Background: CC-90009 is a novel cereblon E3 ligase modulator (CELMoD), which is currently under investigation in a first-in-human, phase I study (CC-90009-AML-001; NCT02848001) in patients with R/R AML. In preclinical models, CC-90009 drives the binding of the target protein, translation termination factor G1 to S phase transition 1 (GSPT1), to cereblon and induces its ubiquitination and proteasome-dependent degradation. Loss of GSPT1 results in activation of the integrated stress response (ISR), inhibition of nonsense-mediated decay (NMD), and induction of apoptosis. Deep degradation of GSPT1, mediated by CC-90009, led to AML cell death in vitro and potent antitumor activity in patient-derived AML xenograft models. In the ongoing phase I study, CC-90009 has demonstrated antileukemic activity. Here, we characterize the pharmacodynamic responses using a suite of novel assays to support CC-90009 dose and schedule optimization.

Methods: Adult patients with R/R AML received intravenous CC-90009 daily on Days 1-5 (D1-5 schedule) or on Days 1-3 and 8-10 (D1-3/8-10 schedule) of a 28-day cycle. Peripheral blood samples taken before, during, and after dosing in the first treatment cycle were analyzed. Levels of intracellular GSPT1 in blasts and normal blood cell types were quantitated by flow cytometry analysis. Transcript levels of ISR and NMD variants in peripheral blood mononuclear cells (PBMC) were measured by qPCR. Bone marrow (BM) core biopsies at screening, Cycle 1 Day 5 and 28, and Cycle 2 and 4 Day 28, were analyzed for GSPT1, cleaved caspase 3, and CD34 protein expression by immunohistochemistry. ATF3 and DDIT3 mRNA levels were assessed in BM samples by RNA in situ hybridization.

Results: The rate and depth of GSPT1 loss in T cells and in circulating AML blasts increased with dose. A marked reduction in GSPT1 was observed in T cells and blast cells of most patients after the first dose of CC-90009 at all dose levels, and GSPT1 levels approached the assay floor between Days 2 and 5 at doses of 1.2 mg and higher on the D1-5 schedule. At 2.4 mg and higher on the D1-5 schedule, a reduction in GSPT1 levels of > 90% was observed in T cells (19 of 29 patients) and in blast cells (11 of 29 patients), with stronger GSPT1 reductions detected in AML blasts and normal T cells compared with B cells or granulocytes. In the 3 mg D1-5 cohort, patients with sustained GSPT1 reduction in peripheral blasts in the days following treatment had more persistent blast suppression compared with patients showing an earlier rebound of GSPT1. At 3 mg and 3.6 mg dose levels, continuous treatment (D1-5) resulted in slower kinetics of GSPT1 rebound and conferred superior antileukemic activity compared with the intermittent dosing schedule (D1-3/D8-10).

In addition to measuring the direct target of CC-90009, GSPT1, we also investigated markers downstream of GSPT1 degradation. Several patients with deep and sustained GSPT1 loss in the high-dose cohorts (2.4 mg and above) showed increased levels of ISR-related transcripts (ATF3 and DDIT3) and NMD-associated splice variants (SRSF3 and SRSF6) in on-treatment PBMC samples. Similarly, in BM, deep GSPT1 loss coincided with induction of ATF3 and DDIT3 mRNA, increased cleaved caspase 3 expression, and reduced CD34⁺ blasts. These clinical findings are consistent with our preclinical studies in which GSPT1 loss culminated in apoptosis, which may be mediated through activation of ISR and inhibition of NMD pathways.

Conclusions: CC-90009 is a novel CELMoD and a first-in-class GSPT1 degrader. A suite of novel pharmacodynamic assays performed …