5 results on '"Lall, Amar"'
Search Results
2. Immunogenicity and efficacy of a chimpanzee adenovirus-vectored Rift Valley Fever vaccine in mice.
- Author
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Warimwe, George M., Lorenzo, Gema, Lopez-Gil, Elena, Reyes-Sandoval, Arturo, Cottingham, Matthew G., Spencer, Alexandra J., Collins, Katharine A., Dicks, Matthew D.J., Milicic, Anita, Lall, Amar, Furze, Julie, Turner, Alison V., Hill, Adrian V.S., Brun, Alejandro, and Gilbert, Sarah C.
- Subjects
RIFT Valley fever ,ARBOVIRUS diseases ,VACCINATION ,VIRAL hepatitis - Abstract
Background Rift Valley Fever (RVF) is a viral zoonosis that historically affects livestock production and human health in sub-Saharan Africa, though epizootics have also occurred in the Arabian Peninsula. Whilst an effective live-attenuated vaccine is available for livestock, there is currently no licensed human RVF vaccine. Replication-deficient chimpanzee adenovirus (ChAd) vectors are an ideal platform for development of a human RVF vaccine, given the low prevalence of neutralizing antibodies against them in the human population, and their excellent safety and immunogenicity profile in human clinical trials of vaccines against a wide range of pathogens. Methods Here, in BALB/c mice, we evaluated the immunogenicity and efficacy of a replicationdeficient chimpanzee adenovirus vector, ChAdOx1, encoding the RVF virus envelope glycoproteins, Gn and Gc, which are targets of virus neutralizing antibodies. The ChAdOx1- GnGc vaccine was assessed in comparison to a replication-deficient human adenovirus type 5 vector encoding Gn and Gc (HAdV5-GnGc), a strategy previously shown to confer protective immunity against RVF in mice. Results A single immunization with either of the vaccines conferred protection against RVF virus challenge eight weeks post-immunization. Both vaccines elicited RVF virus neutralizing antibody and a robust CD8+ T cell response. Conclusions Together the results support further development of RVF vaccines based on replicationdeficient adenovirus vectors, with ChAdOx1-GnGc being a potential candidate for use in future human clinical trials. [ABSTRACT FROM AUTHOR]
- Published
- 2013
- Full Text
- View/download PDF
3. Evaluation of Chimpanzee Adenovirus and MVA Expressing TRAP and CSP from Plasmodium cynomolgi to Prevent Malaria Relapse in Nonhuman Primates.
- Author
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Kim, Young Chan, Dema, Barbara, Rodriguez-Garcia, Roberto, López-Camacho, César, Leoratti, Fabiana M. S., Lall, Amar, Remarque, Edmond J., Kocken, Clemens H. M., and Reyes-Sandoval, Arturo
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MALARIA ,CHIMPANZEES ,PRIMATES ,RHESUS monkeys ,VACCINE effectiveness ,HUMORAL immunity - Abstract
Plasmodium vivax is the world's most widely distributed human malaria parasite, with over 2.8 billion people at risk in Asia, the Americas, and Africa. The 80–90% new P. vivax malaria infections are due to relapses which suggest that a vaccine with high efficacy against relapses by prevention of hypnozoite formation could lead to a significant reduction in the prevalence of P. vivax infections. Here, we describe the development of new recombinant ChAdOx1 and MVA vectors expressing P. cynomolgi Thrombospondin Related Adhesive Protein (PcTRAP) and the circumsporozoite protein (PcCSP). Both were shown to be immunogenic in mice prior to their assessment in rhesus macaques. We confirmed good vaccine-induced humoral and cellular responses after prime-boost vaccination in rhesus macaques prior to sporozoite challenge. Results indicate that there were no significant differences between mock-control and vaccinated animals after challenge, in terms of protective efficacy measured as the time taken to 1st patency, or as number of relapses. This suggests that under the conditions tested, the vaccination with PcTRAP and PcCSP using ChAdOx1 or MVA vaccine platforms do not protect against pre-erythrocytic malaria or relapses despite good immunogenicity induced by the viral-vectored vaccines. [ABSTRACT FROM AUTHOR]
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- 2020
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4. Rational development of a protective P. vivax vaccine evaluated with transgenic rodent parasite challenge models.
