RESUMO
Several vaccines have been found effective against COVID-19, usually administered in homologous regimens, with the same vaccine used for the prime and boost doses. However, recent studies have demonstrated improved protection via heterologous mix-and-match COVID-19 vaccine combinations, and a direct comparison among these regimens is needed to identify the best employment strategies. Here, we show a single-cohort comparison of changes to the humoral and cellular immune compartments following five different COVID-19 vaccines spanning three technologies (adenoviral, mRNA and inactivated vaccines). These vaccines were administered in a combinatorial fashion, resulting in sixteen different homologous and heterologous regimens. SARS-CoV-2-targeting antibody titres were highest when the boost dose consisted of mRNA-1273, independent of the vaccine used for priming. Priming with BBIBP-CorV induced less class-switching among spike-binding memory B cells and the highest antigen-specific T cell responses in heterologous combinations. These were generally more immunogenic in terms of specific antibodies and cellular responses compared to homologous regimens. Finally, single-cell analysis of 754 samples revealed specific B and T cell signatures of the vaccination regimens, indicating distinctive differences in the immune responses. These data provide new insights on the immunological effects of COVID-19 vaccine combinations and a framework for the design of improved vaccination strategies for other pathogens and cancer.
RESUMO
Tumor-draining lymph node (TDLN) invasion by metastatic cells in breast cancer correlates with poor prognosis and is associated with local immunosuppression, which can be partly mediated by regulatory T cells (Tregs). Here, we study Tregs from matched tumor-invaded and non-invaded TDLNs, and breast tumors. We observe that Treg frequencies increase with nodal invasion, and that Tregs express higher levels of co-inhibitory/stimulatory receptors than effector cells. Also, while Tregs show conserved suppressive function in TDLN and tumor, conventional T cells (Tconvs) in TDLNs proliferate and produce Th1-inflammatory cytokines, but are dysfunctional in the tumor. We describe a common transcriptomic signature shared by Tregs from tumors and nodes, including CD80, which is significantly associated with poor patient survival. TCR RNA-sequencing analysis indicates trafficking between TDLNs and tumors and ongoing Tconv/Treg conversion. Overall, TDLN Tregs are functional and express a distinct pattern of druggable co-receptors, highlighting their potential as targets for cancer immunotherapy.
