Cell Adhesion Genes Research Articles

Atrial Fibrillation Related Titin Truncation Is Associated With Atrial Myopathy in Patient-Derived Induced Pluripotent Stem Cell Disease Models.

Protein-truncating mutations in the titin gene are associated with increased risk of atrial fibrillation. However, little is known about the underlying pathophysiology. We identified a heterozygous titin truncating variant (TTNtv) in a patient with unexplained early onset atrial fibrillation and normal ventricular function. We generated patient-specific atrial- and ventricular-like induced pluripotent stem cell-derived cardiomyocytes and engineered heart tissue to evaluate the impact of the TTNtv on electrophysiology, sarcomere structure, contractility, and gene expression. We demonstrate that the TTNtv increases susceptibility to pacing-induced arrhythmia, promotes sarcomere disorganization, and reduces contractile force in atrial induced pluripotent stem cell-derived cardiomyocytes compared with their CRISPR/Cas9-corrected isogenic controls. In ventricular induced pluripotent stem cell-derived cardiomyocytes, this variant was associated with abnormal electrophysiology and sarcomere organization without a reduction in contractile force compared with their isogenic controls. RNA-sequencing revealed an upregulation of cell adhesion and extracellular matrix genes in the presence of the TTNtv for both atrial and ventricular engineered heart tissues. In a patient with unexplained atrial fibrillation, induced pluripotent stem cell-derived cardiomyocytes with a TTNtv showed structural and electrophysiological abnormalities in both atrial and ventricular models, while only atrial engineered heart tissues demonstrated reduced contractility. The observed chamber-specific effect suggests that structural disorganization and reduced contractile function may be associated with atrial myopathy in the presence of truncated titin.

The C-terminal PHDVC5HCH tandem domain of NSD2 is a combinatorial reader of unmodified H3K4 and tri-methylated H3K27 that regulates transcription of cell adhesion genes in multiple myeloma.

Histone methyltransferase NSD2 (MMSET) overexpression in multiple myeloma (MM) patients plays an important role in the development of this disease subtype. Through the expansion of transcriptional activating H3K36me2 and the suppression of repressive H3K27me3 marks, NSD2 activates an aberrant set of genes that contribute to myeloma growth, adhesive and invasive activities. NSD2 transcriptional activity also depends on its non-catalytic domains, which facilitate its recruitment to chromatin through histone binding. In this study, using NMR, ITC and molecular dynamics simulations, we show that the tandem PHD domain of NSD2 (PHDVC5HCHNSD2) is a combinatorial reader of unmodified histone H3K4 and tri-methylated H3K27 (H3K27me3). This is the first PHD tandem cassette known to decode the methylation status of H3K27. Importantly, in a NSD2-dependent MM cellular model, we show that expression of NSD2 mutants, engineered to disrupt the interaction between H3K27me3 and PHDVC5HCH, display in comparison to wild-type NSD2: incomplete loss of H3K27 methylation throughout the genome, decreased activation of adhesive properties and cell adhesion genes, and a decrease of the corresponding H3K27ac signal at promoters. Collectively, these data suggest that the PHDVC5HCH domain of NSD2 plays an important role in modulating gene expression and chromatin modification, providing new opportunities for pharmacological intervention.

Elevated Expression of Cell Adhesion, Metabolic, and Mucus Secretion Gene Clusters Associated with Tumorigenesis, Metastasis, and Poor Survival in Pancreatic Ductal Adenocarcinoma.

Technological advances in identifying gene expression profiles are being applied to study an array of cancers. The goal of this study was to identify differentially expressed genes in pancreatic ductal adenocarcinoma (PDAC) and examine their potential role in tumorigenesis and metastasis. The transcriptomic profiles of PDAC and non-tumorous tissue samples were derived from the gene expression omnibus (GEO), which is a public repository. The GEO2R tool was used to further derive differentially expressed genes from those profiles. In this study, a total of 68 genes were derived from upregulated PDAC genes in three or more transcriptomic profiles and were considered PDAC gene sets. The identified PDAC gene sets were examined in the molecular signatures database (MSigDB) for ontological investigation, which revealed that these genes were involved in the extracellular matrix and associated with the cell adhesion process in PDAC tumorigenesis. The gene set enrichment analysis showed greater enrichment scores for the gene sets. Moreover, the identified gene sets were examined for protein-protein interaction using the STRING database. Based on functional k-means clustering, the following three functional cluster groups were identified in this study: extracellular matrix/cell adhesion, metabolic, and mucus secretion-related protein groups. The receiver operating characteristic (ROC) curve revealed greater specificity and sensitivity for these cluster genes in predicting PDAC tumorigenesis and metastases. In addition, the expression of the cluster genes affects the overall survival rate of PDAC patients. Using the cancer genome atlas (TCGA) database, the associations between expression levels and clinicopathological features were validated. Overall, the genes identified in this study appear to be critical in PDAC development and can serve as potential diagnostic and prognostic targets for pancreatic cancer treatment.

