Vaccinomics Approach to Tick Vaccine Development

AbstractTicks are arthropod vectors of pathogens of both Veterinary and Public health importance. Ticks are largely controlled by acaricide application. However, acaricide efficacy is hampered by high cost, the need for regular application and selection of multi-acaricide resistant tick populations. In light of this, future tick control approaches are poised to rely on integration of rational acaricide application and other methods such as vaccination. To contribute to systematic research-guided efforts to produce anti-tick vaccines, we carried out an in silico tick Aquaporin-1 protein (AQP1) analysis to identify unique tick AQP1 peptide motifs that can be used in future peptide anti-tick vaccine development. We used multiple sequence alignment (MSA), motif analysis, homology modeling, and structural analysis to identify unique tick AQP1 peptide motifs. BepiPred, Chou & Fasman-Turn, Karplus & Schulz Flexibility and Parker-Hydrophilicity prediction models were used to asses these motifs’ abilities to induce antibody mediated immune responses. Tick AQP1 (MK334178) protein homology was largely similar to the bovine AQP1 (PDB:1J4N) (23% sequence similarity; Structural superimposition RMS=1.475). The highest similarities were observed in the transmembrane domains while differences were observed in the extra and intra cellular protein loops. Two unique tick AQP1 (MK334178) motifs, M7 (residues 106-125, p=5.4e-25) and M8 (residues 85-104, p=3.3e-24) were identified. These two motifs are located on the extra-cellular AQP1 domain and showed the highest Parker-Hydrophilicity prediction immunogenic scores of 1.153 and 2.612 respectively. The M7 and M8 motifs are a good starting point for the development of potential peptide-based anti-tick vaccine. Further analyses such as in vivo immunization assays are required to validate these findings.

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Proteomics Informed by Transcriptomics for a Qualitative and Quantitative Analysis of the Sialoproteome of Ornithodoros Moubata Adult Ticks

10.21203/rs.3.rs-512926/v1 ◽

2021 ◽

Author(s):

Ana Oleaga ◽

Angel Carnero-Moran ◽

M. Luz Valero ◽

Ricardo Pérez-Sánchez

Keyword(s):

Mass Spectrometry ◽

Vaccine Development ◽

African Swine Fever Virus ◽

African Swine Fever ◽

Host Feeding ◽

Tick Saliva ◽

Ornithodoros Moubata ◽

Tick Vaccine ◽

Proteomics Informed By Transcriptomics ◽

Selection Of

Abstract Background The argasid tick Ornithodoros moubata is the main vector in mainland Africa of the African swine fever virus and the spirochete Borrelia duttoni, which causes human relapsing fever. Elimination of O. moubata populations would contribute to the prevention and control of these two severe diseases. The development of anti-tick vaccines is an eco-friendly and sustainable method for the elimination of tick populations. The tick saliva forms part of the tick-host interface and knowing its composition is key for the identification and selection of vaccine candidate antigens. The aim of the present work is to expand the data on the saliva proteome composition of O. moubata adult ticks, particularly of female ticks, since a more in-depth knowledge of the O. moubata sialome will allow identifying and selecting novel salivary antigens as targets for tick vaccines. Methods We have analysed samples of female and male saliva using two different mass spectrometry approaches: data-dependent acquisition LC-MS/MS and sequential window acquisition of all theoretical fragment ion spectra mass spectrometry (SWATH-MS). To maximise the number of protein identifications, a proteomics informed by transcriptomics (PIT) analysis was applied using the O. moubata salivary transcriptomic dataset previously obtained by RNAseq. Results The SWATH-MS proved to be superior to LC-MS/MS in the study of female saliva since it increased by 60% the number of identified proteins, enhanced the reproducibility of the results and provided a quantitative image of the saliva components. As a whole, we have identified 299 non-redundant proteins in the O. moubata saliva and quantified the expression of 165 of them in both male and female saliva, among which 13 were significantly overexpressed in females and 40 in males. These results evidence important quantitative differences between sexes in the saliva proteome. Conclusions This work expand our knowledge of the O. moubata sialome, particularly of female ticks, by increasing the identification of novel salivary proteins and functions at the tick–host feeding interface. The integration of this new knowledge together with the information from the O. moubata sialotranscriptome will allow a more rational selection of the salivary candidates as antigen targets for tick vaccine development.

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In Silico Characterization and Structural Modeling of Dermacentor andersoni p36 Immunosuppressive Protein

Advances in Bioinformatics ◽

10.1155/2018/7963401 ◽

2018 ◽

Vol 2018 ◽

pp. 1-12 ◽

Cited By ~ 2

Author(s):

Martin Omulindi Oyugi ◽

Johnson Kangethe Kinyua ◽

Esther Nkirote Magiri ◽

Milcah Wagio Kigoni ◽

Evenilton Pessoa Costa ◽

...

