Chromodomain Helicase DNA-binding Protein Research Articles

Insights From a Novel Splicing Variant and Recurrent Arginine Variants in the CHD3 Gene Causing Snijders Blok-Campeau Syndrome.

Snijders Blok-Campeau syndrome (SNIBCPS, OMIM#618205) is an autosomal dominant neurodevelopmental disorder attributed to pathogenic variants in the chromodomain helicase DNA binding protein 3 (CHD3) gene. To date, more than 100 individuals have been diagnosed with SNIBCPS. The syndrome is characterized by intellectual disability, global developmental delay, speech or language impediments, and dysmorphic features associated with macrocephaly. Additionally, affected individuals may exhibit behavioral issues, hypotonia, and autistic traits. A novel splicing variant (c.5590+1G > T) in the C-terminal 2 region of the CHD3 gene was identified in a patient predominantly exhibiting autistic characteristics. Invitro minigene splicing experiments conducted in HEK293 cells revealed that aberrant splicing resulted in the formation of a cryptic site 46 nucleotides downstream of the 5' splice site. This alteration was predicted to disrupt the reading frame by eliminating the physiological stop codon, consequently causing an extension in protein translation. Furthermore, an additional patient presenting with hypotonia, dysmorphic features, and global developmental delay was documented. This patient harbored a missense variant in the helicase C-terminal domain, c.3505C > T (p. Arg1169Trp). The pathogenic variant was anticipated to impact chromatin remodeling capacity and enzyme activity. Given the high prevalence of arginine residue pathogenic variants in the CHD3 protein and its notable propensity for binding and storing ATP molecules, intriguing insights into the potential effects of arginine residue pathogenic variants on phenotypes are provided. These findings contribute to a more comprehensive understanding of the genetic landscape of SNIBCPS while elucidating potential molecular mechanisms underlying the syndrome.

Discovery of CHD1 Antagonists for PTEN-Deficient Prostate Cancer.

CHD1 is a chromodomain-helicase DNA-binding protein that preferentially recognizes di- and trimethylated lysine 4 on histone H3 (H3K4me2/3). Genetic studies have established CHD1 as a synthetic lethal target in phosphatase and tensin homologue (PTEN)-deficient cancers. Despite this attractive therapeutic link, no inhibitors or antagonists of CHD1 have been reported to date. Herein, we report the discovery of UNC10142, a first-in-class small molecule antagonist of the tandem chromodomains of CHD1 that binds with an IC50 of 1.7 ± 0.2 μM. A cocrystal structure revealed a unique binding mode and competition pull-down experiments in cell lysates confirmed endogenous target engagement. Treatment of PTEN-deficient prostate cancer cells with UNC10142 led to a dose-dependent reduction in viability while PTEN-intact prostate cancer cells were unaffected, phenocopying genetic loss of CHD1. Overall, this study demonstrates the ligandability of the CHD1 chromodomains and suggests more potent and selective antagonists could translate to compounds of therapeutic value in PTEN-deficient cancers.

Refractory testicular germ cell tumors are highly sensitive to the targeting of polycomb pathway demethylases KDM6A and KDM6B

Testicular germ cell tumors (TGCTs) can be treated with cisplatin-based therapy. However, a clinically significant number of cisplatin-resistant patients die from progressive disease as no effective alternatives exist. Curative cisplatin therapy results in acute and life-long toxicities in the young TGCT patient population providing a rationale to decrease cisplatin exposure. In contrast to genetic alterations, recent evidence suggests that epigenetics is a major driving factor for TGCT formation, progression, and response to chemotherapy. Hence, targeting epigenetic pathways with “epidrugs” is one potential relatively unexplored strategy to advance TGCT treatment beyond cisplatin. In this report, we demonstrate for the first time that targeting polycomb demethylases KDM6A and KDM6B with epidrug GSK-J4 can treat both cisplatin-sensitive and -resistant TGCTs. While GSK-J4 had minimal effects alone on TGCT tumor growth in vivo, it dramatically sensitized cisplatin-sensitive and -resistant TGCTs to cisplatin. We validated KDM6A/KDM6B as the target of GSK-J4 since KDM6A/KDM6B genetic depletion had a similar effect to GSK-J4 on cisplatin-mediated anti-tumor activity and transcriptome alterations. Pharmacologic and genetic targeting of KDM6A/KDM6B potentiated or primed the p53-dominant transcriptional response to cisplatin, with also evidence for basal activation of p53. Further, several chromatin modifier genes, including BRD4, lysine demethylases, chromodomain helicase DNA binding proteins, and lysine methyltransferases, were repressed with cisplatin only in KDM6A/KDM6B-targeted cells, implying that KDM6A/KDM6B inhibition sets the stage for extensive chromatin remodeling of TGCT cells upon cisplatin treatment. Our findings demonstrate that targeting polycomb demethylases is a new potent pharmacologic strategy for treating cisplatin resistant TGCTs that warrants clinical development.

