Julian J Freen-van Heeren scite author profile

Non-small cell lung cancer (NSCLC) is the second most prevalent type of cancer. With the current treatment regimens, the mortality rate remains high. Therefore, better therapeutic approaches are necessary. NSCLCs generally possess many genetic mutations and are well infiltrated by T cells (TIL), making TIL therapy an attractive option. Here we show that T cells from treatment naive, stage I-IVa NSCLC tumors can effectively be isolated and expanded, with similar efficiency as from normal lung tissue. Importantly, 76% (13/17) of tested TIL products isolated from NSCLC lesions exhibited clear reactivity against primary tumor digests, with 0.5%-30% of T cells producing the inflammatory cytokine Interferon (IFN)-γ. Both CD4+ and CD8+ T cells displayed tumor reactivity. The cytokine production correlated well with CD137 and CD40L expression. Furthermore, almost half (7/17) of the TIL products contained polyfunctional T cells that produced Tumor Necrosis Factor (TNF)-α and/or IL-2 in addition to IFN-γ, a hallmark of effective immune responses. Tumor-reactivity in the TIL products correlated with high percentages of CD103+CD69+CD8+ T cell infiltrates in the tumor lesions, with PD-1hiCD4+ T cells, and with FoxP3+CD25+CD4+ regulatory T cell infiltrates, suggesting that the composition of T cell infiltrates may predict the level of tumor reactivity. In conclusion, the effective generation of tumor-reactive and polyfunctional TIL products implies that TIL therapy will be a successful treatment regimen for NSCLC patients.

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Critical role of post-transcriptional regulation for IFN-γ in tumor-infiltrating T cells

Salerno

Guislain

Heeren

et al. 2018

OncoImmunology

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Critical role of post-transcriptional regulation for IFN-γ in tumor-infiltrating T cells

Salerno

Guislain

Heeren

et al. 2018

Preprint

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Protective T cell responses against tumors require the production of Interferon gamma (IFN-γ). However, tumor-infiltrating T cells (TILs) gradually lose their capacity to produce IFN-γ and therefore fail to clear malignant cells. Dissecting the underlying mechanisms that block cytokine production is thus key for improving T cell products.Here we show that although TILs express substantial levels of Ifng mRNA, posttranscriptional mechanisms impede the production of IFN-γ protein due to loss of mRNA stability. CD28 triggering, but not PD1 blocking antibodies, effectively restores the stability of Ifng mRNA. Intriguingly, TILs devoid of AU-rich elements within the 3'untranslated region maintain stabilized Ifng mRNA and produce more IFN-γ protein than wild-type TILs. This sustained IFN-γ production translates into effective suppression of tumor outgrowth, which is almost exclusively mediated by direct effects on the tumor cells. We therefore conclude that post-transcriptional mechanisms could be modulated to potentiate effective T cell therapies in cancer.Recently, post-transcriptional mechanisms have become appreciated in modulating the production of cytokines. For instance, AU-rich elements (AREs) within the 3'untranslated region (3'UTR) determine the fate of mRNA by regulating mRNA stability, subcellular localization of the mRNA, and translation efficiency (17)(18)(19)(20). We recently found that these regulatory mechanisms differentially dictate the cytokine production of T cells (21). The immediate production of IFN- mainly depends on rapid translation of pre-formed mRNA, whereas prolonged cytokine production relies on de novo transcription and increased mRNA stability (21). Furthermore, limited de novo transcription and the lack of Ifng mRNA stabilization effectively restricts the magnitude and duration of IFN- production (22). Whether and how post-transcriptional mechanisms govern the production of IFN- in T cells during an acute infection, and how this compares to cytokine production during chronic antigen exposure in tumors is not well understood.Here, we discovered a hitherto unappreciated role of post-transcriptional regulation that restricts the production of IFN- T cells within the tumor environment. Importantly, removing AREs from the Ifng locus was sufficient for TILs to retain the production of IFN-, and thus their capacity to suppress the tumor outgrowth. We therefore propose that adoptive T cell therapy could be potentiated by relieving IFN- from post-transcriptional control mechanisms.

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Costimulation through TLR2 Drives Polyfunctional CD8+ T Cell Responses

Salerno

Heeren

Guislain

et al. 2019

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Optimal T cell activation requires Ag recognition through the TCR, engagement of costimulatory molecules, and cytokines. T cells can also directly recognize danger signals through the expression of TLRs. Whether TLR ligands have the capacity to provide costimulatory signals and enhance Ag-driven T cell activation is not well understood. In this study, we show that TLR2 and TLR7 ligands potently lower the Ag threshold for cytokine production in T cells. To investigate how TLR triggering supports cytokine production, we adapted the protocol for flow cytometry–based fluorescence in situ hybridization to mouse T cells. The simultaneous detection of cytokine mRNA and protein with single-cell resolution revealed that TLR triggering primarily drives de novo mRNA transcription. Ifng mRNA stabilization only occurs when the TCR is engaged. TLR2-, but not TLR7-mediated costimulation, can enhance mRNA stability at low Ag levels. Importantly, TLR2 costimulation increases the percentage of polyfunctional T cells, a hallmark of potent T cell responses. In conclusion, TLR-mediated costimulation effectively potentiates T cell effector function to suboptimal Ag levels.

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