Combining NeuroPainting with transcriptomics reveals cell-type-specific morphological and molecular signatures of the 22q11.2 deletion.

Neuropsychiatric conditions pose substantial challenges for therapeutic development due to their complex and poorly understood underlying mechanisms. High-throughput, unbiased phenotypic assays present a promising path for advancing therapeutic discovery, especially within disease-relevant neural tissues. Here, we introduce NeuroPainting, a novel adaptation of the Cell Painting assay, optimized for high-dimensional morphological phenotyping of neural cell types, including neurons, neuronal progenitor cells, and astrocytes derived from human stem cells. Using NeuroPainting, we quantified cell structure and organelle behavior across various brain cell types, creating a public dataset of over 4,000 cellular traits. This extensive dataset not only sets a new benchmark for phenotypic screening in neuropsychiatric research but also serves as a gold standard for the research community, enabling comparisons and validation of results. We then applied NeuroPainting to identify morphological signatures associated with the 22q11.2 deletion, a major genetic risk factor for schizophrenia. We observed profound cell-type-specific effects of the 22q11.2 deletion, with significant alterations in mitochondrial structure, endoplasmic reticulum organization, and cytoskeletal dynamics, particularly in astrocytes. Transcriptomic analysis revealed reduced expression of cell adhesion genes in 22q11.2 deletion astrocytes, consistent with recent post-mortem findings. Integrating the RNA sequencing data and morphological profiles uncovered a novel biological link between altered expression of specific cell adhesion molecules and observed changes in mitochondrial morphology in 22q11.2 deletion astrocytes. These findings underscore the power of combined phenomic and transcriptomic analyses to reveal mechanistic insights associated with human genetic variants of neuropsychiatric conditions.

Innovative spiral nerve conduits: Addressing nutrient transport and cellular activity for critical-sized nerve defects

Large-gap nerve defects require nerve guide conduits (NGCs) for complete regeneration and muscle innervation. Many NGCs have been developed using various scaffold designs and tissue engineering strategies to promote axon regeneration. Still, most are tubular with inadequate pore sizes and lack surface cues for nutrient transport, cell attachment, and tissue infiltration. This study developed a porous spiral NGC to address these issues using a 3D-printed thermoplastic polyurethane (TPU) fiber lattice. The lattice was functionalized with poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) electrospun aligned (aPHBV) and randomly (rPHBV) oriented nanofibers to enhance cellular activity. TPU lattices were made with 25 %, 35 %, and 50 % infill densities to create scaffolds with varied mechanical compliance. The fabricated TPU/PHBV spiral conduits had significantly higher surface areas (25 % TPU/PHBV: 698.97 mm2, 35 % TPU/PHBV: 500.06 mm2, 50 % TPU/PHBV: 327.61 mm2) compared to commercially available nerve conduits like Neurolac™ (205.26 mm2). Aligned PHBV nanofibers showed excellent Schwann cell (RSC96) adhesion, proliferation, and neurogenic gene expression for all infill densities. Spiral TPU/PHBV conduits with 25 % and 35 % infill densities exhibited Young's modulus values comparable to Neurotube® and ultimate tensile strength like acellular cadaveric human nerves. A 10 mm sciatic nerve defect in Wistar rats treated with TPU/aPHBV NGCs demonstrated muscle innervation and axon healing comparable to autografts over 4 months, as evaluated by gait analysis, functional recovery, and histology. The TPU/PHBV NGC developed in this study shows promise as a treatment for large-gap nerve defects.

Stem Cell Membrane-Camouflaged Biomimetic Nanoparticles Inhibiting Leptin Pathway for Intervertebral Disc Degeneration Therapy.

