H3K9ac Levels Research Articles

Epigenomic profiling nominates master transcription factors (TFs) driving sarcomatoid differentiation (SD) of renal cell carcinoma (RCC)

Abstract Background Sarcomatoid differentiation of RCC (sRCC) is associated with poor survival. Recent studies showed marked response of sRCC to immune checkpoint blockade (ICB). While distinctive patterns of gene expression in sRCC have been identified, the gene regulatory programs and TFs that drive SD remain unknown. The aim of this study is to nominate TFs responsible for SD and to investigate their association with the clinical outcomes of patients with RCC. Methods Chromatin immunoprecipitation and sequencing (ChIP-seq) for H3K27ac – a histone modification associated with active regulatory elements – was performed on pathologically reviewed sRCC and non-sRCC samples collected at the Dana-Farber Cancer Institute. Regulatory elements that were differentially active between the two groups were identified based on levels of H3K27ac (Benjamini-Hochberg q<0.01, log-fold change (LFC) threshold=1). Enrichment of specific TF binding motifs at activated regulatory elements in sRCC was assessed using HOMER. Differential gene expression analysis of TFs was performed using DESeq2 on RNA-seq data from TCGA. A Mann-Whitney U test was performed on RNA-seq data from the IMmotion151 and Javelin Renal 101 clinical trials to compare mean expression level of TFs in transcript per million (TPM) in these trials. Patients with non-sRCC enrolled in the IMmotion151 trials were divided into quartiles based on gene expression levels of candidate TFs. Progression-free survival (PFS) was compared between non-sRCC patients stratified by expression quartiles as well as patients with sRCC using a multivariable Cox proportional-hazards model accounting for age and IMDC risk score. To validate these findings, a similar analysis was performed in the Javelin Renal 101 trial. Results We obtained high-quality H3K27ac ChIP-seq profiles for 9 sRCC and 17 non-sRCC samples. We identified 278 candidate regulatory elements with increased H3K27ac levels in sRCC vs. non-sRCC. These regulatory elements were enriched for nucleotide motifs bound by the TFs FOSL1 and E2F7. Differential expression analysis between 48 sRCC vs. 493 non-sRCC samples showed that FOSL1 and E2F7 were significantly upregulated in sRCC vs. non-sRCC (LFC=1.7, q=5e-11; LFC=1.8, q=1.3e-20; resp.). Mean TPMs of FOSL1 and E2F7 were significantly increased in sRCC vs. non-sRCC in IMmotion151 cohort and Javelin Renal 101 (all p<0.001). Among patients who received sunitinib, those with the highest quartile of FOSL1 and E2F7 expression showed significantly shorter PFS in IMmotion151 patients compared to patients with the lowest quartile of expression (HR=1.6, 95%CI=1.3-2.2, p=0.008 & HR=2.6, 95%CI=1.8-3.7, p<0.001; resp.). Furthermore, patients with highest quartile of expression showed similar PFS compared to patients with sRCC (p=0.56 and p=0.64; resp.). These results were validated in the sunitinib arm of the Javelin Renal 101 cohort (Figure). Figure: Kaplan-Meier curves of progression-free survival (PFS) in patients with in the sunitinib arm of Javelin Renal 101 by sarcomatoid differentiation and FOSL1 expression levels. Conclusions This is the first study to characterize the epigenomic landscape of sRCC by integrating ChIP-seq and RNA-seq data. Our findings implicated FOSL1 and E2F7 as transcriptional regulators of SD with prognostic relevance. These TFs seems to be associated with aggressive behavior in non-sRCC as well. Further studies are underway to functionally validate these results.

Demethylase-independent roles of LSD1 in regulating enhancers and cell fate transition

The major enhancer regulator lysine-specific histone demethylase 1A (LSD1) is required for mammalian embryogenesis and is implicated in human congenital diseases and multiple types of cancer; however, the underlying mechanisms remain enigmatic. Here, we dissect the role of LSD1 and its demethylase activity in gene regulation and cell fate transition. Surprisingly, the catalytic inactivation of LSD1 has a mild impact on gene expression and cellular differentiation whereas the loss of LSD1 protein de-represses enhancers globally and impairs cell fate transition. LSD1 deletion increases H3K27ac levels and P300 occupancy at LSD1-targeted enhancers. The gain of H3K27ac catalyzed by P300/CBP, not the loss of CoREST complex components from chromatin, contributes to the transcription de-repression of LSD1 targets and differentiation defects caused by LSD1 loss. Together, our study demonstrates a demethylase-independent role of LSD1 in regulating enhancers and cell fate transition, providing insight into treating diseases driven by LSD1 mutations and misregulation.

SIRT6 mediated histone H3K9ac deacetylation involves myocardial remodelling through regulating myocardial energy metabolism in TAC mice.

