Your search keyword '"vaccine design"' showing total 883 results

1. Conversion of vaccines from low to high immunogenicity by antibodies with epitope complementarity.

Author

Dvorscek, Alexandra R., McKenzie, Craig I., Stäheli, Vera C., Ding, Zhoujie, White, Jacqueline, Fabb, Stewart A., Lim, Leonard, O'Donnell, Kristy, Pitt, Catherine, Christ, Daniel, Hill, Danika L., Pouton, Colin W., Burnett, Deborah L., Brink, Robert, Robinson, Marcus J., Tarlinton, David M., and Quast, Isaak

Subjects

*B cell differentiation, *B cell receptors, *IMMUNOLOGIC memory, *B cells, *PLASMA cells

Abstract

Existing antibodies (Abs) have varied effects on humoral immunity during subsequent infections. Here, we leveraged in vivo systems that allow precise control of antigen-specific Abs and B cells to examine the impact of Ab dose, affinity, and specificity in directing B cell activation and differentiation. Abs competing with the B cell receptor (BCR) epitope showed affinity-dependent suppression. By contrast, Abs targeting a complementary epitope, not overlapping with the BCR, shifted B cell differentiation toward Ab-secreting cells. Such Abs allowed for potent germinal center (GC) responses to otherwise poorly immunogenic sites by promoting antigen capture and presentation by low-affinity B cells. These mechanisms jointly diversified the B cell repertoire by facilitating the recruitment of high- and low-affinity B cells into Ab-secreting cell, GC, and memory B cell fates. Incorporation of small amounts of monoclonal Abs into protein- or mRNA-based vaccines enhanced immunogenicity and facilitated sustained immune responses, with implications for vaccine design and our understanding of protective immunity. [Display omitted] • Dose- and affinity-dependent implications of antibody (Ab)-mediated epitope masking • Abs promote the Ab-secreting cell fate of B cells recognizing non-overlapping epitopes • Small amounts of non-competitive Abs enhance low-affinity B cell responses, including GCs • Abs as adjuvants for recombinant protein- and mRNA-based vaccines Antibodies that protect us from pathogens also influence how the immune system responds to infection or vaccination. Dvorscek et al. reveal a mechanistic framework of how antibodies can optimize protective immunity, regulating B cell response participation and duration in a way that can be harnessed for vaccine design. [ABSTRACT FROM AUTHOR]

Published

2024

2. Deciphering the HLA-E immunopeptidome with mass spectrometry: an opportunity for universal mRNA vaccines and T-cell-directed immunotherapies.

Author

Weitzen, Maya, Shahbazy, Mohammad, Kapoor, Saketh, and Caron, Etienne

Subjects

CELL surface antigens, MASS spectrometry, PEPTIDES, VIRUS diseases, TREATMENT effectiveness

Abstract

Advances in immunotherapy rely on targeting novel cell surface antigens, including therapeutically relevant peptide fragments presented by HLA molecules, collectively known as the actionable immunopeptidome. Although the immunopeptidome of classical HLA molecules is extensively studied, exploration of the peptide repertoire presented by non-classical HLA-E remains limited. Growing evidence suggests that HLA-E molecules present pathogen-derived and tumor-associated peptides to CD8+ T cells, positioning them as promising targets for universal immunotherapies due to their minimal polymorphism. This mini-review highlights recent developments in mass spectrometry (MS) technologies for profiling the HLA-E immunopeptidome in various diseases. We discuss the unique features of HLA-E, its expression patterns, stability, and the potential for identifying new therapeutic targets. Understanding the broad repertoire of actionable peptides presented by HLA-E can lead to innovative treatments for viral and pathogen infections and cancer, leveraging its monomorphic nature for broad therapeutic efficacy. [ABSTRACT FROM AUTHOR]

Published

2024

3. Immunological Considerations for the Development of an Effective Herpes Vaccine.

Author

Singer, Mahmoud and Husseiny, Mohamed I.

Subjects

IMMUNOLOGIC memory, HERPES simplex virus, SENSORY ganglia, VACCINE effectiveness, PUBLIC health, T cells

Abstract

Research is underway to develop a vaccine to prevent and cure infection from herpes simplex virus (HSV). It emphasizes the critical need for immunization to address public health issues and the shortcomings of existing treatment options. Furthermore, studies on the HSV vaccine advance the field of immunology and vaccine creation, which may help in the battle against other viral illnesses. The current lack of such a vaccine is, in part, due to herpes viral latency in sensory ganglions. Current vaccines rely on tissue-resident memory CD8+ T cells, which are known to provide protection against subsequent HSV reinfection and reactivation without correlating with other immune subsets. For that reason, there is no effective vaccine that can provide protection against latent or recurrent herpes infection. This review focuses on conventional methods for evaluating the efficacy of a herpes vaccine using differential CD8+ T cells and important unaccounted immune aspects for designing an effective vaccine against herpes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Immunomodulatory activity of polycaprolactone nanoparticles with calcium phosphate salts against Leishmania infantum infection

Author

Kübra Kelleci, Adil Allahverdiyev, Melahat Bağırova, Murat Ihlamur, and Emrah Şefik Abamor

Subjects

leishmaniasis, calcium phosphate, polycaprolactone, nanoparticle, antigen delivery system, adjuvant, vaccine design, Arctic medicine. Tropical medicine, RC955-962, Biology (General), QH301-705.5

Abstract

Objective: To prepare and characterize polycaprolactone (PCL) nanoparticles loaded with sonicator fragmented (SLA) and freeze- thaw Leishmania antigens (FTLA) and to investigate the in vitro immunogenicity of antigen-encapsulated nanoparticles with calcium phosphate adjuvant. Methods: The water/oil/water binary emulsion solvent evaporation method was used to synthesize antigen-loaded PCL nanoparticles. Particles were characterized by scanning electron microscopy and zeta potential measurements. Their cytotoxicity in J774 macrophages in vitro was determined by MTT analysis. In addition, the amount of nitric oxide and the level of cytokines produced by macrophages were determined by Griess reaction and ELISA method, respectively. The protective effect of the developed formulations was evaluated by determining the infection index percentage in macrophages infected with Leishmania infantum. Results: Compared to the control group, SLA PCL and FTLA PCL nanoparticles with calcium phosphate adjuvant induced a 6- and 7-fold increase in nitric oxide, respectively. Additionally, the vaccine formulations promoted the production of IFN-γ and IL-12. SLA PCL and FTLA PCL nanoparticles combined with calcium phosphate adjuvant caused an approximately 13- and 11-fold reduction in infection index, respectively, compared to the control group. Conclusions: The encapsulation of antigens obtained by both sonication and freeze-thawing into PCL nanoparticles and the formulations with calcium phosphate adjuvant show strong in vitro immune stimulating properties. Therefore, PCL-based antigen delivery systems and calcium phosphate adjuvant are recommended as a potential vaccine candidate against leishmaniasis.

Published

2024

5. Multi-epitope vaccine design of African swine fever virus considering T cell and B cell immunogenicity

Author

Ting-Yu Chen, Yann-Jen Ho, Fang-Yu Ko, Pei-Yin Wu, Chia-Jung Chang, and Shinn-Ying Ho

Subjects

African swine fever virus, Immunogenicity, Pareto front, Promising epitope, T and B cell activation, Vaccine design, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Abstract T and B cell activation are equally important in triggering and orchestrating adaptive host responses to design multi-epitope African swine fever virus (ASFV) vaccines. However, few design methods have considered the trade-off between T and B cell immunogenicity when identifying promising ASFV epitopes. This work proposed a novel Pareto front-based ASFV screening method PFAS to identify promising epitopes for designing multi-epitope vaccines utilizing five ASFV Georgia 2007/1 sequences. To accurately predict T cell immunogenicity, four scoring methods were used to estimate the T cell activation in the four stages, including proteasomal cleavage probability, transporter associated with antigen processing transport efficiency, class I binding affinity of the major histocompatibility complex, and CD8 + cytotoxic T cell immunogenicity. PFAS ranked promising epitopes using a Pareto front method considering T and B cell immunogenicity. The coefficient of determination between the Pareto ranks of multi-epitope vaccines and survival days of swine vaccinations was R2 = 0.95. Consequently, PFAS scored complete epitope profiles and identified 72 promising top-ranked epitopes, including 46 CD2v epitopes, two p30 epitopes, 10 p72 epitopes, and 14 pp220 epitopes. PFAS is the first method of using the Pareto front approach to identify promising epitopes that considers the objectives of maximizing both T and B cell immunogenicity. The top-ranked promising epitopes can be cost-effectively validated in vitro. The Pareto front approach can be adaptively applied to various epitope predictors for bacterial, viral and cancer vaccine developments. The MATLAB code of the Pareto front method was available at https://github.com/NYCU-ICLAB/PFAS . Graphical Abstract

Published

2024

6. Universal peptide-based potential vaccine design against canine distemper virus (CDV) using a vaccinomic approach

Author

Santiago Rendon-Marin and Julián Ruíz-Saenz

Subjects

Vaccinomics, Peptide, In silico, Morbillivirus canis, Vaccine design, Immunogenic, Medicine, Science

Abstract

Abstract Canine distemper virus (CDV) affects many domestic and wild animals. Variations among CDV genome linages could lead to vaccination failure. To date, there are several vaccine alternatives, such as a modified live virus and a recombinant vaccine; however, most of these alternatives are based on the ancestral strain Onderstepoort, which has not been circulating for years. Vaccine failures and the need to update vaccines have been widely discussed, and the development of new vaccine candidates is necessary to reduce circulation and mortality. Current vaccination alternatives cannot be used in wildlife animals due to the lack of safety data for most of the species, in addition to the insufficient immune response against circulating strains worldwide in domestic species. Computational tools, including peptide-based therapies, have become essential for developing new-generation vaccines for diverse models. In this work, a peptide-based vaccine candidate with a peptide library derived from CDV H and F protein consensus sequences was constructed employing computational tools. The molecular docking and dynamics of the selected peptides with canine MHC-I and MHC-II and with TLR-2 and TLR-4 were evaluated. In silico safety was assayed through determination of antigenicity, allergenicity, toxicity potential, and homologous canine peptides. Additionally, in vitro safety was also evaluated through cytotoxicity in cell lines and canine peripheral blood mononuclear cells (cPBMCs) and through a hemolysis potential assay using canine red blood cells. A multiepitope CDV polypeptide was constructed, synthetized, and evaluated in silico and in vitro by employing the most promising peptides for comparison with single CDV immunogenic peptides. Our findings suggest that predicting immunogenic CDV peptides derived from most antigenic CDV proteins could aid in the development of new vaccine candidates, such as multiple single CDV peptides and multiepitope CDV polypeptides, that are safe in vitro and optimized in silico. In vivo studies are being conducted to validate potential vaccines that may be effective in preventing CDV infection in domestic and wild animals.