Refractory testicular germ cell tumors are highly sensitive to the targeting of polycomb pathway demethylases KDM6A and KDM6B.

Testicular germ cell tumors (TGCTs) can be treated with cisplatin-based therapy. However, a clinically significant number of cisplatin-resistant patients die from progressive disease as no effective alternatives exist. Curative cisplatin therapy results in acute and life-long toxicities in the young TGCT patient population providing a rationale to decrease cisplatin exposure. In contrast to genetic alterations, recent evidence suggests that epigenetics is a major driving factor for TGCT formation, progression, and response to chemotherapy. Hence, targeting epigenetic pathways with "epidrugs" is one potential relatively unexplored strategy to advance TGCT treatment beyond cisplatin. In this report, we demonstrate for the first time that targeting polycomb demethylases KDM6A and KDM6B with epidrug GSK-J4 can treat both cisplatin-sensitive and -resistant TGCTs. While GSK-J4 had minimal effects alone on TGCT tumor growth in vivo, it dramatically sensitized cisplatin-sensitive and -resistant TGCTs to cisplatin. We validated KDM6A/KDM6B as the target of GSK-J4 since KDM6A/KDM6B genetic depletion had a similar effect to GSK-J4 on cisplatin-mediated anti-tumor activity and transcriptome alterations. Pharmacologic and genetic targeting of KDM6A/KDM6B potentiated or primed the p53-dominant transcriptional response to cisplatin, with also evidence for basal activation of p53. Further, several chromatin modifier genes, including BRD4 , lysine demethylases, chromodomain helicase DNA binding proteins, and lysine methyltransferases, were repressed with cisplatin only in KDM6A/KDM6B-targeted cells, implying that KDM6A/KDM6B inhibition sets the stage for extensive chromatin remodeling of TGCT cells upon cisplatin treatment. Our findings demonstrate that targeting polycomb demethylases is a new potent pharmacologic strategy for treating cisplatin resistant TGCTs that warrants clinical development.

Chromatin remodeller Chd7 is developmentally regulated in the neural crest by tissue-specific transcription factors.

Neurocristopathies such as CHARGE syndrome result from aberrant neural crest development. A large proportion of CHARGE cases are attributed to pathogenic variants in the gene encoding CHD7, chromodomain helicase DNA binding protein 7, which remodels chromatin. While the role for CHD7 in neural crest development is well documented, how this factor is specifically up-regulated in neural crest cells is not understood. Here, we use epigenomic profiling of chick and human neural crest to identify a cohort of enhancers regulating Chd7 expression in neural crest cells and other tissues. We functionally validate upstream transcription factor binding at candidate enhancers, revealing novel epistatic relationships between neural crest master regulators and Chd7, showing tissue-specific regulation of a globally acting chromatin remodeller. Furthermore, we find conserved enhancer features in human embryonic epigenomic data and validate the activity of the human equivalent CHD7 enhancers in the chick embryo. Our findings embed Chd7 in the neural crest gene regulatory network and offer potentially clinically relevant elements for interpreting CHARGE syndrome cases without causative allocation.

InVivo CRISPR Screening Reveals CHD7 as a Positive Regulator of Short-lived Effector Cells.

