Zbtb20 identifies and controls a thymus-derived population of regulatory T cells that play a role in intestinal homeostasis.

The expression of BTB-ZF transcription factors such as ThPOK in CD4+ T cells, Bcl6 in T follicular helper cells, and PLZF in natural killer T cells defines the fundamental nature and characteristics of these cells. Screening for lineage-defining BTB-ZF genes led to the discovery of a subset of T cells that expressed Zbtb20. About half of Zbtb20+ T cells expressed FoxP3, the lineage-defining transcription factor for regulatory T cells (Tregs). Zbtb20+ Tregs were phenotypically and genetically distinct from the larger conventional Treg population. Zbtb20+ Tregs constitutively expressed mRNA for interleukin-10 and produced high levels of the cytokine upon primary activation. Zbtb20+ Tregs were enriched in the intestine and specifically expanded when inflammation was induced by the use of dextran sodium sulfate. Conditional deletion of Zbtb20 in T cells resulted in a loss of intestinal epithelial barrier integrity. Consequently, knockout (KO) mice were acutely sensitive to colitis and often died because of the disease. Adoptive transfer of Zbtb20+ Tregs protected the Zbtb20 conditional KO mice from severe colitis and death, whereas non-Zbtb20 Tregs did not. Zbtb20 was detected in CD24hi double-positive and CD62Llo CD4 single-positive thymocytes, suggesting that expression of the transcription factor and the phenotype of these cells were induced during thymic development. However, Zbtb20 expression was not induced in "conventional" Tregs by activation in vitro or in vivo. Thus, Zbtb20 expression identified and controlled the function of a distinct subset of Tregs that are involved in intestinal homeostasis.

Decreased immune response in monkeys administered a human T-effector cell agonist (OX40) antibody.

The OX40 receptor plays a crucial co-stimulatory role in T effector cell survival, expansion, cytokine production, and cytotoxicity to tumor cells; therefore, OX40 agonists are being evaluated as anti-cancer immunotherapies, especially in combination with checkpoint inhibitors. To support clinical development of BMS-986178 (an OX40 agonist antibody), two repeat-dose toxicity studies were conducted in cynomolgus monkeys. In the first study, BMS-986178 was administered intravenously (IV) once weekly for one month at doses from 30 to 120 mg/kg. BMS-986178 was well tolerated; surprisingly, immune function was suppressed rather than increased based on pharmacodynamic (PD) and flow cytometry readouts (e.g. T-cell dependent antibody response [TDAR]). To determine whether immune suppression was due to a bi-phasic response, a follow-up study was conducted at lower doses (1 and 10 mg/kg). Although receptor engagement was confirmed, immune function was still suppressed at both doses. In addition, treatment-emergent anti-drug antibodies (ADAs) at 1 mg/kg resulted in hypersensitivity reactions and reduced BMS-986178 exposure after repeated dosing, which precluded a full PD assessment at this dose. In conclusion, BMS-986178 was clinically well-tolerated by monkeys at weekly IV doses from 10 to 120 mg/kg (AUC[0-168] ≤ 712,000 µg●h/mL). However, despite target engagement, PD assays and other immune endpoints demonstrated immune suppression, not stimulation. Due to the inverted immune response at higher doses and the onset of ADAs, additional repeat-dose toxicity studies of BMS-986178 in monkeys (that would typically be required to support Phase 3 clinical trials and registration) would not add value for human safety assessment.