Published

2024

7. Multi-epitope vaccine design of African swine fever virus considering T cell and B cell immunogenicity.

Author

Chen, Ting-Yu, Ho, Yann-Jen, Ko, Fang-Yu, Wu, Pei-Yin, Chang, Chia-Jung, and Ho, Shinn-Ying

Subjects

*AFRICAN swine fever virus, *CYTOTOXIC T cells, *B cells, *MAJOR histocompatibility complex, *IMMUNE response, *T cells, *AFRICAN swine fever

Abstract

T and B cell activation are equally important in triggering and orchestrating adaptive host responses to design multi-epitope African swine fever virus (ASFV) vaccines. However, few design methods have considered the trade-off between T and B cell immunogenicity when identifying promising ASFV epitopes. This work proposed a novel Pareto front-based ASFV screening method PFAS to identify promising epitopes for designing multi-epitope vaccines utilizing five ASFV Georgia 2007/1 sequences. To accurately predict T cell immunogenicity, four scoring methods were used to estimate the T cell activation in the four stages, including proteasomal cleavage probability, transporter associated with antigen processing transport efficiency, class I binding affinity of the major histocompatibility complex, and CD8 + cytotoxic T cell immunogenicity. PFAS ranked promising epitopes using a Pareto front method considering T and B cell immunogenicity. The coefficient of determination between the Pareto ranks of multi-epitope vaccines and survival days of swine vaccinations was R2 = 0.95. Consequently, PFAS scored complete epitope profiles and identified 72 promising top-ranked epitopes, including 46 CD2v epitopes, two p30 epitopes, 10 p72 epitopes, and 14 pp220 epitopes. PFAS is the first method of using the Pareto front approach to identify promising epitopes that considers the objectives of maximizing both T and B cell immunogenicity. The top-ranked promising epitopes can be cost-effectively validated in vitro. The Pareto front approach can be adaptively applied to various epitope predictors for bacterial, viral and cancer vaccine developments. The MATLAB code of the Pareto front method was available at https://github.com/NYCU-ICLAB/PFAS. Key points: • Proposing a Pareto front-based method for designing swine multi-epitope vaccine. • The method maximizes T and B cell immunogenicity while ranking promising epitopes. • Higher the epitope Pareto ranks leads to longer vaccination survival (R2 = 0.95). [ABSTRACT FROM AUTHOR]

Published

2024

8. Exploring computational approaches to design mRNA Vaccine against vaccinia and Mpox viruses.

Author

Oladipo, Elijah K., Oyelakin, Olanrewaju D., Aiyelabegan, Abdulsamad O., Olajide, Elizabeth O., Olatayo, Victoria O., Owolabi, Kaothar P., Shittu, Yewande B., Olugbodi, Rhoda O., Ajala, Hezekiah A., Rukayat, Raji A., Olayiwola, Deborah O., Irewolede, Boluwatife A., Jimah, Esther M., Oloke, Julius K., Ojo, Taiwo O., Ajani, Olumide F., Iwalokun, Bamidele A., Kolawole, Olatunji M., Ariyo, Olumuyiwa E., and Adediran, Daniel A.

Subjects

*VACCINIA, *HUMORAL immunity, *POXVIRUSES, *VIRUS virulence, *CHEMICAL formulas

Abstract

Background: Messenger RNA (mRNA) vaccines emerged as a powerful tool in the fight against infections. Unlike traditional vaccines, this unique type of vaccine elicits robust and persistent innate and humoral immune response with a unique host cell‐mediated pathogen gene expression and antigen presentation. Methods: This offers a novel approach to combat poxviridae infections. From the genome of vaccinia and Mpox viruses, three key genes (E8L, E7R, and H3L) responsible for virus attachment and virulence were selected and employed for designing the candidate mRNA vaccine against vaccinia and Mpox viral infection. Various bioinformatics tools were employed to generate (B cell, CTL, and HTL) epitopes, of which 28 antigenic and immunogenic epitopes were selected and are linked to form the mRNA vaccine construct. Additional components, including a 5′ cap, 5′ UTR, adjuvant, 3′ UTR, and poly(A) tail, were incorporated to enhance stability and effectiveness. Safety measures such as testing for human homology and in silico immune simulations were implemented to avoid autoimmunity and to mimics the immune response of human host to the designed mRNA vaccine, respectively. The mRNA vaccine's binding affinity was evaluated by docking it with TLR‐2, TLR‐3, TLR‐4, and TLR‐9 receptors which are subsequently followed by molecular dynamics simulations for the highest binding one to predict the stability of the binding complex. Results: With a 73% population coverage, the mRNA vaccine looks promising, boasting a molecular weight of 198 kDa and a molecular formula of C8901H13609N2431O2611S48 and it is said to be antigenic, nontoxic and nonallergic, making it safe and effective in preventing infections with Mpox and vaccinia viruses, in comparison with other insilico‐designed vaccine for vaccinia and Mpox viruses. Conclusions: However, further validation through in vivo and in vitro techniques is underway to fully assess its potential. [ABSTRACT FROM AUTHOR]

Published

2024

9. Intestinal Microbiota and Its Effect on Vaccine-Induced Immune Amplification and Tolerance.

Author

Liu, Yixin, Zhou, Jianfeng, Yang, Yushang, Chen, Xiangzheng, Chen, Longqi, and Wu, Yangping

Subjects

EXTRACELLULAR vesicles, GUT microbiome, VACCINE effectiveness, IMMUNOLOGICAL tolerance, VACCINE development

Abstract

This review provides the potential of intestinal microbiota in vaccine design and application, exploring the current insights into the interplay between the intestinal microbiota and the immune system, with a focus on its intermediary function in vaccine efficacy. It summarizes families and genera of bacteria that are part of the intestinal microbiota that may enhance or diminish vaccine efficacy and discusses the foundational principles of vaccine sequence design and the application of gut microbial characteristics in vaccine development. Future research should further investigate the use of multi-omics technologies to elucidate the interactive mechanisms between intestinal microbiota and vaccine-induced immune responses, aiming to optimize and improve vaccine design. [ABSTRACT FROM AUTHOR]

Published

2024

10. Universal peptide-based potential vaccine design against canine distemper virus (CDV) using a vaccinomic approach.

Author

Rendon-Marin, Santiago and Ruíz-Saenz, Julián

Subjects

*CANINE distemper virus, *MONONUCLEAR leukocytes, *ERYTHROCYTES, *VIRAL vaccines, *VACCINES, *T cell receptors, *POLYPEPTIDES

Abstract

Canine distemper virus (CDV) affects many domestic and wild animals. Variations among CDV genome linages could lead to vaccination failure. To date, there are several vaccine alternatives, such as a modified live virus and a recombinant vaccine; however, most of these alternatives are based on the ancestral strain Onderstepoort, which has not been circulating for years. Vaccine failures and the need to update vaccines have been widely discussed, and the development of new vaccine candidates is necessary to reduce circulation and mortality. Current vaccination alternatives cannot be used in wildlife animals due to the lack of safety data for most of the species, in addition to the insufficient immune response against circulating strains worldwide in domestic species. Computational tools, including peptide-based therapies, have become essential for developing new-generation vaccines for diverse models. In this work, a peptide-based vaccine candidate with a peptide library derived from CDV H and F protein consensus sequences was constructed employing computational tools. The molecular docking and dynamics of the selected peptides with canine MHC-I and MHC-II and with TLR-2 and TLR-4 were evaluated. In silico safety was assayed through determination of antigenicity, allergenicity, toxicity potential, and homologous canine peptides. Additionally, in vitro safety was also evaluated through cytotoxicity in cell lines and canine peripheral blood mononuclear cells (cPBMCs) and through a hemolysis potential assay using canine red blood cells. A multiepitope CDV polypeptide was constructed, synthetized, and evaluated in silico and in vitro by employing the most promising peptides for comparison with single CDV immunogenic peptides. Our findings suggest that predicting immunogenic CDV peptides derived from most antigenic CDV proteins could aid in the development of new vaccine candidates, such as multiple single CDV peptides and multiepitope CDV polypeptides, that are safe in vitro and optimized in silico. In vivo studies are being conducted to validate potential vaccines that may be effective in preventing CDV infection in domestic and wild animals. [ABSTRACT FROM AUTHOR]

Published

2024

11. Computational method for designing vaccines applied to virus-like particles (VLPs) as epitope carriers.

Author

Prosper, Pascalita, Rodríguez Puertas, Rafael, Guérin, Diego M.A., and Branda, María Marta

Subjects

*VIRUS-like particles, *CYTOSKELETAL proteins, *INSECT viruses, *COVID-19 vaccines, *VACCINES

Abstract

[Display omitted] Nonenveloped virus-like particles (VLPs) are self-assembled oligomeric structures composed of one or more proteins that originate from diverse viruses. Because these VLPs have similar antigenicity to the parental virus, they are successfully used as vaccines against cognate virus infection. Furthermore, after foreign antigenic sequences are inserted in their protein components (chimVLPs), some VLPs are also amenable to producing vaccines against pathogens other than the virus it originates from (these VLPs are named platform or epitope carrier). Designing chimVLP vaccines is challenging because the immunogenic response must be oriented against a given antigen without altering stimulant properties inherent to the VLP. An important step in this process is choosing the location of the sequence modifications because this must be performed without compromising the assembly and stability of the original VLP. Currently, many immunogenic data and computational tools can help guide the design of chimVLPs, thus reducing experimental costs and work. In this study, we analyze the structure of a novel VLP that originate from an insect virus and describe the putative regions of its three structural proteins amenable to insertion. For this purpose, we employed molecular dynamics (MD) simulations to assess chimVLP stability by comparing mutated and wild-type (WT) VLP protein trajectories. We applied this procedure to design a chimVLP that can serve as a prophylactic vaccine against the SARS-CoV-2 virus. The methodology described in this work is generally applicable for VLP-based vaccine development. [ABSTRACT FROM AUTHOR]

Published

2024

12. PdPANA: phagemid display as peptide array for neutralizing antibodies, an engineered in silico vaccine candidate against COVID-19.

Author

Uzcátegui, Javier, Mullah, Khaleel, de Virgini, Daniel Buvat, Mendoza, Andrés, Urdaneta, Rafael, and Naranjo, Alejandra

Subjects

*PEPTIDES, *COVID-19, *RECOMBINANT proteins, *PROTEIN engineering, *DISPLAY systems, *IMMUNOGLOBULINS

Abstract

The COVID-19 pandemic has tested the technical, scientific, and industrial resources of all countries worldwide. Faced with the absence of pharmacological strategies against the disease, an effective plan for vaccinating against SARS-CoV-2 has been essential. Due to the lack of production means and necessary infrastructure, only a few nations could adequately confront this pathogen with a production, storage, and distribution scheme in place. This disease has become endemic in many countries, especially in those that are developing, thus necessitating solutions tailored to their reality. In this paper, we propose an in silico method to guide the design towards a thermally stable, universal, efficient, and safe COVID-19 vaccine candidate against SARS-CoV-2 using bioinformatics, immunoinformatics, and molecular modeling approaches for the selection of antigens with higher immunogenic potential, incorporating them into the surface of the M13 phage. Our work focused on using phagemid display as peptide array for neutralizing antibodies (PdPANA). This alternative approach might be useful during the vaccine development process, since it could bring improvements in terms of costeffectiveness in production, durability, and ease of distribution of the vaccine under less stringent thermal conditions compared to existing methods. Our results suggest that in the heavily glycosylated region of SARS-CoV-2 Spike protein (aa 344–583), from its inter-glycosylated regions, useful antigenic peptides can be obtained to be used in M13 phagemid display system. PdPANA, our proposed method might be useful to overcome the classic shortcoming posed by the phage-display technique (i.e., the time-consuming task of in vitro screening through great sized libraries with non-useful recombinant proteins) and obtain the most ideal recombinant proteins for vaccine design purposes. [ABSTRACT FROM AUTHOR]

Published

2024

13. Development and application of EpitopeScan, a Python3 toolset for mutation tracking in SARS-CoV-2 immunogenic epitopes.