CD8+ T cells differentiate into two subpopulations in response to acute viral infection: memory precursor effector cells (MPECs) and short-lived effector cells (SLECs). MPECs and SLECs are epigenetically distinct; however, the epigenetic regulators required for formation of these subpopulations are mostly unknown. In this study, we performed an invivo CRISPR screen in murine naive CD8+ T cells to identify the epigenetic regulators required for MPEC and SLEC formation, using the acute lymphocytic choriomeningitis virus Armstrong infection model. We identified the ATP-dependent chromatin remodeler CHD7 (chromodomain-helicase DNA-binding protein 7) as a positive regulator of SLEC formation, as knockout (KO) of Chd7 reduced SLECs numerically. In contrast, KO of Chd7 increased the formation of central memory T cells following pathogen clearance yet attenuated memory cell expansion following a rechallenge. These findings establish CHD7 as a novel positive regulator of SLEC and a negative regulator of central memory T cell formation.

12466 Dual Bone Defect In Patients With Charge Syndrome

Abstract Disclosure: N. Reyes: None. R.J. Santen: None. S.M. Jan De Beur: None. R. Balasubramanian: None. Chromodomain Helicase DNA-binding protein 7 (Chd7) is an ATP-dependent chromatin modifier that mediates nucleosome remodeling. Chd7 mutations result in CHARGE syndrome characterized by coloboma, heart defects, choanal atresia, growth/developmental delay, ear abnormalities, and hypogonadotropic hypogonadism/Kallmann syndrome (IHH/KS). Testosterone has direct and indirect effects (through estrogen), to increase bone formation and decrease bone resorption. Untreated hypogonadism is associated with decreased bone density and fractures. Reports of fractures and low bone density in CHARGE syndrome patients have been attributed to sex hormone deficiency associated with hypogonadism. However, recent data from a Chd7 mouse knockout model suggests an intrinsic Chd7-related bone defect. In wild-type mice, Chd7 promotes osteogenic differentiation of mesenchymal stem cells. Chd7 deficient mice show markedly reduced osteoblasts. Thus, we propose, a dual bone defect in CHARGE syndrome resulting from impaired osteogenesis from CHD7 and sex steroid deficiency; and increased bone resorption due to lack of sex steroids. Here we present two individuals with CHARGE syndrome with markedly low bone density and literature review supporting the dual bone defect concept. Case 1 is a 30 yo male with a pathogenic CHD7 mutation, multiple congenital anomalies of CHARGE syndrome and hypogonadotropic hypogonadism. He had multiple fractures in his teen age years and a bone density Z score of -5.2 at the lumbar spine and -3.3 at the left femoral neck. Because he did not tolerate androgen therapy, a single infusion of zoledronic acid was administered with no further fractures for eight years following infusion. Case 2 is a male evaluated for IHH/KS and ultimately diagnosed with CHARGE Syndrome based on a pathogenic CHD7 mutation. Despite 7 years of testosterone therapy with full virilization, his bone density remained low at Z-score of -1.9 at the spine and -2.6 at the total hip. Results: Both patients had low bone density, one while untreated and the other after full virilization with exogenous androgens. This raises the question whether the bone defects were related to the CHD7 mutation, to androgen deficiency or both. To answer this question, a literature search examined bone density data in untreated patients with CHARGE syndrome versus IHH/KS. We found substantially lower bone density in untreated CHARGE patients Z score -3.46±0.36 (SEM) (n=13) versus IHH/KS -2.16 ±1.0 (n=4). Furthermore, the bone density was also lower in treated CHARGE patients -2.46±0.28 (n=6) versus IHH/KS -0.94±0.26 (n=140). Conclusion: These data, taken together, provide direct human evidence to support the concept that the CHD7-related CHARGE syndrome patients have a defect in both osteogenesis as well as an effect of sex steroid deficiency on bone. Presentation: 6/3/2024

Frequent CHD1 deletions in prostate cancers of African American men is associated with rapid disease progression

We analyzed genomic data from the prostate cancer of African- and European American men to identify differences contributing to racial disparity of outcome. We also performed FISH-based studies of Chromodomain helicase DNA-binding protein 1 (CHD1) loss on prostate cancer tissue microarrays. We created CHD1-deficient prostate cancer cell lines for genomic, drug sensitivity and functional homologous recombination (HR) activity analysis. Subclonal deletion of CHD1 was nearly three times as frequent in prostate tumors of African American than in European American men and it associates with rapid disease progression. CHD1 deletion was not associated with HR deficiency associated mutational signatures or HR deficiency as detected by RAD51 foci formation. This was consistent with the moderate increase of olaparib and talazoparib sensitivity with several CHD1 deficient cell lines showing talazoparib sensitivity in the clinically relevant concentration range. CHD1 loss may contribute to worse disease outcome in African American men.

