenez, David, and McKay, Matthew R.

Subjects

HEPATITIS C virus, DIAGNOSIS of HIV infections, VIRAL evolution, MULTIPLE correspondence analysis (Statistics), FLAVIVIRUSES

Abstract

Mutational correlation patterns found in population-level sequence data for the Human Immunodeficiency Virus (HIV) and the Hepatitis C Virus (HCV) have been demonstrated to be informative of viral fitness. Such patterns can be seen as footprints of the intrinsic functional constraints placed on viral evolution under diverse selective pressures. Here, considering multiple HIV and HCV proteins, we demonstrate that these mutational correlations encode a modular co-evolutionary structure that is tightly linked to the structural and functional properties of the respective proteins. Specifically, by introducing a robust statistical method based on sparse principal component analysis, we identify near-disjoint sets of collectively-correlated residues (sectors) having mostly a one-to-one association to largely distinct structural or functional domains. This suggests that the distinct phenotypic properties of HIV/HCV proteins often give rise to quasi-independent modes of evolution, with each mode involving a sparse and localized network of mutational interactions. Moreover, individual inferred sectors of HIV are shown to carry immunological significance, providing insight for guiding targeted vaccine strategies. [ABSTRACT FROM AUTHOR]

Published

2018

16. RosettaAntibodyDesign (RAbD): A general framework for computational antibody design.

Author

Adolf-Bryfogle, Jared, Kalyuzhniy, Oleks, Kubitz, Michael, Weitzner, Brian D., Hu, Xiaozhen, Adachi, Yumiko, Schief, William R., and Jr.Dunbrack, Roland L.

Subjects

IMMUNOGLOBULINS, EPITOPES, ANTIGENS, AMINO acids, MONOCLONAL antibodies

Abstract

A structural-bioinformatics-based computational methodology and framework have been developed for the design of antibodies to targets of interest. RosettaAntibodyDesign (RAbD) samples the diverse sequence, structure, and binding space of an antibody to an antigen in highly customizable protocols for the design of antibodies in a broad range of applications. The program samples antibody sequences and structures by grafting structures from a widely accepted set of the canonical clusters of CDRs (North et al., J. Mol. Biol., 406:228–256, 2011). It then performs sequence design according to amino acid sequence profiles of each cluster, and samples CDR backbones using a flexible-backbone design protocol incorporating cluster-based CDR constraints. Starting from an existing experimental or computationally modeled antigen-antibody structure, RAbD can be used to redesign a single CDR or multiple CDRs with loops of different length, conformation, and sequence. We rigorously benchmarked RAbD on a set of 60 diverse antibody–antigen complexes, using two design strategies—optimizing total Rosetta energy and optimizing interface energy alone. We utilized two novel metrics for measuring success in computational protein design. The design risk ratio (DRR) is equal to the frequency of recovery of native CDR lengths and clusters divided by the frequency of sampling of those features during the Monte Carlo design procedure. Ratios greater than 1.0 indicate that the design process is picking out the native more frequently than expected from their sampled rate. We achieved DRRs for the non-H3 CDRs of between 2.4 and 4.0. The antigen risk ratio (ARR) is the ratio of frequencies of the native amino acid types, CDR lengths, and clusters in the output decoys for simulations performed in the presence and absence of the antigen. For CDRs, we achieved cluster ARRs as high as 2.5 for L1 and 1.5 for H2. For sequence design simulations without CDR grafting, the overall recovery for the native amino acid types for residues that contact the antigen in the native structures was 72% in simulations performed in the presence of the antigen and 48% in simulations performed without the antigen, for an ARR of 1.5. For the non-contacting residues, the ARR was 1.08. This shows that the sequence profiles are able to maintain the amino acid types of these conserved, buried sites, while recovery of the exposed, contacting residues requires the presence of the antigen-antibody interface. We tested RAbD experimentally on both a lambda and kappa antibody–antigen complex, successfully improving their affinities 10 to 50 fold by replacing individual CDRs of the native antibody with new CDR lengths and clusters. [ABSTRACT FROM AUTHOR]