Keyword(s):

Vaccine Development ◽

Dynamic Properties ◽

3D Structure ◽

Blood Feeding ◽

Rhipicephalus Appendiculatus ◽

Economic Losses ◽

Dermacentor Andersoni ◽

Laboratory Confirmation ◽

Tick Vaccine

Ticks cause approximately $17–19 billion economic losses to the livestock industry globally. Development of recombinant antitick vaccine is greatly hindered by insufficient knowledge and understanding of proteins expressed by ticks. Ticks secrete immunosuppressant proteins that modulate the host’s immune system during blood feeding; these molecules could be a target for antivector vaccine development. Recombinant p36, a 36 kDa immunosuppressor from the saliva of female Dermacentor andersoni, suppresses T-lymphocytes proliferation in vitro. To identify potential unique structural and dynamic properties responsible for the immunosuppressive function of p36 proteins, this study utilized bioinformatic tool to characterize and model structure of D. andersoni p36 protein. Evaluation of p36 protein family as suitable vaccine antigens predicted a p36 homolog in Rhipicephalus appendiculatus, the tick vector of East Coast fever, with an antigenicity score of 0.7701 that compares well with that of Bm86 (0.7681), the protein antigen that constitute commercial tick vaccine Tickgard™. Ab initio modeling of the D. andersoni p36 protein yielded a 3D structure that predicted conserved antigenic region, which has potential of binding immunomodulating ligands including glycerol and lactose, found located within exposed loop, suggesting a likely role in immunosuppressive function of tick p36 proteins. Laboratory confirmation of these preliminary results is necessary in future studies.

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Applying proteomics to tick vaccine development: where are we?

Expert Review of Proteomics ◽

10.1080/14789450.2017.1284590 ◽

2017 ◽

Vol 14 (3) ◽

pp. 211-221 ◽

Cited By ~ 14

Author(s):

Margarita Villar ◽

Anabel Marina ◽

José de la Fuente

Keyword(s):

Vaccine Development ◽

Tick Vaccine

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Advances in the Study of the Tick Cattle Microbiota and the Influence on Vectorial Capacity

Frontiers in Veterinary Science ◽

10.3389/fvets.2021.710352 ◽

2021 ◽

Vol 8 ◽

Author(s):

Hugo Aguilar-Díaz ◽

Rosa Estela Quiroz-Castañeda ◽

Mayra Cobaxin-Cárdenas ◽

Elizabeth Salinas-Estrella ◽

Itzel Amaro-Estrada

Keyword(s):

Microbial Population ◽

Vaccine Development ◽

Good Prognosis ◽

Infection Process ◽

Pathogen Transmission ◽

Vectorial Capacity ◽

Microbial Populations ◽

Transmission Process ◽

Successful Infection ◽

Tick Vaccine

The information from the tick cattle microbiota suggests that the microbial populations may modulate a successful infection process of the tick-borne pathogens. Therefore, there is a need to know the microbial population and their interactions. In this mini-review, we present several examples of how microbiota regulates the survival of pathogens inside the tick and contributes to fitness, adaptation, and tick immunity, among others. The communication between the tick microbiota and the host microbiota is vital to understanding the pathogen transmission process. As part of the tick microbiota, the pathogen interacts with different microbial populations, including the microorganisms of the host microbiota. These interactions comprise a microsystem that regulates the vectorial capacity involved in tick-borne diseases. The knowledge we have about the vectorial capacity contributes to a better understanding of tick-borne pathogens. Additionally, using approaches based on multi-omics strategies applied to studying the microbiota and its microbiome allows the development of strategies to control ticks. The results derived from those studies reveal the dynamics of the microbiota and potential targets for anti-tick vaccine development. In this context, the anti-microbiota vaccines have emerged as an alternative with a good prognosis. Some strategies developed to control other arthropods vectors, such as paratransgenesis, could control ticks and tick-borne diseases.

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Vaccination with Ectoparasite Proteins Involved in Midgut Function and Blood Digestion Reduces Salmon Louse Infestations

Vaccines ◽

10.3390/vaccines8010032 ◽

2020 ◽

Vol 8 (1) ◽

pp. 32 ◽

Cited By ~ 4

Author(s):

Marinela Contreras ◽

Marius Karlsen ◽

Margarita Villar ◽

Rolf Olsen ◽

Lisa Leknes ◽

...

Keyword(s):

Atlantic Salmon ◽

Vaccine Development ◽

Sea Lice ◽

Salmon Louse ◽

Blood Digestion ◽

Protective Antigens ◽

Salmon Lice ◽

Tick Vaccine ◽

European Aquaculture ◽

Lice Infestations

Infestation with the salmon louse Lepeophtheirus salmonis (Copepoda, Caligidae) affects Atlantic salmon (Salmo salar L.) production in European aquaculture. Furthermore, high levels of salmon lice in farms significantly increase challenge pressure against wild salmon populations. Currently, available control methods for salmon louse have limitations, and vaccination appears as an attractive, environmentally sound strategy. In this study, we addressed one of the main limitations for vaccine development, the identification of candidate protective antigens. Based on recent advances in tick vaccine research, herein, we targeted the salmon louse midgut function and blood digestion for the identification of candidate target proteins for the control of ectoparasite infestations. The results of this translational approach resulted in the identification and subsequent evaluation of the new candidate protective antigens, putative Toll-like receptor 6 (P30), and potassium chloride, and amino acid transporter (P33). Vaccination with these antigens provided protection in Atlantic salmon by reducing adult female (P33) or chalimus II (P30) sea lice infestations. These results support the development of vaccines for the control of sea lice infestations.

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