NEAT1 promotes genome stability via m6A methylation-dependent regulation of CHD4.

Long noncoding (lnc)RNAs emerge as regulators of genome stability. The nuclear-enriched abundant transcript 1 (NEAT1) is overexpressed in many tumors and is responsive to genotoxic stress. However, the mechanism that links NEAT1 to DNA damage response (DDR) is unclear. Here, we investigate the expression, modification, localization, and structure of NEAT1 in response to DNA double-strand breaks (DSBs). DNA damage increases the levels and N6-methyladenosine (m6A) marks on NEAT1, which promotes alterations in NEAT1 structure, accumulation of hypermethylated NEAT1 at promoter-associated DSBs, and DSB signaling. The depletion of NEAT1 impairs DSB focus formation and elevates DNA damage. The genome-protective role of NEAT1 is mediated by the RNA methyltransferase 3 (METTL3) and involves the release of the chromodomain helicase DNA binding protein 4 (CHD4) from NEAT1 to fine-tune histone acetylation at DSBs. Our data suggest a direct role for NEAT1 in DDR.

Molecular characteristics and oncogenic role of CHD family genes: a pan-cancer analysis based on bioinformatic and biological analysis

Chromodomain helicase DNA-binding protein (CHD) gene family, an ATP (adenosine triphosphate) -dependent chromatin remodeler family, is involved in multiple developmental process and tumor development. However, there have been none pan-cancer analyses of this family. The expression levels, survival profiles, mutation profiles and immune infiltration of the CHD family genes from TCGA and TARGET database were analyzed using online tools or R packages. Interestingly, all types of CHD gene expressions were associated with the prognosis of Neuroblastoma, Acute lymphoblastic leukemia-Phase 3 and Acute Myeloid Leukemia (All P < 0.05). Knock down of CHD7 and CHD9 in K562 (human erythromyeloblastoid leukemia) and HEC-1-B (human endometrial adenocarcinoma) cells significantly inhibit cell proliferation and migration (P < 0.05). Proliferation, colony formation and migration assays were performed in CHD7 and CHD9 knockdown K562 and HBC-1-B cell lines. Mechanisms were also analyzed by PPI and GO ontology for our experiments. Histone modification, especially the methylation of H3K4, might be involved in CHD7 and CHD9 related oncogenesis. Through bioinformatic analysis, we showed CHD genes significantly affected the prognosis of different tumor types, including childhood tumor. Our findings provide new insights into the function and mechanism of CHD gene family, especially in CHD7 and CHD9.

CHD1L Regulates Cell Survival in Breast Cancer and Its Inhibition by OTI-611 Impedes the DNA Damage Response and Induces PARthanatos.

The Chromodomain helicase DNA-binding protein 1-like (CHD1L) is a nucleosome remodeling enzyme, which plays a key role in chromatin relaxation during the DNA damage response. Genome editing has shown that deletion of CHD1L sensitizes cells to PARPi, but the effect of its pharmacological inhibition has not been defined. Triple-negative breast cancer SUM149PT, HCC1937, and MDA-MB-231 cells were used to assess the mechanism of action of the CHD1Li OTI-611. Cytotoxicity as a single agent or in combination with standard-of-care treatments was assessed in tumor organoids. Immunofluorescence was used to assess the translocation of PAR and AIF to the cytoplasm or the nucleus and to study markers of DNA damage or apoptosis. Trapping of PARP1/2 or CHD1L onto chromatin was also assessed by in situ subcellular fractionation and immunofluorescence and validated by Western blot. We show that the inhibition of CHD1L's ATPase activity by OTI-611 is cytotoxic to triple-negative breast cancer tumor organoids and synergizes with PARPi and chemotherapy independently of the BRCA mutation status. The inhibition of the remodeling function blocks the phosphorylation of H2AX, traps CHD1L on chromatin, and leaves PAR chains on PARP1/2 open for hydrolysis. PAR hydrolysis traps PARP1/2 at DNA damage sites and mediates PAR translocation to the cytoplasm, release of AIF from the mitochondria, and induction of PARthanatos. The targeted inhibition of CHD1L's oncogenic function by OTI-611 signifies an innovative therapeutic strategy for breast cancer and other cancers. This approach capitalizes on CHD1L-mediated DNA repair and cell survival vulnerabilities, thereby creating synergy with standard-of-care therapies.