Leptin, a kind of adipokine, with its receptor in which the long isoform plays a crucial role in signal transduction, has been identified in intervertebral disc (IVD) tissues, especially showing an increased expression in degenerated discs. Initially identified as a metabolic sensor, leptin has recently been found able to regulate inflammation into imbalance, which favors catabolic degradative processes, thus contributing to progressive intervertebral disc degeneration (IDD). Therefore, efficiently inhibiting the leptin pathway may provide a new strategy to treat IDD. In this study, we introduced an innovative drug delivery system (DDS) that employs stem cell membranes (SCM) to encapsulate (Zeolitic imidazolate frameworks-8) ZIF-8 nanoparticles. These nanoparticles are used to transport a plasmid containing shRNA targeting the leptin receptor (LEPR), with the aim of facilitating repair in IDD. The regenerative performances of this DDS in IDD were verified through a combination of the in vitro western blot and immunofluorescence with the in vivo radiologic examination and histological staining. The DDS demonstrated excellent cell adhesion properties and gene transfection efficiency in vitro, along with impressive treatment outcomes in vivo. Both in vitro and in vivo studies revealed that the DDS effectively reduced leptin receptor expression and alleviated the inflammatory environment, thereby promoting regeneration in degenerated IVDs. We propose that the DDS represents a promising novel approach for treating IDD and may also be beneficial for other degenerative diseases linked to leptin pathway dysfunction.

Identification of potential microRNAs involved in pathogenesis of venous thromboembolism (VTE): A meta analysis

ObjectiveMicroRNAs (MiRNAs) are master regulators of gene expression and have been suggested as potential diagnostic and therapeutic biomarkers in variety of complex diseases. Venous thromboembolism is a major cause of morbidity and mortality worldwide. Several miRNA expression studies have been conducted to identify miRNAs linked to VTE prognosis. These studies reveal that various miRNAs are significantly up-regulated and down-regulated in VTE patients in comparison to healthy controls. Present meta-analysis deliberate findings of such studies to identify most potential miRNA targets associated with VTE. MethodologyComprehensive literature review on Pubmed was conducted. Present analysis assessed 20 research article out of a total of 383 articles screened, based on inclusion and exclusion criteria. The up-regulated and down-regulated miRNAs obtained from selected research articles were subjected to meta-analysis. The differentially expressed miRNAs so obtained and were used for further bioinformatic analysis, including gene ontology and pathway analysis of their target genes, to study their potential involvement in VTE pathogenesis. ResultsTwenty articles selected for meta-analysis included a total of 808 patients. These included 26 up-regulated miRNAs and 11 down-regulated miRNAs. The meta-analysis based on Odds ratio suggested that one up-regulated miRNA (hsa-miR-1233-3p) and two down-regulated miRNAs (hsa-miR-103a-3p and hsa-miR-200c) returned significantly higher Odds compared to other miRNAs. Further bioinformatics analysis of their target genes revealed that these miRNAs target a large number of genes involved in cell adhesion, cell migration, endothelial activation and inflammation genes. ConclusionsThree miRNAs, viz.; hsa-miR-1233-3p, hsa-miR-103a-3p and hsa-miR-200c may play a crucial role in VTE pathogenesis and has potential to serve as reliable diagnostic or therapeutic biomarkers for VTE.

Molecular correlates of social adversity in breast cancer.