Pathological myocardial remodelling is the initial factor of chronic heart failure (CHF) and is induced by multiple factors. We previously demonstrated that histone acetylation is involved in CHF in transverse aortic constriction (TAC) mice, a model for pressure overload-induced heart failure. In this study, we investigated whether the histone deacetylase Sirtuin 6 (SIRT6), which mediates deacetylation of histone 3 acetylated at lysine 9 (H3K9ac), is involved pathological myocardial remodelling by regulating myocardial energy metabolism and explored the underlying mechanisms. We generated a TAC mouse model by partial thoracic aortic banding. TAC mice were injected with the SIRT6 agonist MDL-800 at a dose of 65 mg/kg for 8 weeks. At 4, 8 and 12 weeks after TAC, the level of H3K9ac increased gradually, while the expression of SIRT6 and vascular endothelial growth factor A (VEGFA) decreased gradually. MDL-800 reversed the effects of SIRT6 on H3K9ac in TAC mice and promoted the expression of VEGFA in the hearts of TAC mice. MDL-800 also attenuated mitochondria damage and improved mitochondrial respiratory function through upregulating SIRT6 in the hearts of TAC mice. These results revealed a novel mechanism in which SIRT6-mediated H3K9ac level is involved pathological myocardial remodelling in TAC mice through regulating myocardial energy metabolism. These findings may assist in the development of novel methods for preventing and treating pathological myocardial remodelling.

Abstract A029: Epigenomic profiling nominates master transcription factors (TFs) driving sarcomatoid differentiation of renal cell carcinoma (RCC)

Abstract Introduction Sarcomatoid RCC (sRCC) is associated with poor prognosis. Recent studies showed promising response rates of sRCC to immune checkpoint blockade (ICB). Although distinct patterns of gene expression in sRCC have been reported, the gene regulatory programs that drive SD remain unknown. This study aims to nominate TFs driving SD and to evaluate their impact on the clinical outcomes of patients (pts) with RCC. Methods Chromatin immunoprecipitation and sequencing (ChIP-seq) for H3K27ac was performed on histologically annotated areas of sRCC and non-sRCC fresh frozen tissue samples collected at Dana-Farber Cancer Institute. Regulatory elements that were differentially active between the two groups were identified (cutoff p<0.01, log-fold change (LFC) threshold=1). Enrichment of specific TF binding motifs at activated regulatory elements in sRCC was assessed using HOMER. Differential gene expression analysis of TFs was performed using DESeq2 on RNA-seq data from TCGA (Benjamini-Hochberg q <0.01, LFC threshold=1). An unpaired student’s t-test was performed to compare mean gene expression levels in transcript per million (TPM) on baseline sRCC and non-sRCC tissue samples from the IMmotion151 trial (sunitinib vs. atezolizumab-bevacizumab in metastatic RCC). Pts enrolled in the IMmotion151 trial were divided into quartiles based on gene expression levels of candidate TFs. Progression-free survival (PFS) was compared between the quartiles using a multivariable Cox proportional-hazards model accounting for age and IMDC risk score. The association of TF expression with the objective radiographic response (ORR) was analyzed using a logistic regression model. Results ChIP-seq was performed on 9 sRCC & 17 non-sRCC samples. We identified 278 candidate regulatory elements with increased H3K27ac levels in sRCC vs. non-sRCC that were enriched for nucleotide motifs bound by the TFs FOSL1 and E2F7. Differential expression analysis between 48 sRCC vs. 493 non-sRCC samples showed that FOSL1 & E2F7 were significantly upregulated in sRCC vs. non-sRCC (LFC=1.7, q=5e-11; LFC=1.8, q=1.3e-20; resp.). Mean TPMs of FOSL1 & E2F7 were significantly increased in sRCC vs. non-sRCC in IMmotion151 cohort (2.5 vs. 1.5 TPM for FOSL1, and 2.9 vs. 1.9 TPM for E2F7, all p<0.001). Pts in the highest quartile of FOSL1 and E2F7 expression showed significantly shorter PFS in IMmotion151 pts receiving sunitinib alone (HR=1.6, 95%CI=1.3-2.2, p=0.008 & HR=2.6, 95%CI=1.8-3.7, p<0.001; resp.). We observed similar results even after controlling for the presence of SD. Increased expression of E2F7 was associated with worse ORR in IMmotion151 pts who received sunitinib alone, even after controlling for the presence of SD (OR=0.24±0.4, p<0.001). Conclusion This is the first study to analyze the epigenomic landscape of sRCC by integrating ChIP-seq and RNA-seq data. Our findings implicated FOSL1 & E2F7 as transcriptional regulators of SD with prognostic relevance. Further studies are underway to validate these results. Citation Format: Karl Semaan, Talal El Zarif, Marc Eid, Valisha Shah, Brad Fortunato, Renee Maria Saliby, Amin H. Nassar, Sarah Abou Alaiwi, Ji-Heui Seo, Chris Labaki, Ziad Bakouny, Sayed Matar, Nourhan El Ahmar, Yasmin Nabil Laimon, Gwo-Shu Mary Lee, Mark Pomerantz, Jacob Berchuck, Sabina Signoretti, Eliezer Van Allen, Toni Choueiri, David Braun, Matthew Freedman, Sylvan Baca. Epigenomic profiling nominates master transcription factors (TFs) driving sarcomatoid differentiation of renal cell carcinoma (RCC) [abstract]. In: Proceedings of the AACR Special Conference: Advances in Kidney Cancer Research; 2023 Jun 24-27; Austin, Texas. Philadelphia (PA): AACR; Cancer Res 2023;83(16 Suppl):Abstract nr A029.