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Salman, Ahmed M., Montoya-Díaz, Eduardo, West, Heather, Lall, Amar, Atcheson, Erwan, Lopez-Camacho, Cesar, Ramesar, Jai, Bauza, Karolis, Collins, Katharine A., Brod, Florian, Reis, Fernando, Pappas, Leontios, González-Cerón, Lilia, Janse, Chris J., Hill, Adrian V. S., Khan, Shahid M., and Reyes-Sandoval, Arturo
- Abstract
Development of a protective and broadly-acting vaccine against the most widely distributed human malaria parasite, Plasmodium vivax, will be a major step towards malaria elimination. However, a P. vivax vaccine has remained elusive by the scarcity of pre-clinical models to test protective efficacy and support further clinical trials. In this study, we report the development of a highly protective CSP-based P. vivax vaccine, a virus-like particle (VLP) known as Rv21, able to provide 100% sterile protection against a stringent sporozoite challenge in rodent models to malaria, where IgG2a antibodies were associated with protection in absence of detectable PvCSP-specific T cell responses. Additionally, we generated two novel transgenic rodent P. berghei parasite lines, where the P. berghei csp gene coding sequence has been replaced with either full-length P. vivax VK210 or the allelic VK247 csp that additionally express GFP-Luciferase. Efficacy of Rv21 surpassed viral-vectored vaccination using ChAd63 and MVA. We show for the first time that a chimeric VK210/247 antigen can elicit high level cross-protection against parasites expressing either CSP allele, which provide accessible and affordable models suitable to support the development of P. vivax vaccines candidates. Rv21 is progressing to GMP production and has entered a path towards clinical evaluation. [ABSTRACT FROM AUTHOR]
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- 2017
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5. Defining the Range of Pathogens Susceptible to Ifitm3 Restriction Using a Knockout Mouse Model.
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Everitt, Aaron R., Clare, Simon, McDonald, Jacqueline U., Kane, Leanne, Harcourt, Katherine, Ahras, Malika, Lall, Amar, Hale, Christine, Rodgers, Angela, Young, Douglas B., Haque, Ashraful, Billker, Oliver, Tregoning, John S., Dougan, Gordon, and Kellam, Paul
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PATHOGENIC microorganisms ,INTERFERONS ,DISEASE susceptibility ,CELLULAR signal transduction ,LABORATORY mice ,SINGLE nucleotide polymorphisms ,INFLUENZA viruses - Abstract
The interferon-inducible transmembrane (IFITM) family of proteins has been shown to restrict a broad range of viruses in vitro and in vivo by halting progress through the late endosomal pathway. Further, single nucleotide polymorphisms (SNPs) in its sequence have been linked with risk of developing severe influenza virus infections in humans. The number of viruses restricted by this host protein has continued to grow since it was first demonstrated as playing an antiviral role; all of which enter cells via the endosomal pathway. We therefore sought to test the limits of antimicrobial restriction by Ifitm3 using a knockout mouse model. We showed that Ifitm3 does not impact on the restriction or pathogenesis of bacterial (Salmonella typhimurium, Citrobacter rodentium, Mycobacterium tuberculosis) or protozoan (Plasmodium berghei) pathogens, despite in vitro evidence. However, Ifitm3 is capable of restricting respiratory syncytial virus (RSV) in vivo either through directly restricting RSV cell infection, or by exerting a previously uncharacterised function controlling disease pathogenesis. This represents the first demonstration of a virus that enters directly through the plasma membrane, without the need for the endosomal pathway, being restricted by the IFITM family; therefore further defining the role of these antiviral proteins. [ABSTRACT FROM AUTHOR]
- Published
- 2013
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