Cohesin Rad21 Research Articles

Abstract B021: Aneuploidy-associated cohesin RAD21 gains promote immune evasion in prostate cancers

Abstract Aneuploidy, characterized by imbalanced chromosome numbers, is a hallmark of cancer and is strongly correlated with lethal progression in prostate cancer. Our recent work identified that gains of chromosome 8q, the most frequently gained chromosome in aneuploidy prostate cancers, drive cancer progression, partially through the cohesin RAD21 gene located on the chr8q24 region. We demonstrated that increased RAD21 expression accelerates lethal progression and oncogenesis in both prostate cancer and Ewing sarcoma by alleviating oncogenic stress during early-stage oncogenesis in both cell line and organoid models. Therefore, we hypothesize that elevated RAD21 levels could enable cancer cells to evade immune surveillance by mitigating oncogenic stress and DNA damage. In this study, we developed isogenic prostate and breast cancer cell culture models with varying levels of RAD21. Using a natural killer (NK) cell co-culture assay, we observed that cells with elevated RAD21 expression were significantly less susceptible to NK-mediated cytotoxicity and exhibited increased survivorship when co-cultured with NK cells. These findings align with publicly available data showing that tumors with high RAD21 levels have reduced NK cell infiltration in prostate cancer. Our results suggest that increased RAD21 expression, commonly associated with chr8q gains, facilitates immune evasion in cancer cells, thereby promoting early-stage oncogenesis. Understanding the role of RAD21 in immune evasion could reveal novel therapeutic strategies targeting immune surveillance mechanisms in prostate cancer. Citation Format: Elise G. DeArment, Ruoxi W. Wang, Kate Lu, Xiaofeng A. Su, Andrew Elliott, Nicholas A. Zorko, Justin H. Hwang, Xiaofeng A. Su. Aneuploidy-associated cohesin RAD21 gains promote immune evasion in prostate cancers [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr B021.

Cohesin RAD21 Gene Promoter Methylation in Patients with Acute Myeloid Leukemia.

Aberrant gene promoter methylation is one of the hallmarks of Acute Myeloid Leukemia (AML). RAD21 is an important gene, implicated in sister chromatids cohesion, DNA repair, the regulation of gene transcription, apoptosis and hematopoiesis. In this study, we investigate the possible implication of RAD21 promoter methylation in AML pathogenesis using a cohort of AML patients and a cohort of healthy individuals. RAD21 promoter methylation was found in 24% of patients and in none of the controls (p = 0.023), indicating a possible contribution to AML development. Interestingly, a statistically higher frequency of RAD21 methylation was observed in patients with trisomy 8 (9/21, 42.9%, p = 0.021), while none of the patients with aberrations of chromosome 11 had RAD21 gene promoter methylation (0%, 0/11, p = 0.048). Patients with monosomal and complex karyotypes showed low frequencies of RAD21 methylation (7.7% and 15.4%, respectively) without reaching statistical significance. Moreover, ASXL1 mutations were not found to be associated with RAD21 methylation. This is the first study which provides evidence for a possible pathogenetic role of RAD21 promoter methylation in AML development and especially in AML with trisomy 8. Further studies of RAD21 promoter methylation in large series of different AML genetic subgroups may contribute to the elucidation of AML pathogenesis and to the identification of new epigenetic biomarkers with diagnostic and prognostic value.

Effects of the auxin-dependent degradation of the cohesin and condensin complexes on the repair of distant DNA double-strand breaks in mouse embryonic stem cells.

The SMC protein family, including cohesin and condensin I/II, plays a pivotal role in maintaining the topological structure of chromosomes and influences many cellular processes, notably the repair of double-stranded DNA breaks (DSBs). The cohesin complex impacts DSB repair by spreading γH2AX signal and containing DNA ends in close proximity by loop extrusion. Cohesin supports DNA stability by sister chromatid cohesion during the S/G2 phase, which limits DNA end mobility. Cohesin knockdown was recently shown to stimulate frequencies of genomic deletions produced by distant paired DSBs, but does not affect DNA repair of a single or close DSBs. We examined how auxin-inducible protein degradation of Rad21 (cohesin) or Smc2 (condensins I+II) changes the frequencies of rearrangements between paired distant DSBs in mouse embryonic stem cells (mESCs). We used Cas9 RNP nucleofection to generate deletions and inversions with high efficiency without additional selection. We determined optimal Neon settings and deletion appearance timings. Two strategies for auxin addition were tested (4 independent experiments in total). We examined deletion/inversion frequencies for two regions spanning 3.5 and 3.9 kbp in size. Contrary to expectations, in our setting, Rad21 depletion did not increase deletion/inversion frequencies, not even for the region with an active Ctcf boundary. We actually observed a 12 % decrease in deletions (but not inversions). At the same time, double condensin depletion (Smc2 degron line) demonstrated high biological variability between experiments, complicating the analysis, and requires additional examination in the future. TIDE analysis revealed that editing frequency was consistent (30-50 %) for most experiments with a minor decrease after auxin addition. In the end, we discuss the Neon/ddPCR method for deletion generation and detection in mESCs.