Abstract P1116: Histone Deacetylase Complexes Regulate Direct Cardiac Conversion From Human Fibroblasts

Direct cardiac reprogramming is a promising approach to generate functional cardiomyocytes from non-myocytes for regenerative medicine, drug screening, and disease modeling. This method involves the transformation of specialized cells into functional cardiomyocytes using specific transcription factors or molecular signals. Epigenetic modulators, such as histone deacetylase (HDAC) complexes, may play a critical role in chromatin remodeling underlying cardiac reprogramming. To investigate the role of HDAC complexes in direct cardiac conversion, induced cardiomyocyte-like cells (iCMs) were derived from human fibroblasts through ectopic expression of reprogramming factors, and the changes of histone acetylation were evaluated by western blotting. The results showed decreased levels of H3K9ac, H3K14ac, and H3K27ac along with direct cardiac reprogramming, suggesting the significant chromatin remodeling and gene regulation. A loss-of-function screen of all the components associated with HDAC complex was performed to determine the responsible histone acetylation modifiers. The screen results showed that most of the HDAC components are necessary for direct cardiac reprogramming. Further investigation focused on a newly identified HDAC complex, mitotic deacetylase complex (MiDAC), consisting of mitotic deacetylase associated SANT domain protein MiDEAS (ELMSAN1), DNTTIP1, and HDAC1. Knocking down each of the MiDAC components led to similar reprogramming repression and cell death, indicating that MiDAC plays a critical role in cardiac reprogramming. In addition, the expression analysis of DNTTIP1 and HDAC1 showed a gradual decrease throughout the conversion, while ELMSAN1 diminished at the early stage of reprogramming, suggesting that ELMSAN1 is likely required for MiDAC stability. Furthermore, overexpression of ELMSAN1 significantly improved reprogramming efficiency and led to the increase of H3K9ac, H3K14ac, and H3K27ac levels globally, suggesting that ELMSAN1 and MiDAC might be responsible for the regulation of such histone modifications during the process. Overall, our findings provide novel insights into the epigenetic regulation of direct cardiac reprogramming and reveal the potential role of MiDAC in this process.

Abstract P1107: Elmsan1 Regulates Differentiation And Maturation Of Cardiomyocytes Derived From Human Induced Pluripotent Stem Cells

Introduction: ELMSAN1 is a scaffolding protein of the mitotic deacetylase complex (MiDAC) that is critical for early embryonic development. Studies on Elmsan1 knockout mice show that its absence results in heart malformation and embryo lethality. Despite this, the direct role of ELMSAN1 in heart development and formation remains unknown. To gain insights into this role, we differentiated human-induced pluripotent stem cell (hiPSC) into cardiomyocyte (hiPSC-CM) to mimic early cardiogenesis and assess the involvement of ELMSAN1 in CM maturation. Methods and Results: We utilized shRNA-mediated knockdown and CRISPR-Cas9-mediated knockout techniques to generate ELMSAN1-deficient hiPSC, which were differentiated into CM for characterization. We showed that ELMSAN1 depletion caused a delay in the deactivation of pluripotency genes during early differentiation, resulting in decreased expression of cardiac-specific markers (TNNT2, MHY6), and reduced differentiation efficiency of CM. We also observed the impaired expression of genes associated with contractile sarcomere structure, calcium handling, and ion channels in ELMSAN1-deficient CM. Moreover, through a series of structural and functional assessments, we found these cells exhibited incomplete sarcomere Z-line structure and length (1.3 μm in KD vs. 1.5 μm in control), decreased calcium amplitude, increased time to peak value, faster beat rate with a shorter beat period, decreased field potential duration (300 ± 10 ms in KD vs. 500 ± 10 ms in control), and prolonged propagation delay. Importantly, we confirmed similar immaturity and functional changes in ELMSAN1 knockout CM, excluding the potential off-target effect. Mechanistically, we discovered that ELMSAN1 depletion resulted in decreased levels of H3K27ac in both hiPSC and CM, indicating an unexpected role of ELMSAN1 in maintaining global H3K27ac and gene expression. Conclusion: Our findings offer compelling evidence for the direct involvement of ELMSAN1 in the differentiation and maturation of hiPSC-CM. Notably, we were the first to identify the impact of ELMSAN1 on various aspects of hiPSC-CM generation, including cardiac differentiation, sarcomere formation, calcium handling, and electrophysiological maturation.

LESION SIMULATING DISEASE 3 regulates disease resistance via fine-tuning histone acetylation in cassava.