48 Background: Neighborhood disadvantage (ND) is associated with shorter breast cancer (BCa) survival independent of individual, tumor, and treatment factors, suggesting more aggressive tumor biology in women from disadvantaged neighborhoods. This study evaluates how differential DNA methylation (DNAm), gene expression, and biologic pathways are wired with each other to delineate the regulatory landscape of ND on BCa. Methods: We leveraged 55 geocoded ER+/HER2- BCa samples from Hispanic White women enrolled in a prospective genomic-epidemiologic cohort study. Objective ND was evaluated using the Area Deprivation Index (ADI) and subjective ND was evaluated using the patient-reported Neighborhood Social Environment Adversity Survey and the Everyday Expanded Discrimination Survey. We analyzed the association between ND and (1) DNAm, (2) RNA transcription and miRNAs, and (3) blood concentration levels of DNAm co-factors (B12 and folate) from the same patient. To evaluate how the DNAm/expressed pathways are wired with each other to delineate the regulatory landscape of ND in these tumors, we performed correlation analyses among CpGs, genes, and miRNAs in the same topologically associated domain (TAD). We used Spearman correlation as our metric and adjusted the resulting p-values to FDR values. Results: The cohort was divided into low ND (ADI<5; 31%) and a high ND (ADI>=5; 69%). There were no significant differences between groups by age, race/ethnicity, genetic ancestry, BMI, smoking/alcohol, subtype, stage, or OncotypeDX scores. We discovered that high ND exhibits epigenetic deregulation of immune pathways, consistent with our findings of lower circulating B12 in high ND, suggesting activation of immune pathways through reduced systemic availability of methyl donors. RNA-seq identified higher tumor infiltration of immune cells in patients from high ND (e.g., Interferon alpha and gamma responses and inflammatory responses) consistent with aggressive biology. Estrogen response genes were downregulated suggesting that patients from high ND may develop estrogen-resistant tumors. Higher subjective ND scores discovered epigenetic changes on cell adhesion and calcium signaling genes, along with gene expression of E2F targets and cell cycle’s G2M checkpoint, indicative of a more proliferative/stemness signature. TAD analysis discovered significant developmental, immune, and signaling pathways when correlating DNAm with gene expression (e.g., estrogen response and EMT). Conclusions: In this multi-omic matched cohort, we discovered differentially methylated/expressed pathways, consistent with aggressive biology, wired with each other to identify a novel regulatory landscape of ND on BCa. These findings can inform interventions such as improved access to healthy nutrition (B12) in ND/food deserts or targeted stress-reduction interventions based on our survey findings to ultimately reverse aggressive tumor biology and reduce BCa disparities by ND.

Comprehensive RNA-Seq Gene Co-Expression Analysis Reveals Consistent Molecular Pathways in Hepatocellular Carcinoma across Diverse Risk Factors.

Hepatocellular carcinoma (HCC) has the highest mortality rate and is the most frequent of liver cancers. The heterogeneity of HCC in its etiology and molecular expression increases the difficulty in identifying possible treatments. To elucidate the molecular mechanisms of HCC across grades, data from The Cancer Genome Atlas (TCGA) were used for gene co-expression analysis, categorizing each sample into its pre-existing risk factors. The R library BioNERO was used for preprocessing and gene co-expression network construction. For those modules most correlated with a grade, functional enrichments from different databases were then tested, which appeared to have relatively consistent patterns when grouped by G1/G2 and G3/G4. G1/G2 exhibited the involvement of pathways related to metabolism and the PI3K/Akt pathway, which regulates cell proliferation and related pathways, whereas G3/G4 showed the activation of cell adhesion genes and the p53 signaling pathway, which regulates apoptosis, cell cycle arrest, and similar processes. Module preservation analysis was then used with the no history dataset as the reference network, which found cell adhesion molecules and cell cycle genes to be preserved across all risk factors, suggesting they are imperative in the development of HCC regardless of potential etiology. Through hierarchical clustering, modules related to the cell cycle, cell adhesion, the immune system, and the ribosome were found to be consistently present across all risk factors, with distinct clusters linked to oxidative phosphorylation in viral HCC and pentose and glucuronate interconversions in non-viral HCC, underscoring their potential roles in cancer progression.

Strontium-Modified porous attapulgite composite hydrogel scaffold with advanced angiogenic and osteogenic potential for bone defect repair

Nano-attapulgite (nano-ATP) has shown potential in promoting mesenchymal stem cell (MSC) adhesion, growth and osteogenic gene expression. In this study, we investigated a 3D-bioprinted porous Sr-ATP (strontium-doped nano-ATP)/GelMA/chitosan composite hydrogel scaffold for bone regeneration. The experiment was divided into four groups based on the concentration of Sr-ATP: control (0%), 0.5%, 1.0% and 2.0%. The primary novelty of our research lies in the incorporation of Sr-ATP, which enhances the biological and mechanical properties of scaffolds. Additionally, we utilized a stable Pickering emulsion templating technique combined with 3D printing to fabricate the scaffold, ensuring a uniform and stable porous structure. The biological and mechanical properties of the scaffold were evaluated in vitro, and its potential to promote angiogenesis and osteogenesis was assessed in vivo using cranial defect model. Our results indicate that the scaffold presents a promising solution for bone formation in bone defects, demonstrating significant improvements in both angiogenesis and osteogenesis.