Abstract 75: CTCF and Rad21 Mediated Regulation of Gene Expression in Human-Induced Pluripotent Stem Cells-derived Endothelial Cells

Blood pressure (BP)-relevant non-coding SNPs identified by GWAS may influence the expression of distal protein-coding genes. Our previous study detected 195 SNPs (out of 26585) in CTCF-binding sites. CTCF and Cohesin are known to modulate cell-type-specific gene expression from a distance by forming chromatin loops. We hypothesized that both may regulate gene expression in BP-relevant cell types. To test this, we depleted CTCF and Rad21 (Cohesin subunit) in human induced pluripotent stem cells-derived endothelial cells (iEC) and performed genome-wide transcriptomic analysis. We detected 366 and 4184 differentially expressed genes (DEGs) in CTCF and Rad21 depleted iEC (CTCF-/Rad21-KD-iEC) compared to iEC control, respectively. Among them, 111 DEGs are common between the CTCF-KD and Rad21-KD-iEC, though majority showed opposite regulatory effects (Figure 1A). We found 5619 DEGs in the CTCF-KD vs Rad21-KD-iEC (Figure 1B). Pathway analysis detected elevated cell cycle (G2M checkpoint), DNA replication (E2F targets), and repair pathways in Rad21-KD compared to the CTCF-KD-iEC. Rad21 plays an important role in chromosome partitioning and repair, so its depletion may cause dysregulation of these pathways. While the CTCF-KD-iEC showed enrichment of the Epithelial-to-mesenchymal transition (EMT), inflammatory (IFN-gamma, IFN-alpha), and hypoxia pathways (Figure 1C). As CTCF maintains the chromosome boundaries, CTCF-KD may affect chromatin compactness and trigger abnormal gene expression related to these pathways. In conclusion, our study detected different effects of depletion of CTCF and Rad21 on gene expression in a BP-relevant cell type. The findings provide a basis to explore the role of chromatin looping in BP-relevant gene regulation.

Genetic mutation profiling reveals biomarkers for targeted therapy efficacy and prognosis in non-small cell lung cancer

IntroductionThe genetic heterogeneity of non-small cell lung cancer (NSCLC) with epidermal growth factor receptor (EGFR) mutations may affect clinical responses and outcomes to EGFR tyrosine kinase inhibitors (EGFR-TKIs). This study aims to investigate the genomic factors that influence the efficacy and clinical outcomes of first-line, second-line and third-line treatments in NSCLC and explore the heterogeneity of resistance mechanisms. Materials and methodsThis real-world study comprised 65 patients with EGFR mutant NSCLC. Molecular alterations were detected using a customized DNA panel before and after administering targeted therapy. The efficacy and prognosis of each treatment line were evaluated. ResultsIn first-generation EGFR-TKIs treatment, gefitinib showed favorable efficacy compared to icotinib and erlotinib, particularly in patients with EGFR L858R mutations. The resistance mechanisms to first-generation EGFR-TKIs varied among different EGFR mutation cohorts and different first-generation EGFR-TKIs. In second-line EGFR-TKIs treatment, EPH receptor A3 (EPHA3), IKAROS family zinc finger 1 (IKZF1), p21 (RAC1) activated kinase 5 (PAK5), DNA polymerase epsilon, catalytic subunit (POLE), RAD21 cohesin complex component (RAD21) and RNA binding motif protein 10 (RBM10) mutations were markedly associated with poorer progression-free survival (PFS). Notably, EPHA3, IKZF1 and RBM10 were identified as independent predictors of PFS. The mechanisms of osimertinib resistance exhibited heterogeneity, with a higher proportion of non-EGFR-dependent resistant mutations. In third-line treatments, the combination of osimertinib and anlotinib demonstrated superior efficacy compared to other regimens. Glutamate ionotropic receptor NMDA type subunit 2A (GRIN2A) mutation was an independent risk indicator of shorter OS following third-line treatments. ConclusionsComprehending the tumor evolution in NSCLC is advantageous for assessing the efficacy and prognosis at each stage of treatment, providing valuable insights to guide personalized treatment decisions for patients.