Bacterial blight seriously affects the growth and production of cassava (Manihot esculenta Crantz), but disease resistance genes and the underlying molecular mechanism remain unknown. In this study, we found that LESION SIMULATING DISEASE 3 (MeLSD3) is essential for disease resistance in cassava. MeLSD3 physically interacts with SIRTUIN 1 (MeSRT1), inhibiting MeSRT1-mediated deacetylation modification at the acetylation of histone 3 at K9 (H3K9Ac). This leads to increased H3K9Ac levels and transcriptional activation of SUPPRESSOR OF BIR1 (SOBIR1) and FLAGELLIN-SENSITIVE2 (FLS2) in pattern-triggered immunity, resulting in immune responses in cassava. When MeLSD3 was silenced, the release of MeSRT1 directly decreased H3K9Ac levels and inhibited the transcription of SOBIR1 and FLS2, leading to decreased disease resistance. Notably, DELLA protein GIBBERELLIC ACID INSENSITIVE 1 (MeGAI1) also interacted with MeLSD3, which enhanced the interaction between MeLSD3 and MeSRT1 and further strengthened the inhibition of MeSRT1-mediated deacetylation modification at H3K9Ac of defense genes. In summary, this study illustrates the mechanism by which MeLSD3 interacts with MeSRT1 and MeGAI1, thereby mediating the level of H3K9Ac and the transcription of defense genes and immune responses in cassava.

ZSCAN4 Regulates Zygotic Genome Activation and Telomere Elongation in Porcine Parthenogenetic Embryos.

Zinc finger and SCAN domain-containing 4 (ZSCAN4), a DNA-binding protein, maintains telomere length and plays a key role in critical aspects of mouse embryonic stem cells, including maintaining genomic stability and defying cellular senescence. However, the effect of ZSCAN4 in porcine parthenogenetic embryos remains unclear. To investigate the function of ZSCAN4 and the underlying mechanism in porcine embryo development, ZSCAN4 was knocked down via dsRNA injection in the one-cell stage. ZSCAN4 was highly expressed in the four- and five- to eight-cell stages in porcine embryos. The percentage of four-cell stage embryos, five- to eight-cell stage embryos, and blastocysts was lower in the ZSCAN4 knockdown group than in the control group. Notably, depletion of ZSCAN4 induced the protein expression of DNMT1 and 5-Methylcytosine (5mC, a methylated form of the DNA base cytosine) in the four-cell stage. The H3K27ac level and ZGA genes expression decreased following ZSCAN4 knockdown. Furthermore, ZSCAN4 knockdown led to DNA damage and shortened telomere compared with the control. Additionally, DNMT1-dsRNA was injected to reduce DNA hypermethylation in ZSCAN4 knockdown embryos. DNMT1 knockdown rescued telomere shortening and developmental defects caused by ZSCAN4 knockdown. In conclusion, ZSCAN4 is involved in the regulation of transcriptional activity and is essential for maintaining telomere length by regulating DNMT1 expression in porcine ZGA.

Dimethyl alpha-ketoglutarate inhibits proliferation in diffuse intrinsic pontine glioma by reprogramming epigenetic and transcriptional networks

Diffuse intrinsic pontine glioma (DIPG) is a highly aggressive pediatric brain tumor with limited therapeutic options. Here, we investigated the potential of dimethyl alpha-ketoglutarate (DMKG) as an anti-proliferative agent against DIPG and unraveled its underlying molecular mechanisms. DMKG exhibited robust inhibition of DIPG cell proliferation, colony formation, and neurosphere growth. Transcriptomic analysis revealed substantial alterations in gene expression, with upregulated genes enriched in hypoxia-related pathways and downregulated genes associated with cell division and the mitotic cell cycle. Notably, DMKG induced G1/S phase cell cycle arrest and downregulated histone H3 lysine 27 acetylation (H3K27ac) without affecting H3 methylation levels. The inhibition of AKT and ERK signaling pathways by DMKG coincided with decreased expression of the CBP/p300 coactivator. Importantly, we identified the c-MYC-p300/ATF1-p300 axis as a key mediator of DMKG's effects, demonstrating reduced binding to target gene promoters and decreased H3K27ac levels. Depletion of c-MYC or ATF1 effectively inhibited DIPG cell growth. These findings highlight the potent anti-proliferative properties of DMKG, its impact on epigenetic modifications, and the involvement of the c-MYC-p300/ATF1-p300 axis in DIPG, shedding light on potential therapeutic strategies for this devastating disease.

Genome-Wide Acetylation Modification of H3K27ac in Bovine Rumen Cell Following Butyrate Exposure.

Butyrate contributes epigenetically to the changes in cellular function and tissue development of the rumen in ruminant animals, which might be achieved by its genetic or epigenetic regulation of gene expression. To explore the role of butyrate on bovine rumen epithelial function and development, this study characterized genome-wide H3K27ac modification changes and super-enhancer profiles in rumen epithelial primary cells (REPC) induced with butyrate by ChIP-seq, and analyzed its effects on gene expression and functional pathways by integrating RNA-seq data. The results showed that genome-wide acetylation modification was observed in the REPC with 94,675 and 48,688 peaks in the butyrate treatment and control group, respectively. A total of 9750 and 5020 genes with increased modification (H3K27ac-gain) and decreased modification (H3K27ac-loss) were detected in the treatment group. The super-enhancer associated genes in the butyrate-induction group were involved in the AMPK signaling pathway, MAPK signaling pathway, and ECM-receptor interaction. Finally, the up-regulated genes (PLCG1, CLEC3B, IGSF23, OTOP3, ADTRP) with H3K27ac gain modification by butyrate were involved in cholesterol metabolism, lysosome, cell adhesion molecules, and the PI3K-Akt signaling pathway. Butyrate treatment has the role of genome-wide H3K27ac acetylation on bovine REPC, and affects the changes in gene expression. The effect of butyrate on gene expression correlates with the acetylation of the H3K27ac level. Identifying genome-wide acetylation modifications and expressed genes of butyrate in bovine REPC cells will expand the understanding of the biological role of butyrate and its acetylation.

