Your search keyword '"Zou, Quan"' showing total 21 results

1. Sequence homology score-based deep fuzzy network for identifying therapeutic peptides.

Author

Guo X, Zheng Z, Cheong KH, Zou Q, Tiwari P, and Ding Y

Subjects

Computational Biology methods, Humans, Deep Learning, Area Under Curve, ROC Curve, Algorithms, Fuzzy Logic, Peptides, Neural Networks, Computer

Abstract

The detection of therapeutic peptides is a topic of immense interest in the biomedical field. Conventional biochemical experiment-based detection techniques are tedious and time-consuming. Computational biology has become a useful tool for improving the detection efficiency of therapeutic peptides. Most computational methods do not consider the deviation caused by noise. To improve the generalization performance of therapeutic peptide prediction methods, this work presents a sequence homology score-based deep fuzzy echo-state network with maximizing mixture correntropy (SHS-DFESN-MMC) model. Our method is compared with the existing methods on eight types of therapeutic peptide datasets. The model parameters are determined by 10 fold cross-validation on their training sets and verified by independent test sets. Across the 8 datasets, the average area under the receiver operating characteristic curve (AUC) values of SHS-DFESN-MMC are the highest on both the training (0.926) and independent sets (0.923)., Competing Interests: Declaration of competing interest The authors declare no conflict of interests, (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

2. Integrated convolution and self-attention for improving peptide toxicity prediction.

Author

Jiao S, Ye X, Sakurai T, Zou Q, and Liu R

Subjects

Humans, Amino Acid Sequence, Algorithms, Software, Peptides chemistry, Computational Biology methods

Abstract

Motivation: Peptides are promising agents for the treatment of a variety of diseases due to their specificity and efficacy. However, the development of peptide-based drugs is often hindered by the potential toxicity of peptides, which poses a significant barrier to their clinical application. Traditional experimental methods for evaluating peptide toxicity are time-consuming and costly, making the development process inefficient. Therefore, there is an urgent need for computational tools specifically designed to predict peptide toxicity accurately and rapidly, facilitating the identification of safe peptide candidates for drug development., Results: We provide here a novel computational approach, CAPTP, which leverages the power of convolutional and self-attention to enhance the prediction of peptide toxicity from amino acid sequences. CAPTP demonstrates outstanding performance, achieving a Matthews correlation coefficient of approximately 0.82 in both cross-validation settings and on independent test datasets. This performance surpasses that of existing state-of-the-art peptide toxicity predictors. Importantly, CAPTP maintains its robustness and generalizability even when dealing with data imbalances. Further analysis by CAPTP reveals that certain sequential patterns, particularly in the head and central regions of peptides, are crucial in determining their toxicity. This insight can significantly inform and guide the design of safer peptide drugs., Availability and Implementation: The source code for CAPTP is freely available at https://github.com/jiaoshihu/CAPTP., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

3. Deepstacked-AVPs: predicting antiviral peptides using tri-segment evolutionary profile and word embedding based multi-perspective features with deep stacking model.

Author

Akbar S, Raza A, and Zou Q

Subjects

Humans, Reproducibility of Results, Antiviral Agents pharmacology, Peptides chemistry, Biological Evolution

