Transcriptional Regulatory Complex Research Articles

A stepwise mode of TGFβ-SMAD signaling and DNA methylation regulates naïve-to-primed pluripotency and differentiation

The formation of transcription regulatory complexes by the association of Smad4 with Smad2 and Smad3 (Smad2/3) is crucial in the canonical TGFβ pathway. Although the central requirement of Smad4 as a common mediator is emphasized in regulating TGFβ signaling, it is not obligatory for all responses. The role of Smad2/3 independently of Smad4 remains understudied. Here, we introduce a stepwise paradigm in which Smad2/3 regulate the lineage priming and differentiation of mouse embryonic stem cells (mESCs) by collaboration with different effectors. During the naïve-to-primed transition, Smad2/3 upregulate DNA methyltransferase 3b (Dnmt3b), which establishes the proper DNA methylation patterns and, in turn, enables Smad2/3 binding to the hypomethylated centers of promoters and enhancers of epiblast marker genes. Consequently, in the absence of Smad2/3, Smad4 alone cannot initiate epiblast-specific gene transcription. When primed epiblast cells begin to differentiate, Dnmt3b becomes less actively engaged in global genome methylation, and Smad4 takes over the baton in this relay race, forming a complex with Smad2/3 to support mesendoderm induction. Thus, mESCs lacking Smad4 can undergo the priming process but struggle with the downstream differentiation. This work sheds light on the intricate mechanisms underlying TGFβ signaling and its role in cellular processes.

A multilineage screen identifies actionable synthetic lethal interactions in human cancers.

Cancers are driven by alterations in diverse genes, creating dependencies that can be therapeutically targeted. However, many genetic dependencies have proven inconsistent across tumors. Here we describe SCHEMATIC, a strategy to identify a core network of highly penetrant, actionable genetic interactions. First, fundamental cellular processes are perturbed by systematic combinatorial knockouts across tumor lineages, identifying 1,805 synthetic lethal interactions (95% unreported). Interactions are then analyzed by hierarchical pooling, revealing that half segregate reliably by tissue type or biomarker status (51%) and a substantial minority are penetrant across lineages (34%). Interactions converge on 49 multigene systems, including MAPK signaling and BAF transcriptional regulatory complexes, which become essential on disruption of polymerases. Some 266 interactions translate to robust biomarkers of drug sensitivity, including frequent genetic alterations in the KDM5C/6A histone demethylases, which sensitize to inhibition of TIPARP (PARP7). SCHEMATIC offers a context-aware, data-driven approach to match genetic alterations to targeted therapies.

Mechanisms of Action of the Herba Salviae Chinensis-Fructus Akebiae Pair in the Treatment of Non-small Cell Lung Cancer based on a Network Pharmacology Study

Objective: To study the active ingredients and mechanism of action of "Herba Salviae Chinensis-Fructus Akebiae" drug pair in the treatment of non-small cell lung cancer (NSCLC) by using network pharmacology to provide theoretical basis for clinical application. Methods: The TCMSP (Traditional Chinese Medicine Systematic Pharmacology Database and Analysis Platform) was used to obtain the active ingredients and targets of "Herba Salviae Chinensis-Fructus Akebiae", and the results were analyzed by the Genecard (https://genecard, org/) database, the Online Mendelian Inheritance Network (OMI), the Genecard database, the Genecard database, and the Online Mendelian Inheritance Network. We searched the Genecard (https://genecard, org/) database and the Online Mendelian Inheritance in Man (OMIM) database (http://omim. org/) for non-small cell lung cancer (NSCLC) disease targets by selecting "NSCLC" as a keyword, and then obtained the results of the "Herba Salviae Chinensis-Fructus Akebiae" drug pair by using venn. We used venn to obtain the intersecting targets of the drug pair "Herba Salviae Chinensis-Fructus Akebiae" and NSCLC, and then used the STRING database and Cytoscape to construct a common target visualization network diagram. The gene (GO) enrichment analysis and KEGG enrichment analysis were realized with the help of metascape database and Microbiology platform. Results: Five active ingredients of Ishiminokan-Precipitant were obtained, and 3695 non-small cell lung cancer targets and 123 common targets were obtained. GO analysis showed that the process of GO enrichment was mainly related to the regulation of responses to inorganic substances, transcriptional regulatory complexes, cytokine receptor binding, etc. KEGG enrichment showed that the process of KEGG enrichment was mainly through Pathways in Cancer, ILRT, and cytokine receptor binding. KEGG enrichment showed that KEGG mainly exerted anti-cancer effects through pathways in cancer and IL-17 signaling pathway. Conclusion: Using the method of network pharmacology, it is proved that the drug pair "Herba Salviae Chinensis-Fructus Akebiae" can exert therapeutic effects on NSCLC through multi-components, multi-targets, and multi-pathways, and provides the theoretical basis for the clinical application.

