CDK8/19 kinases, which mediate transcriptional reprogramming, have become an active target for cancer drug discovery. Several small-molecule CDK8/19 inhibitors showed in vivo efficacy and two have entered clinical trials, with no significant toxicities reported. However, Clarke et al. (eLife 2016; 5; e20722) found severe systemic toxicity associated with two potent CDK8/19 inhibitors, Cmpd3 (CCT251921) and Cmpd4 (MSC2530818), and suggested that their toxicity was due to on-target effects. Here, we compared five CDK8/19 inhibitors: Cmpd3, Cmpd4, Senexin B, 16-didehydro-cortistatin A (dCA) and 15w, in different assays. Only Cmpd4 showed striking toxicity in developing zebrafish. In cell-based assays for CDK8 and CDK19 inhibition, Cmpd3, Cmpd4, dCA and 15w showed similar low-nanomolar potency and efficacy against CDK8 and CDK19, while Senexin B was less potent. Only dCA produced sustained inhibition of CDK8/19-dependent gene expression. While toxicity of different compounds did not correlate with their effects on CDK8 and CDK19, kinome profiling identified several off-target kinases for both Cmpd3 and Cmpd4, which could be responsible for their toxicity. Off-target activities could have been achieved in the study of Clarke et al. due to high in vivo doses of Cmpd3 and Cmpd4, chosen for the ability to inhibit STAT1 S727 phosphorylation in tumor xenografts. We show here that STAT1 S727 phosphorylation is induced by various cytokines and stress stimuli in CDK8/19-independent manner, indicating that it is not a reliable pharmacodynamic marker of CDK8/19 activity. These results illustrate the need for careful off-target analysis and dose selection in the development of CDK8/19 inhibitors.
The complex processes necessary for embryogenesis require a gene regulatory network that is complex and systematic. Gene expression regulates development and organogenesis, but this process is altered and fine-tuned by epigenetic regulators that facilitate changes in the chromatin landscape. Epigenetic regulation of embryogenesis adjusts the chromatin structure by modifying both DNA through methylation and nucleosomes through posttranslational modifications of histone tails. The zebrafish is a well-characterized model organism that is a quintessential tool for studying developmental biology. With external fertilization, low cost and high fecundity, the zebrafish are an efficient tool for studying early developmental stages. Genetic manipulation can be performed in vivo resulting in quick identification of gene function. Large-scale genome analyses including RNA sequencing, chromatin immunoprecipitation and chromatin structure all are feasible in the zebrafish. In this review, we highlight the key events in zebrafish development where epigenetic regulation plays a critical role from the early stem cell stages through differentiation and organogenesis.
Hematopoiesis is tightly regulated by a network of transcription factors and complexes that are required for the maintenance and development of HSCs. In a screen for epigenetic regulators of hematopoiesis in zebrafish, we identified a requirement of the tumor suppressor protein, Ing4, in hematopoietic stem and progenitor cell (HSPC) specification. Though the Ing4 mechanism of action remains poorly characterized, it has been shown to promote stem-like cell characteristics in malignant cells and is a frequent target of inactivation in various cancer types. The tumor suppressive activity is, in part, due to the inhibitory role of Ing4 in the NF-kB signaling pathway. In zebrafish, loss of Ing4 results in loss of HSC specification and a significant increase in NF-kB target gene expression. Knockdown of NF-kB expression in Ing4 deficient zebrafish recovered HSC marker expression in the aorta suggesting that NF-kB inhibition could remediate the loss of Ing4 expression. Small molecule NF-kB pathway inhibitors with varying mechanisms were also observed to rescue of HSC marker staining in the zebrafish aorta. Ing4 deficient embryos incubated with a lower dose of inhibitor had a 31% recovery of marker staining and 82% of embryos incubated in the highest dose recovered HSC marker staining emphasizing a dose dependent rescue of HSC specification through NF-kB suppression. As in the zebrafish, we have identified a requirement for Ing4 in murine hematopoiesis. Ing4-/- bone marrow has aberrant hematopoiesis resulting in an increase in the number of short term-HSCs (ST-HSCs) (11.4% vs 31.7%) and a dramatic decrease in multipotent progenitor cells (MPPs) (47.9% vs 19.3%) along with a concurrent modest increase in the population of long-term HSCs (LT-HSCs) (2.4% vs 5.5%). Analysis of differentiation in Ing4 null bone marrow also reveals skewed hematopoiesis. We see a 14% increase in granulocytes in the null mouse marrow and observe similar skewing in CFU assays. Additionally, there were alterations in stress hematopoiesis following hematopoietic stem cell transplant. Sorted LT-HSCs fail to engraft, suggesting an evolutionarily conserved requirement for Ing4 in HSCs. Surprisingly, competitive transplantation assay with Ing4-defecient MPPs versus wild-type showed dramatic increase in peripheral blood multilineage chimerism up to 9 months post-transplantation (19% vs. 59%). This lends to the hypothesis that Ing4 deficient MPPs gain self-renewal capabilities. In further characterization of these cells, we found an increase in MPPs that express lower levels of CD34 (55.5% vs 67.7%). CD34 expression is a marker of HSCs. This CD34+/mid population also express CD229 (85% positive), which is barely detectable in wildtype marrow (less that 0.01%). CD229 is also an HSC marker. Based on these exciting findings, we hypothesize that we have identified a subset of CD34+/midCD229+ MPPs in Ing4 deficient mice that retain self-renewal characteristics. Our data suggest that Ing4 normally functions as a critical suppressor for genes required for self-renewal and developmental potency in MPPs. Overall, our findings suggest that Ing4 plays a crucial role in the regulation of hematopoiesis and provides key tools for further identification and characterization of Ing4 pathways and functions. Given the role of Ing4 in both normal hematopoiesis and cancer, this gene likely has a critical role in regulation of stem cell self-renewal and maintenance. Disclosures Zon: CAMP4: Equity Ownership; Fate Therapeutics: Equity Ownership; Scholar Rock: Equity Ownership.
