Edgar Tello‐Ruiz scite author profile

The coronavirus family member, SARS-CoV-2 has been identified as the causal agent for the pandemic viral pneumonia disease, COVID-19. At this time, no vaccine is available to control further dissemination of the disease. We have previously engineered a synthetic DNA vaccine targeting the MERS coronavirus Spike (S) protein, the major surface antigen of coronaviruses, which is currently in clinical study. Here we build on this prior experience to generate a synthetic DNA-based vaccine candidate targeting SARS-CoV-2 S protein. The engineered construct, INO-4800, results in robust expression of the S protein in vitro. Following immunization of mice and guinea pigs with INO-4800 we measure antigen-specific T cell responses, functional antibodies which neutralize the SARS-CoV-2 infection and block Spike protein binding to the ACE2 receptor, and biodistribution of SARS-CoV-2 targeting antibodies to the lungs. This preliminary dataset identifies INO-4800 as a potential COVID-19 vaccine candidate, supporting further translational study.

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Intradermal-delivered DNA vaccine provides anamnestic protection in a rhesus macaque SARS-CoV-2 challenge model

Patel

Walters

Reuschel

et al. 2020

Preprint

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SummaryCoronavirus disease 2019 (COVID-19), caused by the SARS-CoV-2 virus, has had a dramatic global impact on public health, social, and economic infrastructures. Here, we assess immunogenicity and anamnestic protective efficacy in rhesus macaques of the intradermal (ID)-delivered SARS-CoV-2 spike DNA vaccine, INO-4800. INO-4800 is an ID-delivered DNA vaccine currently being evaluated in clinical trials. Vaccination with INO-4800 induced T cell responses and neutralizing antibody responses against both the D614 and G614 SARS-CoV-2 spike proteins. Several months after vaccination, animals were challenged with SARS-CoV-2 resulting in rapid recall of anti-SARS-CoV-2 spike protein T and B cell responses. These responses were associated with lower viral loads in the lung and with faster nasal clearance of virus. These studies support the immune impact of INO-4800 for inducing both humoral and cellular arms of the adaptive immune system which are likely important for providing durable protection against COVID-19 disease.

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In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity

Wise

Chokkalingam

et al. 2020

Advanced Science

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Nanotechnologies are considered to be of growing importance to the vaccine field. Through decoration of immunogens on multivalent nanoparticles, designed nanovaccines can elicit improved humoral immunity. However, significant practical and monetary challenges in large‐scale production of nanovaccines have impeded their widespread clinical translation. Here, an alternative approach is illustrated integrating computational protein modeling and adaptive electroporation‐mediated synthetic DNA delivery, thus enabling direct in vivo production of nanovaccines. DNA‐launched nanoparticles are demonstrated displaying an HIV immunogen spontaneously self‐assembled in vivo. DNA‐launched nanovaccines induce stronger humoral responses than their monomeric counterparts in both mice and guinea pigs, and uniquely elicit CD8+ effector T‐cell immunity as compared to recombinant protein nanovaccines. Improvements in vaccine responses recapitulate when DNA‐launched nanovaccines with alternative scaffolds and decorated antigen are designed and evaluated. Finally, evaluation of functional immune responses induced by DLnanovaccines demonstrates that, in comparison to control mice or mice immunized with DNA‐encoded hemagglutinin monomer, mice immunized with a DNA‐launched hemagglutinin nanoparticle vaccine fully survive a lethal influenza challenge, and have substantially lower viral load, weight loss, and influenza‐induced lung pathology. Additional study of these next‐generation in vivo‐produced nanovaccines may offer advantages for immunization against multiple disease targets.

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In vivo delivery of synthetic DNA–encoded antibodies induces broad HIV-1–neutralizing activity

Wise¹,

Xu²,

Tello‐Ruiz³

et al. 2020

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Pharmaceuticals and, as such, receive salary and benefits, including ownership of stock and stock options. KM receives grants and consulting fees from Inovio Pharmaceuticals related to DNA vaccine development. DBW has received grant funding, participates in industry collaborations, has received speaking honoraria, and has received fees for consulting, including serving on scientific review committees and board series. Remuneration received by DBW includes direct payments, stock, or stock options, and, in the interest of disclosure, he notes potential conflicts associated with his work with Inovio Pharmaceuticals and possibly others. MCW and DBW have a pending US patent, 62750213.

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DNA-encoded bispecific T cell engagers and antibodies present long-term antitumor activity

Perales‐Puchalt¹,

Duperret²,

Yang³

et al. 2019

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Edgar Tello‐Ruiz

Immunogenicity of a DNA vaccine candidate for COVID-19

Intradermal-delivered DNA vaccine provides anamnestic protection in a rhesus macaque SARS-CoV-2 challenge model

In Vivo Assembly of Nanoparticles Achieved through Synergy of Structure‐Based Protein Engineering and Synthetic DNA Generates Enhanced Adaptive Immunity

In vivo delivery of synthetic DNA–encoded antibodies induces broad HIV-1–neutralizing activity

DNA-encoded bispecific T cell engagers and antibodies present long-term antitumor activity

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