Author

Kovalenko, Alexander and Viatte, Sebastien

Subjects

SARS-CoV-2, EPITOPES, GRAPHICAL user interfaces, GENETIC mutation, PEPTIDES

Abstract

Introduction: Outbreaks of coronaviruses and especially the recent COVID-19 pandemic emphasize the importance of immunological research in this area to mitigate the effect of future incidents. Bioinformatics approaches are capable of providing multisided insights from virus sequencing data, although currently available software options are not entirely suitable for a specific task of mutation surveillance within immunogenic epitopes of SARS-CoV-2. Method: Here, we describe the development of a mutation tracker, EpitopeScan, a Python3 package with command line and graphical user interface tools facilitating the investigation of the mutation dynamics in SARS-CoV-2 epitopes via analysis of multiple-sequence alignments of genomes over time. We provide an application case by examining three Spike protein-derived immunodominant CD4+ T-cell epitopes restricted by HLA-DRB1*04:01, an allele strongly associated with susceptibility to rheumatoid arthritis (RA). Mutations in these peptides are relevant for immune monitoring of CD4+ T-cell responses against SARS-CoV-2 spike protein in patients with RA. The analysis focused on 2.3 million SARS-CoV-2 genomes sampled in England. Results: We detail cases of epitope conservation over time, partial loss of conservation, and complete divergence from the wild type following the emergence of the N969K Omicron-specific mutation in November 2021. The wild type and the mutated peptide represent potential candidates to monitor variant-specific CD4+ T-cell responses. EpitopeScan is available via GitHub repository https://github.com/Aleksandr-biochem/EpitopeScan. [ABSTRACT FROM AUTHOR]

Published

2024

14. Deciphering the HLA-E immunopeptidome with mass spectrometry: an opportunity for universal mRNA vaccines and T-cell-directed immunotherapies

Author

Maya Weitzen, Mohammad Shahbazy, Saketh Kapoor, and Etienne Caron

Subjects

HLA-E peptides, immunopeptidome, mass spectrometry, vaccine design, viral infection, cancer immunotherapy, Immunologic diseases. Allergy, RC581-607

Abstract

Advances in immunotherapy rely on targeting novel cell surface antigens, including therapeutically relevant peptide fragments presented by HLA molecules, collectively known as the actionable immunopeptidome. Although the immunopeptidome of classical HLA molecules is extensively studied, exploration of the peptide repertoire presented by non-classical HLA-E remains limited. Growing evidence suggests that HLA-E molecules present pathogen-derived and tumor-associated peptides to CD8+ T cells, positioning them as promising targets for universal immunotherapies due to their minimal polymorphism. This mini-review highlights recent developments in mass spectrometry (MS) technologies for profiling the HLA-E immunopeptidome in various diseases. We discuss the unique features of HLA-E, its expression patterns, stability, and the potential for identifying new therapeutic targets. Understanding the broad repertoire of actionable peptides presented by HLA-E can lead to innovative treatments for viral and pathogen infections and cancer, leveraging its monomorphic nature for broad therapeutic efficacy.

Published

2024

15. Immunoinformatics for the Diagnosis and Monitoring of Autoimmune Diseases

Author

Gangwar, Shalesh, Sharma, Neha, Toor, Devinder, Patra, Jayanta Kumar, Series Editor, Das, Gitishree, Series Editor, Bose, Sankhadip, editor, Shukla, Amritesh Chandra, editor, Baig, Mirza R., editor, and Banerjee, Sabyasachi, editor

Published

2024

16. Antimicrobial roles of phagocytosis in teleost fish: Phagocytic B cells vs professional phagocytes

Author

Liting Wu, Lan Li, Along Gao, Jianmin Ye, and Jun Li

Subjects

Teleost fish, Phagocytic B cell, Phagocytosis, Antimicrobial role, Vaccine design, Aquaculture. Fisheries. Angling, SH1-691

Abstract

The defense system of teleost fish organized on innate and adaptive immunity protects them against a wide variety of pathogenic microorganisms in the aquatic environment. Phagocytosis is one of the most effective defense strategies against microbial challenge mainly performed by classical ‘professional’ phagocytes (including monocytes, macrophages and granulocytes). They contain, kill and process the internalized pathogens for antigen presentation by providing antigenic ligands to initiate activation and clonal expansion of T and B cells, which bridge the innate and adaptive immunity. The discovery of phagocytic B cells in teleost fish has broken the paradigm that primary vertebrate B cells are lack of phagocytosis of particulates, as well as led to the investigation of phagocytic activity of mammalian B-1 B cells. The active phagocytic, microbicidal capabilities and antigen presentation in teleost phagocytic B cell have demonstrated to be similar as professional phagocytes, providing a potential impact on development of new vaccination strategies to prevent and control infectious diseases. In this review, we aim to address current progress on the antimicrobial role of phagocytic B cells in teleost fish by comparing it with other professional phagocytes and mammalian B-1 B cells, and provide the application prospect of phagocytic B cells in developing vaccines as well as the prevention of fish diseases.

Published

2024

17. A bioinformatic analysis of T-cell epitope diversity in SARS-CoV-2 variants: association with COVID-19 clinical severity in the United States population.

Author

Kim, Grace J., Elnaggar, Jacob H., Varnado, Mallory, Feehan, Amy K., Tauzier, Darlene, Rose, Rebecca, Lamers, Susanna L., Sevalia, Maya, Nicholas, Najah, Gravois, Elizabeth, Fort, Daniel, Crabtree, Judy S., and Miele, Lucio

Subjects

SARS-CoV-2, COVID-19, SARS-CoV-2 Omicron variant, T cells

Abstract

Long-term immunity against severe acute respiratory syndrome coronavirus 2 (SARSCoV-2) requires the identification of T-cell epitopes affecting host immunogenicity. In this computational study, we explored the CD8+ epitope diversity estimated in 27 of the most common HLA-A and HLA-B alleles, representing most of the United States population. Analysis of 16 SARS-CoV-2 variants [B.1, Alpha (B.1.1.7), five Delta (AY.100, AY.25, AY.3, AY.3.1, AY.44), and nine Omicron (BA.1, BA.1.1, BA.2, BA.4, BA.5, BQ.1, BQ.1.1, XBB.1, XBB.1.5)] in analyzedMHC class I alleles revealed that SARS-CoV-2 CD8+ epitope conservation was estimated at 87.6%-96.5% in spike (S), 92.5%-99.6% in membrane (M), and 94.6%-99% in nucleocapsid (N). As the virus mutated, an increasing proportion of S epitopes experienced reduced predicted binding affinity: 70% of Omicron BQ.1-XBB.1.5 S epitopes experienced decreased predicted binding, as compared with ~3% and ~15% in the earlier strains Delta AY.100-AY.44 and Omicron BA.1-BA.5, respectively. Additionally, we identified several novel candidate HLA alleles thatmay be more susceptible to severe disease, notably HLA-A*32:01, HLA-A*26:01, and HLA-B*53:01, and relatively protected from disease, such as HLA-A*31:01, HLAB* 40:01, HLA-B*44:03, and HLA-B*57:01. Our findings support the hypothesis that viral genetic variation affecting CD8 T-cell epitope immunogenicity contributes to determining the clinical severity of acute COVID-19. Achieving long-term COVID-19 immunity will require an understanding of the relationship between T cells, SARS-CoV-2 variants, and host MHC class I genetics. This project is one of the first to explore the SARS-CoV-2 CD8+ epitope diversity that putatively impacts much of the United States population. [ABSTRACT FROM AUTHOR]

Published

2024

18. Structure and design of Langya virus glycoprotein antigens.

Author

Zhaoqian Wang, McCallum, Matthew, Lianying Yan, Gibson, Cecily A., Sharkey, William, Young-Jun Park, Dang, Ha V., Amaya, Moushimi, Person, Ashley, Broder, Christopher C., and Veesler, David

Subjects

*HENIPAVIRUSES, *HENDRA virus, *NIPAH virus, *MEMBRANE fusion, *ANTIGENS

Abstract

Langya virus (LayV) is a recently discovered henipavirus (HNV), isolated from febrile patients in China. HNV entry into host cells is mediated by the attachment (G) and fusion (F) glycoproteins which are the main targets of neutralizing antibodies. We show here that the LayV F and G glycoproteins promote membrane fusion with human, mouse, and hamster target cells using a different, yet unknown, receptor than Nipah virus (NiV) and Hendra virus (HeV) and that NiV-and HeV-elicited monoclonal and polyclonal antibodies do not cross-react with LayV F and G. We determined cryoelectron microscopy structures of LayV F, in the prefusion and postfusion states, and of LayV G, revealing their conformational landscape and distinct antigenicity relative to NiV and HeV. We computationally designed stabilized LayV G constructs and demonstrate the generalizability of an HNV F prefusion-stabilization strategy. Our data will support the development of vaccines and therapeutics against LayV and closely related HNVs. [ABSTRACT FROM AUTHOR]

Published

2024

19. Reverse engineering protection: A comprehensive survey of reverse vaccinology-based vaccines targeting viral pathogens.

