Acute myeloid leukemia (AML) is a heterogeneous disorder and mostly incurable due to relapse and drug resistance. A key challenge is to target the fraction of more quiescent leukemic cells that are resistant to chemotherapeutic drugs.1 During recent years, several new small molecule inhibitors have been developed to uniquely target disease-specific molecular events, such as the FLT3-ITD mutation. However, such targeted therapies have only met moderate clinical success due to drug resistance and relapse, which is associated with selection and expansion of malignant subclones that are not dependent on the initially targeted mutation.2 Thus, additional novel targeted therapeutic strategies are required for leukemia clearance. A particularly attractive approach is to harness specific genetic deficiencies of the tumor cells by targeting synthetic lethal interactions. In this case, a therapeutic effect can be reached even in tumors that are not critically dependent on the mutations that are targeted.
The cohesin protein complex forms a ring-like structure that holds sister chromatids together which is necessary for the proper segregation of chromosomes during mitosis. In addition, cohesin plays an essential role in DNA repair, genome organization and transcriptional regulation.3 The core structure comprises the three proteins RAD21, SMC3 and SMC1A. The fourth subunit consists of either one of two paralogous proteins: STAG1 or STAG2. Whole genome sequencing studies have identified a significant number of somatic mutations in cohesin genes with an accumulated mutation rate between 10% and 15% for AML and myelodysplastic syndrom (MDS).4 An even higher rate of cohesin mutations (around 50%) was observed in Down Syndrome associated childhood acute megakaryocytic leukemia (DS-AMKL).5 Cohesin mutations have loss-of-function consequences arguing for a tumor suppressor role of cohesin in the context of leukemia.4 Since cohesin is necessary for proper chromosomal segregation, mutations were first thought to promote tumor progression via genome instability.6 However, the majority of the cohesin-mutated cancers are euploid suggesting that it is rather non-mitotic functions of cohesin such as transcriptional regulation and chromatin organization which are associated with leukemogenesis.7 With a mutation frequency of approximately 6% in AML and 18% in DS-AMKL, STAG2 is the predominantly mutated gene among the cohesin genes.4 STAG2 mutations result in complete loss-of-function in males since these genes are located on the X chromosome.8 STAG2 knockdown promoted the in vitro expansion of umbilical cord blood (UCB)-derived hematopoietic stem and progenitor cells (HSPC) and enhanced the repopulating activity of human HSPC in xenograft recipients, demonstrating a direct functional association between STAG2 loss and dysregulated hematopoiesis.9 Although STAG1- and STAG2-containing cohesin complexes might have distinct functions,10 they are redundant to ensure the chromatid cohesion during mitosis. Hence, STAG1-mediated mitotic dependency was observed in STAG2 knockout (KO) cell lines.11,12 Moreover, a recent study in knockout mice showed that the combined loss of STAG1 and STAG2, but not that of each gene alone, resulted in bone marrow aplasia and mortality, further supporting the existence of synthetic lethal interactions between STAG1 and STAG2.13 A majority of the cohesin mutations have a high variant allele frequency indicating that they occur relatively early in leukemogenesis.4,14 Inducing synthetic lethality in AML harboring STAG2 mutations should thus eliminate most clones irrespective of any secondary mutations. Though, theoretically possible as a novel therapeutic application to STAG2 null AML, synthetic lethality from targeting STAG1 is yet to be demonstrated in primary human leukemic cells. Here, we provide a functional proof-of-concept demonstration for this approach.
First, in order to demonstrate the existence of STAG1-mediated mitotic dependency in primary human HSPC, we generated STAG2 null HSPC derived from UCB utilizing a CRISPR/Cas9 based knockin system. In brief, an early stop codon, followed by an open reading frame encoding enhanced green fluorescent protein (eGFP) was inserted into the targeted STAG2 locus utilizing homology-directed repair (HDR) (Online Supplementary Figure S1A). With this system, successfully edited, eGFP expressing STAG2 null cells can be distinguished from unedited cells. As STAG2 is located in the X chromosome, we edited CD34+ cells from male donors to achieve successful STAG2 KO by monoallelic editing. Flow cytometry analysis revealed an eGFP frequency of 27% compared to mock control indicating efficient STAG2 editing and eGFP integration in HSPCs (Figure 1A and B). Further, Western blotting analysis of the eGFP expressing cells revealed a near complete loss of STAG2 protein, demonstrating that integration of the eGFP template successfully knocked out STAG2 expression (Figure 1C). Sanger sequencing of the STAG2 locus in eGFP-positive cells reveled a successful integration of the donor template at the expected locus (Online Supplementary Figure S1B). Altogether we successfully generated STAG2 KO human HSPC utilizing CRISPR-mediated HDR.
