Targeting SWI/SNF Complexes in Cancer: Pharmacological Approaches and Implications

Dillon M.T., Guevara J., Mohammed K., Patin E.C., Smith S.A., Dean E., Jones G.N., Willis S.E., Petrone M., Silva C., Thway K., Bunce C., Roxanis I., Nenclares P., Wilkins A., et. al.

Ahmad K., Brahma S., Henikoff S.

In eukaryotic genomes, transcriptional machinery and nucleosomes compete for binding to DNA sequences; thus, a crucial aspect of gene regulatory element function is to modulate chromatin accessibility for transcription factor (TF) and RNA polymerase binding. Recent structural studies have revealed multiple modes of TF engagement with nucleosomes, but how initial “pioneering” results in steady-state DNA accessibility for further TF binding and RNA polymerase II (RNAPII) engagement has been unclear. Even less well understood is how distant sites of open chromatin interact with one another, such as when developmental enhancers activate promoters to release RNAPII for productive elongation. Here, we review evidence for the centrality of the conserved SWI/SNF family of nucleosome remodeling complexes, both in pioneering and in mediating enhancer-promoter contacts. Consideration of the nucleosome unwrapping and ATP hydrolysis activities of SWI/SNF complexes, together with their architectural features, may reconcile steady-state TF occupancy with rapid TF dynamics observed by live imaging.

Nguyen V.T., Tessema M., Weissman B.E.

The switch/sucrose non-fermenting (SWI/SNF) chromatin remodeling complex is a global regulator of gene expression known to maintain nucleosome-depleted regions at active enhancers and promoters. The mammalian SWI/SNF protein subunits are encoded by 29 genes and 11–15 subunits including an ATPase domain of either SMARCA4 (BRG1) or SMARCA2 (BRM) are assembled into a complex. Based on the distinct subunits, SWI/SNF are grouped into 3 major types (subfamilies): the canonical BRG1/BRM-associated factor (BAF/cBAF), polybromo-associated BAF (PBAF), and non-canonical BAF (GBAF/ncBAF). Pan-cancer genome sequencing studies have shown that nearly 25% of all cancers bear mutations in subunits of the SWI/SNF complex, many of which are loss of function (LOF) mutations, suggesting a tumor suppressor role. Inactivation of SWI/SNF complex subunits causes widespread epigenetic dysfunction, including increased dependence on antagonistic components such as polycomb repressor complexes (PRC1/2) and altered enhancer regulation, likely promoting an oncogenic state leading to cancer. Despite the prevalence of mutations, most SWI/SNF-mutant cancers lack targeted therapeutic strategies. Defining the dependencies created by LOF mutations in SWI/SNF subunits will identify better targets for these cancers.

Dominici C., Mayhew D., Adam A., Uzan F., Garbitt-Amaral V., Mikse O., Antonakos B., Ahmad H., Parikh S., Lin M.Y., Sandoval G., Lahr D., Wu H., Xu M., Brennan S., et. al.