Abstract Mo055: CHD4 Interacts With TBX5 to Maintain the Gene Regulatory Network of Postnatal Atrial Cardiomyocytes

Atrial fibrillation (AF) is the most common sustained arrhythmia in humans, leading to increased mortality due to increased incidence of stroke and heart failure. Over 200 genes are associated with AF by GWAS studies, suggesting a nuanced gene regulatory network (GRN) is required to maintain atrial cardiomyocyte (aCM) function and rhythm. Among these genes is the transcription factor TBX5, which we and others have shown is a master regulator of aCM identity that is essential for atrial rhythm homeostasis. We showed that TBX5 is required to maintain the chromatin looping, accessibility, and activity of atrial enhancers. Chromodomain helicase DNA binding protein 4 (CHD4), a chromatin remodeling protein that interacts with TBX5, is canonically thought to repress transcription as a component of the NuRD complex. Here, we investigated the contribution of CHD4 to TBX5 regulation of aCM gene expression. Methods: We inactivated CHD4 specifically within atrial cardiomyocytes using Cre recombinase driven by the aCM-specific Nppa promoter delivered postnatally with AAV9. Atrial remodeling, transcriptomic changes and AF susceptibility were examined. Results: We show that inactivating CHD4 in postnatal aCMs resulted in fibrotic atrial remodeling, spontaneous AF in a subset of mice, and increased AF susceptibility and burden after electrical pacing. Transcriptomic profiling of CHD4 aCM KO atria revealed gene expression changes that were highly correlated to altered gene expression downstream of TBX5 inactivation. Mechanistically, we show TBX5 recruits CHD4 to 33,170 genomic regions that are important for aCM gene regulation, whose expression is concordantly regulated downstream of TBX5 and CHD4. Together, these data reveal that CHD4 is required by TBX5 to promote accessibility of enhancers and activate many TBX5 target genes to maintain atrial rhythm.

Abstract We146: CHD8 is Essential for Postnatal Heart Function through Preserving Mitochondrial Integrity

Objective: Epigenetic regulation plays a crucial role in heart development and disease, although its mechanisms remain elusive. Known mutations in epigenetic regulators have been linked to cardiac disease. For instance, the mutation in the chromodomain helicase DNA-binding (CHD) protein 7 gene, which leads to CHARGE syndrome, is known to results in heart defects. However, the role of CHD8, an interacting partner of CHD7, in the heart has not been investigated. This study aims to explore the function of CHD8 in the heart. Methods and Results: We generated a cardiac-specific Chd8 conditional knockout mouse line (Chd8 cKO) by breeding Chd8 fl/fl mice with aMHC Cre mice. Over 60% of Chd8 cKO mice died between 7 and 9 months of age, with increased heart weight to bodyweight ratio and reduced cardiac function, increased fibrosis, and signs of dilated cardiomyopathy. Electron microscopy analysis revealed disordered sarcomeres and escalated mitophagy in CHD8-deficient hearts. Using Genome-wide transcriptome analysis though RNA sequencing, we discovered that genes involved in mitochondrial oxidative phosphorylation and muscle contraction were down-regulated in Chd8 cKO hearts. Proteins in the electron transport chain complexes were down regulated and mitophagy marker LC3 increased in the Chd8 cKO hearts compared with the control mice. Upregulated pathways include inflammatory response suggesting that the innate immune response may contribute to dilated cardiomyopathy. Conclusions: Our findings underscore CHD8 as a key regulator of cardiac function and regeneration by influencing chromatin accessibility of genes involved in mitochondrial oxidative phosphorylation and contractility. Overall, our study provides new insights into the epigenetic regulation of cardiac function and the CHD8’s role in heart development and disease. It implies that activating CHD8 may be a promising therapeutic strategy for treating dilated cardiomyopathy and other heart-related diseases.