Published

2018

17. Improving pairwise comparison of protein sequences with domain co-occurrence.

Author

Menichelli, Christophe, Gascuel, Olivier, and Bréhélin, Laurent

Subjects

AMINO acid sequence, BIOINFORMATICS, PHYLOGENY, PLASMODIUM falciparum, PROTEIN analysis

Abstract

Comparing and aligning protein sequences is an essential task in bioinformatics. More specifically, local alignment tools like BLAST are widely used for identifying conserved protein sub-sequences, which likely correspond to protein domains or functional motifs. However, to limit the number of false positives, these tools are used with stringent sequence-similarity thresholds and hence can miss several hits, especially for species that are phylogenetically distant from reference organisms. A solution to this problem is then to integrate additional contextual information to the procedure. Here, we propose to use domain co-occurrence to increase the sensitivity of pairwise sequence comparisons. Domain co-occurrence is a strong feature of proteins, since most protein domains tend to appear with a limited number of other domains on the same protein. We propose a method to take this information into account in a typical BLAST analysis and to construct new domain families on the basis of these results. We used Plasmodium falciparum as a case study to evaluate our method. The experimental findings showed an increase of 14% of the number of significant BLAST hits and an increase of 25% of the proteome area that can be covered with a domain. Our method identified 2240 new domains for which, in most cases, no model of the Pfam database could be linked. Moreover, our study of the quality of the new domains in terms of alignment and physicochemical properties show that they are close to that of standard Pfam domains. Source code of the proposed approach and supplementary data are available at: [ABSTRACT FROM AUTHOR]

Published

2018

18. Computational-experimental approach to drug-target interaction mapping: A case study on kinase inhibitors.

Author

Cichonska, Anna, Ravikumar, Balaguru, Parri, Elina, Timonen, Sanna, Pahikkala, Tapio, Airola, Antti, Wennerberg, Krister, Rousu, Juho, and Aittokallio, Tero

Subjects

KINASE inhibitors, CHEMICALS, MACHINE learning, REGRESSION analysis, THREONINE

Abstract

Due to relatively high costs and labor required for experimental profiling of the full target space of chemical compounds, various machine learning models have been proposed as cost-effective means to advance this process in terms of predicting the most potent compound-target interactions for subsequent verification. However, most of the model predictions lack direct experimental validation in the laboratory, making their practical benefits for drug discovery or repurposing applications largely unknown. Here, we therefore introduce and carefully test a systematic computational-experimental framework for the prediction and pre-clinical verification of drug-target interactions using a well-established kernel-based regression algorithm as the prediction model. To evaluate its performance, we first predicted unmeasured binding affinities in a large-scale kinase inhibitor profiling study, and then experimentally tested 100 compound-kinase pairs. The relatively high correlation of 0.77 (p < 0.0001) between the predicted and measured bioactivities supports the potential of the model for filling the experimental gaps in existing compound-target interaction maps. Further, we subjected the model to a more challenging task of predicting target interactions for such a new candidate drug compound that lacks prior binding profile information. As a specific case study, we used tivozanib, an investigational VEGF receptor inhibitor with currently unknown off-target profile. Among 7 kinases with high predicted affinity, we experimentally validated 4 new off-targets of tivozanib, namely the Src-family kinases FRK and FYN A, the non-receptor tyrosine kinase ABL1, and the serine/threonine kinase SLK. Our sub-sequent experimental validation protocol effectively avoids any possible information leakage between the training and validation data, and therefore enables rigorous model validation for practical applications. These results demonstrate that the kernel-based modeling approach offers practical benefits for probing novel insights into the mode of action of investigational compounds, and for the identification of new target selectivities for drug repurposing applications. [ABSTRACT FROM AUTHOR]

Published

2017

19. Inherent limitations of probabilistic models for protein-DNA binding specificity.

Author

Ruan, Shuxiang and Stormo, Gary D.