Abstract B076: Morphological diversity predicts functional traits in pancreatic cancer

Abstract Cell morphologies represent a phenotypic integration of intrinsic cellular processes, changes in cell state, and interactions with neighboring cells. While analyses of large cell line collections such as the Cancer Dependency Map (DepMap) have greatly enhanced discovery of novel molecular biomarkers and therapeutic targets, morphological analysis of these models has not yet been performed. Hence, there is a rich opportunity to discover novel regulators and functional properties of cell morphologies by linking image-based profiling to -omics based assays. Here, we studied the transcriptional and functional properties of 16 human pancreatic cancer cell lines, associations with distinct cell morphologies, and treatment-induced remodeling. At baseline, we observed extensive morphological heterogeneity across and within cell lines, as well as differences in multicellular organization. We categorized cell line morphologies into epithelial, mesenchymal, and spheroid, and organizational patterns into tightly aggregated, multilayered, and dispersed. We performed differential expression analysis across morphological subtypes utilizing DepMap transcriptomics data and queried functional correlates including CRISPR dependency, drug sensitivity, and proclivity for metastasis. For example, we discovered that the mesenchymal morphology and multilayered organizational pattern [WH3] were associated with metastatic potential, while expressing reduced levels of tight junction and cell adhesion genes. We then explored treatment associated morphological changes and their potential as cost-effective biomarkers for cell-intrinsic resistance to chemotherapy (e.g., 5-FU and gemcitabine) and KRAS inhibitors (e.g., MRTX1133 and RMC- 6236). Cells were treated continuously and monitored with live cell imaging (Incucyte SX5) followed by Cell Painting at the three-day endpoint. We observed conserved morphological responses to therapy across cell lines including a shift towards spindle-like cell shapes with neurite-like projections in chemotherapy-treated conditions, and a cell bloating phenomena characterized by an increase in cell area in KRAS inhibitor treated conditions. To directly link transcriptional state to morphology, we performed 1000-plex spatial molecular imaging (Nanostring CosMx) at subcellular resolution to pools of cell lines, demonstrating that morphological diversity within cell lines corresponded to distinct transcriptional states. In conclusion, this study highlights the potential of harnessing cell morphological information in a rapid, cost-effective phenotyping assay to aid precision oncology efforts leveraging patient- derived in vitro models. Citation Format: Dennis Gong, William L Hwang. Morphological diversity predicts functional traits in pancreatic cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr B076.

Epidemiologically relevant phthalates affect human endometrial cells in vitro through cell specific gene expression changes related to the cytoskeleton and mitochondria

Phthalates are endocrine disrupting chemicals (EDCs) found in common consumer products such as soft plastics and cosmetics. Although the knowledge regarding the adverse effects of phthalates on female fertility are accumulating, information on the hormone sensitive endometrium is still scarce. Here, we studied the effects of phthalates on endometrial cell proliferation and gene expression. Human endometrial primary epithelial and stromal cells were isolated from healthy fertile-aged women (n=3), and were compared to endometrial cell lines T-HESC and Ishikawa. Three different epidemiologically relevant phthalate mixtures were used, defined by urine samples in the Midlife Women Health Study (MWHS) cohort. Mono (2-ethyl-5-hydroxyhexyl) phthalate (MEHHP) was used as a single phthalate control. Cells were harvested for proliferation testing and transcriptomic analyses after 24 h exposure. Even though all cell models responded differently to the phthalate exposures, many overlapping differentially expressed genes (DEGs, FDR<0.1), related to cell adhesion, cytoskeleton and mitochondria were found in all cell types. The qPCR analysis confirmed that MEHHP significantly affected cell adhesion gene vinculin (VCL) and NADH:ubiquinone oxidoreductase subunit B7 (NDUFB7), important for oxidative phosphorylation. Benchmark dose modelling showed that MEHHP had significant concentration-dependent effects on cytoskeleton gene actin-beta (ACTB). In conclusion, short 24 h phthalate exposures significantly altered gene expression cell-specifically in human endometrial cells, with six shared DEGs. The mixture effects were similar to those of MEHHP, suggesting MEHHP could be the main driver in the mixture. Impact of phthalate exposures on endometrial functions including receptivity should be addressed.