Endothelial Chromatin-Remodeling Enzymes Regulate the Production of Critical ECM Components During Murine Lung Development.

The chromatin-remodeling enzymes BRG1 (brahma-related gene 1) and CHD4 (chromodomain helicase DNA-binding protein 4) independently regulate the transcription of genes critical for vascular development, but their coordinated impact on vessels in late-stage embryos has not been explored. In this study, we genetically deleted endothelial Brg1 and Chd4 in mixed background mice (Brg1fl/fl;Chd4fl/fl;VE-Cadherin-Cre), and littermates that were negative for Cre recombinase were used as controls. Tissues were analyzed by immunostaining, immunoblot, and flow cytometry. Quantitative reverse transcription polymerase chain reaction was used to determine gene expression, and chromatin immunoprecipitation revealed gene targets of BRG1 and CHD4 in cultured endothelial cells. We found Brg1/Chd4 double mutants grew normally but died soon after birth with small and compact lungs. Despite having normal cellular composition, distal air sacs of the mutant lungs displayed diminished ECM (extracellular matrix) components and TGFβ (transforming growth factor-β) signaling, which typically promotes ECM synthesis. Transcripts for collagen- and elastin-related genes and the TGFβ ligand Tgfb1 were decreased in mutant lung endothelial cells, but genetic deletion of endothelial Tgfb1 failed to recapitulate the small lungs and ECM defects seen in Brg1/Chd4 mutants. We instead found several ECM genes to be direct targets of BRG1 and CHD4 in cultured endothelial cells. Collectively, our data highlight essential roles for endothelial chromatin-remodeling enzymes in promoting ECM deposition in the distal lung tissue during the saccular stage of embryonic lung development.

Cancer-associated fibroblast-derived colony-stimulating factor 2 confers acquired osimertinib resistance in lung adenocarcinoma via promoting ribosome biosynthesis.

Acquired resistance is a major obstacle to the therapeutic efficacy of osimertinib in lung adenocarcinoma (LUAD), but the underlying mechanisms are still not fully understood. Cancer-associated fibroblasts (CAFs) are the most abundant stromal cell type in LUAD tumor-microenvironment (TME) and have emerged as a key player in chemoresistance. However, the function of CAFs in osimertinib resistance is still unclear. Here, we showed that CAFs derived from osimertinib-resistant LUAD tissues (CAFOR) produced much more colony-stimulating factor 2 (CSF2) than those isolated from osimertinib-sensitive tissues. CAFOR-derived CSF2 activated the Janus kinase 2 (JAK2)/Signal transducer and activator of transcription 3 (STAT3) signaling pathway and upregulated lnc-CSRNP3 in LUAD cells. Lnc-CSRNP3 then promoted the expression of nearby gene CSRNP3 by recruiting chromodomain helicase DNA binding protein 9 (CHD9) and inhibited the phosphatase activity of the serine/threonine protein phosphatase 1 catalytic subunit α (PP1α), thereby induced osimertinib resistance by enhancing ribosome biogenesis. Collectively, our study reveals a critical role for CAFs in the development of osimertinib resistance and identifies the CSF2 pathway as an attractive target for monitoring osimertinib efficacy and overcoming osimertinib resistance in LUAD.

Expanding the Mutational Landscape and Clinical Phenotype of CHD2-Related Encephalopathy.