Maternal exercise represses Nox4 via SIRT1 to prevent vascular oxidative stress and endothelial dysfunction in SHR offspring.

Maternal exercise during pregnancy has emerged as a potentially promising approach to protect offspring from cardiovascular disease, including hypertension. Although endothelial dysfunction is involved in the pathophysiology of hypertension, limited studies have characterized how maternal exercise influences endothelial function of hypertensive offspring. In this study, pregnant spontaneously hypertensive rats and Wistar-Kyoto rats were assigned either to a sedentary lifestyle or to swimming training daily, and fetal histone deacetylase-mediated epigenetic modification and offspring vascular function of mesenteric arteries were analyzed. Maternal exercise ameliorated the impairment of acetylcholine-induced vasodilation without affecting sodium nitroprusside-induced vasodilation in mesenteric arteries from the hypertensive offspring. In accordance, maternal exercise reduced NADPH oxidase-4 (Nox4) protein to prevent the loss of nitric oxide generation and increased reactive oxygen species production in mesenteric arteries of hypertensive offspring. We further found that maternal exercise during pregnancy upregulated vascular SIRT1 (sirtuin 1) expression, leading to a low level of H3K9ac (histone H3 lysine 9 acetylation), resulting in the transcriptional downregulation of Nox4 in mesenteric arteries of hypertensive fetuses. These findings show that maternal exercise alleviates oxidative stress and the impairment of endothelium-dependent vasodilatation via SIRT1-regulated deacetylation of Nox4, which might contribute to improved vascular function in hypertensive offspring.

Combined low levels of H4K16ac and H4K20me3 predicts poor prognosis in breast cancer.

Results of previous studies about the prognostic roles of histone H4 lysine 16 acetylation (H4K16ac) and histone H4 lysine 20 trimethylation (H4K20me3) in breast cancer were inconsistent. Cellular experiments revealed the interplays between H4K16ac and H4K20me3, but no population study explored the interaction between them on the prognosis. H4K16ac and H4K20me3 levels in tumors were evaluated by immunohistochemistry for 958 breast cancer patients. Hazard ratios for overall survival (OS) and progression-free survival (PFS) were estimated using Cox regression models. Interaction was assessed on multiplicative scale. Concordance index (C-index) was calculated to verify the predictive performance. The prognostic roles of the low level of H4K16ac or H4K20me3 were significant only in patients with the low level of another marker and their interactions were significant. Moreover, compared with joint high levels of both them, only the combined low levels of both them was associated with a poor prognosis but not the low level of single one. The C-index of the clinicopathological model combined the joint expression of H4K16ac and H4K20me3 [0.739 for OS; 0.672 for PFS] was significantly larger than that of the single clinicopathological model [0.699 for OS, P < 0.001; 0.642 for PFS, P = 0.003] or the model combined with the single H4K16ac [0.712 for OS, P < 0.001; 0.646 for PFS, P < 0.001] or H4K20me3 [0.724 for OS, P = 0.031; 0.662 for PFS, P = 0.006]. There was an interaction between H4K16ac and H4K20me3 on the prognosis of breast cancer and the combination of them was a superior prognostic marker compared to the single one.

Knockdown of ACC1 promotes migration of esophageal cancer cell

Objective: To investigate the effect of acetyl-CoA carboxylase 1 (ACC1) knockdown on the migration of esophageal squamous cell carcinoma (ESCC) KYSE-450 cell and underlying mechanism. Methods: Lentiviral transfection was conducted to establish sh-NC control cell and ACC1 knocking down cell (sh-ACC1). Human siRNA HSP27 and control were transfected by Lipo2000 to get si-HSP27 and si-NC. The selective acetyltransferase P300/CBP inhibitor C646 was used to inhibit histone acetylation and DMSO was used as vehicle control. Transwell assay was performed to detect cell migration. The expression of HSP27 mRNA was examined by reverse transcription-quantitative real-time polymerase chain reaction (RT-qPCR) and the expressions of ACC1, H3K9ac, HSP27 and epithelial-mesenchymal transition-related proteins E-cadherin and Vimentin were detected by western blot. Results: The expression level of ACC1 in sh-NC group was higher than that in sh-ACC1 group (P<0.01). The number of cell migration in sh-NC group was (159.00±24.38), lower than (361.80±26.81) in sh-ACC1 group (P<0.01). The protein expression levels of E-cadherin and Vimentin in sh-NC group were statistically significant compared with sh-AAC1 group (P<0.05). The migrated cell number in sh-NC+ si-NC group was (189.20±16.02), lower than (371.60±38.40) in sh-ACC1+ si-NC group (P<0.01). The migrated cell number in sh-NC+ si-NC group was higher than that in sh-NC+ si-HSP27 group (152.40±24.30, P<0.01), and the migrated cell number in sh-ACC1+ si-NC group was higher than that in sh-ACC1+ si-HSP27 group (P<0.01). The protein expression levels of E-cadherin and Vimentin in sh-NC+ si-NC group were significantly different from those in sh-ACC1+ si-NC and sh-NC+ si-HSP27 groups (P<0.01). The protein expression levels of E-cadherin and Vimentin in sh-ACC1+ si-NC group were significantly different from those in sh-ACC1+ si-HSP27 group (P<0.01). After 24 h treatment with C646 at 20 μmmo/L, the migrated cell number in sh-NC+ DMSO group was (190.80±11.95), lower than (395.80±17.10) in sh-ACC1+ DMSO group (P<0.01). The migrated cell number in sh-NC+ DMSO group was lower than that in sh-NC+ C646 group (256.20±23.32, P<0.01). The migrated cell number in sh-ACC1+ DMSO group was higher than that in sh-ACC1+ C646 group (87.80±11.23, P<0.01). The protein expressions of H3K9ac, HSP27, E-cadherin and Vimentin in sh-NC+ DMSO group were significantly different from those in sh-ACC1+ DMSO group and sh-NC+ C646 group (P<0.01). The protein expression levels of H3K9ac, HSP27, E-cadherin and Vimentin in sh-ACC1+ DMSO group were significantly different from those in sh-ACC1+ C646 group (P<0.01). Conclusion: Knockdown of ACC1 promotes the migration of KYSE-450 cell by up-regulating HSP27 and increasing histone acetylation.