Abstract Acute myeloid leukemia (AML) is a complex disease with multiple sub-types, each characterized by unique clinical and molecular features, driving the need to develop targeted therapies which exploit specific vulnerabilities. Bromodomain-containing protein 9 (BRD9) is a component of the ncBAF chromatin remodeling complex, and has been recently indicated as a strong dependency in AML (Weisberg et al 2022). It has been shown that inhibitors of BRD9 induce growth inhibition and expression of apoptotic makers in AML cell lines (Hohmann et al 2016; Zhou et al 2021). It has also been reported that BRD9 is critical to AML cell survival through the maintenance of STAT5 signaling (Del Gaudio et al 2019). Herein, we profile the in vitro anti-proliferative effects of FHD-609, a potent and selective degrader of BRD9, in a panel of 40 AML cell lines representative of a broad range of AML sub-types. We observed that FHD-609 was effective at inhibiting the growth of a subset of AML cell lines, consistent with previous reports in the literature. We further investigated whether treatment of AML cell lines with FHD-609 would induce changes in cell cycle, and found an increase in G1 in the same subset of cell lines that showed cell growth inhibition. Furthermore, treatment with FHD-609 induced apoptosis in these cell lines. To identify the mechanisms of action of FHD-609 in AML, as well as potential predictive biomarkers for AML sensitivity to FHD-609, we performed a range of mechanistic studies including ATACseq, ChIPseq and RNAseq in AML cells treated with FHD-609. We observed significant changes in the chromatin landscape in sensitive AML cell lines, and negligible changes in insensitive cell lines. Further bioinformatics analysis identified a possible biomarker strategy that correlates with the sensitivity of AML cell lines to FHD-609 in vitro. To confirm whether this biomarker strategy would successfully predict response in vivo, we dosed AML CDX and PDX models with FHD-609 based on the biomarker selection strategy. We observed a strong anti-tumor effect in AML CDX models and significantly extended survival of the mice in the AML PDX models. In summary, we have shown that FHD-609 demonstrates strong anti-tumor efficacy in a subtype of AML and have identified a possible biomarker strategy to predict response. Citation Format: Claudia Dominici, David Mayhew, Ammar Adam, Flore Uzan, Victoria Garbitt-Amaral, Oliver Mikse, Brandon Antonakos, Hafiz Ahmad, Salonee Parikh, Mei Yun Lin, Gabriel Sandoval, David Lahr, Hsin-Jung Wu, Mengni Xu, Sean Brennan, Luis M. M. Soares, Jordana Muwanguzi, Huawei Chen, Zhaoxia Yang, Jason T Lowe, Matt Netherton, Laura Zawadzke, Johannes Voigt, Liyue Huang, Sabine Ruppel, Ho Man Chan, Ryan Kruger, David S Milan, Scott Innis, Qianhe Zhou, Steven F Bellon. Investigation of FHD-609, a potent degrader of BRD9, in preclinical models of acute myeloid leukemia (AML) [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr A049.

Zhang J., Duan H., Gui R., Wu M., Shen L., Jin Y., Pang A., Yu X., Zeng S., Zhang B., Lin N., Huang W., Wang Y., Yao X., Li J., et. al.

BRD9 is essential in regulating gene transcription and chromatin remodeling, and blocking BRD9 profoundly affects the survival of AML cells. However, the inhibitors of BRD9 suffer from various drawbacks, including poor phenotype and selectivity, and BRD9 PROTAC still faces the challenge of druggability, which limits the development of blocking BRD9 in AML. This study described an oral activity BRD9 PROTAC C6 by recruiting the highly efficient E3 ligase. C6 demonstrated remarkable efficacy and selectivity in BRD9 degradation with a BRD9 degradation DC50 value of 1.02 ± 0.52 nM and no degradation of BRD4 or BRD7. Moreover, our findings highlighted its therapeutic potential, as evidenced by profound in vitro activity against the AML cell line MV4-11. Furthermore, C6 exhibited superior oral activity, with a Cmax value of 3436.95 ng/mL. These findings demonstrated that C6, as a novel BRD9 PROTAC with remarkable pharmacodynamic and pharmacokinetic properties, had the potential to be developed as a promising therapeutic agent for AML treatment.

Mancarella C., Morrione A., Scotlandi K.

Sarcomas are heterogeneous bone and soft tissue cancers representing the second most common tumor type in children and adolescents. Histology and genetic profiling discovered more than 100 subtypes, which are characterized by peculiar molecular vulnerabilities. However, limited therapeutic options exist beyond standard therapy and clinical benefits from targeted therapies were observed only in a minority of patients with sarcomas. The rarity of these tumors, paucity of actionable mutations, and limitations in the chemical composition of current targeted therapies hindered the use of these approaches in sarcomas. Targeted protein degradation (TPD) is an innovative pharmacological modality to directly alter protein abundance with promising clinical potential in cancer, even for undruggable proteins. TPD is based on the use of small molecules called degraders or proteolysis-targeting chimeras (PROTACs), which trigger ubiquitin-dependent degradation of protein of interest. In this review, we will discuss major features of PROTAC and PROTAC-derived genetic systems for target validation and cancer treatment and focus on the potential of these approaches to overcome major issues connected to targeted therapies in sarcomas, including drug resistance, target specificity, and undruggable targets. A deeper understanding of these strategies might provide new fuel to drive molecular and personalized medicine to sarcomas.