Hematopoiesis is tightly regulated by a network of transcription factors and complexes that are required for the maintenance and development of HSCs. In a screen for epigenetic regulators of hematopoiesis in zebrafish, we identified a requirement of the tumor suppressor protein, Ing4, in hematopoietic stem and progenitor cell (HSPC) specification. Though the Ing4 mechanism of action remains poorly characterized, it has been shown to promote stem-like cell characteristics in malignant cells. This activity is, in part, due to the inhibitory role of Ing4 in the NF-kB signaling pathway. In the absence of Ing4, there is a significant increase in NF-kB target gene expression. As in the zebrafish, we have identified a requirement for Ing4 in murine hematopoiesis, where Ing4 deficiency impairs hematopoietic stem cell (HSC) function, but enhances multipotent progenitor cell (MPP) regenerative capacity. Given the role of Ing4 in both normal hematopoiesis and cancer, this gene likely has a critical role in regulation of stem cell self-renewal and maintenance. To define the role of Ing4 in zebrafish HSPCs, we designed an anti-sense morpholino oligo against Ing4 and injected into zebrafish embryos at the single cell stage. Embryos were screened using in situ hybridizations for c-myb and runx1 expression, which are highly expressed in the aorta, gonad, mesonephros (AGM) region in the developing zebrafish embryo. We found that Ing4-deficient zebrafish embryos lose >90% of runx1+/c-myb+ cells in the AGM, demonstrating a lack of HSPC specification. Analysis of ephrinB2 expression showed normal specification of the aorta in Ing4 morphant embryos, signifying that the step of HSPC specification is affected in the absence of Ing4. Overexpression of human Ing4 in zebrafish embryos resulted in increased HSPC marker staining suggesting that normal expression levels of Ing4 are required for HSC specification. As Ing4 is an epigenetic regulator that binds specific gene loci, we examined the chromatin occupancy of Ing4 in human peripheral blood CD34+ progenitor cells. Using ChIP-seq for Ing4 in CD34+ cells, we show that Ing4 binds to many regulators of blood development including MYB, LMO2, RUNX1, and IKAROS, and several NF-kB target genes. In other tissues, Ing4 negatively regulates NF-kB, so accordingly, loss of Ing4 results in an overabundance of NF-kB signaling. To address NF-kB target gene expression in Ing4-deficient zebrafish embryos, we performed qPCR analysis at 36hpf. These assays showed an increase in the expression of a subset of NF-kB target genes (IKBKE, IL-19, IL-1b, IL-20R). Simultaneous knockdown of both Ing4 and RelA, through combined morpholino injections against both factors, resulted in the rescue of HSC marker expression in the aorta. These results suggest that NF-kB inhibition could remediate the loss of Ing4. A mouse model for Ing4 deficiency was generated to further evaluate the role of Ing4 in differentiated immune cells. These mice are developmentally normal but are hypersensitive to stimulation with LPS. Interestingly, we found that Ing4-/- mice showed skewed hematopoiesis resulting in an increase in the number of short term-HSCs (ST-HSCs) (11.4% vs 31.7%) and a dramatic decrease in multipotent progenitor cells (MPPs) (47.9% vs 19.3%) along with concurrent modest increase in the population of long-term HSCs (LT-HSCs) (2.4% vs 5.5%). Additionally, there were alterations in stress hematopoiesis following hematopoietic stem cell transplant. Sorted LT-HSCs fail to engraft, suggesting an evolutionarily conserved requirement for Ing4 in HSCs. Surprisingly, competitive transplantation assay with Ing4-defecient MPPs versus wild-type showed dramatic increase in peripheral blood multilineage chimerism up to 9 months post-transplantation (19% vs. 59%). This lends to the hypothesis that Ing4 deficient MPPs gain self-renewal capabilities. Based on these exciting findings, we hypothesize that Ing4 normally functions as a critical suppressor for genes required for self-renewal and developmental potency in MPPs. Overall, our findings suggest that Ing4 plays a crucial role in the regulation of hematopoiesis and provides key tools for further identification and characterization of Ing4 pathways and functions. Disclosures No relevant conflicts of interest to declare.
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