Subjects

DNA-protein interactions, DNA-binding proteins, TRANSCRIPTION factors, BIOPHYSICAL labeling, GENE expression

Abstract

The specificities of transcription factors are most commonly represented with probabilistic models. These models provide a probability for each base occurring at each position within the binding site and the positions are assumed to contribute independently. The model is simple and intuitive and is the basis for many motif discovery algorithms. However, the model also has inherent limitations that prevent it from accurately representing true binding probabilities, especially for the highest affinity sites under conditions of high protein concentration. The limitations are not due to the assumption of independence between positions but rather are caused by the non-linear relationship between binding affinity and binding probability and the fact that independent normalization at each position skews the site probabilities. Generally probabilistic models are reasonably good approximations, but new high-throughput methods allow for biophysical models with increased accuracy that should be used whenever possible. [ABSTRACT FROM AUTHOR]

Published

2017

20. Metagenome and Metatranscriptome Analyses Using Protein Family Profiles.

Author

Zhong, Cuncong, Edlund, Anna, Yang, Youngik, McLean, Jeffrey S., and Yooseph, Shibu

Subjects

METABOLIC profile tests, GENE expression, MARKOV processes, ANTI-infective agents, NUCLEOTIDE sequence, ESTIMATION theory

Abstract

Analyses of metagenome data (MG) and metatranscriptome data (MT) are often challenged by a paucity of complete reference genome sequences and the uneven/low sequencing depth of the constituent organisms in the microbial community, which respectively limit the power of reference-based alignment and de novo sequence assembly. These limitations make accurate protein family classification and abundance estimation challenging, which in turn hamper downstream analyses such as abundance profiling of metabolic pathways, identification of differentially encoded/expressed genes, and de novo reconstruction of complete gene and protein sequences from the protein family of interest. The profile hidden Markov model (HMM) framework enables the construction of very useful probabilistic models for protein families that allow for accurate modeling of position specific matches, insertions, and deletions. We present a novel homology detection algorithm that integrates banded Viterbi algorithm for profile HMM parsing with an iterative simultaneous alignment and assembly computational framework. The algorithm searches a given profile HMM of a protein family against a database of fragmentary MG/MT sequencing data and simultaneously assembles complete or near-complete gene and protein sequences of the protein family. The resulting program, HMM-GRASPx, demonstrates superior performance in aligning and assembling homologs when benchmarked on both simulated marine MG and real human saliva MG datasets. On real supragingival plaque and stool MG datasets that were generated from healthy individuals, HMM-GRASPx accurately estimates the abundances of the antimicrobial resistance (AMR) gene families and enables accurate characterization of the resistome profiles of these microbial communities. For real human oral microbiome MT datasets, using the HMM-GRASPx estimated transcript abundances significantly improves detection of differentially expressed (DE) genes. Finally, HMM-GRASPx was used to reconstruct comprehensive sets of complete or near-complete protein and nucleotide sequences for the query protein families. HMM-GRASPx is freely available online from . [ABSTRACT FROM AUTHOR]

Published

2016

21. Evolution-Based Functional Decomposition of Proteins.

Author

Rivoire, Olivier, Reynolds, Kimberly A., and Ranganathan, Rama

Subjects

BIODEGRADATION, AMINO acids, PROTEINS, COEVOLUTION, INTEGRATED software, PYTHON programming language

Abstract

The essential biological properties of proteins—folding, biochemical activities, and the capacity to adapt—arise from the global pattern of interactions between amino acid residues. The statistical coupling analysis (SCA) is an approach to defining this pattern that involves the study of amino acid coevolution in an ensemble of sequences comprising a protein family. This approach indicates a functional architecture within proteins in which the basic units are coupled networks of amino acids termed sectors. This evolution-based decomposition has potential for new understandings of the structural basis for protein function. To facilitate its usage, we present here the principles and practice of the SCA and introduce new methods for sector analysis in a python-based software package (pySCA). We show that the pattern of amino acid interactions within sectors is linked to the divergence of functional lineages in a multiple sequence alignment—a model for how sector properties might be differentially tuned in members of a protein family. This work provides new tools for studying proteins and for generally testing the concept of sectors as the principal units of function and adaptive variation. [ABSTRACT FROM AUTHOR]