Abstract B059: Identification of cohesin RAD21 as a novel aneuploidy-associated marker driving prostate cancer progression by mitigating toxic DNA damage

Abstract Prostate cancer (PCa) is one of the most common cancers among men, leading to the second cause of death for men with cancers in the US. Aneuploidy, featured by imbalanced chromosome numbers, is a hallmark of cancer. Epidemiology studies on primary PCa cohorts of Physicians' Health Study and Health Professionals Follow-up Study (PHS and HPFS) have shown that high levels of whole-genome aneuploidy correlate with lethal progression in PCa. However, the detail mechanisms of how aneuploidy drives aggressiveness of PCa are still unclear. Here, we used the case of chromosome 8q (chr 8q, the long arm of chr 8) gain to study aneuploidy-associated prostatic malignancies. Chr 8q gains are the most frequently gain events that occur in around 23% of PCa cases. By using the PHS and HPFS cohorts, we modeled the increased expression of each gene located on chr 8q, for predicting the risks for lethal progression, and obtained the odds ratio (OR) for each. Then, we ranked the ORs for lethal progression and identified several important genes highly associated with lethality when overexpressed. Among them, the cohesin subunit gene, RAD21, is one of the top associators. Increased RAD21 mRNA level, per se, is highly correlated with lethality in all PCa cases, and the lethality is synergistically aggravated in the cases with both increased RAD21 expression and chr 8q gains. indicating that RAD21 cooperates with other chr 8q genes to drive cancer progression and chr 8q gains. To determine how RAD21 overexpression promotes PCa, we studied the effect of overexpression of RAD21 in early prostatic oncogenic events. We utilized the isogenic mouse prostate organoid models carrying an inducible the fusion-oncogene, TMPRSS2-ERG (T-ERG), which 50% of PCa cases harbor. We found that induction of T-ERG leads to a strong oncogenic replication stress at an early stage. Such stress results in an increase in apoptosis and growth impairment in these primary organoids. Overexpression of RAD21, mimicking the chr 8q gain situation, mitigates such replication stress and rescues the growth defect caused by T-ERG. These data suggest the role of increased RAD21 in promoting oncogenic growth of PCa cells by reducing oncogenic toxicity at an early stage. In addition, we showed that such role of RAD21 overexpression sustains in the more advanced cancerous organoid (ERG positive and PTEN loss) and promotes the growth of the cancer organoids. Consistently, increased RAD21 expression correlates with increase proliferative markers in human prostate cancer cases. In conclusion, we identified that overexpression of multiple chr 8q genes are correlated with lethal progression in primary PCa, and RAD21 is one of such genes. Increased RAD21 plays a fundamental role in reducing toxic DNA damage caused by prostatic oncogenesis. Citation Format: Xiaofeng A Su, Konrad H Stopsack, Daniel R Schmidt, Duanduan Ma, Zhe Li, Thomas Janas, Matthew G Vander Heiden, Kathryn L Penny, Paul A Scheet, Tamara L Lotan, Angelika Amon, Lorelei A Mucci. Identification of cohesin RAD21 as a novel aneuploidy-associated marker driving prostate cancer progression by mitigating toxic DNA damage [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr B059.