Abstract

Background: Viral infections have been the main health issue in the last decade. Antiviral peptides (AVPs) are a subclass of antimicrobial peptides (AMPs) with substantial potential to protect the human body against various viral diseases. However, there has been significant production of antiviral vaccines and medications. Recently, the development of AVPs as an antiviral agent suggests an effective way to treat virus-affected cells. Recently, the involvement of intelligent machine learning techniques for developing peptide-based therapeutic agents is becoming an increasing interest due to its significant outcomes. The existing wet-laboratory-based drugs are expensive, time-consuming, and cannot effectively perform in screening and predicting the targeted motif of antiviral peptides., Methods: In this paper, we proposed a novel computational model called Deepstacked-AVPs to discriminate AVPs accurately. The training sequences are numerically encoded using a novel Tri-segmentation-based position-specific scoring matrix (PSSM-TS) and word2vec-based semantic features. Composition/Transition/Distribution-Transition (CTDT) is also employed to represent the physiochemical properties based on structural features. Apart from these, the fused vector is formed using PSSM-TS features, semantic information, and CTDT descriptors to compensate for the limitations of single encoding methods. Information gain (IG) is applied to choose the optimal feature set. The selected features are trained using a stacked-ensemble classifier., Results: The proposed Deepstacked-AVPs model achieved a predictive accuracy of 96.60%%, an area under the curve (AUC) of 0.98, and a precision-recall (PR) value of 0.97 using training samples. In the case of the independent samples, our model obtained an accuracy of 95.15%, an AUC of 0.97, and a PR value of 0.97., Conclusion: Our Deepstacked-AVPs model outperformed existing models with a ~ 4% and ~ 2% higher accuracy using training and independent samples, respectively. The reliability and efficacy of the proposed Deepstacked-AVPs model make it a valuable tool for scientists and may perform a beneficial role in pharmaceutical design and research academia., (© 2024. The Author(s).)

Published

2024

4. FEOpti-ACVP: identification of novel anti-coronavirus peptide sequences based on feature engineering and optimization.

Author

Jiang J, Pei H, Li J, Li M, Zou Q, and Lv Z

Subjects

Humans, Amino Acid Sequence, Machine Learning, Peptides pharmacology, Algorithms

Abstract

Anti-coronavirus peptides (ACVPs) represent a relatively novel approach of inhibiting the adsorption and fusion of the virus with human cells. Several peptide-based inhibitors showed promise as potential therapeutic drug candidates. However, identifying such peptides in laboratory experiments is both costly and time consuming. Therefore, there is growing interest in using computational methods to predict ACVPs. Here, we describe a model for the prediction of ACVPs that is based on the combination of feature engineering (FE) optimization and deep representation learning. FEOpti-ACVP was pre-trained using two feature extraction frameworks. At the next step, several machine learning approaches were tested in to construct the final algorithm. The final version of FEOpti-ACVP outperformed existing methods used for ACVPs prediction and it has the potential to become a valuable tool in ACVP drug design. A user-friendly webserver of FEOpti-ACVP can be accessed at http://servers.aibiochem.net/soft/FEOpti-ACVP/., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

5. AIPs-SnTCN: Predicting Anti-Inflammatory Peptides Using fastText and Transformer Encoder-Based Hybrid Word Embedding with Self-Normalized Temporal Convolutional Networks.

Author

Raza A, Uddin J, Almuhaimeed A, Akbar S, Zou Q, and Ahmad A

Subjects

Humans, Reproducibility of Results, Inflammation drug therapy, Support Vector Machine, Peptides pharmacology, Peptides chemistry, Anti-Inflammatory Agents

Abstract

Inflammation is a biologically resistant response to harmful stimuli, such as infection, damaged cells, toxic chemicals, or tissue injuries. Its purpose is to eradicate pathogenic micro-organisms or irritants and facilitate tissue repair. Prolonged inflammation can result in chronic inflammatory diseases. However, wet-laboratory-based treatments are costly and time-consuming and may have adverse side effects on normal cells. In the past decade, peptide therapeutics have gained significant attention due to their high specificity in targeting affected cells without affecting healthy cells. Motivated by the significance of peptide-based therapies, we developed a highly discriminative prediction model called AIPs-SnTCN to predict anti-inflammatory peptides accurately. The peptide samples are encoded using word embedding techniques such as skip-gram and attention-based bidirectional encoder representation using a transformer (BERT). The conjoint triad feature (CTF) also collects structure-based cluster profile features. The fused vector of word embedding and sequential features is formed to compensate for the limitations of single encoding methods. Support vector machine-based recursive feature elimination (SVM-RFE) is applied to choose the ranking-based optimal space. The optimized feature space is trained by using an improved self-normalized temporal convolutional network (SnTCN). The AIPs-SnTCN model achieved a predictive accuracy of 95.86% and an AUC of 0.97 by using training samples. In the case of the alternate training data set, our model obtained an accuracy of 92.04% and an AUC of 0.96. The proposed AIPs-SnTCN model outperformed existing models with an ∼19% higher accuracy and an ∼14% higher AUC value. The reliability and efficacy of our AIPs-SnTCN model make it a valuable tool for scientists and may play a beneficial role in pharmaceutical design and research academia.