Structural studies of intrinsically disordered MLL-fusion protein AF9 in complex with peptidomimetic inhibitors.

AF9 (MLLT3) and its paralog ENL(MLLT1) are members of the YEATS family of proteins with important role in transcriptional and epigenetic regulatory complexes. These proteins are two common MLL fusion partners in MLL-rearranged leukemias. The oncofusion proteins MLL-AF9/ENL recruit multiple binding partners, including the histone methyltransferase DOT1L, leading to aberrant transcriptional activation and enhancing the expression of a characteristic set of genes that drive leukemogenesis. The interaction between AF9 and DOT1L is mediated by an intrinsically disordered C-terminal ANC1 homology domain (AHD) in AF9, which undergoes folding upon binding of DOT1L and other partner proteins. We have recently reported peptidomimetics that disrupt the recruitment of DOT1L by AF9 and ENL, providing a proof-of-concept for targeting AHD and assessing its druggability. Intrinsically disordered proteins, such as AF9 AHD, are difficult to study and characterize experimentally on a structural level. In this study, we present a successful protein engineering strategy to facilitate structural investigation of the intrinsically disordered AF9 AHD domain in complex with peptidomimetic inhibitors by using maltose binding protein (MBP) as a crystallization chaperone connected with linkers of varying flexibility and length. The strategic incorporation of disulfide bonds provided diffraction-quality crystals of the two disulfide-bridged MBP-AF9 AHD fusion proteins in complex with the peptidomimetics. These successfully determined first series of 2.1-2.6 Å crystal complex structures provide high-resolution insights into the interactions between AHD and its inhibitors, shedding light on the role of AHD in recruiting various binding partner proteins. We show that the overall complex structures closely resemble the reported NMR structure of AF9 AHD/DOT1L with notable difference in the conformation of the β-hairpin region, stabilized through conserved hydrogen bonds network. These first series of AF9 AHD/peptidomimetics complex structures are providing insights of the protein-inhibitor interactions and will facilitate further development of novel inhibitors targeting the AF9/ENL AHD domain.

Downregulation of Glis3 in INS1 cells exposed to chronically elevated glucose contributes to glucotoxicity-associated β cell dysfunction

ABSTRACT Chronically elevated levels of glucose are deleterious to pancreatic β cells and contribute to β cell dysfunction, which is characterized by decreased insulin production and a loss of β cell identity. The Krüppel-like transcription factor, Glis3 has previously been shown to positively regulate insulin transcription and mutations within the Glis3 locus have been associated with the development of several pathologies including type 2 diabetes mellitus. In this report, we show that Glis3 is significantly downregulated at the transcriptional level in INS1 832/13 cells within hours of being subjected to high glucose concentrations and that diminished expression of Glis3 is at least partly attributable to increased oxidative stress. CRISPR/Cas9-mediated knockdown of Glis3 indicated that the transcription factor was required to maintain normal levels of both insulin and MafA expression and reduced Glis3 expression was concomitant with an upregulation of β cell disallowed genes. We provide evidence that Glis3 acts similarly to a pioneer factor at the insulin promoter where it permissively remodels the chromatin to allow access to a transcriptional regulatory complex including Pdx1 and MafA. Finally, evidence is presented that Glis3 can positively regulate MafA transcription through its pancreas-specific promoter and that MafA reciprocally regulates Glis3 expression. Collectively, these results suggest that decreased Glis3 expression in β cells exposed to chronic hyperglycemia may contribute significantly to reduced insulin transcription and a loss of β cell identity.

Longitudinal profiling of human androgenotes through single-cell analysis unveils paternal gene expression dynamics in early embryo development.

