Combining FoxP3 and Helios with GARP/LAP markers can identify expanded Treg subsets in cancer patients.

Regulatory T cells (Tregs) comprise numerous heterogeneous subsets with distinct phenotypic and functional features. Identifying Treg markers is critical to investigate the role and clinical impact of various Treg subsets in pathological settings, and also for developing more effective immunotherapies. We have recently shown that non-activated FoxP3-Helios+ and activated FoxP3+/-Helios+ CD4+ T cells express GARP/LAP immunosuppressive markers in healthy donors. In this study we report similar observations in the peripheral blood of patients with pancreatic cancer (PC) and liver metastases from colorectal cancer (LICRC). Comparing levels of different Treg subpopulations in cancer patients and controls, we report that in PC patients, and unlike LICRC patients, there was no increase in Treg levels as defined by FoxP3 and Helios. However, defining Tregs based on GARP/LAP expression showed that FoxP3-LAP+ Tregs in non-activated and activated settings, and FoxP3+Helios+GARP+LAP+ activated Tregs were significantly increased in both groups of patients, compared with controls. This work implies that a combination of Treg-specific markers could be used to more accurately determine expanded Treg subsets and to understand their contribution in cancer settings. Additionally, GARP-/+LAP+ CD4+ T cells made IL-10, and not IFN-γ, and levels of IL-10-secreting CD4+ T cells were elevated in LICRC patients, especially with higher tumor staging. Taken together, our results indicate that investigations of Treg levels in different cancers should consider diverse Treg-related markers such as GARP, LAP, Helios, and others and not only FoxP3 as a sole Treg-specific marker.

Helios, and not FoxP3, is the marker of activated Tregs expressing GARP/LAP.

Regulatory T cells (Tregs) are key players of immune regulation/dysregulation both in physiological and pathophysiological settings. Despite significant advances in understanding Treg function, there is still a pressing need to define reliable and specific markers that can distinguish different Treg subpopulations. Herein we show for the first time that markers of activated Tregs [latency associated peptide (LAP) and glycoprotein A repetitions predominant (GARP, or LRRC32)] are expressed on CD4+FoxP3- T cells expressing Helios (FoxP3-Helios+) in the steady state. Following TCR activation, GARP/LAP are up-regulated on CD4+Helios+ T cells regardless of FoxP3 expression (FoxP3+/-Helios+). We show that CD4+GARP+/-LAP+ Tregs make IL-10 immunosuppressive cytokine but not IFN-γ effector cytokine. Further characterization of FoxP3/Helios subpopulations showed that FoxP3+Helios+ Tregs proliferate in vitro significantly less than FoxP3+Helios- Tregs upon TCR stimulation. Unlike FoxP3+Helios- Tregs, FoxP3+Helios+ Tregs secrete IL-10 but not IFN-γ or IL-2, confirming they are bona fide Tregs with immunosuppressive characteristics. Taken together, Helios, and not FoxP3, is the marker of activated Tregs expressing GARP/LAP, and FoxP3+Helios+ Tregs have more suppressive characteristics, compared with FoxP3+Helios- Tregs. Our work implies that therapeutic modalities for treating autoimmune and inflammatory diseases, allergies and graft rejection should be designed to induce and/or expand FoxP3+Helios+ Tregs, while therapies against cancers or infectious diseases should avoid such expansion/induction.

Phenotypic alterations, clinical impact and therapeutic potential of regulatory T cells in cancer.

INTRODUCTION: Regulatory T cells (Tregs) have been characterised in different cancers. They accumulate in peripheral blood and tumour microenvironments where they suppress tumour-specific immune responses, enabling tumours to develop without challenge. This tumour immune evasion represents a major obstacle to successful cancer therapies. Whilst Tregs are generally divided into thymic-derived and peripherally induced, Tregs exhibit a wide spectrum of phenotypes and functional capacity dependent on microenvironment. This phenotypic diversity is also reflected in tumour-infiltrating Treg (TI Treg) populations, which may explain the variable impact of Treg accumulation on prognosis in different cancers. Identifying TI Treg subsets is critical to understand TI Treg biology and for developing effective immunotherapies. AREAS COVERED: This review discusses current and potential markers, and the modulation of these markers in cancer. In addition, we systematically review the clinical impact of Tregs in cancer and their potential as a therapeutic target, with a focus on TI Tregs. EXPERT OPINION: TI Tregs represent dynamic and diverse subsets that are key in promoting tumour progression through their suppressive activities. Targeting specific TI Treg subpopulations and functional TI Treg markers represents a feasible therapeutic strategy that might allow reestablishment of antitumour immune responses without affecting physiological immune regulation.