Author

Ponne, Saravanaraman, Kumar, Rajender, Vanmathi, S.M., Brilhante, Raimunda Sâmia Nogueira, and Kumar, Chinnadurai Raj

Subjects

*VIRAL vaccines, *REVERSE engineering, *VACCINE effectiveness, *PEPTIDE vaccines, *VACCINE development

Abstract

Vaccines have significantly reduced the impact of numerous deadly viral infections. However, there is an increasing need to expedite vaccine development in light of the recurrent pandemics and epidemics. Also, identifying vaccines against certain viruses is challenging due to various factors, notably the inability to culture certain viruses in cell cultures and the wide-ranging diversity of MHC profiles in humans. Fortunately, reverse vaccinology (RV) efficiently overcomes these limitations and has simplified the identification of epitopes from antigenic proteins across the entire proteome, streamlining the vaccine development process. Furthermore, it enables the creation of multiepitope vaccines that can effectively account for the variations in MHC profiles within the human population. The RV approach offers numerous advantages in developing precise and effective vaccines against viral pathogens, including extensive proteome coverage, accurate epitope identification, cross-protection capabilities, and MHC compatibility. With the introduction of RV, there is a growing emphasis among researchers on creating multiepitope-based vaccines aiming to stimulate the host's immune responses against multiple serotypes, as opposed to single-component monovalent alternatives. Regardless of how promising the RV-based vaccine candidates may appear, they must undergo experimental validation to probe their protection efficacy for real-world applications. The time, effort, and resources allocated to the laborious epitope identification process can now be redirected toward validating vaccine candidates identified through the RV approach. However, to overcome failures in the RV-based approach, efforts must be made to incorporate immunological principles and consider targeting the epitope regions involved in disease pathogenesis, immune responses, and neutralizing antibody maturation. Integrating multi-omics and incorporating artificial intelligence and machine learning-based tools and techniques in RV would increase the chances of developing an effective vaccine. This review thoroughly explains the RV approach, ideal RV-based vaccine construct components, RV-based vaccines designed to combat viral pathogens, its challenges, and future perspectives. [ABSTRACT FROM AUTHOR]

Published

2024

20. The 2023 Nobel Prize in Physiology or Medicine: A Pandora's Box of Goldilocks Stories.

Author

Rath, Satyajit

Subjects

NOBEL Prize in Physiology or Medicine

Published

2024

21. Exosome-Mediated Antigen Delivery: Unveiling Novel Strategies in Viral Infection Control and Vaccine Design.

Author

El Safadi, Daed, Mokhtari, Alexandre, Krejbich, Morgane, Lagrave, Alisé, Hirigoyen, Ugo, Lebeau, Grégorie, Viranaicken, Wildriss, and Krejbich-Trotot, Pascale

Subjects

INFECTION control, SECRETORY granules, VIRUS diseases, EXTRACELLULAR vesicles, VIRAL antigens

Abstract

Exosomes are small subtypes of extracellular vesicles (EVs) naturally released by different types of cells into their environment. Their physiological roles appear to be multiple, yet many aspects of their biological activities remain to be understood. These vesicles can transport and deliver a variety of cargoes and may serve as unconventional secretory vesicles. Thus, they play a crucial role as important vectors for intercellular communication and the maintenance of homeostasis. Exosome production and content can vary under several stresses or modifications in the cell microenvironment, influencing cellular responses and stimulating immunity. During infectious processes, exosomes are described as double-edged swords, displaying both beneficial and detrimental effects. Owing to their tractability, the analysis of EVs from multiple biofluids has become a booming tool for monitoring various pathologies, from infectious to cancerous origins. In this review, we present an overview of exosome features and discuss their particular and ambiguous functions in infectious contexts. We then focus on their properties as diagnostic or therapeutic tools. In this regard, we explore the capacity of exosomes to vectorize immunogenic viral antigens and their function in mounting adaptive immune responses. As exosomes provide interesting platforms for antigen presentation, we further review the available data on exosome engineering, which enables peptides of interest to be exposed at their surface. In the light of all these data, exosomes are emerging as promising avenues for vaccine strategies. [ABSTRACT FROM AUTHOR]

Published

2024

22. Exploring computational approaches to design mRNA Vaccine against vaccinia and Mpox viruses

Author

Elijah K. Oladipo, Olanrewaju D. Oyelakin, Abdulsamad O. Aiyelabegan, Elizabeth O. Olajide, Victoria O. Olatayo, Kaothar P. Owolabi, Yewande B. Shittu, Rhoda O. Olugbodi, Hezekiah A. Ajala, Raji A. Rukayat, Deborah O. Olayiwola, Boluwatife A. Irewolede, Esther M. Jimah, Julius K. Oloke, Taiwo O. Ojo, Olumide F. Ajani, Bamidele A. Iwalokun, Olatunji M. Kolawole, Olumuyiwa E. Ariyo, Daniel A. Adediran, Seun E. Olufemi, and Helen Onyeaka

Subjects

immunoinformatics, Mpox virus, mRNA vaccine, Pox viruses, vaccine design, vaccinia virus, Immunologic diseases. Allergy, RC581-607

Abstract

Abstract Background Messenger RNA (mRNA) vaccines emerged as a powerful tool in the fight against infections. Unlike traditional vaccines, this unique type of vaccine elicits robust and persistent innate and humoral immune response with a unique host cell‐mediated pathogen gene expression and antigen presentation. Methods This offers a novel approach to combat poxviridae infections. From the genome of vaccinia and Mpox viruses, three key genes (E8L, E7R, and H3L) responsible for virus attachment and virulence were selected and employed for designing the candidate mRNA vaccine against vaccinia and Mpox viral infection. Various bioinformatics tools were employed to generate (B cell, CTL, and HTL) epitopes, of which 28 antigenic and immunogenic epitopes were selected and are linked to form the mRNA vaccine construct. Additional components, including a 5′ cap, 5′ UTR, adjuvant, 3′ UTR, and poly(A) tail, were incorporated to enhance stability and effectiveness. Safety measures such as testing for human homology and in silico immune simulations were implemented to avoid autoimmunity and to mimics the immune response of human host to the designed mRNA vaccine, respectively. The mRNA vaccine's binding affinity was evaluated by docking it with TLR‐2, TLR‐3, TLR‐4, and TLR‐9 receptors which are subsequently followed by molecular dynamics simulations for the highest binding one to predict the stability of the binding complex. Results With a 73% population coverage, the mRNA vaccine looks promising, boasting a molecular weight of 198 kDa and a molecular formula of C8901H13609N2431O2611S48 and it is said to be antigenic, nontoxic and nonallergic, making it safe and effective in preventing infections with Mpox and vaccinia viruses, in comparison with other insilico‐designed vaccine for vaccinia and Mpox viruses. Conclusions However, further validation through in vivo and in vitro techniques is underway to fully assess its potential.

Published

2024

23. Bioinformatic elucidation of conserved epitopes to design a potential vaccine candidate against existing and emerging SARS-CoV-2 variants of concern

Author

Amber Rastogi, Sakshi Gautam, and Manoj Kumar

Subjects

SARS-CoV-2, COVID-19, Variants of concern, Immunogenic epitope, Multi-epitope, Vaccine design, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

The COVID-19 pandemic caused by SARS-CoV-2 poses a significant adverse effects on health and economy globally. Due to mutations in genome, COVID-19 vaccine efficacy decreases. We used immuno-informatics to design a Multi epitope vaccine (MEV) candidate for SARS-CoV-2 variants of concern (VOCs). Hence, we predicted binders/epitopes MHC-I, CD8+, MHC-II, CD4+, and CTLs from spike, membrane and envelope proteins of VOCs. In addition, we assessed the conservation of these binders and epitopes across different VOCs. Subsequently, we designed MEV by combining the predicted CTL and CD4+ epitopes from spike protein, peptide linkers, and an adjuvant. Further, we evaluated the binding of MEV candidate against immune receptors namely HLA class I histocompatibility antigen, HLA class II histocompatibility antigen, and TLR4, achieving binding scores of −1265.3, −1330.7, and −1337.9. Molecular dynamics and normal mode analysis revealed stable docking complexes. Moreover, immune simulation suggested MEV candidate elicits both innate and adaptive immune response. We anticipate that this conserved MEV candidate will provide protection from VOCs and emerging strains.

Published

2024

24. PdPANA: phagemid display as peptide array for neutralizing antibodies, an engineered in silico vaccine candidate against COVID-19

Author

Javier Uzcátegui, Khaleel Mullah, Daniel Buvat de Virgini, Andrés Mendoza, Rafael Urdaneta, and Alejandra Naranjo

Subjects

PdPANA, phage-display, COVID-19, SARS-CoV-2, immunoinformatics, vaccine design, Physiology, QP1-981

Abstract

The COVID-19 pandemic has tested the technical, scientific, and industrial resources of all countries worldwide. Faced with the absence of pharmacological strategies against the disease, an effective plan for vaccinating against SARS-CoV-2 has been essential. Due to the lack of production means and necessary infrastructure, only a few nations could adequately confront this pathogen with a production, storage, and distribution scheme in place. This disease has become endemic in many countries, especially in those that are developing, thus necessitating solutions tailored to their reality. In this paper, we propose an in silico method to guide the design towards a thermally stable, universal, efficient, and safe COVID-19 vaccine candidate against SARS-CoV-2 using bioinformatics, immunoinformatics, and molecular modeling approaches for the selection of antigens with higher immunogenic potential, incorporating them into the surface of the M13 phage. Our work focused on using phagemid display as peptide array for neutralizing antibodies (PdPANA). This alternative approach might be useful during the vaccine development process, since it could bring improvements in terms of cost-effectiveness in production, durability, and ease of distribution of the vaccine under less stringent thermal conditions compared to existing methods. Our results suggest that in the heavily glycosylated region of SARS-CoV-2 Spike protein (aa 344–583), from its inter-glycosylated regions, useful antigenic peptides can be obtained to be used in M13 phagemid display system. PdPANA, our proposed method might be useful to overcome the classic shortcoming posed by the phage-display technique (i.e., the time-consuming task of in vitro screening through great sized libraries with non-useful recombinant proteins) and obtain the most ideal recombinant proteins for vaccine design purposes.

Published

2024

25. Designing a smallpox B-cell and T-cell multi-epitope subunit vaccine using a comprehensive immunoinformatics approach

Author

Changqing Yu, Qi Wu, Jiuqing Xin, Qiujuan Yu, Zhixin Ma, Mengzhou Xue, Qingyuan Xu, and Chunfu Zheng

Subjects

smallpox, variola virus, vaccine design, multi-epitopes vaccine, Microbiology, QR1-502

Abstract

ABSTRACT Smallpox is a highly contagious human disease caused by the variola virus. Although the disease was eliminated in 1979 due to its highly contagious nature and historical pathogenicity, with a mortality rate of up to 30%, this virus is an important candidate for biological weapons. Currently, vaccines are the critical measures to prevent this virus infection and spread. In this study, we designed a peptide vaccine using immunoinformatics tools, which have the potential to activate human immunity against variola virus infection efficiently. The design of peptides derives from vaccine-candidate proteins showing protective potential in vaccinia WR strains. Potential non-toxic and nonallergenic T-cell and B-cell binding and cytokine-inducing epitopes were then screened through a priority prediction using special linkers to connect B-cell epitopes and T-cell epitopes, and an appropriate adjuvant was added to the vaccine construction to enhance the immunogenicity of the peptide vaccine. The 3D structure display, docking, and free energy calculation analysis indicate that the binding affinity between the vaccine peptide and Toll-like receptor 3 is high, and the vaccine receptor complex is highly stable. Notably, the vaccine we designed is obtained from the protective protein of the vaccinia and combined with preventive measures to avoid side effects. This vaccine is highly likely to produce an effective and safe immune response against the variola virus infection in the body.IMPORTANCEIn this work, we designed a vaccine with a cluster of multiple T-cell/B-cell epitopes, which should be effective in inducing systematic immune responses against variola virus infection. Besides, this work also provides a reference in vaccine design for preventing monkeypox virus infection, which is currently prevalent.

Published

2024

26. Immunological Considerations for the Development of an Effective Herpes Vaccine

Author

Mahmoud Singer and Mohamed I. Husseiny

Subjects

vaccine design, herpes simplex virus (HSV), virus latency, innate immunity, adaptive immunity, CD8 T cells, Biology (General), QH301-705.5

Abstract

Research is underway to develop a vaccine to prevent and cure infection from herpes simplex virus (HSV). It emphasizes the critical need for immunization to address public health issues and the shortcomings of existing treatment options. Furthermore, studies on the HSV vaccine advance the field of immunology and vaccine creation, which may help in the battle against other viral illnesses. The current lack of such a vaccine is, in part, due to herpes viral latency in sensory ganglions. Current vaccines rely on tissue-resident memory CD8+ T cells, which are known to provide protection against subsequent HSV reinfection and reactivation without correlating with other immune subsets. For that reason, there is no effective vaccine that can provide protection against latent or recurrent herpes infection. This review focuses on conventional methods for evaluating the efficacy of a herpes vaccine using differential CD8+ T cells and important unaccounted immune aspects for designing an effective vaccine against herpes.