How do transcriptomics vary in haploid human androgenote embryos at single cell level in the first four cell cycles of embryo development? Gene expression peaks at the fourth cell cycle, however some androcytes exhibit unique transcriptional behaviors. The developmental potential of an embryo is determined by the competence of the oocyte and the sperm. However, studies of the contribution of the paternal genome using pure haploid androgenotes are very scarce. This study was performed analyzing the single-cell transcriptomic sequencing of 38 androcytes obtained from 10 androgenote bioconstructs previously produced in vitro (de Castro et al., 2023). These results were analyzed through different bioinformatics software such as g: Profiler, GSEA, Cytoscape, and Reactome. Single cell sequencing was used to obtain the transcriptomic profiles of the different androcytes. The results obtained were compared between the different cycles studied using the DESeq2 program and functional enrichment pathways using g: Profiler, Cytoscape, and Reactome. A wave of paternally driven transcriptomic activation was found during the third-cell cycle, with 1128 upregulated and 225 downregulated genes and the fourth-cell cycle, with 1373 upregulated and 286 downregulated genes, compared to first-cell cycle androcytes. Differentially expressed routes related to cell differentiation, DNA-binding transcription, RNA biosynthesis and RNA polymerase II transcription regulatory complex, and cell death were found in the third and fourth with respect to the first-cell cycle. Conversely, in the fourth cell cycle, 153 downregulated and 332 upregulated genes were found compared with third cell cycle, associated with differentially expressed processes related to E-box binding and zinc finger protein 652 (ZNF652) transcription factor. Further, significant overexpression of LEUTX, PRAMEF1, DUXA, RFPL4A, TRIM43, and ZNF675 found in androgenotes, compared to biparental embryos, highlights the paternal contributions to zygote genome activation. All raw sequencing data are available through the Gene Expression Omnibus (GEO) under accessions number: GSE216501. Extrapolation of biological events from uniparental constructs to biparental embryos should be done with caution. Maternal and paternal genomes do not act independently of each other in a natural condition. The absence of one genome may affect gene transcription of the other. In this sense, the haploid condition of the bioconstructs could mask the transcriptomic patterns of the single cells. The results obtained demonstrated the level of involvement of the human paternal haploid genome in the early stages of embryo development as well as its evolution at the transcriptomic level, laying the groundwork for the use of these bioconstructs as reliable models to dispel doubts about the genetic role played by the paternal genome in the early cycles of embryo development. This study was funded by Instituto de Salud Carlos III (ISCIII) through the project 'PI22/00924', co-funded by European Regional Development Fund (ERDF); 'A way to make Europe'. F.D. was supported by the Spanish Ministry of Economy and Competitiveness through the Miguel Servet program (CPII018/00002). M.J.E. was supported by Instituto de Salud Carlos III (PI19/00577 [M.J.E.]) and FI20/00086. P.dC. was supported by a predoctoral grant for training in research into health (PFIS PI19/00577) from the Instituto de Salud Carlos III. All authors declare having no conflict of interest with regard to this trial.

Abstract 1690: LSD1 and CoREST2 demethylate STAT3 to promote enteroendocrine cell differentiation in mucinous colorectal cancer

Abstract Across different cancer types, tumor heterogeneity has been shown to drive tumor progression, metastasis, and therapeutic resistance. Adenocarcinoma to neuroendocrine lineage transition is an emergent mechanism of targeted therapy resistance in several cancer types, including lung and prostate cancer. Therefore, understanding the dynamics and mechanisms driving neuroendocrine cell fates in cancer is critical. Mucinous colorectal cancer accounts for upwards of 20% of colorectal cancer cases and is characterized by tumors with mucous accounting for at least 50% of the tumor volume. The normal colon epithelium consists of several specialized cell types, including hormone secreting enteroendocrine cells (EECs), which are the neuroendocrine cell of the intestine. We have previously shown that EEC progenitors are enriched in mucinous colorectal cancer and promote cancer cell survival via secreted factors. Additionally, we have shown that lysine specific demethylase 1 (LSD1) promotes EEC differentiation in these tumors; however, the mechanism by which LSD1 promotes EEC differentiation has remained unknown. Typically to carry out its enzymatic function, LSD1 must be a part of a transcriptional regulatory complex. One such complex is the CoREST complex, which contains LSD1, HDAC1, and one of three CoREST protein family members. Here we report that LSD1 and CoREST2 promote EEC differentiation by demethylating the transcription factor signal transducer and activator of transcription 3 (STAT3) to promote STAT3 chromatin binding. Additionally, we demonstrate that knocking down CoREST2 decreases tumor growth and lung metastases of mucinous colorectal cancer cells injected orthotopically into the colons of immunocompromised mice. Furthermore, we utilized single cell multi-omics that combines single cell RNA sequencing with single cell ATAC sequencing to show that during EEC differentiation there is an increase in chromatin accessibility at regulatory regions of known EEC-promoting transcription factors. Finally, through our single cell multi-omics analysis we identify a new rare cell type with neuron-like but not secretory characteristics. Mucinous colorectal cancer is an aggressive and chemotherapeutically intractable form of CRC that is enriched for EEC progenitors. Our data demonstrates that LSD1 and STAT3 promote EEC differentiation, suggesting that inhibiting LSD1 and or STAT3 may have benefits for patients with mucinous colorectal cancer. Citation Format: Christopher A. Ladaika, Ahmed H. Ghobashi, William C. Boulton, Heather M. O'Hagan. LSD1 and CoREST2 demethylate STAT3 to promote enteroendocrine cell differentiation in mucinous colorectal cancer [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 1690.