Published

2023

6. Explainable Deep Hypergraph Learning Modeling the Peptide Secondary Structure Prediction.

Author

Jiang Y, Wang R, Feng J, Jin J, Liang S, Li Z, Yu Y, Ma A, Su R, Zou Q, Ma Q, and Wei L

Subjects

Peptides

Abstract

Accurately predicting peptide secondary structures remains a challenging task due to the lack of discriminative information in short peptides. In this study, PHAT is proposed, a deep hypergraph learning framework for the prediction of peptide secondary structures and the exploration of downstream tasks. The framework includes a novel interpretable deep hypergraph multi-head attention network that uses residue-based reasoning for structure prediction. The algorithm can incorporate sequential semantic information from large-scale biological corpus and structural semantic information from multi-scale structural segmentation, leading to better accuracy and interpretability even with extremely short peptides. The interpretable models are able to highlight the reasoning of structural feature representations and the classification of secondary substructures. The importance of secondary structures in peptide tertiary structure reconstruction and downstream functional analysis is further demonstrated, highlighting the versatility of our models. To facilitate the use of the model, an online server is established which is accessible via http://inner.wei-group.net/PHAT/. The work is expected to assist in the design of functional peptides and contribute to the advancement of structural biology research., (© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

7. Anticancer peptides prediction with deep representation learning features.

Author

Lv Z, Cui F, Zou Q, Zhang L, and Xu L

Subjects

Amino Acid Sequence, Antineoplastic Agents chemistry, Benchmarking, Computer Simulation, Humans, Memory, Short-Term, Peptides chemistry, Antineoplastic Agents therapeutic use, Computational Biology methods, Deep Learning, Drug Discovery methods, Neoplasms drug therapy, Peptides therapeutic use

Abstract

Anticancer peptides constitute one of the most promising therapeutic agents for combating common human cancers. Using wet experiments to verify whether a peptide displays anticancer characteristics is time-consuming and costly. Hence, in this study, we proposed a computational method named identify anticancer peptides via deep representation learning features (iACP-DRLF) using light gradient boosting machine algorithm and deep representation learning features. Two kinds of sequence embedding technologies were used, namely soft symmetric alignment embedding and unified representation (UniRep) embedding, both of which involved deep neural network models based on long short-term memory networks and their derived networks. The results showed that the use of deep representation learning features greatly improved the capability of the models to discriminate anticancer peptides from other peptides. Also, UMAP (uniform manifold approximation and projection for dimension reduction) and SHAP (shapley additive explanations) analysis proved that UniRep have an advantage over other features for anticancer peptide identification. The python script and pretrained models could be downloaded from https://github.com/zhibinlv/iACP-DRLF or from http://public.aibiochem.net/iACP-DRLF/., (© The Author(s) 2021. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2021

8. ITP-Pred: an interpretable method for predicting, therapeutic peptides with fused features low-dimension representation.

Author

Cai L, Wang L, Fu X, Xia C, Zeng X, and Zou Q

Subjects

Peptides chemistry, Peptides therapeutic use, Machine Learning, Models, Genetic, Peptides genetics, Sequence Analysis, Protein

Abstract

The peptide therapeutics market is providing new opportunities for the biotechnology and pharmaceutical industries. Therefore, identifying therapeutic peptides and exploring their properties are important. Although several studies have proposed different machine learning methods to predict peptides as being therapeutic peptides, most do not explain the decision factors of model in detail. In this work, an Interpretable Therapeutic Peptide Prediction (ITP-Pred) model based on efficient feature fusion was developed. First, we proposed three kinds of feature descriptors based on sequence and physicochemical property encoded, namely amino acid composition (AAC), group AAC and coding autocorrelation, and concatenated them to obtain the feature representation of therapeutic peptide. Then, we input it into the CNN-Bi-directional Long Short-Term Memory (BiLSTM) model to automatically learn recognition of therapeutic peptides. The cross-validation and independent verification experiments results indicated that ITP-Pred has a higher prediction performance on the benchmark dataset than other comparison methods. Finally, we analyzed the output of the model from two aspects: sequence order and physical and chemical properties, mining important features as guidance for the design of better models that can complement existing methods., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2021