Published

2016

22. Effective Design of Multifunctional Peptides by Combining Compatible Functions.

Author

Diener, Christian, Garza Ramos Martínez, Georgina, Moreno Blas, Daniel, Castillo González, David A., Corzo, Gerardo, Castro-Obregon, Susana, and Del Rio, Gabriel

Subjects

PEPTIDE antibiotics, DNA-binding proteins, CELL-penetrating peptides, MACHINE learning, PHEROMONES

Abstract

Multifunctionality is a common trait of many natural proteins and peptides, yet the rules to generate such multifunctionality remain unclear. We propose that the rules defining some protein/peptide functions are compatible. To explore this hypothesis, we trained a computational method to predict cell-penetrating peptides at the sequence level and learned that antimicrobial peptides and DNA-binding proteins are compatible with the rules of our predictor. Based on this finding, we expected that designing peptides for CPP activity may render AMP and DNA-binding activities. To test this prediction, we designed peptides that embedded two independent functional domains (nuclear localization and yeast pheromone activity), linked by optimizing their composition to fit the rules characterizing cell-penetrating peptides. These peptides presented effective cell penetration, DNA-binding, pheromone and antimicrobial activities, thus confirming the effectiveness of our computational approach to design multifunctional peptides with potential therapeutic uses. Our computational implementation is available at . [ABSTRACT FROM AUTHOR]

Published

2016

23. A Multi-Method Approach for Proteomic Network Inference in 11 Human Cancers.

Author

Şenbabaoğlu, Yasin, Sümer, Selçuk Onur, Sánchez-Vega, Francisco, Bemis, Debra, Ciriello, Giovanni, Schultz, Nikolaus, and Sander, Chris

Subjects

PROTEOMICS, PROTEIN expression, PROTEIN microarrays, PROTEIN-protein interactions, CANCER research

Abstract

Protein expression and post-translational modification levels are tightly regulated in neoplastic cells to maintain cellular processes known as ‘cancer hallmarks’. The first Pan-Cancer initiative of The Cancer Genome Atlas (TCGA) Research Network has aggregated protein expression profiles for 3,467 patient samples from 11 tumor types using the antibody based reverse phase protein array (RPPA) technology. The resultant proteomic data can be utilized to computationally infer protein-protein interaction (PPI) networks and to study the commonalities and differences across tumor types. In this study, we compare the performance of 13 established network inference methods in their capacity to retrieve the curated Pathway Commons interactions from RPPA data. We observe that no single method has the best performance in all tumor types, but a group of six methods, including diverse techniques such as correlation, mutual information, and regression, consistently rank highly among the tested methods. We utilize the high performing methods to obtain a consensus network; and identify four robust and densely connected modules that reveal biological processes as well as suggest antibody–related technical biases. Mapping the consensus network interactions to Reactome gene lists confirms the pan-cancer importance of signal transduction pathways, innate and adaptive immune signaling, cell cycle, metabolism, and DNA repair; and also suggests several biological processes that may be specific to a subset of tumor types. Our results illustrate the utility of the RPPA platform as a tool to study proteomic networks in cancer. [ABSTRACT FROM AUTHOR]

Published

2016

24. Improved Contact Predictions Using the Recognition of Protein Like Contact Patterns.

Author

Skwark, Marcin J., Raimondi, Daniele, Michel, Mirco, and Elofsson, Arne

Subjects

PROTEIN-protein interactions, COMPUTATIONAL biology, INFERENTIAL statistics, MACHINE learning, PROTEIN structure, PROTEIN folding

Abstract

Given sufficient large protein families, and using a global statistical inference approach, it is possible to obtain sufficient accuracy in protein residue contact predictions to predict the structure of many proteins. However, these approaches do not consider the fact that the contacts in a protein are neither randomly, nor independently distributed, but actually follow precise rules governed by the structure of the protein and thus are interdependent. Here, we present PconsC2, a novel method that uses a deep learning approach to identify protein-like contact patterns to improve contact predictions. A substantial enhancement can be seen for all contacts independently on the number of aligned sequences, residue separation or secondary structure type, but is largest for β-sheet containing proteins. In addition to being superior to earlier methods based on statistical inferences, in comparison to state of the art methods using machine learning, PconsC2 is superior for families with more than 100 effective sequence homologs. The improved contact prediction enables improved structure prediction. [ABSTRACT FROM AUTHOR]