Soshnikova N.V., Azieva A.M., Klimenko N.S., Khamidullina A.I., Feoktistov A.V., Sheynov A.A., Brechalov A.V., Tatarskiy V.V., Georgieva S.G.

The Polybromo-associated BAF (BRG1- or BRM-associated factors) (PBAF) chromatin-remodeling complex is essential for transcription in mammalian cells. In this study, we describe a novel variant of the PBAF complex from differentiated neuronal cells, called dcPBAF, that differs from the canonical PBAF existing in proliferating neuroblasts. We describe that in differentiated adult neurons, a specific subunit of PBAF, PHF10, is replaced by a PHF10 isoform that lacks N- and C-terminal domains (called PHF10D). In addition, dcPBAF does not contain the canonical BRD7 subunit. dcPBAF binds promoters of the actively transcribed neuron-specific and housekeeping genes in terminally differentiated neurons of adult mice. Furthermore, in differentiated human neuronal cells, PHF10D-containing dcPBAF maintains a high transcriptional level at several neuron-specific genes.

Wang X., Song C., Ye Y., Gu Y., Li X., Chen P., Leng D., Xiao J., Wu H., Xie S., Liu W., Zhao Q., Chen D., Chen X., Wu Q., et. al.

Abstract Bromodomain-containing protein 9 (BRD9) is a specific subunit of the non-canonical SWI/SNF (ncBAF) chromatin-remodeling complex, whose function in human embryonic stem cells (hESCs) remains unclear. Here, we demonstrate that impaired BRD9 function reduces the self-renewal capacity of hESCs and alters their differentiation potential. Specifically, BRD9 depletion inhibits meso-endoderm differentiation while promoting neural ectoderm differentiation. Notably, supplementation of NODAL, TGF-β, Activin A or WNT3A rescues the differentiation defects caused by BRD9 loss. Mechanistically, BRD9 forms a complex with BRD4, SMAD2/3, β-CATENIN and P300, which regulates the expression of pluripotency genes and the activity of TGF-β/Nodal/Activin and Wnt signaling pathways. This is achieved by regulating the deposition of H3K27ac on associated genes, thus maintaining and directing hESC differentiation. BRD9-mediated regulation of the TGF-β/Activin/Nodal pathway is also demonstrated in the development of pancreatic and breast cancer cells. In summary, our study highlights the crucial role of BRD9 in the regulation of hESC self-renewal and differentiation, as well as its participation in the progression of pancreatic and breast cancers.

Cochran A.G., Flynn M.

Li L., Wang L., Liu D., Zhao Y.

AbstractCheckpoint kinase 1 (CHK1), a key effector in the cellular response to DNA lesions, is a crucial component of all cell cycle checkpoints. Recent reports have revealed that CHK1 is highly expressed in numerous cancer types in the clinical settings. However, the mechanisms underlying the regulation of CHK1 expression in tumor cells remain unclear. Here, we report that CHK1 is negatively regulated by the bromodomain-containing protein 7 (BRD7). Specifically, BRD7 silencing increased CHK1 (but not CHK2) expression at both mRNA and protein levels, in a p53-independent manner in multiple tumor cell lines. Furthermore, BRD7 silencing stabilized CHK1 via reducing its ubiquitination. Mechanistically, BRD7 knockdown not only increased the levels of USP1, a deubiquitinase for CHK1, but also promoted the interaction between CHK1 and USP1, subsequently enhancing the de-ubiquitination of CHK1. USP1 knockdown abrogated BRD7 silencing-induced CHK1 induction. Biologically, the increased expression of CHK1 in tumor cells caused by BRD7 silencing significantly increased cell sensitivity to CHK1 inhibitors by enhancing tumor cell apoptosis, and this effect was reversed by the simultaneous knockdown of CHK1 or USP1. Taken together, our findings suggest that BRD7 is a potential genetic or drug target that may help to improve the efficacy of chemotherapeutic drugs targeting CHK1 in combinatorial therapy.