Published

2024

27. Multi-epitope-based vaccine designing against Junín virus glycoprotein: immunoinformatics approach.

Author

Praveen, Mallari

Subjects

*DRUG discovery, *HEMORRHAGIC fever, *VACCINES, *ENDEMIC diseases, *B cells

Abstract

Background: The Junín virus (JUNV) is well known for causing argentine haemorrhagic fever (AHF), a severe endemic disease in farming premises. The glycoprotein of JUNV is an important therapeutic target in vaccine design. Despite using drugs and neutralizing weakened antibodies being used in the medication, neither the severity reduced nor eradicated the infection. However, this constraint can be resolved by immunoinformatic approaches. Results: The glycoprotein fasta sequence was retrieved from NCBI to anticipate the B cell and T cell epitopes through the Immune Epitope Database. Furthermore, each epitope underwent validation in Vaxijen 2.0, Aller Top, and Toxin Pred to find antigenic, nonallergic, and non-toxic peptides. Moreover, the vaccine is designed with appropriate adjuvants and linkers. Subsequently, physicochemical properties were determined in ProtParam including solubility and disulphide bonds in the SCRATCH server. The vaccine 3D structure was built using I-TASSER and refined in ModRefine. Docking between JUNV glycoprotein (PDB ID:5NUZ) with a built vaccine revealed a balanced docked complex visualized in the Drug Discovery studio, identified 280 hydrogen bonds between them. The docking score of − 15.5 kcal/mol was determined in the MM/GBSA analysis in HawkDock. MD simulations employed using the GROMACS at 20 ns resulted in minimal deviation and fewer fluctuations, particularly with high hydrogen bond-forming residues. Conclusion: However, these findings present a potential vaccine for developing against JUNV glycoprotein after validating the epitopes and 3D vaccine construct through in silico methods. Therefore, further investigation in the wet laboratory is necessary to confirm the potentiality of the predicted vaccine. [ABSTRACT FROM AUTHOR]

Published

2024

28. Rational design of a cross-type HPV vaccine through immunodominance shift guided by a cross-neutralizing antibody.

Author

Wang, Zhiping, Wang, Daning, Chen, Jie, Gao, Fei, Jiang, Yanan, Yang, Chengyu, Qian, Ciying, Chi, Xin, Zhang, Shuyue, Xu, Yujie, Lu, Yihan, Shen, Jingjia, Zhang, Chengzong, Li, Jinjin, Zhou, Lizhi, Li, Tingting, Zheng, Qingbing, Yu, Hai, Li, Shaowei, and Xia, Ningshao

Subjects

*IMMUNOGLOBULINS, *HUMAN papillomavirus vaccines, *MONOCLONAL antibodies, *HUMAN papillomavirus, *VACCINE immunogenicity, *VIRUS-like particles, *SITE-specific mutagenesis

Abstract

[Display omitted] In vaccine development, broadly or cross-type neutralizing antibodies (bnAbs or cnAbs) are frequently targeted to enhance protection. Utilizing immunodominant antibodies could help fine-tune vaccine immunogenicity and augment the precision of immunization strategies. However, the methodologies to capitalize on the attributes of bnAbs in vaccine design have not been clearly elucidated. In this study, we discovered a cross-type neutralizing monoclonal antibody, 13H5, against human papillomavirus 6 (HPV6) and HPV11. This nAb exhibited a marked preference for HPV6, demonstrating superior binding activity to virus-like particles (VLPs) and significantly higher prevalence in anti-HPV6 human serum as compared to HPV11 antiserum (90% vs. 31%). Through co-crystal structural analysis of the HPV6 L1 pentamer:13H5 complex, we delineated the epitope as spanning four segments of amino acids (Phe42-Ala47, Gly172-Asp173, Glu255-Val275, and Val337-Tyr351) on the L1 surface loops. Further interaction analysis and site-directed mutagenesis revealed that the Ser341 residue in the HPV6 HI loop plays a critical role in the interaction between 13H5 and L1. Substituting Ser341 with alanine, which is the residue type present in HPV11 L1, almost completely abolished binding activity to 13H5. By swapping amino acids in the HPV11 HI loop with corresponding residues in HPV6 L1 (Ser341, Thr338, and Thr339), we engineered chimeric HPV11-6HI VLPs. Remarkably, the chimeric HPV11-6HI VLPs shifted the high immunodominance of 13H5 from HPV6 to the engineered VLPs and yielded comparable neutralization titers for both HPV6 and HPV11 in mice and non-human primates. This approach paves the way for the design of broadly protective vaccines from antibodies within the main immunization reservoir. [ABSTRACT FROM AUTHOR]

Published

2024

29. DiscoTope-3.0: improved B-cell epitope prediction using inverse folding latent representations.

Author

Høie, Magnus Haraldson, Gade, Frederik Steensgaard, Johansen, Julie Maria, Würtzen, Charlotte, Winther, Ole, Nielsen, Morten, and Marcatili, Paolo

Subjects

INTERNET servers, VACCINE development, FORECASTING, LEARNING strategies, EPITOPES

Abstract

Accurate computational identification of B-cell epitopes is crucial for the development of vaccines, therapies, and diagnostic tools. However, current structure-based prediction methods face limitations due to the dependency on experimentally solved structures. Here, we introduce DiscoTope-3.0, a markedly improved B-cell epitope prediction tool that innovatively employs inverse folding structure representations and a positive-unlabelled learning strategy, and is adapted for both solved and predicted structures. Our tool demonstrates a considerable improvement in performance over existing methods, accurately predicting linear and conformational epitopes across multiple independent datasets. Most notably, DiscoTope-3.0 maintains high predictive performance across solved, relaxed and predicted structures, alleviating the need for experimental structures and extending the general applicability of accurate B-cell epitope prediction by 3 orders of magnitude. DiscoTope-3.0 is made widely accessible on two web servers, processing over 100 structures per submission, and as a downloadable package. In addition, the servers interface with RCSB and AlphaFoldDB, facilitating large-scale prediction across over 200 million cataloged proteins. DiscoTope-3.0 is available at: https://services.healthtech.dtu.dk/service.php?DiscoTope-3.0. [ABSTRACT FROM AUTHOR]

Published

2024

30. Structure and Dynamics Guiding Design of Antibody Therapeutics and Vaccines.

Author

Fernández-Quintero, Monica L., Pomarici, Nancy D., Fischer, Anna-Lena M., Hoerschinger, Valentin J., Kroell, Katharina B., Riccabona, Jakob R., Kamenik, Anna S., Loeffler, Johannes R., Ferguson, James A., Perrett, Hailee R., Liedl, Klaus R., Han, Julianna, and Ward, Andrew B.

Subjects

*MOLECULAR recognition, *IMMUNOGLOBULINS, *X-ray crystallography, *IMMUNE response, *IMMUNE recognition

Abstract

Antibodies and other new antibody-like formats have emerged as one of the most rapidly growing classes of biotherapeutic proteins. Understanding the structural features that drive antibody function and, consequently, their molecular recognition is critical for engineering antibodies. Here, we present the structural architecture of conventional IgG antibodies alongside other formats. We emphasize the importance of considering antibodies as conformational ensembles in solution instead of focusing on single-static structures because their functions and properties are strongly governed by their dynamic nature. Thus, in this review, we provide an overview of the unique structural and dynamic characteristics of antibodies with respect to their antigen recognition, biophysical properties, and effector functions. We highlight the numerous technical advances in antibody structure prediction and design, enabled by the vast number of experimentally determined high-quality structures recorded with cryo-EM, NMR, and X-ray crystallography. Lastly, we assess antibody and vaccine design strategies in the context of structure and dynamics. [ABSTRACT FROM AUTHOR]

Published

2023

31. Development and application of EpitopeScan, a Python3 toolset for mutation tracking in SARS-CoV-2 immunogenic epitopes

Author

Alexander Kovalenko and Sebastien Viatte

Subjects

SARS-CoV-2, epitope, mutation tracking, vaccine design, rheumatoid arthritis, immune monitoring, Immunologic diseases. Allergy, RC581-607

Abstract

IntroductionOutbreaks of coronaviruses and especially the recent COVID-19 pandemic emphasize the importance of immunological research in this area to mitigate the effect of future incidents. Bioinformatics approaches are capable of providing multisided insights from virus sequencing data, although currently available software options are not entirely suitable for a specific task of mutation surveillance within immunogenic epitopes of SARS-CoV-2.MethodHere, we describe the development of a mutation tracker, EpitopeScan, a Python3 package with command line and graphical user interface tools facilitating the investigation of the mutation dynamics in SARS-CoV-2 epitopes via analysis of multiple-sequence alignments of genomes over time. We provide an application case by examining three Spike protein-derived immunodominant CD4+ T-cell epitopes restricted by HLA-DRB1*04:01, an allele strongly associated with susceptibility to rheumatoid arthritis (RA). Mutations in these peptides are relevant for immune monitoring of CD4+ T-cell responses against SARS-CoV-2 spike protein in patients with RA. The analysis focused on 2.3 million SARS-CoV-2 genomes sampled in England.ResultsWe detail cases of epitope conservation over time, partial loss of conservation, and complete divergence from the wild type following the emergence of the N969K Omicron-specific mutation in November 2021. The wild type and the mutated peptide represent potential candidates to monitor variant-specific CD4+ T-cell responses. EpitopeScan is available via GitHub repository https://github.com/Aleksandr-biochem/EpitopeScan.

Published

2024

32. An inclusive approach to designing a multi-epitope chimeric vaccine for Taenia infections by integrating proteomics and reverse vaccinology

Author

Swati Sharma, Ujjawal Sharan, Rimanpreet Kaur, Anubha Chaudhary, Suraj S. Rawat, Anand K. Keshri, Naina Arora, and Amit Prasad

Subjects

helminths, Taenia genus, MALDI, immune-informatics, vaccine design, molecular dynamic simulations, Arctic medicine. Tropical medicine, RC955-962

Abstract

BackgroundSoil- and water-transmitted helminths are a major concern in the developing world due to their high prevalence. More than a quarter of the population were estimated to be infected with helminths in these endemic zones.Research designAn in silico approach was used to design a vaccine construct against the Taenia genus utilizing the proteomic information and evaluation of the construct using immune-informatics.ResultsOur study identified 451 conserved proteins in Taenia spp. using the existing proteome; out of these, 141 were found to be expressed in cysticerci. These proteins were screened for antigenic epitopes and a multi-subunit vaccine was constructed. The constructed vaccine was assessed for its efficacy in mounting the appropriate immune response. Our constructed vaccine showed stability and optimal performance against the TLR 4 receptor, which is reported to be upregulated in Taenia infections in hosts.ConclusionImmune-informatics tools help design vaccines for neglected diseases such as those attributed to helminths, which are known to cause widespread morbidity. Our vaccine construct holds tremendous potential in conferring protection against all Taenia spp. of clinical relevance to human.