Upregulation of Microglial Sirt6 and Inhibition of Microglial Activation by Vitamin D3 in Lipopolysaccharide-stimulated Mice and BV-2 Cells

Vitamin D3 may suppress microglial activation and neuroinflammation, which play a central role in the pathophysiology of many neurological disorders. Sirt6 can remove histone 3 lysine 9 acetylation (H3K9ac) to repress expression of pathological genes and produce anti-inflammatory effects. However, whether vitamin D3 upregulates microglial Sirt6 to exert its protective effects against microglial activation and neuroinflammation is unclear. The effects of lower, normal, and higher dosages (1, 10 and 100 μg/kg/day) of vitamin D3 on behavioral and neuromorphological changes, brain inflammatory factors, Sirt6 and H3K9ac levels, and microglial Sirt6 distribution in hippocampus were evaluated in lipopolysaccharide (LPS)-stimulated mice. In addition, the effects of vitamin D3 on inflammatory factors, reactive oxygen species, Sirt6, and H3K9ac were confirmed in LPS-stimulated BV-2 cells. We verified that vitamin D3 ameliorated the impaired sociability of LPS-stimulated mice by three-chamber test. In addition, vitamin D3 upregulated brain Sirt6 generation, reduced H3K9ac levels and inhibited generation of brain inflammatory factors. Moreover, vitamin D3 promoted microglial Sirt6 distribution and attenuated microglia displaying an activated morphology in the hippocampus of LPS-stimulated mice. Similarly, vitamin D3 upregulated Sirt6 generation and intensity, reduced H3K9ac levels, and inhibited the inflammatory activation of LPS-stimulated BV-2 cells. In conclusion, vitamin D3 may upregulate microglial Sirt6 to reduce H3K9ac and inhibit microglial activation, thereby antagonizing neuroinflammation.

Erchen Decoction alleviates obesity-related hepatic steatosis via modulating gut microbiota-drived butyric acid contents and promoting fatty acid β-oxidation

Ethnopharmacological relevanceErchen decoction (ECD) is a traditional Chinese medicine formula comprising six distinct herbs and has been documented to possess a protective effect against obesity. The study conducted previously demonstrated that ECD has the potential to effectively modulate the composition of gut microbiota and levels of short-chain fatty acids (SCFAs) in obese rat. However, the regulatory mechanism of ECD on gut microbiota and SCFAs and further improvement of obesity have not been thoroughly explained. Aim of the studyThe objective of this study was to examine the therapeutic effect and molecular mechanism of ECD in a rat model of high-fat diet (HFD) feeding. Materials and methodsRats with HFD-induced obesity were treated with ECD. Upon completion of the study, serum and liver samples were procured to conduct biochemical, pathological, and Western blotting analyses. The investigation of alterations in the gut microbiota subsequent to ECD treatment was conducted through the utilization of 16S rRNA sequencing. The metabolic alterations in the cecal contents were examined through the utilization of mass spectrometry-ultraperformance liquid chromatography. ResultsECD treatment improved lipid metabolic disorders and reduced hepatic steatosis in HFD-induced obese rats. Obese rat treated with ECD showed a higher abundance of SCFA-producing bacteria, including Lactobacillus, Bifidobacterium, and Butyricicoccus, and lower abundance of disease-related bacteria, such as Bacteroides, Parabacteroides, and Sediminibacterium. Additionally, ECD caused an increase in total SCFAs levels; in particular, butyric acid was dramatically increased in the HFD group. Rats treated with ECD also exhibited significantly increased butyric acid concentrations in the serum and liver. The subsequent reduction in histone deacetylase 1 expression and increase in acetyl-histone 3-lysine 9 (H3K9ac) levels contributed to the promotion of fatty acid β-oxidation (FAO) in liver by ECD. ConclusionThis study demonstrates that ECD regulates the gut microbiota and promotes butyric acid production to ameliorate obesity-related hepatic steatosis. The mechanism might be related to the promotion of FAO via a butyric acid–mediated increase in H3K9ac levels in the liver.