Studying the effect of hyperoside on recovery from cyclophosphamide induced oligoasthenozoospermia

Oligoasthenozoospermia is becoming a serious problem, but effective prevention or treatment is lacking. Hyperoside, one of the main active ingredients in traditional Chinese medicine, may be effective in the treatment of oligoasthenozoospermia. In this study, we used cyclophosphamide (CTX: 50 mg/kg) to establish a mouse model of Oligoasthenozoospermia to investigate the therapeutic effect of hyperoside (30 mg/kg) on CTX-induced oligoasthenozoospermia. All mice were divided into four groups: blank control group (Control), treatment control group (Hyp), disease group (CTX) and treatment group (CTX + H). Mice body weight, testicular weight, sperm parameters and testicular histology were used to assess the reproductive capacity of mice and to explore the underlying mechanism of hyperoside in the treatment of oligoasthenozoospermia by assessing hormone levels, protein levels of molecules related to hormone synthesis and transcript levels of important genes related to spermatogenesis. Treatment with hyperoside significantly improved sperm density, sperm viability and testicular function compared to untreated oligoasthenozoospermia mice. In mechanism, treatment with hyperoside resulted in significant improvement in pathological changes in spermatogenic tubules, with an increase in testosterone production, and upregulations of Protein Kinase CAMP-Activated Catalytic Subunit Beta (PRKACB), Steroidogenic Acute Regulatory Protein (STAR), and Cytochrome P450 Family 17 Subfamily A Member 1 (CYP17A1) for testosterone production. Hyperoside also promoted the cell cycle of germ cells and up-regulated meiosis and spermatogenesis-related genes, including DNA Meiotic Recombinase 1 (Dmc1), Ataxia telangiectasia mutated (Atm) and RAD21 Cohesin Complex Component (Rad21). In conclusion, hyperoside exerted protective effects on oligoasthenozoospermia mice by regulating testosterone production, meiosis and sperm maturation of germ cells.

Mapping separase-mediated cleavage in situ.

Separase is a protease that performs critical functions in the maintenance of genetic homeostasis. Among them, the cleavage of the meiotic cohesin during meiosis is a key step in producing gametes in eukaryotes. However, the exact chromosomal localization of this proteolytic cleavage was not addressed due to the lack of experimental tools. To this end, we developed a method based on monoclonal antibodies capable of recognizing the predicted neo-epitopes produced by separase-mediated proteolysis in the RAD21 and REC8 cohesin subunits. To validate the epigenomic strategy of mapping cohesin proteolysis, anti-RAD21 neo-epitopes antibodies were used in ChIP-On-ChEPseq analysis of human cells undergoing mitotic anaphase. Second, a similar analysis applied for mapping of REC8 cleavage in germline cells in Macaque showed a correlation with a subset of alpha-satellites and other repeats, directly demonstrating that the site-specific mei-cohesin proteolysis hotspots are coincident but not identical with centromeres. The sequences for the corresponding immunoglobulin genes show a convergence of antibodies with close specificity. This approach could be potentially used to investigate cohesin ring opening events in other chromosomal locations, if applied to single cells.

Cohesin RAD21 Gene Promoter Methylation Correlated with Better Prognosis in Breast Cancer Patients

RAD21 plays multiple roles in numerous cancers. In breast cancer (BC), a high level of RAD21 correlates with poor disease outcomes and resistance to chemotherapy. However, data regarding RAD21 promoter methylation in BC tissue and its correlation with clinical outcomes in patients with BC remain limited. Here, we investigated the clinicopathological features associated with the methylation status of RAD21 in BC to figure out its possible role in pathogenesis and the formation of breast carcinogenesis. The methylation status of the RAD21 gene was significantly associated with better clinical outcomes in patients with BC.

MiR-122 Inhibits the Cervical Cancer Development by Targeting the Oncogene RAD21.

Cervical cancer (CC) is one of the most frequentlydiagnosed tumors in female. miR-122 has been proved to be dominant in CC. The particular role of miR-122 in CC is unclear. Thus, we attempted to investigate the prognostic role of miR-122 in CC. We used the database of Kaplan-Meier curve plot. Growth and apoptosis of C33A cells were detected by CCK-8, colony formation assay, transwell assays and flow cytometry analysis. The target gene of miR-122 was identified using bioinformatics, q-PCR, western blot and luciferase assay. It showed that CC patients with overexpression of miR-122 have a better prognosis in the Kaplan-Meier plot database analysis. Overexpressed miR-122 inhibited the malignant growth and induced apoptosis of CC. miR-122 targeting of RAD21 cohesin complex component (RAD21) was identified using bioinformatics, Q-PCR, western blot and luciferase assay analyses. Moreover, we found miR-122 conduct its functions via RAD21 via the PI3K/AKT signaling pathway. Importantly, overexpression of RAD21 restored the roles of miR-122 in CC. Our data suggested that miR-122 could block malignant growth and promoted apoptosis by targeting RAD21 in CC. Our finding indicates miR-122 could potentially participate in the pathogenesis and be a biomarker or the potential therapeutic target of CC.