9. DeepAVP: A Dual-Channel Deep Neural Network for Identifying Variable-Length Antiviral Peptides.

Author

Li J, Pu Y, Tang J, Zou Q, and Guo F

Subjects

Deep Learning, Antiviral Agents, Computational Biology methods, Drug Discovery methods, Neural Networks, Computer, Peptides

Abstract

Antiviral peptides (AVPs) have been experimentally verified to block virus into host cells, which have antiviral activity with decapeptide amide. Therefore, utilization of experimentally validated antiviral peptides is a potential alternative strategy for targeting medically important viruses. In this article, we propose a dual-channel deep neural network ensemble method for analyzing variable-length antiviral peptides. The LSTM channel can capture long-term dependencies for effectively studying original variable-length sequence data. The CONV channel can build dynamic neural network for analyzing the local evolution information. Also, our model can fine-tune the substitution matrix for specifically functional peptides. Applying it to a novel experimentally verified dataset, our AVPs predictor, DeepAVP, demonstrates state-of-the-art performance of [Formula: see text] accuracy and 0.85 MCC, which is far better than existing prediction methods for identifying antiviral peptides. Therefore, DeepAVP, web server for predicting the effective AVPs, would make significantly contributions to peptide-based antiviral research.

Published

2020

10. PPTPP: a novel therapeutic peptide prediction method using physicochemical property encoding and adaptive feature representation learning.

Author

Zhang YP and Zou Q

Subjects

Machine Learning, Peptides

Abstract

Motivation: Peptide is a promising candidate for therapeutic and diagnostic development due to its great physiological versatility and structural simplicity. Thus, identifying therapeutic peptides and investigating their properties are fundamentally important. As an inexpensive and fast approach, machine learning-based predictors have shown their strength in therapeutic peptide identification due to excellences in massive data processing. To date, no reported therapeutic peptide predictor can perform high-quality generic prediction and informative physicochemical properties (IPPs) identification simultaneously., Results: In this work, Physicochemical Property-based Therapeutic Peptide Predictor (PPTPP), a Random Forest-based prediction method was presented to address this issue. A novel feature encoding and learning scheme were initiated to produce and rank physicochemical property-related features. Besides being capable of predicting multiple therapeutics peptides with high comparability to established predictors, the presented method is also able to identify peptides' informative IPP. Results presented in this work not only illustrated the soundness of its working capacity but also demonstrated its potential for investigating other therapeutic peptides., Availability and Implementation: https://github.com/YPZ858/PPTPP., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2020

11. Intranasal immunization with immunodominant epitope peptides derived from HpaA conjugated with CpG adjuvant protected mice against Helicobacter pylori infection.

Author

Yang WC, Sun HW, Sun HQ, Yuan HM, Li B, Li HB, Hu J, Yang Y, Zou QM, Guo H, Wu C, and Chen L

Subjects

Adjuvants, Immunologic, Administration, Intranasal, Animals, Antibodies, Bacterial immunology, Female, Flow Cytometry, Immunization methods, Mice, Mice, Inbred BALB C, Vaccination methods, Helicobacter Infections immunology, Helicobacter Infections prevention & control, Helicobacter pylori immunology, Helicobacter pylori pathogenicity, Immunodominant Epitopes immunology, Peptides administration & dosage, Peptides immunology