DIPG-24. BRD4 INHIBITION AS A RADIOSENSITIZER THROUGH BLOCKING DNA REPAIR FOR THE TREATMENT OF DIFFUSE MIDLINE GLIOMA

Abstract Diffuse intrinsic pontine glioma (DIPG) is one of the devastating childhood cancers. Radiation therapy (RT) remains the only effective treatment yet provides a 5-year survival rate of only 1%. Several clinical trials have attempted to enhance RT efficacy by combining it with radiosensitizing agents, though none have been successful in doing so. Given this, there is a critical need to identify effective therapeutics to enhance the RT anti-tumor activity in DIPG. Here, we identified BRD4 inhibitors as candidate radiosensitizers from a high throughput drug screening. DIPG cells show increased H3 K27 acetylation (H3K27ac) levels, which bind to BET bromodomain protein 4 (BRD4) and are strongly associated with active transcription. We tested two BRD4 inhibitors (BRD4i: AZD5153 and JQ-1) as well as genetic BRD4 depletion, and observed enhancement of radiation-induced DNA damage, confirming BRD4i as potential radiosensitizers in the treatment of DIPG. We evaluated the effects of BRD4i on gene expression using RNAseq, and observed significant inhibition of DNA-repair proteins such as BRCA1 and RAD51. CUT-RUN qPCR showed decreased H3K27ac at BRCA1 and RAD51 promoters. Combination of BRD4i and RT inhibited cell viability significantly using clonogenic survival assay, apoptosis assay, and also showed cell cycle arrest. Radiation-induced DNA double-strand break (DSB) repair was prolonged with BRD4i with high levels of gH2AX and 53BP1 likely due to inhibition of DNA-repair. In vivo studies revealed increased survival of animals treated with combination therapy of RT and BRD4i in comparison to either monotherapy. Together, these results highlight BRD4i as a potential radiosensitizer and provide a rationale for developing combination therapy with radiation in the treatment of DIPG.

Abstract A014: NFI-family transcriptional factors direct AR cistrome redistribution during prostate cancer tumorigenesis

Abstract Previous studies found AR cistrome reprogramming during transition from normal prostate to PCa, and progression to CRPC. AR binding sites (bs) in PCa were reported to be enriched for FOXA1 and HOXB13, in comparison to normal prostate where these are not enriched. However, mechanisms that may drive FOXA1 and HOXB13 to these sites and initiate this neoplastic transformation remain unclear. To address this, we first asked if there are other transcription factors (TFs) involved in tumor evolution. A motif enrichment analysis using patient data set (GSE130408) showed significant enrichment of NFI and NFI half motifs at AR bs in localized hormone sensitive PCa in comparison to normal prostate (0.07 vs 0.04, p=0.0001; and 0.27 vs 0.21, p=0.0044, respectively). Notably, NFI TFs were shown previously to be associated with AR bs in PCa cells, and to modulate AR-target gene expression and changes in chromatin accessibility. This suggested that NFI TFs may contribute to AR cistrome redistribution that drives PCa development. Next, we generated a CRPC cell model resistant to enzalutamide (ENZ), and found that AR activity in these cells was driven by the ARv7 splice variant. Notably, ATAC-seq identified in these cells a subset of sites with greatly increased chromatin accessibility, and ChIP-seq showed that these ATAC-up sites were associated with ARv7 binding and increased H3K27acetylation (H3K27ac, the mark of active enhancers). Significantly, these sites also were enriched for NFI and NFI half motifs (0.04, p&amp;lt;0.0001 and 0.1, p&amp;lt;0.0001, respectively). Notably, while AR is known as a transcriptional activator, it also has repressive functions. To study AR-direct repression, we examined the redistribution of H3K27ac mark in response to AR-inhibition (ENZ) or stimulation (DHT). We identified subsets of AR-bound regions with increased H3K27ac after ENZ that corresponded to regions with decreased H3K27ac after DHT. These regions were highly enriched for NFI and NFI-half motifs (0.04, p&amp;lt;0.0001 and 0.14, p&amp;lt;0.0001, respectively). As expected, these regions also were associated with DHT-repressed genes including UGT2B15, physiologically involved in steroid hormones metabolism. Notably, depletion of NFI-B and X (the most expressed NFI-family members in PCa) resulted in increased H3K27ac levels at UGT2B15, and impaired the suppressive effect of DHT on UGT2B15 expression. RNA-seq after NFIB and X knockdown then showed 212 up- and 119 downregulated genes, indicating NFI is a modulator of both AR-activated and repressed genes. Ingenuity Pathway Analysis demonstrated contribution of NFIs to androgen signaling and maintaining the activity of Sirtuin (SIRT) pathways. SIRTs possess deacetylase activity, including deacetylation of histones, and inhibition of SIRT1 resulted in dramatically increased UGT2B15 expression. Collectively, these data support a role for NFI TFs in directing the AR cistrome during PCa tumorigenesis, and in modulating its transcriptional activation versus repressive functions, with the latter being mediated by recruitment of SIRT1. Citation Format: Larysa Poluben, Joshua Russo, Olga Voznesensky, Mannan Nouri, Anastasia Stavridi, Xintao Qiu, Matthew Freedman, Henry W. Long, Steven P. Balk. NFI-family transcriptional factors direct AR cistrome redistribution during prostate cancer tumorigenesis [abstract]. In: Proceedings of the AACR Special Conference: Advances in Prostate Cancer Research; 2023 Mar 15-18; Denver, Colorado. Philadelphia (PA): AACR; Cancer Res 2023;83(11 Suppl):Abstract nr A014.