To present a case series of novel CHD2 variants in patients presenting with genetic epileptic and developmental encephalopathy. CHD2 gene encodes an ATP-dependent enzyme, chromodomain helicase DNA-binding protein 2, involved in chromatin remodeling. Pathogenic variants in CHD2 are linked to early-onset conditions such as developmental and epileptic encephalopathy, drug-resistant epilepsies, and neurodevelopmental disorders. Approximately 225 diagnosed patients from 28 countries exhibit various allelic variants in CHD2, including small intragenic deletions/insertions and missense, nonsense, and splice site variants. We present the molecular and clinical characteristics of 17 unreported individuals from 17 families with novel pathogenic or likely pathogenic variants in CHD2. All individuals presented with severe global developmental delay, childhood-onset myoclonic epilepsy, and additional neuropsychiatric features, such as behavioral including autism, ADHD, and hyperactivity. Additional findings include abnormal reflexes, hypotonia and hypertonia, motor impairment, gastrointestinal problems, and kyphoscoliosis. Neuroimaging features included hippocampal signal alterations (4/10), with additional volume loss in 2 cases, inferior vermis hypoplasia (7/10), mild cerebellar atrophy (4/10), and cerebral atrophy (1/10). Our study broadens the geographic scope of CHD2-related phenotypes, providing valuable insights into the prevalence and clinical characteristics of this genetic disorder in previously underrepresented populations.

IGF1R and FLT1 in female endothelial cells and CHD2 in male microglia play important roles in Alzheimer's disease based on gender difference analysis

ObjectiveThis study investigated sex-specific pathogenesis mechanisms in Alzheimer's disease (AD) using single-nucleus RNA sequencing (snRNA-seq) data. MethodsData from the Gene Expression Omnibus (GEO) were searched using terms “Alzheimer's Disease”, “single cell”, and “Homo sapiens”. Studies excluding APOE E4 and including comprehensive gender information with 10× sequencing methods were selected, resulting in GSE157827 and GSE174367 datasets from human prefrontal cortex samples. Sex-stratified analyses were conducted on these datasets, and the outcomes of the analysis for GSE157827 were compared with those of GSE174367. The findings were validated using expression profiling from the mouse dataset GSE85162. Furthermore, real-time PCR experiments in mice further confirmed these findings. The Seurat R package was used to identify cell types, and batch effects were mitigated using the Harmony R package. Cell proportions by sex were compared using the Mann-Whitney-Wilcoxon test, and gene expression variability was displayed with an empirical cumulative distribution plot. Differentially expressed genes were identified using the FindMarkers function with the MAST test. Transcription factors were analyzed using the RcisTarget R package. ResultsSeven cell types were identified: astrocytes, endothelial cells, excitatory neurons, inhibitory neurons, microglia, oligodendrocytes, and oligodendrocyte progenitor cells. Additionally, five distinct subpopulations of both endothelial and microglial cells were also identified, respectively. Key findings included: (1) In endothelial cells, genes involved in synapse organization, such as Insulin Like Growth Factor 1 Receptor (IGF1R) and Fms Related Receptor Tyrosine Kinase 1(FLT1), showed higher expression in females with AD. (2) In microglial cells, genes in the ribosome pathway exhibited higher expression in males without AD compared to females (with or without AD) and males with AD. (3) Chromodomain Helicase DNA Binding Protein 2 (CHD2) negatively regulated gene expression in the ribosome pathway in male microglia, suppressing AD, this finding was further validated in mice. (4) Differences between Asians and Caucasians were observed based on sex and disease status stratification. ConclusionsIGF1R and FLT1 in endothelial cells contribute to AD in females, while CHD2 negatively regulates ribosome pathway gene expression in male microglia, suppressing AD in humans and mice.

CHD2 Regulates Neuron-Glioma Interactions in Pediatric Glioma.

High-grade gliomas (HGG) are deadly diseases for both adult and pediatric patients. Recently, it has been shown that neuronal activity promotes the progression of multiple subgroups of HGG. However, epigenetic mechanisms that govern this process remain elusive. Here we report that the chromatin remodeler chromodomain helicase DNA-binding protein 2 (CHD2) regulates neuron-glioma interactions in diffuse midline glioma (DMG) characterized by onco-histone H3.1K27M. Depletion of CHD2 in H3.1K27M DMG cells compromises cell viability and neuron-to-glioma synaptic connections in vitro, neuron-induced proliferation of H3.1K27M DMG cells in vitro and in vivo, activity-dependent calcium transients in vivo, and extends the survival of H3.1K27M DMG-bearing mice. Mechanistically, CHD2 coordinates with the transcription factor FOSL1 to control the expression of axon-guidance and synaptic genes in H3.1K27M DMG cells. Together, our study reveals a mechanism whereby CHD2 controls the intrinsic gene program of the H3.1K27M DMG subtype, which in turn regulates the tumor growth-promoting interactions of glioma cells with neurons. Significance: Neurons drive the proliferation and invasion of glioma cells. Here we show that chromatin remodeler chromodomain helicase DNA-binding protein 2 controls the epigenome and expression of axon-guidance and synaptic genes, thereby promoting neuron-induced proliferation of H3.1K27M diffuse midline glioma and the pathogenesis of this deadly disease.

