Your search keyword '"Ong, Edison"' showing total 6 results

1. COVID-19 vaccine design using reverse and structural vaccinology, ontology-based literature mining and machine learning.

Author

Huffman, Anthony, Ong, Edison, Hur, Junguk, D'Mello, Adonis, Tettelin, Hervé, and He, Yongqun

Subjects

*COVID-19 vaccines, *VACCINATION complications, *COVID-19, *VACCINE safety, *STRUCTURAL engineering, *MACHINE learning

Abstract

Rational vaccine design, especially vaccine antigen identification and optimization, is critical to successful and efficient vaccine development against various infectious diseases including coronavirus disease 2019 (COVID-19). In general, computational vaccine design includes three major stages: (i) identification and annotation of experimentally verified gold standard protective antigens through literature mining, (ii) rational vaccine design using reverse vaccinology (RV) and structural vaccinology (SV) and (iii) post-licensure vaccine success and adverse event surveillance and its usage for vaccine design. Protegen is a database of experimentally verified protective antigens, which can be used as gold standard data for rational vaccine design. RV predicts protective antigen targets primarily from genome sequence analysis. SV refines antigens through structural engineering. Recently, RV and SV approaches, with the support of various machine learning methods, have been applied to COVID-19 vaccine design. The analysis of post-licensure vaccine adverse event report data also provides valuable results in terms of vaccine safety and how vaccines should be used or paused. Ontology standardizes and incorporates heterogeneous data and knowledge in a human- and computer-interpretable manner, further supporting machine learning and vaccine design. Future directions on rational vaccine design are discussed. [ABSTRACT FROM AUTHOR]

Published

2022

2. Reverse Microbiomics: A New Reverse Dysbiosis Analysis Strategy and Its Usage in Prediction of Autoantigens and Virulent Factors in Dysbiotic Gut Microbiomes From Rheumatoid Arthritis Patients.

Author

Wang, Haihe, Ong, Edison, Kao, John Y., Sun, Duxin, and He, Yongqun

Subjects

RHEUMATOID arthritis, ATP-binding cassette transporters, AUTOANTIGENS, BIFIDOBACTERIUM bifidum, GUT microbiome, BIFIDOBACTERIUM

Abstract

Alterations in the gut microbiome have been associated with various human diseases. Most existing gut microbiome studies stopped at the stage of identifying microbial alterations between diseased or healthy conditions. As inspired by reverse vaccinology (RV), we developed a new strategy called Reverse Microbiomics (RM) that turns this process around: based on the identified microbial alternations, reverse-predicting the molecular mechanisms underlying the disease and microbial alternations. Our RM methodology starts by identifying significantly altered microbiota profiles, performing bioinformatics analysis on the proteomes of the microbiota identified, and finally predicting potential virulence or protective factors relevant to a microbiome-associated disease. As a use case study, this reverse methodology was applied to study the molecular pathogenesis of rheumatoid arthritis (RA), a common autoimmune and inflammatory disease. Those bacteria differentially associated with RA were first identified and annotated from published data and then modeled and classified using the Ontology of Host-Microbiome Interactions (OHMI). Our study identified 14 species increased and 9 species depleted in the gut microbiota of RA patients. Vaxign was used to comparatively analyze 15 genome sequences of the two pairs of species: Gram-negative Prevotella copri (increased) and Prevotella histicola (depleted), as well as Gram-positive Bifidobacterium dentium (increased) and Bifidobacterium bifidum (depleted). In total, 21 auto-antigens were predicted to be related to RA, and five of them were previously reported to be associated with RA with experimental evidence. Furthermore, we identified 94 potential adhesive virulence factors including 24 microbial ABC transporters. While eukaryotic ABC transporters are key RA diagnosis markers and drug targets, we identified, for the first-time, RA-associated microbial ABC transporters and provided a novel hypothesis of RA pathogenesis. Our study showed that RM, by broadening the scope of RV, is a novel and effective strategy to study from bacterial level to molecular level factors and gain further insight into how these factors possibly contribute to the development of microbial alterations under specific diseases. [ABSTRACT FROM AUTHOR]

Published

2021

3. COVID-19 Coronavirus Vaccine Design Using Reverse Vaccinology and Machine Learning.

Author

Ong, Edison, Wong, Mei U, Huffman, Anthony, and He, Yongqun

Abstract

To ultimately combat the emerging COVID-19 pandemic, it is desired to develop an effective and safe vaccine against this highly contagious disease caused by the SARS-CoV-2 coronavirus. Our literature and clinical trial survey showed that the whole virus, as well as the spike (S) protein, nucleocapsid (N) protein, and membrane (M) protein, have been tested for vaccine development against SARS and MERS. However, these vaccine candidates might lack the induction of complete protection and have safety concerns. We then applied the Vaxign and the newly developed machine learning-based Vaxign-ML reverse vaccinology tools to predict COVID-19 vaccine candidates. Our Vaxign analysis found that the SARS-CoV-2 N protein sequence is conserved with SARS-CoV and MERS-CoV but not from the other four human coronaviruses causing mild symptoms. By investigating the entire proteome of SARS-CoV-2, six proteins, including the S protein and five non-structural proteins (nsp3, 3CL-pro, and nsp8-10), were predicted to be adhesins, which are crucial to the viral adhering and host invasion. The S, nsp3, and nsp8 proteins were also predicted by Vaxign-ML to induce high protective antigenicity. Besides the commonly used S protein, the nsp3 protein has not been tested in any coronavirus vaccine studies and was selected for further investigation. The nsp3 was found to be more conserved among SARS-CoV-2, SARS-CoV, and MERS-CoV than among 15 coronaviruses infecting human and other animals. The protein was also predicted to contain promiscuous MHC-I and MHC-II T-cell epitopes, and the predicted linear B-cell epitopes were found to be localized on the surface of the protein. Our predicted vaccine targets have the potential for effective and safe COVID-19 vaccine development. We also propose that an "Sp/Nsp cocktail vaccine" containing a structural protein(s) (Sp) and a non-structural protein(s) (Nsp) would stimulate effective complementary immune responses. [ABSTRACT FROM AUTHOR]