Yang C., He Y., Wang Y., McKinnon P.J., Shahani V., Miller D.D., Pfeffer L.M.

AbstractGlioblastoma (GBM) is an aggressive brain cancer with a poor prognosis. While surgical resection is the primary treatment, adjuvant temozolomide (TMZ) chemotherapy and radiotherapy only provide slight improvement in disease course and outcome. Unfortunately, most treated patients experience recurrence of highly aggressive, therapy‐resistant tumours and eventually succumb to the disease. To increase chemosensitivity and overcome therapy resistance, we have modified the chemical structure of the PFI‐3 bromodomain inhibitor of the BRG1 and BRM catalytic subunits of the SWI/SNF chromatin remodelling complex. Our modifications resulted in compounds that sensitized GBM to the DNA alkylating agent TMZ and the radiomimetic bleomycin. We screened these chemical analogues using a cell death ELISA with GBM cell lines and a cellular thermal shift assay using epitope tagged BRG1 or BRM bromodomains expressed in GBM cells. An active analogue, IV‐129, was then identified and further modified, resulting in new generation of bromodomain inhibitors with distinct properties. IV‐255 and IV‐275 had higher bioactivity than IV‐129, with IV‐255 selectively binding to the bromodomain of BRG1 and not BRM, while IV‐275 bound well to both BRG1 and BRM bromodomains. In contrast, IV‐191 did not bind to either bromodomain or alter GBM chemosensitivity. Importantly, both IV‐255 and IV‐275 markedly increased the extent of DNA damage induced by TMZ and bleomycin as determined by nuclear γH2AX staining. Our results demonstrate that these next‐generation inhibitors selectively bind to the bromodomains of catalytic subunits of the SWI/SNF complex and sensitize GBM to the anticancer effects of TMZ and bleomycin. This approach holds promise for improving the treatment of GBM.

Ordonez-Rubiano S.C., Maschinot C.A., Wang S., Sood S., Baracaldo-Lancheros L.F., Strohmier B.P., McQuade A.J., Smith B.C., Dykhuizen E.C.

Davó-Martínez C., Helfricht A., Ribeiro-Silva C., Raams A., Tresini M., Uruci S., van Cappellen W., Taneja N., Demmers J.A., Pines A., Theil A., Vermeulen W., Lans H.

Abstract The SWI/SNF family of ATP-dependent chromatin remodeling complexes is implicated in multiple DNA damage response mechanisms and frequently mutated in cancer. The BAF, PBAF and ncBAF complexes are three major types of SWI/SNF complexes that are functionally distinguished by their exclusive subunits. Accumulating evidence suggests that double-strand breaks (DSBs) in transcriptionally active DNA are preferentially repaired by a dedicated homologous recombination pathway. We show that different BAF, PBAF and ncBAF subunits promote homologous recombination and are rapidly recruited to DSBs in a transcription-dependent manner. The PBAF and ncBAF complexes promote RNA polymerase II eviction near DNA damage to rapidly initiate transcriptional silencing, while the BAF complex helps to maintain this transcriptional silencing. Furthermore, ARID1A-containing BAF complexes promote RNaseH1 and RAD52 recruitment to facilitate R-loop resolution and DNA repair. Our results highlight how multiple SWI/SNF complexes perform different functions to enable DNA repair in the context of actively transcribed genes.

Padilla-Benavides T., Olea-Flores M., Sharma T., Syed S.A., Witwicka H., Zuñiga-Eulogio M.D., Zhang K., Navarro-Tito N., Imbalzano A.N.