Published

2024

33. Multi-epitope vaccine design against leishmaniasis using IFN-γ inducing epitopes from immunodominant gp46 and gp63 proteins

Author

Amir Dehghani, Mina Mamizadeh, Atena Karimi, Seyyed Amir Hosseini, Davood Siamian, Morteza Shams, Shadan Ghiabi, Gholam Basati, and Amir Abaszadeh

Subjects

Leishmania major, Leishmaniasis, Gp46, Gp63, Vaccine design, In silico, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

There is no currently approved human vaccine against leishmaniasis. Utilization of immunogenic antigens and their epitopes capable of enhancing immune responses against leishmaniasis is a crucial step for rational in silico vaccine design. The objective of this study was to generate and evaluate a potential vaccine candidate against leishmaniasis, designed by immunodominant proteins from gp46 and gp63 of Leishmania major, which can stimulate helper T-lymphocytes (HTL) and cytotoxic T-lymphocytes (CTL). For this aim, the IFN-γ-inducing MHC-I and MHC-II binders were predicted for each examined protein (gp46 and gp63) and connected with appropriate linkers, along with an adjuvant (Mycobacterium tuberculosis L7/L12) and a histidine tag. The vaccine’s stability, antigenicity, structure, and interaction with the TLR-4 receptor were evaluated in silico. The resulting chimeric vaccine was composed of 344 amino acids and had a molecular weight of 35.64 kDa. Physico-chemical properties indicated that it was thermotolerant, soluble, highly antigenic, and non-allergenic. Predictions of the secondary and tertiary structures were made, and further analyses confirmed that the vaccine construct could interact with the human TLR-4 receptor. Virtual immune simulation demonstrated strong stimulation of T-cell responses, particularly by an increase in IFN-γ, following vaccination. In summary, the in silico data indicated that the vaccine candidate showed high antigenicity in humans. It was also found to trigger significant levels of clearance mechanisms and other components of the cellular immune profile. Nevertheless, further wet experiments are required to properly assess the efficacy of this multi-epitope vaccine candidate against leishmaniasis.

Published

2024

34. Intestinal Microbiota and Its Effect on Vaccine-Induced Immune Amplification and Tolerance

Author

Yixin Liu, Jianfeng Zhou, Yushang Yang, Xiangzheng Chen, Longqi Chen, and Yangping Wu

Subjects

intestinal microbiota, vaccine, immune amplification, immune tolerance, vaccine design, outer membrane vesicles, Medicine

Abstract

This review provides the potential of intestinal microbiota in vaccine design and application, exploring the current insights into the interplay between the intestinal microbiota and the immune system, with a focus on its intermediary function in vaccine efficacy. It summarizes families and genera of bacteria that are part of the intestinal microbiota that may enhance or diminish vaccine efficacy and discusses the foundational principles of vaccine sequence design and the application of gut microbial characteristics in vaccine development. Future research should further investigate the use of multi-omics technologies to elucidate the interactive mechanisms between intestinal microbiota and vaccine-induced immune responses, aiming to optimize and improve vaccine design.

Published

2024

35. InflANNet: a neural network predictor for Influenza A CTL and HTL epitopes to aid robust vaccine design

Author

R. Karthika, Sathya Muthusamy, and Prince R. Prabhu

Subjects

Vaccine design, Influenza A, T-cell epitopes, Neuraminidase, Machine learning, Deep learning, Science

Abstract

Abstract Background An efficient and reliable data-driven method is essential to aid robust vaccine design, particularly in the case of an epidemic like Influenza A. Although various prediction tools are existing, most of them focus on the MHC-peptide binding affinity predictions. A tool which can incorporate more features other than binding affinity which characterizes the T-cell epitopes as vaccine candidates would be of much value in this scenario. The objective of this study is to develop two separate neural network models for the predictions of CTLs (cytotoxic T lymphocyte) and HTLs (helper T lymphocyte) with the manually curated datasets as a part of this study from the raw viral sequences of Influenza A. Results The epitope datasets curated from the raw sequences of the broadly protective Neuraminidase protein were utilized for building and training the models for CTLs and HTLs. Each set consisted of nearly a balanced mix of vaccine candidates and non-vaccine candidates for both CTLs and HTLs. These were fed to neural networks as they are proven to be powerful for the predictions when compared with the other machine/deep learning algorithms. A set of epitopes experimentally proved were chosen to validate the model which was also tested through mutational analysis and cross-reactivity. The prepared dataset gave some valuable insights into the epitope distribution statistics and their conservancy in various outbreaks. An idea about the most probable range of peptide-MHC binding affinities was also obtained. Both the models performed well giving high accuracies when validated. These epitopes were checked for cross-reactivity with other antigens upon which it proved to be highly conservative and ideal for vaccine formulation. Conclusions The combination of various features and the resulting model efficiencies in turn proved that the collected features are valuable in the easy identification of the vaccine candidates. This suggests that our proposed models have more potential for conserved epitope prediction compared to other existing models trained on similar data and features. The possibility of refining the model with more set threshold values based on more parameters is an added feature that makes it more user driven. Furthermore, the uniqueness of the model due to exclusive set of Neuraminidase epitopes paves a robust way for rapid vaccine design. Graphical abstract

Published

2023

36. Advanced subunit vaccine delivery technologies: From vaccine cascade obstacles to design strategies

Author

Yingying Hou, Min Chen, Yuan Bian, Xi Zheng, Rongsheng Tong, and Xun Sun

Subjects

Subunit vaccine, Vaccine design, Lymph node targeting, Dendritic cell subset targeting, B cell modulation, Antigen cross-presentation, Therapeutics. Pharmacology, RM1-950

Abstract

Designing and manufacturing safe and effective vaccines is a crucial challenge for human health worldwide. Research on adjuvant-based subunit vaccines is increasingly being explored to meet clinical needs. Nevertheless, the adaptive immune responses of subunit vaccines are still unfavorable, which may partially be attributed to the immune cascade obstacles and unsatisfactory vaccine design. An extended understanding of the crosstalk between vaccine delivery strategies and immunological mechanisms could provide scientific insight to optimize antigen delivery and improve vaccination efficacy. In this review, we summarized the advanced subunit vaccine delivery technologies from the perspective of vaccine cascade obstacles after administration. The engineered subunit vaccines with lymph node and specific cell targeting ability, antigen cross-presentation, T cell activation properties, and tailorable antigen release patterns may achieve effective immune protection with high precision, efficiency, and stability. We hope this review can provide rational design principles and inspire the exploitation of future subunit vaccines.

Published

2023

37. Understanding Fc function for rational vaccine design against pathogens

Author

Kathryn A. Bowman, Paulina Kaplonek, and Ryan P. McNamara

Subjects

antibody, Fc receptor, Fc-effector function, vaccine, vaccine design, Microbiology, QR1-502

Abstract

ABSTRACTAntibodies represent the primary correlate of immunity following most clinically approved vaccines. However, their mechanisms of action vary from pathogen to pathogen, ranging from neutralization, to opsonophagocytosis, to cytotoxicity. Antibody functions are regulated both by antigen specificity (Fab domain) and by the interaction of their Fc domain with distinct types of Fc receptors (FcRs) present in immune cells. Increasing evidence highlights the critical nature of Fc:FcR interactions in controlling pathogen spread and limiting the disease state. Moreover, variation in Fc-receptor engagement during the course of infection has been demonstrated across a range of pathogens, and this can be further influenced by prior exposure(s)/immunizations, age, pregnancy, and underlying health conditions. Fc:FcR functional variation occurs at the level of antibody isotype and subclass selection as well as post-translational modification of antibodies that shape Fc:FcR-interactions. These factors collectively support a model whereby the immune system actively harnesses and directs Fc:FcR interactions to fight disease. By defining the precise humoral mechanisms that control infections, as well as understanding how these functions can be actively tuned, it may be possible to open new paths for improving existing or novel vaccines.

Published

2024

38. An in silico approach to decipher immunogenic epitopes in Toxoplasma gondii GRA1 and GRA3

Author

Narges Safari, Alireza Khodaei Ardakan, Erfan Hamedi, Faezeh Kalantarzadeh, Pedram Kaveh, Parham Rahmanian, Shadan Ghiabi, Seyed Amir Hosseini, Davood Siamian, Mohammad Gorgipour, and Mohammad Arad Zandieh

Subjects

Toxoplasma gondii, GRA, Vaccine design, Immunization, Computer applications to medicine. Medical informatics, R858-859.7

Abstract

Toxoplasma gondii (T. gondii) infection is a worldwide parasitic infection, causing serious threats to humans and livestock. Due to lack of a commercial vaccine, this study aimed at biochemical characterization and identification of immunogenic targets in GRA1 and GRA3 of T. gondii. A number of immunoinformatics web servers were used to predict antigenicity, allergenicity, solubility, physico-chemical properties, subcellular localization, post-translational modifications (PTMs), signal peptide and transmembrane domain, secondary and tertiary structure, along with B- and T-cell epitopes. Good antigenicity scores of 0.4815 (GRA1) and 0.5425 (GRA2) were predicted, without any allergenicity and Ig epitopes. Both proteins were soluble, hydrophilic and thermotolerable molecules. The length and molecular weight (MW) of GRA1 were 190 amino acids and 20.14 kDa, respectively, while the length of GRA3 was 222 residues with a MW of 24.24 kDa. Several antigenic epitopes were found in both protein sequences, some which were capable to induce IFN‐γ and/or IL-4 cytokines. In conclusion, we obtained comprehensive data on potential immunogenic epitopes through computer simulations. These findings serve as a basis for future Toxoplasma vaccine researches.

Published

2024

39. Immunoinformatic exploration of a multi-epitope-based peptide vaccine candidate targeting emerging variants of SARS-CoV-2.

