ABSTRACT
Objectives High‐magnitude CD8+ T cell responses are associated with mild COVID‐19 disease;however, the underlying characteristics that define CD8+ T cell‐mediated protection are not well understood. The antigenic breadth and the immunodominance hierarchies of epitope‐specific CD8+ T cells remain largely unexplored and are essential for the development of next‐generation broad‐protective vaccines. This study identified a broad spectrum of conserved SARS‐CoV‐2 CD8+ T cell epitopes and defined their respective immunodominance and phenotypic profiles following SARS‐CoV‐2 infection. Methods CD8+ T cells from 51 convalescent COVID‐19 donors were analysed for their ability to recognise 133 predicted and previously described SARS‐CoV‐2‐derived peptides restricted by 11 common HLA class I allotypes using heterotetramer combinatorial coding, which combined with phenotypic markers allowed in‐depth ex vivo profiling of CD8+ T cell responses at quantitative and phenotypic levels. Results A comprehensive panel of 49 mostly conserved SARS‐CoV‐2‐specific CD8+ T cell epitopes, including five newly identified low‐magnitude epitopes, was established. We confirmed the immunodominance of HLA‐A*01:01/ORF1ab1637–1646 and B*07:02/N105–113 and identified B*35:01/N325–333 as a third epitope with immunodominant features. The magnitude of subdominant epitope responses, including A*03:01/N361–369 and A*02:01/S269–277, depended on the donors' HLA‐I context. All epitopes expressed prevalent memory phenotypes, with the highest memory frequencies in severe COVID‐19 donors. Conclusion SARS‐CoV‐2 infection induces a predominant CD8+ T memory response directed against a broad spectrum of conserved SARS‐CoV‐2 epitopes, which likely contributes to long‐term protection against severe disease. The observed immunodominance hierarchy emphasises the importance of T cell epitopes derived from nonspike proteins to the overall protective and cross‐reactive immune response, which could aid future vaccine strategies. Fifty‐one convalescent COVID‐19 donors were analysed for their ability to recognise 133 predicted SARS‐CoV‐2‐derived peptides restricted by 11 common HLA‐I allotypes using heterotetramer combinatorial coding. Forty‐nine mostly conserved SARS‐CoV‐2‐specific CD8+ T cell epitopes, including five new, were identified. This study revealed three dominant epitopes (HLA‐A*01:01/ORF1ab1637–1646, B*07:02/N105–113 and B*35:01/N325–333). The magnitude of subdominant epitope responses, including HLA‐A*03:01/N361–369 and A*02:01/S269–277, largely depended on the donors' HLA context. All epitopes had a prevalent memory phenotype, which were significantly higher in severe COVID‐19 donors.
ABSTRACT
Understanding the mechanisms and impact of booster vaccinations are essential in the design and delivery of vaccination programs. Here we show that a three dose regimen of a synthetic peptide vaccine elicits an accruing CD8+ T cell response against one SARS-CoV-2 Spike epitope. We see protection against lethal SARS-CoV-2 infection in the K18-hACE2 transgenic mouse model in the absence of neutralizing antibodies, but two dose approaches are insufficient to confer protection. The third vaccine dose of the single T cell epitope peptide results in superior generation of effector-memory T cells and tissue-resident memory T cells, and these tertiary vaccine-specific CD8+ T cells are characterized by enhanced polyfunctional cytokine production. Moreover, fate mapping shows that a substantial fraction of the tertiary CD8+ effector-memory T cells develop from re-migrated tissue-resident memory T cells. Thus, repeated booster vaccinations quantitatively and qualitatively improve the CD8+ T cell response leading to protection against otherwise lethal SARS-CoV-2 infection.