Revisiting an Old Issue: Sex Identification of Short-eared Owls (Asio flammeus) at an Asian Wintering Site

Abstract At wintering sites of the migratory Short-eared Owl (Asio flammeus) in subtropical Asia, behavioral interactions between males and females are limited, and the body mass and plumage features between the sexes overlap significantly. Thus, sexing the species morphometrically for research and conservation activities is difficult. We aimed to develop a quantitative method for sexing Short-eared Owls, and we here present a new formula to do so using plumage features. We used a total of 198 Short-eared Owls (163 from bird rescue efforts at 15 airports and 35 preserved specimens from a museum in Taiwan) and carefully examined their morphological data and plumage images, then determined their sex using polymerase chain reactions of chromodomain helicase DNA-binding protein genes on sex chromosomes or gonad inspection. Eight of the ten traits we evaluated differed significantly between males and females. Females had a greater number of cross bars on primaries, secondaries, and outermost tail feathers; a higher proportion of yellowish-brown underwing coverage; and larger measurements in head length, bill length, tarsus length, and body mass. The best-fit model suggested simplifying the formula to just the proportion of the yellowish-brown underwing coverage, which provided sexing accuracy exceeding 95.9% for the 49 live individuals in the test data set and 94.3% for the 35 preserved specimens. This formula addresses the challenges posed by ambiguous individuals in the wintering region and offers an efficient and accurate means for sexing Short-eared Owls when DNA or gonad inspection is unavailable.

Evaluation of CHD5, H3K9me3, and H4K12ac in Human Testes with Spermatogenic Maturation Arrest: A Cross-Sectional Study.

Spermatogenic maturation arrest is thought to be caused by epigenetic defects, specifically in chromatin remodeling and histone modification. This study evaluated the status of chromatin remodeling chromodomain helicase DNA binding protein 5 (CHD5) and histone modifications histone 4 lys-12 acetylation (H4K12ac) and histone 3 lys-9 trimethylation (H3K9me3) in human testicular biopsies, based on maturation arrest type. The cross-sectional study utilized 18 Bouin-fixed paraffin-embedded (BFPE) specimens prepared from residual tissue from routine laboratory tests of infertile patients. The expression of CHD5, H4K12ac, and H3K9me3 was examined through immunohistochemistry (IHC). The intensity was measured using ImageJ with IHC Profiler and StarDist plugins. Statistical analysis was performed using Python with Scipy.Stats module. The data were tested with Shapiro- Wilk for normality and Levene test for homogeneity. The differences in the intensity of spermatogenic cells were assessed using Kruskal-Wallis and Mann-Whitney tests. A difference was considered statistically significant if P<0.05. We found three types of maturation arrest, including Sertoli cell only (n=5), spermatocyte arrest (n=4), and spermatid arrest (n=9). CHD5 was positive in spermatogonia and round spermatids but absent in spermatocytes. The mean grey value (MGV) of CHD5 in spermatogonia was generally weak in spermatocyte arrest (157.4 ± 16.6) and spermatid arrest (155.3 ± 16.8), and there was no significant difference between them [P=0.49, 95% confidence interval (CI): (-4.3, 6), effect size (r): 0.02]. Although there was a significant difference in the expression of H3K9me3 and H4K12ac (P<0.001), both histone modifications were found in all observed spermatogenic cells. The expressions of CHD5, H3K9me3, and H4K12ac in different spermatogenic cell types produce similar results, indicating that they cannot be used as markers to determine the type of spermatogenic maturation arrest in humans. The significant finding in this research is the expression of CHD5 in human spermatogonia cells, which requires further study for elaboration.