Pharmacological activation of mesenchymal stem cells increases gene expression pattern of cell adhesion molecules and fusion with neonatal cardiomyocytes.

Cellular therapy is considered a better option for the treatment of degenerative disorders. Different cell types are being used for tissue regeneration. Despite extensive research in this field, several issues remain to be addressed concerning cell transplantation. One of these issues is the survival and homing of administered cells in the injured tissue, which depends on the ability of these cells to adhere. To enhance cell adherence and survival, Rap1 GTPase was activated in mesenchymal stem cells (MSCs) as well as in cardiomyocytes (CMs) by using 8-pCPT-2'-O-Me-cAMP, and the effect on gene expression dynamics was determined through quantitative reverse transcriptase-polymerase chain reactionanalysis. Pharmacological activation of MSCs and CMsresulted in the upregulation of connexin-43 and cell adhesion genes, which increased the cell adhesion ability of MSCs and CMs, and increased the fusion of MSCs with neonatal CMs. Treating stem cells with a pharmacological agent that activates Rap1a before transplantation can enhance their fusion with CMs and increase cellular regeneration.

Expression Patterns of Grainyhead-Like 2 and Ovo-Like 2 in Mouse Mammary Gland Development During Pregnancy, Lactation, and Weaning.

Grainyhead-like 2 (Grhl2) is a transcription factor that regulates cell adhesion genes in mammary ductal development and serves as a repressor of the epithelial-mesenchymal transition. Conversely, Ovo-like2 (Ovol2) is a target gene of Grhl2 but functions as a substitute in Grhl2-deficient mice, facilitating successful epithelial barrier formation and lumen expansion in kidney-collecting ductal epithelial cells. Our objective was to examine the expression patterns of Grhl2, Ovol2, and their associated genes during the intricate phases of mouse mammary gland development. The mRNA expression of Grhl2 and Ovol2 increased after pregnancy. We observed Grhl2 protein presence in the epithelial cell's region, coinciding with acini formation, and its signal significantly correlated with E-cadherin (Cdh1) expression. However, Ovol2 was present in the epithelial region without a correlation with Cdh1. Similarly, Zeb1, a mesenchymal transcription factor, showed Cdh1-independent expression. Subsequently, we explored the interaction between Rab25, a small G protein, and Grhl2/Ovol2. The expressions of Grhl2 and Ovol2 exhibited a strong correlation with Rab25 and claudin-4, a tight junction protein. These findings suggest that Grhl2 and Ovol2 may collaborate to regulate genes associated with cell adhesion and are crucial for maintaining epithelial integrity during the different phases of mammary gland development.

Cell-Specific Impacts of Surface Coating Composition on Extracellular Vesicle Secretion.

Biomaterial properties have recently been shown to modulate extracellular vesicle (EV) secretion and cargo; however, the effects of substrate composition on EV production remain underexplored. This study investigates the impacts of surface coatings composed of collagen I (COLI), fibronectin (FN), and poly l-lysine (PLL) on EV secretion for applications in therapeutic EV production and to further understanding of how changes in the extracellular matrix microenvironment affect EVs. EV secretion from primary bone marrow-derived mesenchymal stromal cells (BMSCs), primary adipose-derived stem cells (ASCs), HEK293 cells, NIH3T3 cells, and RAW264.7 cells was characterized on the different coatings. Expression of EV biogenesis genes and cellular adhesion genes was also analyzed. COLI coatings significantly decreased EV secretion in RAW264.7 cells, with associated decreases in cell viability and changes in EV biogenesis-related and cell adhesion genes at day 4. FN coatings increased EV secretion in NIH3T3 cells, while PLL coatings increased EV secretion in ASCs. Surface coatings had significant effects on the capacity of EVs derived from RAW264.7 and NIH3T3 cells to impact in vitro macrophage proliferation. Overall, surface coatings had different cell-specific effects on EV secretion and in vitro functional capacity, thus highlighting the potential of substrate coatings to further the development of clinical EV production systems.