Abstract

HpaA is considered to be an effective protective antigen for vaccination against Helicobacter pylori (H. pylori) infection. Oral immunization with HpaA significantly decreases bacterial colonization in H. pylori infected mice. In this study, we investigated whether subcutaneous or intranasal immunization with HpaA could protect against H. pylori infection. Mice immunized subcutaneously with HpaA in Complete Freund's adjuvant, but not mice intranasally immunized with HpaA in CpG adjuvant acquired protection against H. pylori infection. However, intranasal immunization with immunodominant epitope peptides in CpG adjuvant protected mice against H. pylori infection, and immunodominant epitope peptides stimulated stronger Th1 responses and mediated more robust protection against H. pylori infection than subdominant ones. Our results suggest that the length of a candidate antigen is critical for particular vaccination routes, and that immunodominant epitope peptides are promising candidates for protection against H. pylori infection through nasal vaccination., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

12. DeepAVP-TPPred: identification of antiviral peptides using transformed image-based localized descriptors and binary tree growth algorithm.

Author

Ullah, Matee, Akbar, Shahid, Raza, Ali, and Zou, Quan

Subjects

ARTIFICIAL neural networks, TREE growth, PEPTIDES, LIFE cycles (Biology), FEATURE selection, FEATURE extraction, IDENTIFICATION

Abstract

Motivation Despite the extensive manufacturing of antiviral drugs and vaccination, viral infections continue to be a major human ailment. Antiviral peptides (AVPs) have emerged as potential candidates in the pursuit of novel antiviral drugs. These peptides show vigorous antiviral activity against a diverse range of viruses by targeting different phases of the viral life cycle. Therefore, the accurate prediction of AVPs is an essential yet challenging task. Lately, many machine learning-based approaches have developed for this purpose; however, their limited capabilities in terms of feature engineering, accuracy, and generalization make these methods restricted. Results In the present study, we aim to develop an efficient machine learning-based approach for the identification of AVPs, referred to as DeepAVP-TPPred, to address the aforementioned problems. First, we extract two new transformed feature sets using our designed image-based feature extraction algorithms and integrate them with an evolutionary information-based feature. Next, these feature sets were optimized using a novel feature selection approach called binary tree growth Algorithm. Finally, the optimal feature space from the training dataset was fed to the deep neural network to build the final classification model. The proposed model DeepAVP-TPPred was tested using stringent 5-fold cross-validation and two independent dataset testing methods, which achieved the maximum performance and showed enhanced efficiency over existing predictors in terms of both accuracy and generalization capabilities. Availability and implementation https://github.com/MateeullahKhan/DeepAVP-TPPred. [ABSTRACT FROM AUTHOR]

Published

2024

13. CoraL: interpretable contrastive meta-learning for the prediction of cancer-associated ncRNA-encoded small peptides.

Author

Li, Zhongshen, Jin, Junru, He, Wenjia, Long, Wentao, Yu, Haoqing, Gao, Xin, Nakai, Kenta, Zou, Quan, and Wei, Leyi

Subjects

TUMOR markers, PEPTIDES, HUMAN fingerprints, CORALS, DEEP learning, CARCINOGENESIS, SOURCE code

Abstract

NcRNA-encoded small peptides (ncPEPs) have recently emerged as promising targets and biomarkers for cancer immunotherapy. Therefore, identifying cancer-associated ncPEPs is crucial for cancer research. In this work, we propose CoraL, a novel supervised contrastive meta-learning framework for predicting cancer-associated ncPEPs. Specifically, the proposed meta-learning strategy enables our model to learn meta-knowledge from different types of peptides and train a promising predictive model even with few labeled samples. The results show that our model is capable of making high-confidence predictions on unseen cancer biomarkers with only five samples, potentially accelerating the discovery of novel cancer biomarkers for immunotherapy. Moreover, our approach remarkably outperforms existing deep learning models on 15 cancer-associated ncPEPs datasets, demonstrating its effectiveness and robustness. Interestingly, our model exhibits outstanding performance when extended for the identification of short open reading frames derived from ncPEPs, demonstrating the strong prediction ability of CoraL at the transcriptome level. Importantly, our feature interpretation analysis discovers unique sequential patterns as the fingerprint for each cancer-associated ncPEPs, revealing the relationship among certain cancer biomarkers that are validated by relevant literature and motif comparison. Overall, we expect CoraL to be a useful tool to decipher the pathogenesis of cancer and provide valuable information for cancer research. The dataset and source code of our proposed method can be found at https://github.com/Johnsunnn/CoraL. [ABSTRACT FROM AUTHOR]