Mammalian SWI/SNF (mSWI/SNF) complexes are ATP-dependent chromatin remodeling enzymes that are critical for normal cellular functions. mSWI/SNF enzymes are classified into three sub-families based on the presence of specific subunit proteins. The sub-families are Brm- or Brg1-associated factor (BAF), ncBAF (non-canonical BAF), and polybromo-associated BAF (PBAF). The biological roles for the different enzyme sub-families are poorly described. We knocked down the expression of genes encoding unique subunit proteins for each sub-family, Baf250A, Brd9, and Baf180, which mark the BAF, ncBAF, and PBAF sub-families, respectively, and examined the requirement for each in myoblast differentiation. We found that Baf250A and the BAF complex were required to drive lineage-specific gene expression. KD of Brd9 delayed differentiation. However, while the Baf250A-dependent gene expression profile included myogenic genes, the Brd9-dependent gene expression profile did not, suggesting Brd9 and the ncBAF complex indirectly contributed to differentiation. Baf180 was dispensable for myoblast differentiation. The results distinguish between the roles of the mSWI/SNF enzyme sub-families during myoblast differentiation.

Sharma T., Olea-Flores M., Imbalzano A.N.

Skeletal muscle differentiation is a tightly regulated process, and the importance of the mammalian SWI/SNF (mSWI/SNF) chromatin remodeling family for regulation of genes involved in skeletal myogenesis is well-established. Our prior work showed that bromodomains of mSWI/SNF ATPases BRG1 and BRM contribute to myogenesis by facilitating the binding of mSWI/SNF enzymes to regulatory regions of myogenic and other target genes. Here, we report that pathway analyses of differentially expressed genes from that study identified an additional role for mSWI/SNF enzymes via the regulation of the Wnt signaling pathway. The Wnt pathway has been previously shown to be important for skeletal muscle development. To investigate the importance of mSWI/SNF enzymes for the regulation of the Wnt pathway, individual and dual knockdowns were performed for BRG1 and BRM followed by RNA-sequencing. The results show that BRG1, but not BRM, is a regulator of Wnt pathway components and downstream genes. Reactivation of Wnt pathway by stabilization of β-catenin could rescue the defect in myogenic gene expression and differentiation due to BRG1 knockdown or bromodomain inhibition using a specific small molecule inhibitor, PFI-3. These results demonstrate that BRG1 is required upstream of β-catenin function. Chromatin immunoprecipitation of BRG1, BRM and β-catenin at promoters of Wnt pathway component genes showed binding of BRG1 and β-catenin, which provides further mechanistic insight to the transcriptional regulation of these genes.

Kurosawa K., Nakano M., Yokoseki I., Tomii M., Higuchi Y., Uehara S., Yoneda N., Suemizu H., Fukami T., Nakajima M.

Hsia B., Bitar G., Alshaka S.A., Kim J.D., Valencia-Sanchez B.A., Faraji F., Brandel M.G., Sato M., Crawford J.R., Levy M.L., Patel V.A., Polster S.P.

Background: Chordoma is a rare primary tumor originating from embryonic notochord remnants, with limited systemic therapeutic options due to a poor understanding of its genomic landscape. This study aims to characterize the genetic alterations in chordoma using a large national patient-level genomic repository, the AACR Project GENIE, to identify potential therapeutic targets and improve disease modeling. Methods: A retrospective analysis of chordoma samples was conducted using the AACR Project GENIE database. Targeted sequencing data were analyzed for recurrent somatic mutations, tumor mutational burden, and chromosomal copy number variations, with significance set at p < 0.05. Results: Frequent mutations were observed in genes associated with SWI/SNF complex affecting chromatin remodeling (SETD2, PBRM1, ARID1A). Mutations were also common among the TERT promoter regions, and cell cycle regulation (CDKN2A). Significant co-occurrences were identified among PBRM1, BRCA2, and KMT2D mutations. CDKN2A/B deletions were enriched in metastatic tumors, and pediatric cases demonstrated distinct mutation profiles compared to adults. Conclusions: This study provides a genomic profile of chordoma, identifying key mutations and potential therapeutic targets. These findings highlight the roles of chromatin remodeling and cell cycle pathways in chordoma biology, offering insights for future precision medicine approaches and therapeutic interventions.

Wang L., Hung C., Wang T., Hsu H., Kung H., Lin K.