Autophagy inhibition mediated by intrauterine miR-1912-3p/CTSD programming participated in the susceptibility to osteoarthritis induced by prenatal dexamethasone exposure in male adult offspring rats.

Autophagy inhibition is known to be involved in the development of adult osteoarthritis. Dexamethasone, as a synthetic glucocorticoid, is widely used for premature delivery and related pregnancy diseases in clinics. We have previously shown that prenatal dexamethasone exposure (PDE) was associated with increased susceptibility to postnatal osteoarthritis in offspring. However, whether the occurrence of fetal-originated adult osteoarthritis induced by PDE is related to autophagy remains unclear. In this study, we first found that PDE could increase the mRNA and protein expression of cartilage matrix-degrading enzymes (MMP3, MMP13, and ADAMTS5) and decrease the cartilage matrix contents in adult offspring, and the in vitro results suggested that this might be related to the autophagy inhibition of chondrocytes. Further, we demonstrated a persistent autophagy inhibition with autolysosome accumulation, low expression of cathepsin D (CTSD), increased H3K9ac level, and expression of miR-1912-3p in the cartilage of PDE offspring from fetus to adulthood. In vitro experiments showed that dexamethasone inhibited autophagy flux and CTSD expression in fetal chondrocytes, while overexpression of CTSD could alleviate the inhibition of autophagic flux induced by dexamethasone. Finally, we confirmed that dexamethasone increased the H3K9ac level and expression of miR-1912-3p through activation of the glucocorticoid receptor (GR), resulting in the decreased expression of CTSD and inhibition of autophagy flux in fetal chondrocytes. In conclusion, intrauterine miR-1912-3p/CTSD programming-mediated autophagy inhibition promoted the susceptibility to osteoarthritis in PDE adult offspring rats. This study provides new ideas for exploring early prevention and therapeutic targets in fetal-originated osteoarthritis.

Mechanism of histone deacetylase HDAC2 in FOXO3-mediated trophoblast pyroptosis in preeclampsia.

Histone deacetylase 2 (HDAC2) has been demonstrated to regulate trophoblast behaviors. However, its role in trophoblast pyroptosis remains unknown. This study sought to analyze the molecular mechanism of HDAC2 in trophoblast pyroptosis in PE. Expression levels of HDAC2, forkhead box O3 (FOXO3), and protein kinase R-like endoplasmic reticulum kinase (PERK) in placenta tissues and HTR8/SVneo cells and H3K27ac levels in cells were determined. Levels of IL-1β and IL-18 in placenta tissues were determined, and their correlation with HDAC2 was analyzed. Cell proliferation, migration, and invasion were evaluated, and levels of pyroptosis-associated proteins and cytokines were determined. The enrichments of H3K27 acetylation (H3K27ac) and FOXO3 in the FOXO3/PERK promoter region were determined. HDAC2 was downregulated, and FOXO3, PERK, IL-1β, and IL-18 levels were elevated in PE placenta tissues. In HTR8/SVneo cells, HDAC2 downregulation suppressed cell proliferation, migration, and invasion and increased pyroptosis. HDAC2 erased H3K27ac in the FOXO3 promoter region and repressed FOXO3, and FOXO3 bound to the PERK promoter and increased PERK transcription. Functional rescue experiments revealed that silencing FOXO3 or PERK counteracted HDAC2 downregulation-induced cell pyroptosis. Overall, HDAC2 downregulation enhanced H3K27ac to activate FOXO3 and PERK, leading to the occurrence of trophoblast pyroptosis in PE.

RUNX1 colludes with NOTCH1 to reprogram chromatin in T cell acute lymphoblastic leukemia

Runt-related transcription factor 1 (RUNX1) is oncogenic in diverse types of leukemia and epithelial cancers where its expression is associated with poor prognosis. Current models suggest that RUNX1 cooperates with other oncogenic factors (e.g., NOTCH1, TAL1) to drive the expression of proto-oncogenes in Tcell acute lymphoblastic leukemia (T-ALL) but the molecular mechanisms controlled by RUNX1 and its cooperation with other factors remain unclear. Integrative chromatin and transcriptional analysis following inhibition of RUNX1 and NOTCH1 revealed a surprisingly widespread role of RUNX1 in the establishment of global H3K27ac levels and that RUNX1 is required by NOTCH1 for cooperative transcription activation of key NOTCH1 target genes including MYC, DTX1, HES4, IL7R, and NOTCH3. Super-enhancers were preferentially sensitive to RUNX1 knockdown and RUNX1-dependent super-enhancers were disrupted following the treatment of a pan-BET inhibitor, I-BET151.