Balancing cohesin eviction and retention prevents aberrant chromosomal interactions, Polycomb-mediated repression, and X-inactivation

Depletion of architectural factors globally alters chromatin structure but only modestly affects gene expression. We revisit the structure-function relationship using the inactive X chromosome (Xi) as a model. We investigate cohesin imbalances by forcing its depletion or retention using degron-tagged RAD21 (cohesin subunit) or WAPL (cohesin release factor). Cohesin loss disrupts the Xi superstructure, unveiling superloops between escapee genes with minimal effect on gene repression. By contrast, forced cohesin retention markedly affects Xi superstructure, compromises spreading of Xist RNA-Polycomb complexes, and attenuates Xi silencing. Effects are greatest at distal chromosomal ends, where looping contacts with the Xist locus are weakened. Surprisingly, cohesin loss creates an Xi superloop, and cohesin retention creates Xi megadomains on the active X chromosome. Across the genome, a proper cohesin balance protects against aberrant inter-chromosomal interactions and tempers Polycomb-mediated repression. We conclude that a balance of cohesin eviction and retention regulates X inactivation and inter-chromosomal interactions across the genome.

Abstract 1081: DNA methylation at the intersect of chromatin structure and transcriptome diversity

Abstract Dysregulation of DNA methylation and mRNA alternative cleavage and polyadenylation (APA) are both prevalent in cancer, but they have been studied as independent processes. We discovered a DNA methylation regulated APA mechanism when we compared genome-wide DNA methylation and polyadenylation site usage between DNA methylation-competent and DNA methylation-deficient cells. Here we show that removal of DNA methylation enables CTCF binding and recruitment of the cohesin complex, which in turn, promotes proximal polyadenylation site usage. In this DNA de-methylated context, depletion of the RAD21 cohesin complex component can recover distal polyadenylation site usage. We also confirmed, using chromosomal conformation capture (3C), that CTCF and the cohesin complex mediate chromatin loops in the absence of DNA methylation to modulate polyadenylation site usage. Leveraging data from The Cancer Genome Atlas, we authenticated the relationship between DNA methylation and mRNA polyadenylation isoform expression in vivo. This DNA methylation regulated APA mechanism demonstrates how aberrant DNA methylation impacts transcriptome diversity and highlights the potential sequelae of global DNA methylation inhibition as a cancer treatment. Citation Format: Angela H. Ting, Vishal Nanavaty, Elizabeth Abrash, Byron Lee, Emily Fink, Tae Hyun Hwang, Changjin Hong. DNA methylation at the intersect of chromatin structure and transcriptome diversity [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 1081.

DNA Methylation Regulates Alternative Polyadenylation via CTCF and the Cohesin Complex

Dysregulation of DNA methylation and mRNA alternative cleavage and polyadenylation (APA) are both prevalent in cancer and have been studied as independent processes. We discovered a DNA methylation-regulated APA mechanism when we compared genome-wide DNA methylation and polyadenylation site usage between DNA methylation-competent and DNA methylation-deficient cells. Here, we show that removal of DNA methylation enables CTCF binding and recruitment of the cohesin complex, which, in turn, form chromatin loops that promote proximal polyadenylation site usage. In this DNA demethylated context, either deletion of the CTCF binding site or depletion of RAD21 cohesin complex protein can recover distal polyadenylation site usage. Using data from The Cancer Genome Atlas, we authenticated the relationship between DNA methylation and mRNA polyadenylation isoform expression invivo. This DNA methylation-regulated APA mechanism demonstrates how aberrant DNA methylation impacts transcriptome diversity and highlights the potential sequelae of global DNA methylation inhibition as a cancer treatment.

Dysregulation of NIPBL leads to impaired RUNX1 expression and haematopoietic defects.

