Chemically engineered glycan-modified cancer vaccines to mobilize skin dendritic cells

Dendritic cell (DC)–targeting vaccines show great promise in increasing antitumor immunity. Glycan-engineered vaccines facilitate both DC targeting and increased uptake by DCs for processing and presentation to CD4+ and CD8+ T cells to induce tumor-specific T-cell responses. However, the complexity of various DC subsets in skin tissues, expressing different glycan-binding receptors that can mediate vaccine uptake or drainage of vaccines via lymphatics directly to the lymph node–resident DCs, complicates the success of vaccines. Moreover, the influx of inflammatory immune cells to the site of vaccination, such as monocytes that differentiate to DCs and coexpress glycan-binding receptors, may contribute to the strength of DC-targeting glycovaccines for future clinical use

Memory CD8⁺ T cell heterogeneity is primarily driven by pathogen-specific cues and additionally shaped by the tissue environment

SummaryFactors that govern the complex formation of memory T cells are not completelyunderstood. A better understanding of thedevelopment of memory Tcell hetero-geneity is however required to enhance vaccination and immunotherapy ap-proaches. Here we examined the impact of pathogen- and tissue-specific cueson memory CD8+T cell heterogeneity using high-dimensional single-cell mass cy-tometry and a tailored bioinformatics pipeline. We identified distinct populationsof pathogen-specific CD8+T cells that uniquely connected to a specific pathogenor associated to multiple types of acute and persistent infections. In addition, thetissue environment shaped the memory CD8+T cell heterogeneity, albeit to alesser extent than infection. The programming of memory CD8+T cell differenti-ation during acute infection is eventually superseded by persistent infection.Thus, the plethora of distinct memory CD8+T cell subsets that arise upon infec-tion is dominantly sculpted by the pathogen-specific cues and further shaped by the tissue environment.</p

Memory CD8⁺ T cell heterogeneity is primarily driven by pathogen-specific cues and additionally shaped by the tissue environment

SummaryFactors that govern the complex formation of memory T cells are not completelyunderstood. A better understanding of thedevelopment of memory Tcell hetero-geneity is however required to enhance vaccination and immunotherapy ap-proaches. Here we examined the impact of pathogen- and tissue-specific cueson memory CD8+T cell heterogeneity using high-dimensional single-cell mass cy-tometry and a tailored bioinformatics pipeline. We identified distinct populationsof pathogen-specific CD8+T cells that uniquely connected to a specific pathogenor associated to multiple types of acute and persistent infections. In addition, thetissue environment shaped the memory CD8+T cell heterogeneity, albeit to alesser extent than infection. The programming of memory CD8+T cell differenti-ation during acute infection is eventually superseded by persistent infection.Thus, the plethora of distinct memory CD8+T cell subsets that arise upon infec-tion is dominantly sculpted by the pathogen-specific cues and further shaped by the tissue environment.Pattern Recognition and Bioinformatic

OX40 agonism enhances PD-L1 checkpoint blockade by shifting the cytotoxic T cell differentiation spectrum

Immune checkpoint therapy (ICT) has the power to eradicate cancer, but the mechanisms that determine effective therapy-induced immune responses are not fully understood. Here, using high-dimensional single-cell profiling, we interrogate whether the landscape of T cell states in the peripheral blood predict responses to combinatorial targeting of the OX40 costimulatory and PD-1 inhibitory pathways. Single-cell RNA sequencing and mass cytometry expose systemic and dynamic activation states of therapy-responsive CD4+ and CD8+ T cells in tumor-bearing mice with expression of distinct natural killer (NK) cell receptors, granzymes, and chemokines/chemokine receptors. Moreover, similar NK cell receptor-expressing CD8+ T cells are also detected in the blood of immunotherapy-responsive cancer patients. Targeting the NK cell and chemokine receptors in tumor-bearing mice shows the functional importance of these receptors for therapy-induced anti-tumor immunity. These findings provide a better understanding of ICT and highlight the use and targeting of dynamic biomarkers on T cells to improve cancer immunotherapy