Castration-resistant prostate cancer (CRPC) presents significant challenges in clinical management due to its resistance to conventional androgen receptor (AR)-targeting therapies. The advent of proteolysis targeting chimeras (PROTACs) has revolutionized cancer therapy by enabling the targeted degradation of key molecular players implicated in CRPC progression. In this review we discuss the developments of PROTACs for CRPC treatment, focusing on AR and other CRPC-associated regulators. We provide an overview of the strategic trends in AR PROTAC development from the aspect of targeting site selection and preclinical antitumor evaluation, as well as updates on AR degraders in clinical applications. Additionally, we briefly address the current status of selective AR degrader development. Furthermore, we review new developments in PROTACs as potential CRPC treatment paradigms, highlighting those targeting chromatin modulators BRD4, EZH2, and SWI/SNF; transcription regulator SMAD3; and kinases CDK9 and PIM1. Given the molecular targets shared between CRPC and neuroendocrine prostate cancer (NEPC), we also discuss the potential of PROTACs in addressing NEPC.

Hu Y., Liu W., Fang W., Dong Y., Zhang H., Luo Q.

AbstractTumor energy metabolism plays a crucial role in the occurrence, progression, and drug resistance of tumors. The study of tumor energy metabolism has gradually become an emerging field of tumor treatment. Recent studies have shown that epigenetic regulation is closely linked to tumor energy metabolism, influencing the metabolic remodeling and biological traits of tumor cells. This review focuses on the primary pathways of tumor energy metabolism and explores therapeutic strategies to target these pathways. It covers key areas such as glycolysis, the Warburg effect, mitochondrial function, oxidative phosphorylation, and the metabolic adaptability of tumors. Additionally, this article examines the role of the epigenetic regulator SWI/SNF complex in tumor metabolism, specifically its interactions with glucose, lipids, and amino acids. Summarizing therapeutic strategies aimed at these metabolic pathways, including inhibitors of glycolysis, mitochondrial-targeted drugs, exploitation of metabolic vulnerabilities, and recent developments related to SWI/SNF complexes as potential targets. The clinical significance, challenges, and future directions of tumor metabolism research are discussed, including strategies to overcome drug resistance, the potential of combination therapy, and the application of new technologies.

Dai W., Qiao X., Fang Y., Guo R., Bai P., Liu S., Li T., Jiang Y., Wei S., Na Z., Xiao X., Li D.

AbstractEpigenetics governs a chromatin state regulatory system through five key mechanisms: DNA modification, histone modification, RNA modification, chromatin remodeling, and non-coding RNA regulation. These mechanisms and their associated enzymes convey genetic information independently of DNA base sequences, playing essential roles in organismal development and homeostasis. Conversely, disruptions in epigenetic landscapes critically influence the pathogenesis of various human diseases. This understanding has laid a robust theoretical groundwork for developing drugs that target epigenetics-modifying enzymes in pathological conditions. Over the past two decades, a growing array of small molecule drugs targeting epigenetic enzymes such as DNA methyltransferase, histone deacetylase, isocitrate dehydrogenase, and enhancer of zeste homolog 2, have been thoroughly investigated and implemented as therapeutic options, particularly in oncology. Additionally, numerous epigenetics-targeted drugs are undergoing clinical trials, offering promising prospects for clinical benefits. This review delineates the roles of epigenetics in physiological and pathological contexts and underscores pioneering studies on the discovery and clinical implementation of epigenetics-targeted drugs. These include inhibitors, agonists, degraders, and multitarget agents, aiming to identify practical challenges and promising avenues for future research. Ultimately, this review aims to deepen the understanding of epigenetics-oriented therapeutic strategies and their further application in clinical settings.

Ji M., Yu D., Liu X., Wang L., Zhang D., Yang Z., Huang W., Fan H., Wang L., Sun H.

