Multi-antigen pan-sarbecovirus DNA vaccines generate protective T cell immune responses

• Published in: JCI insight
• Main Authors: van Bergen, Jeroen, Camps, Marcel, Pardieck, Iris N, Veerkamp, Dominique, Leung, Wing Yan, Leijs, Anouk A, Myeni, Sebenzile K, Kikkert, Marjolein, Arens, Ramon, Zondag, Gerben C, Ossendorp, Ferry
• Format: Journal Article
• Language: English
• Published: 14.09.2023
• ISSN: 2379-3708; 2379-3708
• DOI: 10.1172/jci.insight.172488

SARS-CoV-2 is the third zoonotic coronavirus to cause a major outbreak in humans in recent years, and many more SARS-like coronaviruses with pandemic potential are circulating in several animal species. Vaccines inducing T cell immunity against broadly conserved viral antigens may protect against hospitalisation and death caused by outbreaks such viruses. We report the design and pre-clinical testing of two T-cell-based pan-sarbecovirus vaccines, based on conserved regions within viral proteins of sarbecovirus isolates of human and other carrier animals, like bats and pangolins. One vaccine (CoVAX_ORF1ab) encoded antigens derived from non-structural proteins, the other (CoVAX_MNS) antigens from structural proteins. Both multi-antigen DNA vaccines contained a large set of antigens shared across sarbecoviruses and were rich in predicted and experimentally validated human T cell epitopes. In mice, the multi-antigen vaccines generated both CD8 and CD4 T cell responses to shared epitopes. Upon encounter of full-length spike antigen, CoVAX_MNS-induced CD4 T cells were responsible for accelerated CD8 T cell and IgG antibody responses specific to the incoming spike, irrespective of its sarbecovirus origin. Finally, both vaccines elicited partial protection against a lethal SARS-CoV-2 challenge in human-ACE2-transgenic mice. These results support clinical testing of this universal sarbecovirus vaccine for pandemic preparedness.SARS-CoV-2 is the third zoonotic coronavirus to cause a major outbreak in humans in recent years, and many more SARS-like coronaviruses with pandemic potential are circulating in several animal species. Vaccines inducing T cell immunity against broadly conserved viral antigens may protect against hospitalisation and death caused by outbreaks such viruses. We report the design and pre-clinical testing of two T-cell-based pan-sarbecovirus vaccines, based on conserved regions within viral proteins of sarbecovirus isolates of human and other carrier animals, like bats and pangolins. One vaccine (CoVAX_ORF1ab) encoded antigens derived from non-structural proteins, the other (CoVAX_MNS) antigens from structural proteins. Both multi-antigen DNA vaccines contained a large set of antigens shared across sarbecoviruses and were rich in predicted and experimentally validated human T cell epitopes. In mice, the multi-antigen vaccines generated both CD8 and CD4 T cell responses to shared epitopes. Upon encounter of full-length spike antigen, CoVAX_MNS-induced CD4 T cells were responsible for accelerated CD8 T cell and IgG antibody responses specific to the incoming spike, irrespective of its sarbecovirus origin. Finally, both vaccines elicited partial protection against a lethal SARS-CoV-2 challenge in human-ACE2-transgenic mice. These results support clinical testing of this universal sarbecovirus vaccine for pandemic preparedness.