The transcription factor RUNX1, a pivotal regulator of HSCs and haematopoiesis, is a frequent target of chromosomal translocations, point mutations or altered gene/protein dosage. These modifications lead or contribute to the development of myelodysplasia, leukaemia or platelet disorders. A better understanding of how regulatory elements contribute to fine‐tune the RUNX1 expression in haematopoietic tissues could improve our knowledge of the mechanisms responsible for normal haematopoiesis and malignancy insurgence. The cohesin RAD21 was reported to be a regulator of RUNX1 expression in the human myeloid HL60 cell line and during primitive haematopoiesis in zebrafish. In our study, we demonstrate that another cohesin, NIPBL, exerts positive regulation of RUNX1 in three different contexts in which RUNX1 displays important functions: in megakaryocytes derived from healthy donors, in bone marrow samples obtained from adult patients with acute myeloid leukaemia and during zebrafish haematopoiesis. In this model, we demonstrate that alterations in the zebrafish orthologue nipblb reduce runx1 expression with consequent defects in its erythroid and myeloid targets such as gata1a and spi1b in an opposite way to rad21. Thus, also in the absence of RUNX1 translocation or mutations, additional factors such as defects in the expression of NIPBL might induce haematological diseases.

Effects of the microtubule nucleator Mto1 on chromosomal movement, DNA repair, and sister chromatid cohesion in fission yeast.

Although the function of microtubules (MTs) in chromosomal segregation during mitosis is well characterized, much less is known about the role of MTs in chromosomal functions during interphase. In the fission yeast Schizosaccharomyces pombe, dynamic cytoplasmic MT bundles move chromosomes in an oscillatory manner during interphase via linkages through the nuclear envelope (NE) at the spindle pole body (SPB) and other sites. Mto1 is a cytoplasmic factor that mediates the nucleation and attachment of cytoplasmic MTs to the nucleus. Here, we test the function of these cytoplasmic MTs and Mto1 on DNA repair and recombination during interphase. We find that mto1Δ cells exhibit defects in DNA repair and homologous recombination (HR) and abnormal DNA repair factory dynamics. In these cells, sister chromatids are not properly paired, and binding of Rad21 cohesin subunit along chromosomal arms is reduced. Our findings suggest a model in which cytoplasmic MTs and Mto1 facilitate efficient DNA repair and HR by promoting dynamic chromosomal organization and cohesion in the nucleus.

DNA topoisomerase IIα and RAD21 cohesin complex component are predicted as potential therapeutic targets in bladder cancer.

Cancer is essentially a genetic disease. Accumulated gene mutations accelerate genome instability, which eventually leads to uncontrollable growth of the tumor. Bladder cancer is the most common form of urinary tract cancer. This form of cancer has a poor prognosis due to its clinical heterogeneity and molecular diversity. Despite recent scientific advances, the knowledge and treatment of bladder cancer still lags behind that of other types of solid tumor. In the present study, available large data portals and other studies were used to obtain clinically relevant information, and the data were systematically processed to decipher the genes associated with bladder cancer. Genes associated with the survival time of patients with bladder cancer were successfully identified. The genes were enriched in common biological processes and pathways, and upregulated in tumor samples from patients. Among the top genes identified as associated with good or poor survival in bladder cancer, DNA topoisomerase IIα (TOP2α) and RAD21 cohesin complex component (RAD21) were also increased in bladder cancer tissues and cell lines. Therefore, TOP2α and RAD21 could be used as potential therapeutic targets in bladder cancer.

RNA Stabilizes Transcription-Dependent Chromatin Loops Induced By Nuclear Hormones

We show that transcription induced by nuclear receptors for estrogen (E2) or retinoic acid (RA) is associated with formation of chromatin loops that juxtapose the 5’ end (containing the promoter) with the enhancer and the 3′ polyA addition site of the target gene. We find three loop configurations which change as a function of time after induction: 1. RA or E2-induced loops which connect the 5′ end, the enhancer and the 3′ end of the gene, and are stabilized by RNA early after induction; 2. E2-independent loops whose stability does not require RNA; 3. Loops detected only by treatment of chromatin with RNAse H1 prior to hormonal induction. RNAse H1 digests RNA that occludes the relevant restriction sites, thus preventing detection of these loops. R-loops at the 5′ and 3′ ends of the RA or E2-target genes were demonstrated by immunoprecipitation with anti-DNA-RNA hybrid antibodies as well as by sensitivity to RNAse H1. The cohesin RAD21 subunit is preferentially recruited to the target sites upon RA or E2 induction of transcription. RAD21 binding to chromatin is eliminated by RNAse H1. We identified E2-induced and RNase H1-sensitive antisense RNAs located at the 5′ and 3′ ends of the E2-induced transcription unit which stabilize the loops and RAD21 binding to chromatin. This is the first report of chromatin loops that form after gene induction that are maintained by RNA:DNA hybrids.