Published

2014

25. Identifying individual risk rare variants using protein structure guided local tests (POINT)

Author

Sheng Mao Chang, Jung-Ying Tzeng, Denis Fourches, Daniel M. Rotroff, Mélaine A. Kuenemann, John B. Buse, Wenbin Lu, Michael J. Wagner, Michael C. Wu, Alison A. Motsinger-Reif, and Rachel Marceau West

Subjects

0301 basic medicine, Proteomics, Heredity, Computer science, Kernel Functions, Test Statistics, Inference, Biochemistry, Database and Informatics Methods, Protein Structure Databases, 0302 clinical medicine, Mathematical and Statistical Techniques, Risk Factors, Macromolecular Structure Analysis, Biochemical Simulations, Biology (General), Operator Theory, Ecology, Proteomic Databases, Statistics, Genetic Mapping, Kernel method, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Structural Proteins, Proprotein Convertase 9, Research Article, Protein Structure, QH301-705.5, Association (object-oriented programming), Variant Genotypes, Computational biology, Research and Analysis Methods, Ranking (information retrieval), 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, Angiopoietin-Like Protein 4, Humans, Computer Simulation, Genetic Predisposition to Disease, Statistical Methods, Set (psychology), Molecular Biology, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Genetic Association Studies, Genetic association, Statistical hypothesis testing, Models, Genetic, Biology and Life Sciences, Proteins, Computational Biology, Genetic Variation, Sequence Analysis, DNA, Cholesterol Ester Transfer Proteins, Protein Structure, Tertiary, 030104 developmental biology, Biological Databases, 030217 neurology & neurosurgery, Mathematics

Abstract

Rare variants are of increasing interest to genetic association studies because of their etiological contributions to human complex diseases. Due to the rarity of the mutant events, rare variants are routinely analyzed on an aggregate level. While aggregation analyses improve the detection of global-level signal, they are not able to pinpoint causal variants within a variant set. To perform inference on a localized level, additional information, e.g., biological annotation, is often needed to boost the information content of a rare variant. Following the observation that important variants are likely to cluster together on functional domains, we propose a protein structure guided local test (POINT) to provide variant-specific association information using structure-guided aggregation of signal. Constructed under a kernel machine framework, POINT performs local association testing by borrowing information from neighboring variants in the 3-dimensional protein space in a data-adaptive fashion. Besides merely providing a list of promising variants, POINT assigns each variant a p-value to permit variant ranking and prioritization. We assess the selection performance of POINT using simulations and illustrate how it can be used to prioritize individual rare variants in PCSK9, ANGPTL4 and CETP in the Action to Control Cardiovascular Risk in Diabetes (ACCORD) clinical trial data., Author summary While it is known that rare variants play an important role in understanding associations between genotype and complex diseases, pinpointing individual rare variants likely to be responsible for association is still a daunting task. Due to their low frequency in the population and reduced signal, localizing causal rare variants often requires additional information, such as type of DNA change or location of variant along the sequence, to be incorporated in a biologically meaningful fashion that does not overpower the genotype data. In this paper, we use the observation that important variants tend to cluster together on functional domains to propose a new approach for prioritizing rare variants: the protein structure guided local test (POINT). POINT uses a gene’s 3-dimensional protein folding structure to guide aggregation of information from neighboring variants in the protein in a robust manner. We show how POINT improves selection performance over existing methods. We further illustrate how it can be used to prioritize individual rare variants using the Action to Control Cardiovascular Risk in Diabetes (ACCORD) clinical trial data, finding promising variants within genes in association with lipoprotein-related outcomes.