Id2 epigenetically controls CD8+ T-cell exhaustion by disrupting the assembly of the Tcf3-LSD1 complex

CD8+ T-cell exhaustion is a state of dysfunction that promotes tumor progression and is marked by the generation of Slamf6+ progenitor exhausted (Texprog) and Tim-3+ terminally exhausted (Texterm) subpopulations. Inhibitor of DNA binding protein 2 (Id2) has been shown to play important roles in T-cell development and CD8+ T-cell immunity. However, the role of Id2 in CD8+ T-cell exhaustion is unclear. Here, we found that Id2 transcriptionally and epigenetically regulates the generation of Texprog cells and their conversion to Texterm cells. Genetic deletion of Id2 dampens CD8+ T-cell-mediated immune responses and the maintenance of stem-like CD8+ T-cell subpopulations, suppresses PD-1 blockade and increases tumor susceptibility. Mechanistically, through its HLH domain, Id2 binds and disrupts the assembly of the Tcf3-Tal1 transcriptional regulatory complex, and thus modulates chromatin accessibility at the Slamf6 promoter by preventing the interaction of Tcf3 with the histone lysine demethylase LSD1. Therefore, Id2 increases the abundance of the permissive H3K4me2 mark on the Tcf3-occupied E-boxes in the Slamf6 promoter, modulates chromatin accessibility at the Slamf6 promoter and epigenetically regulates the generation of Slamf6+ Texprog cells. An LSD1 inhibitor GSK2879552 can rescue the Id2 knockout phenotype in tumor-bearing mice. Inhibition of LSD1 increases the abundance of Slamf6+Tim-3− Texprog cells in tumors and the expression level of Tcf1 in Id2-deleted CD8+ T cells. This study demonstrates that Id2-mediated transcriptional and epigenetic modification drives hierarchical CD8+ T-cell exhaustion, and the mechanistic insights gained may have implications for therapeutic intervention with tumor immune evasion.

Network pharmacology and molecular-docking-based strategy to explore the potential mechanism of salidroside-inhibited oxidative stress in retinal ganglion cell.

Salidroside (SAL), the main component of Rhodiola rosea extract, is a flavonoid with biological activities, such as antioxidative stress, anti-inflammatory, and hypolipidemic. In this study, the potential therapeutic targets and mechanisms of SAL against oxidative stress in retinal ganglion cells (RGCs) were investigated on the basis of in-vitro experiments, network pharmacology, and molecular docking techniques. RGC oxidative stress models were constructed, and cell activity, reactive oxygen species (ROS), and apoptosis levels were examined for differences. The genes corresponding to rhodopsin, RGCs, and oxidative stress were screened from GeneCards, TCMSP database, and an analysis platform. The intersection of the three was taken, and a Venn diagram was drawn. Protein interactions, GO functional enrichment, and KEGG pathway enrichment data were analyzed by STRING database, Cytohubba plugin, and Metascape database. The key factors in the screening pathway were validated using qRT-PCR. Finally, molecular docking prediction was performed using MOE 2019 software, molecular dynamic simulations was performed using Gromacs 2018 software. In the RGC oxidative stress model in vitro, the cell activity was enhanced, ROS was reduced, and apoptosis was decreased after SAL treatment. A total of 16 potential targets of oxidative stress in SAL RGCs were obtained, and the top 10 core targets were screened by network topology analysis. GO analysis showed that SAL retinal oxidative stress treatment mainly involved cellular response to stress, transcriptional regulatory complexes, and DNA-binding transcription factor binding. KEGG analysis showed that most genes were mainly enriched in multiple cancer pathways and signaling pathways in diabetic complications, nonalcoholic fatty liver, and lipid and atherosclerosis. Validation by PCR, molecular docking and molecular dynamic simulations revealed that SAL may attenuate oxidative stress and reduce apoptosis in RGCs by regulating SIRT1, NRF2, and NOS3. This study initially revealed the antioxidant therapeutic effects and molecular mechanisms of SAL on RGCs, providing a theoretical basis for subsequent studies.