Published

2023

14. Prediction of Cell-Penetrating Peptides Using a Novel HSIC-Based Multiview TSK Fuzzy System.

Author

Liu, Peng, Zhao, Shulin, Zou, Quan, and Ding, Yijie

Subjects

CELL-penetrating peptides, MACHINE learning, INDEPENDENT sets, FUZZY systems, FORECASTING, PEPTIDES

Abstract

Cell-penetrating peptides (CPPs) are short peptides that can carry cargo into cells. CPPs are widely utilized due to their powerful loading capacity and transduction efficiency. Identifying CPPs is the basis for studying their functions and mechanisms; however, experimental methods to identify CPPs are expensive and time-consuming. Recently, CPP predictors based on machine learning methods have become a research hotspot. Although considerable progress has been made, some challenges remain unresolved. First, most predictors employ a variety of feature descriptors to transform an original sequence into multiview data; however, extant methods ignore the relationships between different views, limiting further performance improvement. Second, most machine learning models are actually black boxes and cannot offer insightful advice. In this paper, a novel Hilbert–Schmidt independence criterion (HSIC)-based multiview TSK fuzzy system is proposed. Compared with other machine learning methods, TSK fuzzy systems have better interpretability, and the introduction of multiview mechanisms provides comprehensive insight into the intrinsic laws of the data. HSIC is utilized here to measure the independence and enhance the complementarity between different views. Notably, the proposed method attained prediction accuracy results of 92.2% and 96.2% for the training and independent test sets, respectively. The empirical results show that our promising approach features greater recognition performance than the state-of-the-art method. [ABSTRACT FROM AUTHOR]

Published

2022

15. Structured Sparse Regularized TSK Fuzzy System for predicting therapeutic peptides.

Author

Guo, Xiaoyi, Jiang, Yizhang, and Zou, Quan

Subjects

PEPTIDES, DIGESTIVE organs, MACHINE learning, AMINO acid sequence

Abstract

Therapeutic peptides act on the skeletal system, digestive system and blood system, have antibacterial properties and help relieve inflammation. In order to reduce the resource consumption of wet experiments for the identification of therapeutic peptides, many computational-based methods have been developed to solve the identification of therapeutic peptides. Due to the insufficiency of traditional machine learning methods in dealing with feature noise. We propose a novel therapeutic peptide identification method called Structured Sparse Regularized Takagi–Sugeno–Kang Fuzzy System on Within-Class Scatter (SSR-TSK-FS-WCS). Our method achieves good performance on multiple therapeutic peptides and UCI datasets. [ABSTRACT FROM AUTHOR]

Published

2022

16. PEPred-Suite: improved and robust prediction of therapeutic peptides using adaptive feature representation learning.

Author

Wei, Leyi, Zhou, Chen, Su, Ran, and Zou, Quan

Subjects

INTERNET servers, DESCRIPTOR systems, RECEIVER operating characteristic curves, PEPTIDES, DNA-binding proteins

Abstract

Motivation Prediction of therapeutic peptides is critical for the discovery of novel and efficient peptide-based therapeutics. Computational methods, especially machine learning based methods, have been developed for addressing this need. However, most of existing methods are peptide-specific; currently, there is no generic predictor for multiple peptide types. Moreover, it is still challenging to extract informative feature representations from the perspective of primary sequences. Results In this study, we have developed PEPred-Suite, a bioinformatics tool for the generic prediction of therapeutic peptides. In PEPred-Suite, we introduce an adaptive feature representation strategy that can learn the most representative features for different peptide types. To be specific, we train diverse sequence-based feature descriptors, integrate the learnt class information into our features, and utilize a two-step feature optimization strategy based on the area under receiver operating characteristic curve to extract the most discriminative features. Using the learnt representative features, we trained eight random forest models for eight different types of functional peptides, respectively. Benchmarking results showed that as compared with existing predictors, PEPred-Suite achieves better and robust performance for different peptides. As far as we know, PEPred-Suite is currently the first tool that is capable of predicting so many peptide types simultaneously. In addition, our work demonstrates that the learnt features can reliably predict different peptides. Availability and implementation The user-friendly webserver implementing the proposed PEPred-Suite is freely accessible at http://server.malab.cn/PEPred-Suite. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2019

