Targeting CDK8/CDK19 to Disrupt Leukemic Stem Cell-like Population in Acute Myeloid Leukemia: Exploring RVU120 As a Promising Frontline Therapy

Abstract

Leukemic stem cells (LSCs) are implicated in the initiation, maintenance, and relapse of leukemia. The failure of current standard induction chemotherapy, which primarily targets dividing cells, has been linked to the quiescence of LSCs, leading to resistance to treatment. Consequently, there is an urgent need for novel therapies specifically aimed at eradicating LSCs to achieve more effective and durable treatment responses. CDK8 and its paralog CDK19 associate with the mediator complex and regulate gene expression programs linked to cancer and stem cell pluripotency. RVU120, a highly selective and potent CDK8/19 inhibitor, is currently undergoing clinical trials for AML and high-risk myelodysplastic syndrome (HR-MDS) (NCT04021368). Previous studies have demonstrated its potential mechanism of action on LSCs, wherein inhibition of CDK8/CDK19 led to the activation of lineage commitment genes in sensitive AML cells. Through recent gene expression analysis, it was discovered that inhibition of CDK8/CDK19 in transformed CD34+ cord blood cells resulted in the downregulation of stemness and quiescence-associated genes, while simultaneously upregulating genes associated with hematopoietic lineage-committed progenitors. Building on these findings, this study further investigates the potential of CDK8/CDK19 inhibition as a means to target LSCs, providing a rationale for RVU120 as a frontline treatment option in AML. The impact of RVU120 on LSCs has been investigated using an in vitro hierarchical AML-8227 model. This primary model maintains distinct populations in culture conditions, including CD34+CD38- cells with quiescent LSC potential, CD34+CD38+ cells enriched in progenitors, and CD34- more mature blasts (Lechman et al., 2016, Cancer Cell). The CD34+CD38- LSC population was further characterized by flow cytometry showing the expression of LSC surface markers, namely CD45RA, CD123, CD44, and negative expression for CD90, rendering it a suitable model for mechanistic studies. Next, AML-8227 cells were subjected to RVU120 treatment, resulting in a noticeable reduction in cell proliferation and viability. Flow cytometric analysis demonstrated a significant decrease in the percentage and total cell number of LSC-enriched/progenitor populations within the AML hierarchical model upon inhibition of CDK8/CDK19. Furthermore, RVU120 treatment induced the differentiation of cells, as evidenced by a sequential increase in the percentage of early myeloid differentiation marker, CD64, and late myeloid differentiation marker, CD14 (Fig. 1). In order to deconvolute the activity and mechanism of action of RVU120 in different cell populations, single-cell RNAseq analysis on AML-8227 cells has been performed at 24h and 3 days of treatment using technology from 10xGenomics. Additionally, analyzed AML-8227 cells have been enriched in the CD34+ population to evaluate the effect of RVU120 on stem and progenitor fraction at the single-cell level. The bioinformatic analysis of the performed experiment is ongoing and its results will be integrated into the data described above. CDK8 activity can be conveniently tracked by measuring specific phosphorylation of its target S726 on STAT5 protein. Dose and exposure-dependent inhibition of this marker has been established in cells exposed to RVU120. Levels of STAT5 S726 have been measured in different cell populations in patients from the first-in-human study of RVU120 in AML/HR-MDS. Consistent with established roles of CDK8 in LSCs, significantly elevated levels of pSTAT5 were observed in CD34+ stem/progenitor-enriched population when compared to CD34- blast cells measured at baseline before the start of the treatment (p<0.0001; ratio paired t-test; updated data from ASH 2022; Fig. 2). In summary, RVU120 displays cytotoxic and differentiating effects on well-characterized LSC populations in various models. Additionally, the CDK8 activity marker is directly associated with LSC-enriched bone marrow cells in AML patients, highlighting RVU120's potential as a promising therapeutic for targeting AML LSCs. Moreover, single-cell studies offer insights into its inhibitory effects on LSC-enriched populations and capacity for inducing differentiation. Overall, these results support RVU120 as a frontline candidate in AML therapy, countering therapeutic failure caused by persistent LSCs.