Genome-wide identification and analysis of epithelial-mesenchymal transition-related RNA-binding proteins and alternative splicing in a human breast cancer cell line

Exploring the mechanism of breast cancer metastasis and searching for new drug therapeutic targets are still the focuses of current research. RNA-binding proteins (RBPs) may affect breast cancer metastasis by regulating alternative splicing (AS) during epithelial-mesenchymal transition (EMT). We hypothesised that during EMT development in breast cancer cells, the expression level of RBPs and the gene AS pattern in the cell were significantly changed on a genome-wide scale. Using GEO database, this study identified differentially expressed RBPs and differential AS events at different stages of EMT in breast cancer cells. By establishing the correlation network of differential RBPs and differential AS events, we found that RBM47, PCBP3, FRG1, SRP72, RBMS3 and other RBPs may regulate the AS of ITGA6, ADGRE5, TNC, COL6A3 and other cell adhesion genes. By further analysing above EMT-related RBPs and AS in breast cancer tissues in TCGA, it was found that the expression levels of ADAT2, C2orf15, SRP72, PAICS, RBMS3, APOBEC3G, NOA1, ACO1 and the AS of TNC and COL6A3 were significantly correlated with the prognosis of breast cancer patients. The expression levels of all 8 RBPs were significantly different in breast cancer tissues without metastasis compared with normal breast tissues. Conclusively, eight RBPs such as RBMS3 and AS of TNC and COL6A3 could be used as predictors of breast cancer prognosis. These findings need to be further explored as possible targets for breast cancer treatment.

Influence of DNA-methylation at multiple stages of limb chondrogenesis

Precise regulation of gene expression is of utmost importance during cell fate specification. DNA methylation is a key epigenetic mechanism that plays a significant role in the regulation of cell fate by recruiting repression proteins or inhibiting the binding of transcription factors to DNA to regulate gene expression. Limb development is a well-established model for understanding cell fate decisions, and the formation of skeletal elements is coordinated through a sequence of events that control chondrogenesis spatiotemporally. It has been established that epigenetic control participates in cartilage maturation. However, further investigation is required to determine its role in the earliest stages of chondrocyte differentiation. This study investigates how the DNA methylation environment affects cell fate divergence during the early chondrogenic events. Our research has shown for the first time that inhibiting DNA methylation in interdigital tissue with 5-azacytidine results in the formation of an ectopic digit. This discovery suggested that DNA methylation dynamics could regulate the fate of cells between chondrogenesis and cell death during autopod development. Our in vitro findings indicate that DNA methylation at the early stages of chondrogenesis is integral in regulating condensation by controlling cell adhesion and proapoptotic genes. As a result, the dynamics of methylation and demethylation are crucial in governing chondrogenesis and cell death during different stages of limb chondrogenesis.

Characterization of transcriptional profiles associated with stress-induced neuronal activation in Arc-GFP mice

Chronic stress has become a predominant factor associated with a variety of psychiatric disorders, such as depression and anxiety, in both human and animal models. Although multiple studies have looked at transcriptional changes after social defeat stress, these studies primarily focus on bulk tissues, which might dilute important molecular signatures of social interaction in activated cells. In this study, we employed the Arc-GFP mouse model in conjunction with chronic social defeat (CSD) to selectively isolate activated nuclei (AN) populations in the ventral hippocampus (vHIP) and prefrontal cortex (PFC) of resilient and susceptible animals. Nuclear RNA-seq of susceptible vs. resilient populations revealed distinct transcriptional profiles linked predominantly with neuronal and synaptic regulation mechanisms. In the vHIP, susceptible AN exhibited increased expression of genes related to the cytoskeleton and synaptic organization. At the same time, resilient AN showed upregulation of cell adhesion genes and differential expression of major glutamatergic subunits. In the PFC, susceptible mice exhibited upregulation of synaptotagmins and immediate early genes (IEGs), suggesting a potentially over-amplified neuronal activity state. Our findings provide a novel view of stress-exposed neuronal activation and the molecular response mechanisms in stress-susceptible vs. resilient animals, which may have important implications for understanding mental resilience.