17. Fast Prediction of Protein Methylation Sites Using a Sequence-Based Feature Selection Technique.

Author

Wei, Leyi, Xing, Pengwei, Shi, Gaotao, Ji, Zhiliang, and Zou, Quan

Abstract

Protein methylation, an important post-translational modification, plays crucial roles in many cellular processes. The accurate prediction of protein methylation sites is fundamentally important for revealing the molecular mechanisms undergoing methylation. In recent years, computational prediction based on machine learning algorithms has emerged as a powerful and robust approach for identifying methylation sites, and much progress has been made in predictive performance improvement. However, the predictive performance of existing methods is not satisfactory in terms of overall accuracy. Motivated by this, we propose a novel random-forest-based predictor called MePred-RF, integrating several discriminative sequence-based feature descriptors and improving feature representation capability using a powerful feature selection technique. Importantly, unlike other methods based on multiple, complex information inputs, our proposed MePred-RF is based on sequence information alone. Comparative studies on benchmark datasets via vigorous jackknife tests indicate that our proposed MePred-RF method remarkably outperforms other state-of-the-art predictors, leading by a 4.5 percent average in terms of overall accuracy. A user-friendly webserver that implements the proposed method has been established for researchers' convenience, and is now freely available for public use through http://server.malab.cn/MePred-RF. We anticipate our research tool to be useful for the large-scale prediction and analysis of protein methylation sites. [ABSTRACT FROM AUTHOR]

Published

2019

18. PhosPred-RF: A Novel Sequence-Based Predictor for Phosphorylation Sites Using Sequential Information Only.

Author

Wei, Leyi, Xing, Pengwei, Tang, Jijun, and Zou, Quan

Abstract

Many recent efforts have been made for the development of machine learning-based methods for fast and accurate phosphorylation site prediction. Currently, a majority of well-performing methods are based on hybrid information to build prediction models, such as evolutionary information, disorder information, and so on. Unfortunately, this type of methods suffers two major limitations: one is that it would not be much of help for protein phosphorylation site prediction in case of no obvious homology detected; the other is that computing such the complicated information is time-consuming, which probably limits the usage of predictors in practical applications. In this paper, we present a simple, fast, and powerful feature representation algorithm, which sufficiently explores the sequential information from multiple perspectives only based on primary sequences, and successfully captures the differences between true phosphorylation sites and hboxnon-phosphorylation sites. Using the proposed features, we propose a random forest-based predictor named PhosPred-RF in the prediction of protein phosphorylation sites from proteins. We evaluate and compare the proposed predictor with the state-of-the-art predictors on some benchmark data sets. The experimental results show that PhosPred-RF outperforms other existing predictors, demonstrating its potential to be a useful tool for protein phosphorylation site prediction. Currently, the proposed PhosPred-RF is freely accessible to the public through the user-friendly webserver http://server.malab.cn/PhosPred-RF. [ABSTRACT FROM PUBLISHER]

Published

2017

19. Immunisation With Immunodominant Linear B Cell Epitopes Vaccine of Manganese Transport Protein C Confers Protection against Staphylococcus aureus Infection.