SMARCA2 and SMARCA4 are the mutually exclusive catalytic subunits of the mammalian Switch/Sucrose Non-Fermentable (SWI/SNF) chromatin remodeling complex, and have recently been considered as attractive synthetic lethal targets for PROTAC-based cancer therapy. However, the potential off-tissue toxicity towards normal tissues remains a concern. Here, we optimize a GSH-inducible SMARCA2/4-based PROTAC precursor with selective antitumor activity towards lung cancer cells and negligible cytotoxicity towards normal cells in both in vitro and in vivo studies. The precursor is not bioactive or cytotoxic, but preferentially responds to endogenous GSH in GSH-rich lung cancer cells, releasing active PROTAC to degrade SMARCA2/4 via PROTAC-mediated proteasome pathway. Subsequent xenograft model study reveals that selective SMARCA2/4 degradation in lung tumors triggers DNA damage and apoptosis, which significantly inhibits lung cancer cell proliferation without obvious adverse events towards normal tissues. This study exemplifies the targeted degradation of SMARCA2/4 in lung cancer cells by the GSH-responsive PROTAC precursor, highlighting its potential as an encouraging cancer therapeutic strategy.

Olea‐Flores M., Sharma T., Verdejo‐Torres O., DiBartolomeo I., Thompson P.R., Padilla‐Benavides T., Imbalzano A.N.

AbstractPyruvate kinase is a glycolytic enzyme that converts phosphoenolpyruvate and ADP into pyruvate and ATP. There are two genes that encode pyruvate kinase in vertebrates; Pkm and Pkl encode muscle‐ and liver/erythrocyte‐specific forms, respectively. Each gene encodes two isoenzymes due to alternative splicing. Both muscle‐specific enzymes, PKM1 and PKM2, function in glycolysis, but PKM2 also has been implicated in gene regulation due to its ability to phosphorylate histone 3 threonine 11 (H3T11) in cancer cells. Here, we examined the roles of PKM1 and PKM2 during myoblast differentiation. RNA‐seq analysis revealed that PKM2 promotes the expression of Dpf2/Baf45d and Baf250a/Arid1A. DPF2 and BAF250a are subunits that identify a specific sub‐family of the mammalian SWI/SNF (mSWI/SNF) of chromatin remodeling enzymes that is required for the activation of myogenic gene expression during differentiation. PKM2 also mediated the incorporation of DPF2 and BAF250a into the regulatory sequences controlling myogenic gene expression. PKM1 did not affect expression but was required for nuclear localization of DPF2. Additionally, PKM2 was required not only for the incorporation of phosphorylated H3T11 in myogenic promoters but also for the incorporation of phosphorylated H3T6 and H3T45 at myogenic promoters via regulation of AKT and protein kinase C isoforms that phosphorylate those amino acids. Our results identify multiple unique roles for PKM2 and a novel function for PKM1 in gene expression and chromatin regulation during myoblast differentiation.

Olea-Flores M., Sharma T., Verdejo-Torres O., DiBartolomeo I., Thompson P.R., Padilla-Benavides T., Imbalzano A.N.

ABSTRACTPyruvate kinase is a glycolytic enzyme that converts phosphoenolpyruvate and ADP into pyruvate and ATP. There are two genes that encode pyruvate kinase in vertebrates;PkmandPklencode muscle- and liver/erythrocyte-specific forms, respectively. Each gene encodes two isoenzymes due to alternative splicing. Both muscle-specific enzymes, Pkm1 and Pkm2, function in glycolysis, but Pkm2 also has been implicated in gene regulation due to its ability to phosphorylate histone 3 threonine 11 (H3T11) in cancer cells. Here, we examined the roles of Pkm1 and Pkm2 during myoblast differentiation. RNA-seq analysis revealed that Pkm2 promotes the expression ofDpf2/Baf45dandBaf250a/Arid1A. Dpf2 and Baf250a are subunits that identify a specific sub-family of the mammalian SWI/SNF (mSWI/SNF) of chromatin remodeling enzymes that is required for activation of myogenic gene expression during differentiation. Pkm2 also mediated the incorporation of Dpf2 and Baf250a into the regulatory sequences controlling myogenic gene expression. Pkm1 did not affect expression but was required for nuclear localization of Dpf2. Additionally, Pkm2 was required not only for the incorporation of phosphorylated H3T11 in myogenic promoters, but also for the incorporation of phosphorylated H3T6 and H3T45 at myogenic promoters via regulation of AKT and protein kinase C isoforms that phosphorylate those amino acids. Our results identify multiple unique roles for Pkm2 and a novel function for Pkm1 in gene expression and chromatin regulation during myoblast differentiation.