Author

Kumar, K. M., Karthik, Yalpi, Ramakrishna, D., Balaji, S., Skariyachan, Sinosh, Murthy, T. P. Krishna, Sakthivel, Kunnathur Murugesan, Alotaibi, Badriyah S., Shukry, Mustafa, Sayed, Samy M., and Mushtaq, Muntazir

Subjects

SARS-CoV-2, PEPTIDES, ESCHERICHIA coli, PEPTIDE vaccines, B cells, SARS-CoV-2 Omicron variant, IMMUNOGLOBULINS, GENETIC code

Abstract

Many countries around the world are facing severe challenges due to the recently emerging variants of SARS-CoV-2. Over the last few months, scientists have been developing treatments, drugs, and vaccines to subdue the virus and prevent its transmission. In this context, a peptide-based vaccine construct containing pathogenic proteins of the virus known to elicit an immune response was constructed. An analysis of the spike protein-based epitopes allowed us to design an "epitope-based subunit vaccine" against coronavirus using the approaches of "reverse vaccinology" and "immunoinformatics." Computational experimentation and a systematic, comprehensive protocol were followed with an aim to develop and design a multi-epitope-based peptide (MEBP) vaccine candidate. Our study attempted to predict an MEBP vaccine by introducing mutations of SARS-CoV-2 (Delta, Lambda, Iota, Omicron, and Kappa) in Spike glycoprotein and predicting dual-purpose epitopes (B-cell and T-cell). This was followed by screening the selected epitopes based on antigenicity, allergenicity, and population coverage and constructing theminto a vaccine by using linkers and adjuvants. The vaccine construct was analyzed for its physicochemical properties and secondary structure prediction, and a 3D structure was built, refined, and validated. Furthermore, the peptide-protein interaction of the vaccine construct with Toll-like receptor (TLR) molecules was performed. Immune profiling was performed to check the immune response. Codon optimization of the vaccine construct was performed to obtain the GC content before cloning it into the E. coli genome, facilitating its progression it into a vector. Finally, an in-silico simulation of the vaccine-protein complex was performed to comprehend its stability and conformational behavior. [ABSTRACT FROM AUTHOR]

Published

2023

40. Artificial COVID-19 T-Cell Immunogen.

Author

Borgoyakova, M. B., Karpenko, L. I., Rudometov, A. P., Starostina, E. V., Zadorozhny, A. M., Kisakova, L. A., Kisakov, D. N., Sharabrin, S. V., Ilyichev, A. A., and Bazhan, S. I.

Subjects

*SARS-CoV-2, *SYNTHETIC genes, *COVID-19, *CELLULAR immunity, *VIRAL proteins

Abstract

An artificial T-cell immunogen consisting of conserved fragments of different proteins of the SARS-CoV-2 virus and its immunogenic properties were studied in BALB/c mice. To create a T-cell immunogen, we used an approach based on the design of artificial antigens that combine many epitopes from the main proteins of the SARS-CoV-2 virus in the one molecule. The gene of the engineered immunogen protein was cloned as part of the pVAX1 plasmid in two versions: with an N-terminal ubiquitin and without it. The obtained plasmids were analyzed for their ability to provide the synthesis of the immunogen protein in vitro and in vivo. It has been shown that protein product of the created artificial genes is actively processed in HEK293T cells and induces cellular immunity in mice. [ABSTRACT FROM AUTHOR]

Published

2023

41. A design strategy to generate a SARS‐CoV‐2 RBD vaccine that abrogates ACE2 binding and improves neutralizing antibody responses.

Author

Ratswohl, Christoph, Vázquez García, Clara, Ahmad, Ata ul Wakeel, Gonschior, Hannes, Lebedin, Mikhail, Silvis, Casper Ewijn, Spatt, Lisa, Gerhard, Cathrin, Lehmann, Martin, Sander, Leif E., Kurth, Florian, Olsson, Simon, and de la Rosa, Kathrin

Subjects

COVID-19 vaccines, ANTIBODY formation, ANGIOTENSIN converting enzyme, VACCINE effectiveness, VACCINE development

Abstract

The structure‐based design of antigens holds promise for developing vaccines with higher efficacy and improved safety profiles. We postulate that abrogation of host receptor interaction bears potential for the improvement of vaccines by preventing antigen‐induced modification of receptor function as well as the displacement or masking of the immunogen. Antigen modifications may yet destroy epitopes crucial for antibody neutralization. Here, we present a methodology that integrates deep mutational scans to identify and score SARS‐CoV‐2 receptor binding domain variants that maintain immunogenicity, but lack interaction with the widely expressed host receptor. Single point mutations were scored in silico, validated in vitro, and applied in vivo. Our top‐scoring variant receptor binding domain‐G502E prevented spike‐induced cell‐to‐cell fusion, receptor internalization, and improved neutralizing antibody responses by 3.3‐fold in rabbit immunizations. We name our strategy BIBAX for body‐inert, B‐cell‐activating vaccines, which in the future may be applied beyond SARS‐CoV‐2 for the improvement of vaccines by design. [ABSTRACT FROM AUTHOR]

Published

2023

42. Vaccinomics-based next- generation multi-epitope chimeric vaccine models prediction against Leishmania tropica - a hierarchical subtractive proteomics and immunoinformatics approach.

Author

Aiman, Sara, Ahmad, Abbas, Khan, Azmat Ali, Alanazi, Amer M., Samad, Abdus, Ali, Syed Luqman, Chunhua Li, Zhiguang Ren, Khan, Asifullah, and Khattak, Saadullah

Subjects

ESCHERICHIA coli, PROTEOMICS, PREDICTION models, LEISHMANIA, VACCINES, WHEAT breeding

Abstract

Leishmania tropica is a vector-borne parasitic protozoa that is the leading cause of leishmaniasis throughout the global tropics and subtropics. L. tropica is a multidrug-resistant parasite with a diverse set of serological, biochemical, and genomic features. There are currently no particular vaccines available to combat leishmaniasis. The present study prioritized potential vaccine candidate proteins of L. tropica using subtractive proteomics and vaccinomics approaches. These vaccine candidate proteins were downstream analyzed to predict B- and T-cell epitopesbasedonhighantigenicity, non-allergenic, and non-toxic characteristics. The top-ranked overlapping MHC-I, MHC-II, and linear B-cell epitopes were prioritized for model vaccine designing. The lead epitopes were linked together by suitable linker sequences to design multi-epitope constructs. Immunogenic adjuvant sequences were incorporated at the N-terminus of the model vaccine constructs to enhance their immunological potential. Among different combinations of constructs, four vaccine designs were selected based on their physicochemical and immunological features. The tertiary structure models of the designed vaccine constructs were predicted and verified. The molecular docking and molecular dynamic (MD) simulation analyses indicated that the vaccine design V1 demonstrated robust and stable molecular interactions with toll-like receptor 4 (TLR4). The top-ranked vaccine construct model-IV demonstrated significant expressive capability in the E. coli expression system during in-silico restriction cloning analysis. The results of the present study are intriguing; nevertheless, experimental bioassays are required to validate the efficacy of the predicted model chimeric vaccine. [ABSTRACT FROM AUTHOR]

Published

2023

43. Mining Autoimmune-Disorder-Linked Molecular-Mimicry Candidates in Clostridioides difficile and Prospects of Mimic-Based Vaccine Design: An In Silico Approach.

Author

Alshamrani, Saleh, Mashraqi, Mutaib M., Alzamami, Ahmad, Alturki, Norah A., Almasoudi, Hassan H., Alshahrani, Mohammed Abdulrahman, and Basharat, Zarrin

Subjects

CLOSTRIDIOIDES difficile, MOLECULAR mimicry, AUTOIMMUNE diseases, ALZHEIMER'S disease, BACTERIAL diseases

Abstract

Molecular mimicry, a phenomenon in which microbial or environmental antigens resemble host antigens, has been proposed as a potential trigger for autoimmune responses. In this study, we employed a bioinformatics approach to investigate the role of molecular mimicry in Clostridioides difficile-caused infections and the induction of autoimmune disorders due to this phenomenon. Comparing proteomes of host and pathogen, we identified 23 proteins that exhibited significant sequence homology and were linked to autoimmune disorders. The disorders included rheumatoid arthritis, psoriasis, Alzheimer's disease, etc., while infections included viral and bacterial infections like HIV, HCV, and tuberculosis. The structure of the homologous proteins was superposed, and RMSD was calculated to find the maximum deviation, while accounting for rigid and flexible regions. Two sequence mimics (antigenic, non-allergenic, and immunogenic) of ≥10 amino acids from these proteins were used to design a vaccine construct to explore the possibility of eliciting an immune response. Docking analysis of the top vaccine construct C2 showed favorable interactions with HLA and TLR-4 receptor, indicating potential efficacy. The B-cell and T-helper cell activity was also simulated, showing promising results for effective immunization against C. difficile infections. This study highlights the potential of C. difficile to trigger autoimmunity through molecular mimicry and vaccine design based on sequence mimics that trigger a defensive response. [ABSTRACT FROM AUTHOR]

Published

2023

44. In silico designing of multiepitope-based-peptide (MBP) vaccine against MAPK protein express for Alzheimer's disease in Zebrafish

Author

Yasir Arfat, Imran Zafar, Sheikh Arslan Sehgal, Mazhar Ayaz, Muhammad Sajid, Jamal Muhammad Khan, Muhammad Ahsan, Mohd Ashraf Rather, Azmat Ali Khan, Jamilah M. Alshehri, Shopnil Akash, Eugenie Nepovimova, Kamil Kuca, and Rohit Sharma

Subjects

Pharmacophore, Virtual screening, Molecular docking, Multiepitope, Vaccine design, MAPK1, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Understanding the role of the mitogen-activated protein kinases (MAPKs) signalling pathway is essential in advancing treatments for neurodegenerative disorders like Alzheimer's. In this study, we investigate in-silico techniques involving computer-based methods to extract the MAPK1 sequence. Our applied methods enable us to analyze the protein's structure, evaluate its properties, establish its evolutionary relationships, and assess its prevalence in populations. We also predict epitopes, assess their ability to trigger immune responses, and check for allergenicity using advanced computational tools to understand their immunological properties comprehensively. We apply virtual screening, docking, and structure modelling to identify promising drug candidates, analyze their interactions, and enhance drug design processes. We identified a total of 30 cell-targeting molecules against the MAPK1 protein, where we selected top 10 CTL epitopes (PAGGGPNPG, GGGPNPGSG, SAPAGGGPN, AVSAPAGGG, AGGGPNPGS, ATAAVSAPA, TAAVSAPAG, ENIIGINDI, INDIIRTPT, and NDIIRTPTI) for further evaluation to determine their potential efficacy, safety, and suitability for vaccine design based on strong binding potential. The potential to cover a large portion of the world's population with these vaccines is substantial—88.5 % for one type and 99.99 % for another. In exploring the molecular docking analyses, we examined a library of compounds from the ZINC database. Among them, we identified twelve compounds with the lowest binding energy. Critical residues in the MAPK1 protein, such as VAL48, LYS63, CYS175, ASP176, LYS160, ALA61, LEU165, TYR45, SER162, ARG33, PRO365, PHE363, ILE40, ASN163, and GLU42, are pivotal for interactions with these compounds. Our result suggests that these compounds could influence the protein's behaviour. Moreover, our docking analyses revealed that the predicted peptides have a strong affinity for the MAPK1 protein. These peptides form stable complexes, indicating their potential as potent inhibitors. This study contributes to the identification of new drug compounds and the screening of their desired properties. These compounds could potentially help reduce the excessive activity of MAPK1, which is linked to Alzheimer's disease.