Dysregulation of the cohesin subunit RAD21 by Hepatitis C virus mediates host-virus interactions.

Hepatitis C virus (HCV) infection is the leading cause of chronic hepatitis, which often results in liver fibrosis, cirrhosis and hepatocellular carcinoma (HCC). HCV possesses an RNA genome and its replication is confined to the cytoplasm. Yet, infection with HCV leads to global changes in gene expression, and chromosomal instability (CIN) in the host cell. The mechanisms by which the cytoplasmic virus affects these nuclear processes are elusive. Here, we show that HCV modulates the function of the Structural Maintenance of Chromosome (SMC) protein complex, cohesin, which tethers remote regions of chromatin. We demonstrate that infection of hepatoma cells with HCV leads to up regulation of the expression of the RAD21 cohesin subunit and changes cohesin residency on the chromatin. These changes regulate the expression of genes associated with virus-induced pathways. Furthermore, siRNA downregulation of viral-induced RAD21 reduces HCV infection. During mitosis, HCV infection induces hypercondensation of chromosomes and the appearance of multi-centrosomes. We provide evidence that the underlying mechanism involves the viral NS3/4 protease and the cohesin regulator, WAPL. Altogether, our results provide the first evidence that HCV induces changes in gene expression and chromosome structure of infected cells by modulating cohesin.

Possible Molecular Mechanisms for the Roles of MicroRNA-21 Played in Lung Cancer.

Background:We aimed to find the possible molecular mechanisms for the roles of microRNA-21 underlying lung cancer development.Methods:MicroRNA-21-5p inhibitor was transfected into A549 cells. Total RNA was isolated from 10 samples, including 3 in control group (A549 cells), 3 in negative control group (A549 cells transferred with microRNA-21 negative control), and 4 in SH group (A549 cells transferred with microRNA-21 inhibitor), followed by RNA sequencing. Then, differentially expressed genes were screened for negative control group versus control group, SH group versus control group, and SH group versus negative control group. Functional enrichment analyses, protein–protein interaction network, and modules analyses were conducted. Target genes of hsa-miR-21-5p and transcription factors were predicted, followed by the regulatory network construction.Results:Minichromosome maintenance 10 replication initiation factor and cell division cycle associated 8 were important nodes in protein–protein interaction network with higher degrees. Cell division cycle associated 8 was enriched in cell division biological process. Furthermore, maintenance 10 replication initiation factor and cell division cycle associated 8 were significantly enriched in cluster 1 and micro-RNA-transcription factor-target genes regulating network. In addition, transcription factor Dp family member 3 (transcription factor of maintenance 10 replication initiation factor and cell division cycle associated 8) and RAD21 cohesin complex component (transcription factor of maintenance 10 replication initiation factor) were target genes of hsa-miR-21-5p.Conclusions:Micro-RNA-21 may play a key role in lung cancer partly via maintenance 10 replication initiation factor and cell division cycle associated 8. Furthermore, microRNA-21 targeted cell division cycle associated 8 and then played roles in lung cancer via the process of cell division. Transcription factor Dp family member 3 and RAD21 cohesin complex component are important transcription factors in microRNA-21-interfered lung cancer.

Modeling Cornelia de Lange syndrome in vitro and in vivo reveals a role for cohesin complex in neuronal survival and differentiation.

Cornelia de Lange syndrome (CdLS), which is reported to affect ∼1 in 10000 to 30000 newborns, is a multisystem organ developmental disorder with relatively mild to severe effects. Among others, intellectual disability represents an important feature of this condition. CdLS can result from mutations in at least five genes: nipped-B-like protein, structural maintenance of chromosomes 1A, structural maintenance of chromosomes 3, RAD21 cohesin complex component and histone deacetylase 8 (HDAC8). It is believed that mutations in these genes cause CdLS by impairing the function of the cohesin complex (to which all the aforementioned genes contribute to the structure or function), disrupting gene regulation during critical stages of early development. Since intellectual disorder might result from alterations in neural development, in this work, we studied the role of Hdac8 gene in mouse neural stem cells (NSCs) and in vertebrate (Danio rerio) brain development by knockdown and chemical inhibition experiments. Underlying features of Hdac8 deficiency is an increased cell death in the developing neural tissues, either in mouse NSCs or in zebrafish embryos.