Published

2019

26. Accurate De Novo Prediction of Protein Contact Map by Ultra-Deep Learning Model

Author

Jinbo Xu, Sheng Wang, Siqi Sun, Zhen Li, and Renyu Zhang

Subjects

0301 basic medicine, FOS: Computer and information sciences, Computer science, Protein Conformation, Cell Membranes, Protein Structure Prediction, computer.software_genre, Residual, Quantitative Biology - Quantitative Methods, Biochemistry, Machine Learning (cs.LG), Machine Learning, Database and Informatics Methods, Protein Structure Databases, Protein structure, Mathematical and Statistical Techniques, Statistics - Machine Learning, Protein methods, Sequence Analysis, Protein, Macromolecular Structure Analysis, Databases, Protein, lcsh:QH301-705.5, Quantitative Methods (q-bio.QM), 0303 health sciences, Artificial neural network, Ecology, 030302 biochemistry & molecular biology, Protein structure prediction, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Protein folding, Data mining, Cellular Structures and Organelles, Biological system, Algorithm, Algorithms, Statistics (Mathematics), Research Article, Protein Structure, Computer and Information Sciences, Multiple Alignment Calculation, Neural Networks, Protein contact map, Machine Learning (stat.ML), Research and Analysis Methods, 03 medical and health sciences, Cellular and Molecular Neuroscience, Computational Techniques, Genetics, Homology modeling, Statistical Methods, CASP, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, business.industry, Deep learning, Computational Biology, Proteins, Biology and Life Sciences, Membrane Proteins, Biomolecules (q-bio.BM), Cell Biology, Split-Decomposition Method, Convolution, Computer Science - Learning, 030104 developmental biology, Biological Databases, Membrane protein, Quantitative Biology - Biomolecules, De novo protein structure prediction, lcsh:Biology (General), FOS: Biological sciences, Artificial intelligence, Neural Networks, Computer, business, computer, Mathematical Functions, Mathematics, Neuroscience, Forecasting

Abstract

Motivation Protein contacts contain key information for the understanding of protein structure and function and thus, contact prediction from sequence is an important problem. Recently exciting progress has been made on this problem, but the predicted contacts for proteins without many sequence homologs is still of low quality and not very useful for de novo structure prediction. Method This paper presents a new deep learning method that predicts contacts by integrating both evolutionary coupling (EC) and sequence conservation information through an ultra-deep neural network formed by two deep residual neural networks. The first residual network conducts a series of 1-dimensional convolutional transformation of sequential features; the second residual network conducts a series of 2-dimensional convolutional transformation of pairwise information including output of the first residual network, EC information and pairwise potential. By using very deep residual networks, we can accurately model contact occurrence patterns and complex sequence-structure relationship and thus, obtain higher-quality contact prediction regardless of how many sequence homologs are available for proteins in question. Results Our method greatly outperforms existing methods and leads to much more accurate contact-assisted folding. Tested on 105 CASP11 targets, 76 past CAMEO hard targets, and 398 membrane proteins, the average top L long-range prediction accuracy obtained by our method, one representative EC method CCMpred and the CASP11 winner MetaPSICOV is 0.47, 0.21 and 0.30, respectively; the average top L/10 long-range accuracy of our method, CCMpred and MetaPSICOV is 0.77, 0.47 and 0.59, respectively. Ab initio folding using our predicted contacts as restraints but without any force fields can yield correct folds (i.e., TMscore>0.6) for 203 of the 579 test proteins, while that using MetaPSICOV- and CCMpred-predicted contacts can do so for only 79 and 62 of them, respectively. Our contact-assisted models also have much better quality than template-based models especially for membrane proteins. The 3D models built from our contact prediction have TMscore>0.5 for 208 of the 398 membrane proteins, while those from homology modeling have TMscore>0.5 for only 10 of them. Further, even if trained mostly by soluble proteins, our deep learning method works very well on membrane proteins. In the recent blind CAMEO benchmark, our fully-automated web server implementing this method successfully folded 6 targets with a new fold and only 0.3L-2.3L effective sequence homologs, including one β protein of 182 residues, one α+β protein of 125 residues, one α protein of 140 residues, one α protein of 217 residues, one α/β of 260 residues and one α protein of 462 residues. Our method also achieved the highest F1 score on free-modeling targets in the latest CASP (Critical Assessment of Structure Prediction), although it was not fully implemented back then. Availability http://raptorx.uchicago.edu/ContactMap/, Author Summary Protein contact prediction and contact-assisted folding has made good progress due to direct evolutionary coupling analysis (DCA). However, DCA is effective on only some proteins with a very large number of sequence homologs. To further improve contact prediction, we borrow ideas from deep learning, which has recently revolutionized object recognition, speech recognition and the GO game. Our deep learning method can model complex sequence-structure relationship and high-order correlation (i.e., contact occurrence patterns) and thus, improve contact prediction accuracy greatly. Our test results show that our method greatly outperforms the state-of-the-art methods regardless how many sequence homologs are available for a protein in question. Ab initio folding guided by our predicted contacts may fold many more test proteins than the other contact predictors. Our contact-assisted 3D models also have much better quality than homology models built from the training proteins, especially for membrane proteins. One interesting finding is that even trained mostly with soluble proteins, our method performs very well on membrane proteins. Recent blind CAMEO test confirms that our method can fold large proteins with a new fold and only a small number of sequence homologs.