Next, in order to assess STAG1-mediated mitotic dependency, we transduced STAG2 KO human HSPC with two independent short hairpin RNA (shRNA) targeting STAG1 as well scrambled (Scr) control shRNA. The pLKO shRNA vectors were engineered to express Kusabira orange (KuO) enabling tracking of the transduced cells in conjunction with the eGFP marker for STAG2 null cells. Both STAG1 shRNA showed successful knockdown of STAG1 at the mRNA and protein level 72 hours post-transduction (Online Supplementary Figure 1C and D). We monitored cell number and frequency of the KuO and GFP-positive population during 1 week of culture and observed that both STAG1 shRNA, but not the control shRNA, induced a significant depletion of STAG2 null HSPC. Moreover, isogenic control cells with intact STAG2 were unaffected by the STAG1 shRNA, demonstrating that the observed cell depletion was highly specific to the combined loss of STAG1 and STAG2 (Figure 1D and E). We reasoned that depletion of both STAG1 and STAG2 in the HSPC model may disrupt cohesin’s essential functions of sister chromatid cohesion during cell division and thereby limit cell survival.11,12 Indeed, we observed that STAG1 knockdown induced marked sister chromatid cohesion defects in more than 50% of the STAG2 null cells (Figure 1F and G). Later we have also analyzed the effects of STAG1 knockdown in two primary AML samples that lacked STAG2 protein expression due to truncating mutations (Figure 1H; Online Supplementary Table S1). STAG1 knockdown induced a 2-5-fold reduction in expansion of STAG2 null AML cells compared to the scrambled control while the STAG2 wild-type (WT) control AML cells were unperturbed (Figure 1I). Overall, these findings demonstrate the existence of a synthetic lethal interaction between STAG1 and STAG2 in primary human HSPC and AML cells.
Figure 1.STAG1 knockdown perturbs STAG2 null hematopoietic stem and progenitor cells. Umbilical cord blood (UCB) CD34+ cells were cultured in serum-free expansion medium (SFEM) added with stem cell factor (SCF), thrombopoietin (TPO) and FMS-like tyrosine kinase 3 ligand (FLT3L) at final concentration of 100 ng/mL each. (A) Flow cytometry analysis of enhanced green fluorescent protein (eGFP) expression in UCB CD34+ cells edited with either mock or with single guide RNA (sgRNA) (UCUGGUCCAAACCGAAUGAA) - Cas9 ribonucleoproteins targeting STAG2 along with adeno-associated virus donor template. (B) Quantification of CRISPR/Cas9-mediated eGFP knockin efficiency measurement across 3 replicates. (C) Western blot analysis of STAG2 protein in the mock and eGFP sorted UCB CD34+ cells. (D) Day 5 co-transduction analysis of Kusabira orange positive STAG1 small interfing RNA (shRNA) and eGFP-positive STAG2 null cells by flow cytometry. (E) Quantification of STAG1 shRNA-mediated cell proliferation in mock and STAG2 null CD34+ cells compared to the scrambled control. Two-way ANOVA, **P<0.01. (F) Fluorescence in situ hybridization to analyze the sister chromatid cohesin in STAG2 null cells 3 days after shRNA transduction. (G) Cohesion defects were quantified in around 8-15 cells for each condition. Primary constriction gaps (PCG) measured are the visible gaps between the sister chromatids at the centromeres; PCG mild - defects in 1-4 chromosomes, PCG moderate - defects in 4-19 chromosomes. (H) STAG2 protein expression in a control and 2 STAG2-mutated primary acute myeloid leukemia (AML) samples (AML 16 and 94). (I) The primary AML cells were co-cultured with OP9M2 Stroma and transduced with STAG1 shRNA. Fold expansion of scrambled and STAG1 shRNA transduced cells at day 5 as compared to day 2 is shown. Scr: scrambled shRNA CAACAAGATGAAGAGCACCAA; Sh1: STAG1 shRNA1 CTTCAGCCTTTGGTGTTCAAT; Sh2: STAG1 shRNA2 GCCAATGAAAGGTTGGAGTTA.