Published

2023

45. Multi-epitope vaccine candidates based on mycobacterial membrane protein large (MmpL) proteins against Mycobacterium ulcerans

Author

Tamara Z. Ishwarlall, Victoria T. Adeleke, Leah Maharaj, Moses Okpeku, Adebayo A. Adeniyi, and Matthew A. Adeleke

Subjects

Buruli ulcer, immunoinformatics, Mycobacterium ulcerans, vaccine design, Biology (General), QH301-705.5

Abstract

Buruli ulcer (BU) is a neglected tropical disease. It is caused by the bacterium Mycobacterium ulcerans and is characterized by skin lesions. Several studies were performed testing the Bacillus Calmette-Guérin (BCG) vaccine in human and animal models and M. ulcerans-specific vaccines in animal models. However, there are currently no clinically accepted vaccines to prevent M. ulcerans infection. The aim of this study was to identify T-cell and B-cell epitopes from the mycobacterial membrane protein large (MmpL) proteins of M. ulcerans. These epitopes were analysed for properties including antigenicity, immunogenicity, non-allergenicity, non-toxicity, population coverage and the potential to induce cytokines. The final 8 CD8+, 12 CD4+ T-cell and 5 B-cell epitopes were antigenic, non-allergenic and non-toxic. The estimated global population coverage of the CD8+ and CD4+ epitopes was 97.71%. These epitopes were used to construct five multi-epitope vaccine constructs with different adjuvants and linker combinations. The constructs underwent further structural analyses and refinement. The constructs were then docked with Toll-like receptors. Three of the successfully docked complexes were structurally analysed. Two of the docked complexes successfully underwent molecular dynamics simulations (MDS) and post-MDS analysis. The complexes generated were found to be stable. However, experimental validation of the complexes is required.

Published

2023

46. Immunoinformatic exploration of a multi-epitope-based peptide vaccine candidate targeting emerging variants of SARS-CoV-2

Author

K. M. Kumar, Yalpi Karthik, D. Ramakrishna, S. Balaji, Sinosh Skariyachan, T. P. Krishna Murthy, Kunnathur Murugesan Sakthivel, Badriyah S. Alotaibi, Mustafa Shukry, Samy M. Sayed, and Muntazir Mushtaq

Subjects

SARS-CoV-2, vaccine design, in-silico modeling, peptide-protein docking, immune response profiling, MD simulation, Microbiology, QR1-502

Abstract

Many countries around the world are facing severe challenges due to the recently emerging variants of SARS-CoV-2. Over the last few months, scientists have been developing treatments, drugs, and vaccines to subdue the virus and prevent its transmission. In this context, a peptide-based vaccine construct containing pathogenic proteins of the virus known to elicit an immune response was constructed. An analysis of the spike protein-based epitopes allowed us to design an “epitope-based subunit vaccine” against coronavirus using the approaches of “reverse vaccinology” and “immunoinformatics.” Computational experimentation and a systematic, comprehensive protocol were followed with an aim to develop and design a multi-epitope-based peptide (MEBP) vaccine candidate. Our study attempted to predict an MEBP vaccine by introducing mutations of SARS-CoV-2 (Delta, Lambda, Iota, Omicron, and Kappa) in Spike glycoprotein and predicting dual-purpose epitopes (B-cell and T-cell). This was followed by screening the selected epitopes based on antigenicity, allergenicity, and population coverage and constructing them into a vaccine by using linkers and adjuvants. The vaccine construct was analyzed for its physicochemical properties and secondary structure prediction, and a 3D structure was built, refined, and validated. Furthermore, the peptide-protein interaction of the vaccine construct with Toll-like receptor (TLR) molecules was performed. Immune profiling was performed to check the immune response. Codon optimization of the vaccine construct was performed to obtain the GC content before cloning it into the E. coli genome, facilitating its progression it into a vector. Finally, an in-silico simulation of the vaccine–protein complex was performed to comprehend its stability and conformational behavior.

Published

2023

47. Vaccinomics-based next-generation multi-epitope chimeric vaccine models prediction against Leishmania tropica - a hierarchical subtractive proteomics and immunoinformatics approach

Author

Sara Aiman, Abbas Ahmad, Azmat Ali Khan, Amer M. Alanazi, Abdus Samad, Syed Luqman Ali, Chunhua Li, Zhiguang Ren, Asifullah Khan, and Saadullah Khattak

Subjects

leishmaniasis, reverse vaccinology, multi-epitope vaccine design, immunoinformatics, tropical diseases, vaccine design, Immunologic diseases. Allergy, RC581-607

Abstract

Leishmania tropica is a vector-borne parasitic protozoa that is the leading cause of leishmaniasis throughout the global tropics and subtropics. L. tropica is a multidrug-resistant parasite with a diverse set of serological, biochemical, and genomic features. There are currently no particular vaccines available to combat leishmaniasis. The present study prioritized potential vaccine candidate proteins of L. tropica using subtractive proteomics and vaccinomics approaches. These vaccine candidate proteins were downstream analyzed to predict B- and T-cell epitopes based on high antigenicity, non-allergenic, and non-toxic characteristics. The top-ranked overlapping MHC-I, MHC-II, and linear B-cell epitopes were prioritized for model vaccine designing. The lead epitopes were linked together by suitable linker sequences to design multi-epitope constructs. Immunogenic adjuvant sequences were incorporated at the N-terminus of the model vaccine constructs to enhance their immunological potential. Among different combinations of constructs, four vaccine designs were selected based on their physicochemical and immunological features. The tertiary structure models of the designed vaccine constructs were predicted and verified. The molecular docking and molecular dynamic (MD) simulation analyses indicated that the vaccine design V1 demonstrated robust and stable molecular interactions with toll-like receptor 4 (TLR4). The top-ranked vaccine construct model-IV demonstrated significant expressive capability in the E. coli expression system during in-silico restriction cloning analysis. The results of the present study are intriguing; nevertheless, experimental bioassays are required to validate the efficacy of the predicted model chimeric vaccine.

Published

2023

48. InflANNet: a neural network predictor for Influenza A CTL and HTL epitopes to aid robust vaccine design.

Author

Karthika, R., Muthusamy, Sathya, and Prabhu, Prince R.

Subjects

*CYTOTOXIC T cells, *EPITOPES, *MACHINE learning, *ARTIFICIAL neural networks, *INFLUENZA, *T cells

Abstract

Background: An efficient and reliable data-driven method is essential to aid robust vaccine design, particularly in the case of an epidemic like Influenza A. Although various prediction tools are existing, most of them focus on the MHC-peptide binding affinity predictions. A tool which can incorporate more features other than binding affinity which characterizes the T-cell epitopes as vaccine candidates would be of much value in this scenario. The objective of this study is to develop two separate neural network models for the predictions of CTLs (cytotoxic T lymphocyte) and HTLs (helper T lymphocyte) with the manually curated datasets as a part of this study from the raw viral sequences of Influenza A. Results: The epitope datasets curated from the raw sequences of the broadly protective Neuraminidase protein were utilized for building and training the models for CTLs and HTLs. Each set consisted of nearly a balanced mix of vaccine candidates and non-vaccine candidates for both CTLs and HTLs. These were fed to neural networks as they are proven to be powerful for the predictions when compared with the other machine/deep learning algorithms. A set of epitopes experimentally proved were chosen to validate the model which was also tested through mutational analysis and cross-reactivity. The prepared dataset gave some valuable insights into the epitope distribution statistics and their conservancy in various outbreaks. An idea about the most probable range of peptide-MHC binding affinities was also obtained. Both the models performed well giving high accuracies when validated. These epitopes were checked for cross-reactivity with other antigens upon which it proved to be highly conservative and ideal for vaccine formulation. Conclusions: The combination of various features and the resulting model efficiencies in turn proved that the collected features are valuable in the easy identification of the vaccine candidates. This suggests that our proposed models have more potential for conserved epitope prediction compared to other existing models trained on similar data and features. The possibility of refining the model with more set threshold values based on more parameters is an added feature that makes it more user driven. Furthermore, the uniqueness of the model due to exclusive set of Neuraminidase epitopes paves a robust way for rapid vaccine design. Highlights: The analysis of the past viral strains of Neuraminidase, delivered an interesting list of possible epitopes for vaccine design. The class-I & class-II MHC binding reports of the test set of epitopes, strongly validate the high performance (~ or above 90%) of the ML models. The homology studies with nematode antigens suggest that our predicted epitopes are free from cross-reactivity with parasitic epitopes. The very few mutations reported for Neuraminidase (being the conserved one among the other proteins) from the mutational analysis prove that the vaccine formulations with our predicted epitopes are capable of overcoming any antigenic drifts in the future. [ABSTRACT FROM AUTHOR]

Published

2023

49. Optimization and Deoptimization of Codons in SARS‐CoV‐2 and Related Implications for Vaccine Development.

Author

Wu, Xinkai, Shan, Ke‐jia, Zan, Fuwen, Tang, Xiaolu, Qian, Zhaohui, and Lu, Jian

Subjects

*VACCINE development, *COVID-19, *SARS-CoV-2, *GENE expression, *GENETIC variation, *GENETIC code

Abstract

The spread of coronavirus disease 2019 (COVID‐19), caused by severe respiratory syndrome coronavirus 2 (SARS‐CoV‐2), has progressed into a global pandemic. To date, thousands of genetic variants have been identified among SARS‐CoV‐2 isolates collected from patients. Sequence analysis reveals that the codon adaptation index (CAI) values of viral sequences have decreased over time but with occasional fluctuations. Through evolution modeling, it is found that this phenomenon may result from the virus's mutation preference during transmission. Using dual‐luciferase assays, it is further discovered that the deoptimization of codons in the viral sequence may weaken protein expression during virus evolution, indicating that codon usage may play an important role in virus fitness. Finally, given the importance of codon usage in protein expression and particularly for mRNA vaccines, it is designed several codon‐optimized Omicron BA.2.12.1, BA.4/5, and XBB.1.5 spike mRNA vaccine candidates and experimentally validated their high levels of expression. This study highlights the importance of codon usage in virus evolution and provides guidelines for codon optimization in mRNA and DNA vaccine development. [ABSTRACT FROM AUTHOR]

Published

2023

50. Polyfunctional antibodies: a path towards precision vaccines for vulnerable populations.

Author

Purcell, Ruth A., Theisen, Robert M., Arnold, Kelly B., Chung, Amy W., and Selva, Kevin J.

Subjects

VACCINE effectiveness, IMMUNOGLOBULINS, IMMUNE response, CLINICAL trials, VACCINES

Abstract

Vaccine efficacy determined within the controlled environment of a clinical trial is usually substantially greater than real-world vaccine effectiveness. Typically, this results from reduced protection of immunologically vulnerable populations, such as children, elderly individuals and people with chronic comorbidities. Consequently, these high-risk groups are frequently recommended tailored immunisation schedules to boost responses. In addition, diverse groups of healthy adults may also be variably protected by the same vaccine regimen. Current population-based vaccination strategies that consider basic clinical parameters offer a glimpse into what may be achievable if more nuanced aspects of the immune response are considered in vaccine design. To date, vaccine development has been largely empirical. However, next-generation approaches require more rational strategies. We foresee a generation of precision vaccines that consider the mechanistic basis of vaccine response variations associated with both immunogenetic and baseline health differences. Recent efforts have highlighted the importance of balanced and diverse extra-neutralising antibody functions for vaccine-induced protection. However, in immunologically vulnerable populations, significant modulation of polyfunctional antibody responses that mediate both neutralisation and effector functions has been observed. Here, we review the current understanding of key genetic and inflammatory modulators of antibody polyfunctionality that affect vaccination outcomes and consider how this knowledge may be harnessed to tailor vaccine design for improved public health. [ABSTRACT FROM AUTHOR]

Published

2023