Published

2020

4. Identification of New Features from Known Bacterial Protective Vaccine Antigens Enhances Rational Vaccine Design.

Author

Ong, Edison, Wong, Mei U., and Yongqun He

Subjects

VACCINE effectiveness, BIOINFORMATICS, ANTIGEN analysis

Abstract

With many protective vaccine antigens reported in the literature and verified experimentally, how to use the knowledge mined from these antigens to support rational vaccine design and study underlying design mechanism remains unclear. In order to address the problem, a systematic bioinformatics analysis was performed on 291 Gram-positive and Gram-negative bacterial protective antigens with experimental evidence manually curated in the Protegen database. The bioinformatics analyses evaluated included subcellular localization, adhesin probability, peptide signaling, transmembrane α-helix and β-barrel, conserved domain, Clusters of Orthologous Groups, and Gene Ontology functional annotations. Here we showed the critical role of adhesins, along with subcellular localization, peptide signaling, in predicting secreted extracellular or surface-exposed protective antigens, with mechanistic explanations supported by functional analysis. We also found a significant negative correlation of transmembrane α-helix to antigen protectiveness in Gram-positive and Gram-negative pathogens, while a positive correlation of transmembrane β-barrel was observed in Gram-negative pathogens. The commonly less-focused cytoplasmic and cytoplasmic membrane proteins could be potentially predicted with the help of other selection criteria such as adhesin probability and functional analysis. The significant findings in this study can support rational vaccine design and enhance our understanding of vaccine design mechanisms. [ABSTRACT FROM AUTHOR]

Published

2017

5. Identification of Mycobacterium tuberculosis Antigens with Vaccine Potential Using a Machine Learning-Based Reverse Vaccinology Approach.

Author

Teahan, Blaine, Ong, Edison, and Yang, Zhenhua

Subjects

MYCOBACTERIUM tuberculosis, TUBERCULOSIS vaccines, CAUSES of death, INFECTION, VACCINE effectiveness, TEAM learning approach in education

Abstract

Tuberculosis (TB) is the leading cause of death of any single infectious agent, having led to 1.4 million deaths in 2019 alone. Moreover, an estimated one-quarter of the global population is latently infected with Mycobacterium tuberculosis (MTB), presenting a huge pool of potential future disease. Nonetheless, the only currently licensed TB vaccine fails to prevent the activation of latent TB infections (LTBI). These facts together illustrate the desperate need for a more effective TB vaccine strategy that can prevent both primary infection and the activation of LTBI. In this study, we employed a machine learning-based reverse vaccinology approach to predict the likelihood that each protein within the proteome of MTB laboratory reference strain H37Rv would be a protective antigen (PAg). The proteins predicted most likely to be a PAg were assessed for their belonging to a protein family of previously established PAgs, the relevance of their biological processes to MTB virulence and latency, and finally the immunogenic potential that they may provide in terms of the number of promiscuous epitopes within each. This study led to the identification of 16 proteins with the greatest vaccine potential for further in vitro and in vivo studies. It also demonstrates the value of computational methods in vaccine development. [ABSTRACT FROM AUTHOR]

Published

2021

6. Rational Vaccine Design by Reverse & Structural Vaccinology and Ontology

Author

Ong, Edison

Subjects

bioinformatics, vaccine design, immunology, reverse vaccinology, structural vaccinology, ontology

Abstract

Vaccination is one of the most successful public health interventions in modern medicine. However, it is still challenging to develop effective vaccines against many infectious diseases such as tuberculosis, HIV, and malaria. There are challenges in integrating the high volume, variety, and variability of vaccine-related data and rationally designing effective and safe vaccines efficiently. In my thesis study, I systematically and comprehensively analyzed manually annotated protective vaccine antigens in the Protegen database and identified these protective antigens' enriched patterns. I then created Vaxign-ML, a novel machine learning-based reverse vaccinology method based on the curated Protegen data for rational vaccine design. Vaxign-ML was used to successfully predict vaccine antigens for tuberculosis and Coronavirus Disease 2019 (COVID-19). I also developed a new structural vaccinology design program that optimizes COVID-19 spike glycoprotein as a vaccine candidate for enhanced vaccine protection via T cell epitope engineering. The vaccine antigens selected and optimized by Reverse and Structural Vaccinology in this dissertation are subjected to future experimental verification. Furthermore, I created a community-based Ontology of Host-Pathogen Interactions (OHPI), which served as a platform to semantically represent the interactions between host and virulence factors that are also protective antigens. I developed the Vaccine Investigation Ontology (VIO) for standardized metadata representation for high throughput vaccine OMICS data analysis. Overall, my thesis research aims to uncover protective antigen patterns, create methods/tools to effectively develop vaccines against infectious diseases of public health significance, and strengthen our understanding of vaccine protection mechanisms. These works can be further expanded and integrated with other technologies such as epitope prediction, molecular epidemiology, and high-throughput sequencing to build the foundation of precision vaccinology.

Published

2021