We then sought to assess whether we could induce synthetic lethality in vivo by targeting STAG1 in STAG2-mutated primary AML cells. We chose a primary human AML sample (AML 21) that was readily transplantable in immunodeficient mice and that had been propagated as a patient-derived xenograft (PDX) sample to allow assessment in vivo. This sample carried a STAG2 loss-of-function mutation with a variant allele frequency of 89% accompanied with other candidate driver mutations such as IDH2, SRSF2 and NRAS. (Online Supplementary Table S1). We analyzed STAG2 protein levels in the PDX sample by western blotting and found a complete lack of STAG2 expression, in line with the sequencing data (Figure 2A). We successfully transduced bulk mononuclear PDX cells with either scrambled or the two independent STAG1 shRNA at frequencies of 30-60% and transplanted into sub-lethally irradiated NOD-scid IL2Rgnull-3/GM/SF (NSG-S) mice (Figure 2B; Online Supplementary Figure S2A). As a reference control, and to assess the effect of STAG1 perturbation on normal HSPC, we also transduced UCB CD34+ cells with the same vectors and assayed the cells both in vitro and in vivo by transplantation to sub-lethally irradiated NOD.Cg-PrkdcscidIl2rgtm1Wjl/SzJ (NSG) mice. Importantly, STAG1 knockdown did not appear to negatively impact the engraftment of UCB CD34+ cells (Figure 2C and D). Rather, we observed a moderate increase in the fold expansion of CD34+ cells in vitro, and a robust contribution of transduced cells in vivo that was steadily increasing over time, similar to cells transduced with the scramble control (Online Supplementary Figure S2B and C). Altogether this indicates that partial perturbation of STAG1 is well tolerated by human HSPC without a major influence on their repopulation and differentiation properties (Online Supplementary Figure 2D to H). By contrast, when we analyzed the bone marrow of NSG-S mice transplanted with transduced PDX-derived AML cells, we found a near complete depletion of cells transduced with either of the two STAG1 shRNA, whereas the mice transplanted with scrambled shRNA transduced cells retained a stable transduced KuO+ population (Figure 2E and F). We have also analyzed the PDX material for STAG2 expression to exclude the possibilities of a potential drift of STAG2 null clones and found that the AML cells from scrambled and shRNA transduced conditions maintained STAG2 null clones (Online Supplementary Figure 2I). Overall, this suggests that STAG1 knockdown induces a selective impairment of STAG2 null AML cells that is sufficient to eliminate them upon transplantation.
Taken together, we demonstrate that partial perturbation of STAG1 selectively eliminates primary human HSPC and AML cells lacking STAG2, while it is well tolerated by normal HSPC. Developing small molecules such as proteolytic chimeras that selectively degrade STAG1 by recruiting the ubiquitin-proteasomal system would be an ideal way to translate these findings into clinical applications. Moreover, a recent study by van der Lelij et al. identified critical elements of STAG1 that are essential for interaction with the RAD21 protein, thereby opening up another possibility to develop selective STAG1-RAD21 interaction inhibitors.15 Our study provides a rationale for exploiting synthetic lethality to develop more specific and targeted therapies for tumors with STAG2 mutations, demonstrating a first proof-of-concept within the hematopoietic system.
Figure 2.STAG1 knockdown selectively perturbs acute myeloid leukemia cells. (A) STAG1 and STAG2 expression in umbilical cord blood (UCB) and STAG2 null acute myeloid leukemia (AML) 21 cells. (B) UCB and AML cells were transduced with scrambled (Scr) and STAG1 small interfing RNA (shRNA) and transplanted into sub-lethally irradiated NSG and NSG-S mice respectively. Prior to transplantation AML xenograft cells were transduced in vitro with lentiviral particles and transferred to a new plate coated with irradiated OP9M2 stroma cells. (C) Fluorescence-activated cell sorting (FACS) plots showing the chimerism of UCB grafts (humanCD45) and frequencies of Kusabira orange-positive shRNA transduced cells at NSG bone marrow 16 weeks post transplantation. (D) Frequency of hCD45 chimerism and the proportion of transduced cells were quantified for each shRNA (n=5). Kruskal-Wallis test with comparison to the scrambled control. ns: not significant. (E) Chimerism of AML grafts (human CD45) and frequencies of Kusabira orange positive shRNA expressing cells in NSG-S bone marrow, analyzed 16 weeks post transplantation. (F) Frequency of AML engraftment and the proportion of transduced cells were quantified for each shRNA (n=4). Kruskal-Wallis test with comparison to the scrambled control. *P<0.05; **P<0.01. Scr: scrambled shRNA; Sh1: STAG1 shRNA1; Sh2: STAG1 shRNA2.
Footnotes
- Received November 18, 2021
- Accepted May 27, 2022
Correspondence
Disclosures
No conflicts of interest to disclose.
Contributions
AS, CS, KZ, LS, AuB, AB, EA, SH, and NM performed the experiments and acquired data. LMC and KP helped with the cohesion assay. CS, TF and MM performed molecular analysis of the AML samples and provided the materials. AS and JL conceived and designed the study, interpreted the results and wrote the manuscript.
Data-sharing statement
The datasets generated or analyzed in this study are available upon reasonable request to the corresponding authors (AS and JL).
Funding
Acknowledgements
We would like to thank the staff at animal house and FACS core facilities for their excellent support. We also would like to thank Jenny G. Johansson for helping with the AAV vector production.
References
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