Published

2017

27. A knowledge-based T2-statistic to perform pathway analysis for quantitative proteomic data

Author

Yi Hau Chen, En Yu Lai, and Kun Pin Wu

Subjects

Proteomics, 0301 basic medicine, Cell signaling, Proteome, Knowledge Bases, Protein Expression, Gene Expression, Signal transduction, computer.software_genre, Biochemistry, Database and Informatics Methods, 0302 clinical medicine, False positive paradox, Post-Translational Modification, Phosphorylation, lcsh:QH301-705.5, Cytoskeleton, Statistic, Cellular localization, Covariance, TCR signaling cascade, Ecology, Proteomic Databases, Covariance matrix, Signaling cascades, Computational Theory and Mathematics, Null (SQL), Data Interpretation, Statistical, 030220 oncology & carcinogenesis, Modeling and Simulation, Physical Sciences, Data mining, Cellular Structures and Organelles, Algorithms, Research Article, Cell biology, MAPK signaling cascades, Biology, Research and Analysis Methods, Models, Biological, 03 medical and health sciences, Cellular and Molecular Neuroscience, Gene Expression and Vector Techniques, Genetics, Test statistic, Computer Simulation, Molecular Biology Techniques, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Molecular Biology Assays and Analysis Techniques, Models, Statistical, Biology and life sciences, Proteins, Random Variables, Probability Theory, Biological Databases, 030104 developmental biology, lcsh:Biology (General), Sample size determination, computer, Mathematics

Abstract

Approaches to identify significant pathways from high-throughput quantitative data have been developed in recent years. Still, the analysis of proteomic data stays difficult because of limited sample size. This limitation also leads to the practice of using a competitive null as common approach; which fundamentally implies genes or proteins as independent units. The independent assumption ignores the associations among biomolecules with similar functions or cellular localization, as well as the interactions among them manifested as changes in expression ratios. Consequently, these methods often underestimate the associations among biomolecules and cause false positives in practice. Some studies incorporate the sample covariance matrix into the calculation to address this issue. However, sample covariance may not be a precise estimation if the sample size is very limited, which is usually the case for the data produced by mass spectrometry. In this study, we introduce a multivariate test under a self-contained null to perform pathway analysis for quantitative proteomic data. The covariance matrix used in the test statistic is constructed by the confidence scores retrieved from the STRING database or the HitPredict database. We also design an integrating procedure to retain pathways of sufficient evidence as a pathway group. The performance of the proposed T2-statistic is demonstrated using five published experimental datasets: the T-cell activation, the cAMP/PKA signaling, the myoblast differentiation, and the effect of dasatinib on the BCR-ABL pathway are proteomic datasets produced by mass spectrometry; and the protective effect of myocilin via the MAPK signaling pathway is a gene expression dataset of limited sample size. Compared with other popular statistics, the proposed T2-statistic yields more accurate descriptions in agreement with the discussion of the original publication. We implemented the T2-statistic into an R package T2GA, which is available at https://github.com/roqe/T2GA., Author summary Pathway analysis is a common approach to quickly access the pathways being regulated in the experiments. There are numerous statistics to perform pathway analysis; most of them assume that the genes or proteins are independent of each other for statistical ease. This assumption, however, is unrealistic to the real biological system and may cause false positives in practice. A standard way to address this issue is to measure the associations among genes or proteins. Unfortunately, the estimation of associations requires sufficient sample size, which is usually not available for proteomic data produced by mass spectrometry. In this study, we propose a T2-statistic, which estimates the associations among gene products, to perform pathway analysis for quantitative proteomic data. Instead of calculating the associations directly from data, we use the confidence scores retrieved from protein-protein interaction databases. We also design an integrating procedure to reserve pathways of sufficient evidence as a regulated pathway group. We compare the proposed T2-statistic to other popular statistics using five published experimental datasets, and the T2-statistic yields more accurate descriptions in agreement with the discussion of the original papers.