Author

Yang, Hui-Jie, Zhang, Jin-Yong, Wei, Chao, Yang, Liu-Yang, Zuo, Qian-Fei, Zhuang, Yuan, Feng, You-Jun, Srinivas, Swaminath, Zeng, Hao, and Zou, Quan-Ming

Subjects

B cells, EPITOPES, MANGANESE, IMMUNIZATION, PROTEIN C, STAPHYLOCOCCUS aureus infections, PHYSIOLOGY

Abstract

Vaccination strategies for Staphylococcus aureus, particularly methicillin-resistant S. aureus (MRSA) infections have attracted much research attention. Recent efforts have been made to select manganese transport protein C, or manganese binding surface lipoprotein C (MntC), which is a metal ion associated with pathogen nutrition uptake, as potential candidates for an S. aureus vaccine. Although protective humoral immune responses to MntC are well-characterised, much less is known about detailed MntC-specific B cell epitope mapping and particularly epitope vaccines, which are less-time consuming and more convenient. In this study, we generated a recombinant protein rMntC which induced strong antibody response when used for immunisation with CFA/IFA adjuvant. On the basis of the results, linear B cell epitopes within MntC were finely mapped using a series of overlapping synthetic peptides. Further studies indicate that MntC113-136, MntC209-232, and MntC263-286 might be the original linear B-cell immune dominant epitope of MntC, furthermore, three-dimensional (3-d) crystal structure results indicate that the three immunodominant epitopes were displayed on the surface of the MntC antigen. On the basis of immunodominant MntC113-136, MntC209-232, and MntC263-286 peptides, the epitope vaccine for S. aureus induces a high antibody level which is biased to TH2 and provides effective immune protection and strong opsonophagocytic killing activity in vitro against MRSA infection. In summary, the study provides strong proof of the optimisation of MRSA B cell epitope vaccine designs and their use, which was based on the MntC antigen in the development of an MRSA vaccine. [ABSTRACT FROM AUTHOR]

Published

2016

20. Subspace projection-based weighted echo state networks for predicting therapeutic peptides.

Author

Guo, Xiaoyi, Tiwari, Prayag, Zou, Quan, and Ding, Yijie

Subjects

*MACHINE learning, *PEPTIDES, *BIOLOGICAL classification

Abstract

Detection of therapeutic peptide is a major research direction in the current biopharmaceutical field. However, traditional biochemical experimental detection methods take a lot of time. As supplementary methods for biochemical experiments, the computational methods can improve the efficiency of therapeutic peptide detection. Currently, most machine learning-based therapeutic peptide identification algorithms do not consider the processing of noisy samples. We propose a therapeutic peptide classifier, called weighted echo state networks based on subspace projection (WESN-SP), which reduces the bias caused by high-dimensional noisy features and noisy samples. WESN-SP is trained by sparse Bayesian learning algorithm (SBL) and introduces a weight coefficient for each sample by kernel dependence maximization-based subspace projection. The experimental results show that WESN-SP has better performance than other existing methods. [ABSTRACT FROM AUTHOR]

Published

2023

21. Screening and identification of a novel B-cell neutralizing epitope from Helicobacter pylori UreB

Author

Li, Hai-Xia, Mao, Xu-Hu, Shi, Yun, Ma, Ying, Wu, Ya-Nan, Zhang, Wei-Jun, Luo, Ping, Yu, Shu, Zhou, Wei-Ying, Guo, Ying, Wu, Chao, Guo, Gang, and Zou, Quan-Ming

Subjects

*HELICOBACTER pylori, *B cells, *EPITOPES, *HELICOBACTER pylori infections, *UREASE, *PEPTIDES, *DRUG development, *PREVENTIVE medicine, *MEDICAL screening, *PREVENTION, *THERAPEUTICS

Abstract

Abstract: Urease plays a crucial role in the survival and pathogenesis of Helicobacter pylori (H. pylori), and antibody neutralizing the urease activity may be implicated for the protection against H. pylori infection. Previously, a neutralizing monoclonal antibody (MAb) 6E6 against UreB of H. pylori was developed. In this work, we try to identify the B-cell epitope recognized by neutralizing MAb 6E6. Following screening a series of truncated proteins of UreB, an epitope was primarily localized in the aa 200–230 of UreB. Subsequently, we screened the overlapping synthetic peptides covering the aa 200–230 and identified a novel B-cell epitope (U211–225, IEAGAIGFKIHEDWG) that was recognized by specific MAb 6E6. The newly identified epitope may help understanding of the protective immunity against H. pylori and be implicated for vaccine development. [Copyright &y& Elsevier]

Published

2008