Abstract 1718: The lysine demethylase KDM2A regulates tumor cell clustering to potentiate metastasis

Abstract Approximately 70% of patients diagnosed with non-small cell lung cancer (NSCLC) are not eligible for curative resection, often due to disseminated disease at diagnosis. Thus, the advent of novel therapeutics, especially those efficacious for metastatic disease, is of primary importance. Metastasis correlates with epigenetic alterations that drive tumor plasticity and adaptive heterogeneity in response to the multiple microenvironments metastatic cells see, yet the molecular mechanisms underlying these epigenetic alterations remain poorly understood. We performed a functional genomic screen and identified the lysine 36 on histone H3 (H3K36) demethylase KDM2A as a mediator of in vivo and in vitro metastatic competence in multiple models of NSCLC. KDM2A depletion in highly metastatic NSCLC cell lines reduces their capacity to form multi-tumor cell clusters. In vivo, KDM2A depletion does not impact lung orthotopic tumor cell growth or the total number of circulating tumor cells (CTCs) but does reduce their ability to colonize distant metastatic sites. This is consistent with the fact that human CTCs found in clusters are more metastatic than CTCs which disseminate as single-cells. Because the molecular and biological consequences of H3K36 regulation are context dependent, we performed for the first time an integrated transcriptomic-epigenomic analysis of target gene regulation, KDM2A genomic binding, H3K36 methylation, and H3K27 acetylation, in metastatic cell clusters. KDM2A enhances the expression of cell adhesion and anti-oxidant genes, while suppressing inflammatory gene responses, and this regulation preferentially occurs in tumor cell clusters. Transcriptomic analysis of CTCs from patients confirms that KDM2A regulated transcriptional responses correlate with metastatic relapse across multiple cancer types. Moreover, KDM2A may function both as a transcriptional activator and repressor in metastatic clusters. As KDM2A encodes for several domains which can independently regulate E3-ubiqutin ligation, H3K36me2 demethylation, and DNA methylation, we have also performed a structure function analysis of K2MDA in the context of metastatic phenotypes. Thus, the distinct biochemical functions of KDM2A in relation to its regulation of CTC gene transcription and histone modification will also be presented. In conclusion, we have identified KDM2A as a novel regulator of NSCLC metastatic spread. The ability to inhibit KDM2A with small molecule inhibitors may be translated into effective therapeutic interventions for NSCLC patients with metastasis disease. Citation Format: Carolyn Kravitz, Kiran D. Patel, Wesley L. Cai, Anna Arnal-Estapé, Dejian Zhao, Emily Wingrove, Laura Stevens, Thomas F. Westbrook, Qin Yan, Don X. Nguyen. The lysine demethylase KDM2A regulates tumor cell clustering to potentiate metastasis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 1718.

Surface-Engineered Titanium with Nanoceria to Enhance Soft Tissue Integration Via Reactive Oxygen Species Modulation and Nanotopographical Sensing.

The design of implantable biomaterials involves precise tuning of surface features because the early cellular fate on such engineered surfaces is highly influenced by many physicochemical factors [roughness, hydrophilicity, reactive oxygen species (ROS) responsiveness, etc.]. Herein, to enhance soft tissue integration for successful implantation, Ti substrates decorated with uniform layers of nanoceria (Ce), called Ti@Ce, were optimally developed by a simple and cost-effective in situ immersion coating technique. The characterization of Ti@Ce shows a uniform Ce distribution with enhanced roughness (∼3-fold increase) and hydrophilicity (∼4-fold increase) and adopted ROS-scavenging capacity by nanoceria coating. When human gingival fibroblasts were seeded on Ti@Ce under oxidative stress conditions, Ti@Ce supported cellular adhesion, spreading, and survivability by its cellular ROS-scavenging capacity. Mechanistically, the unique nanocoating resulted in higher expression of amphiphysin (a nanotopology sensor), paxillin (a focal adhesion protein), and cell adhesive proteins (collagen-1 and fibronectin). Ti@Ce also led to global chromatin condensation by decreasing histone 3 acetylation as an early differentiation feature. Transcriptome analysis by RNA sequencing confirmed the chromatin remodeling, antiapoptosis, antioxidant, cell adhesion, and TGF-β signaling-related gene signatures in Ti@Ce. As key fibroblast transcription (co)factors, Ti@Ce promotes serum response factor and MRTF-α nucleus localization. Considering all of this, it is proposed that the surface engineering approach using Ce could improve the biological properties of Ti implants, supporting their functioning at soft tissue interfaces and utilization as a bioactive implant for clinical conditions such as peri-implantitis.