Published

2017

28. Amino acid composition predicts prion activity

Author

Asa Ben-Hur, Eric D. Ross, and Fayyaz ul Amir Afsar Minhas

Subjects

0301 basic medicine, Proteomes, Glutamine, Yeast and Fungal Models, Biochemistry, Prion Diseases, Machine Learning, Database and Informatics Methods, Yeasts, Zoonoses, Medicine and Health Sciences, QD, Asparagine, Computational analysis, lcsh:QH301-705.5, Peptide sequence, Mathematics, Ecology, Infectious Diseases, Experimental Organism Systems, Computational Theory and Mathematics, Amino acid composition, Modeling and Simulation, Saccharomyces Cerevisiae, Primary sequence, Sequence Analysis, Research Article, Amyloid, Computer and Information Sciences, Prions, Bioinformatics, Computational biology, Research and Analysis Methods, QA76, Saccharomyces, 03 medical and health sciences, Cellular and Molecular Neuroscience, Model Organisms, Protein Domains, Amino Acid Sequence Analysis, Artificial Intelligence, Support Vector Machines, Genetics, Code (cryptography), Humans, Amino Acid Sequence, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Sequence (medicine), Organisms, Fungi, Computational Biology, Biology and Life Sciences, Proteins, Composition (combinatorics), QP, Yeast, 030104 developmental biology, lcsh:Biology (General)

Abstract

Many prion-forming proteins contain glutamine/asparagine (Q/N) rich domains, and there are conflicting opinions as to the role of primary sequence in their conversion to the prion form: is this phenomenon driven primarily by amino acid composition, or, as a recent computational analysis suggested, dependent on the presence of short sequence elements with high amyloid-forming potential. The argument for the importance of short sequence elements hinged on the relatively-high accuracy obtained using a method that utilizes a collection of length-six sequence elements with known amyloid-forming potential. We weigh in on this question and demonstrate that when those sequence elements are permuted, even higher accuracy is obtained; we also propose a novel multiple-instance machine learning method that uses sequence composition alone, and achieves better accuracy than all existing prion prediction approaches. While we expect there to be elements of primary sequence that affect the process, our experiments suggest that sequence composition alone is sufficient for predicting protein sequences that are likely to form prions. A web-server for the proposed method is available at http://faculty.pieas.edu.pk/fayyaz/prank.html, and the code for reproducing our experiments is available at http://doi.org/10.5281/zenodo.167136., Author summary The determinants of prion formation in proteins that are rich in glutamine and asparagine are still under debate: is the process driven by primary sequence or by amino acid composition? In 2015 Sabate et al. published a paper suggesting that the process is triggered by short amyloid-prone sequences. Their argument was based on the success of their pWALTZ classifier, which uses a database of short peptides with known amyloid forming propensities. To explore the validity of their argument we compared their original scoring matrices with shuffled scoring matrices, and found no decrease in accuracy, suggesting that the success of pWALTZ is the result of the ability of the scoring matrices to capture amino acid composition. Furthermore, we propose a novel machine learning approach with accuracy that is superior to all published prion prediction methods that are currently available, and uses sequence composition alone.

Published

2017