YAP/TEAD-induced PRIM1 contributes to the progression and poor prognosis of gastric carcinoma

Gastric carcinoma has a poor prognosis and low survival rate. PRIM1 is closely associated with the origin of DNA replication and serves as a carcinogenic factor in multiple tumors. This study aimed to explore the functions of PRIM1 in the progression of gastric carcinoma. The luciferase reporter assay examined the regulatory effect of YAP1/TEAD4 on PRIM1. A xenograft tumor mouse model was constructed to observe cancer cell proliferation in vivo. The upregulation of PRIM1 was found in gastric carcinoma cells and tissues, and it was associated with poor prognosis. Silencing PRIM1 inhibited cell proliferation, arrested the cell cycle, and upregulated Cdc25, Cyclin B, and Cdc2 expression. In addition, apoptosis was increased upon PRIM1 knockdown, accompanied by increased protein levels of cleaved caspase-3 and caspase-8. In vivo, knockdown of PRIM1 suppressed the growth of xenograft tumors formed by gastric carcinoma cells. Moreover, PRIM1 silencing elevated the chemosensitivity of gastric carcinoma cells. By investigating molecular events downstream of the Hippo signaling pathway, we found that PRIM1 was a target gene of the YAP1/TEAD4 transcriptional regulatory complex. PRIM1 represents a novel target for gastric carcinoma therapeutic approaches.

An apicomplexan bromodomain protein, TgBDP1, associates with diverse epigenetic factors to regulate essential transcriptional processes in Toxoplasma gondii.

The protozoan pathogen Toxoplasma gondii relies on tight regulation of gene expression to invade and establish infection in its host. The divergent gene regulatory mechanisms of Toxoplasma and related apicomplexan pathogens rely heavily on regulators of chromatin structure and histone modifications. The important contribution of histone acetylation for Toxoplasma in both acute and chronic infection has been demonstrated, where histone acetylation increases at active gene loci. However, the direct consequences of specific histone acetylation marks and the chromatin pathway that influences transcriptional regulation in response to the modification are unclear. As a reader of lysine acetylation, the bromodomain serves as a mediator between the acetylated histone and transcriptional regulators. Here we show that the bromodomain protein, TgBDP1, which is conserved among Apicomplexa and within the Alveolata superphylum, is essential for Toxoplasma asexual proliferation. Using cleavage under targets and tagmentation, we demonstrate that TgBDP1 is recruited to transcriptional start sites of a large proportion of parasite genes. Transcriptional profiling during TgBDP1 knockdown revealed that loss of TgBDP1 leads to major dysregulation of gene expression, implying multiple roles for TgBDP1 in both gene activation and repression. This is supported by interactome analysis of TgBDP1 demonstrating that TgBDP1 forms a core complex with two other bromodomain proteins and an ApiAP2 factor. This core complex appears to interact with other epigenetic factors such as nucleosome remodeling complexes. We conclude that TgBDP1 interacts with diverse epigenetic regulators to exert opposing influences on gene expression in the Toxoplasma tachyzoite. IMPORTANCE Histone acetylation is critical for proper regulation of gene expression in the single-celled eukaryotic pathogen Toxoplasma gondii. Bromodomain proteins are "readers" of histone acetylation and may link the modified chromatin to transcription factors. Here, we show that the bromodomain protein TgBDP1 is essential for parasite survival and that loss of TgBDP1 results in global dysregulation of gene expression. TgBDP1 is recruited to the promoter region of a large proportion of parasite genes, forms a core complex with two other bromodomain proteins, and interacts with different transcriptional regulatory complexes. We conclude that TgBDP1 is a key factor for sensing specific histone modifications to influence multiple facets of transcriptional regulation in Toxoplasma gondii.

NUSAP1-LDHA-Glycolysis-Lactate feedforward loop promotes Warburg effect and metastasis in pancreatic ductal adenocarcinoma

Pancreatic ductal adenocarcinoma (PDAC) is characterized by hypoxia and hypovascular tumor microenvironment. Nucleolar and spindle associated protein 1 (NUSAP1) is a microtubule-associated protein that is known to be involved in cancer biology. Our study aimed to investigate the role of NUSAP1 in glycolytic metabolism and metastasis in PDAC. Expression and prognostic value of NUSAP1 in PDAC and common gastrointestinal tumors was evaluated. The function of NUSAP1 in PDAC progression was clarified by single-cell RNA-seq and further experiments in vitro, xenograft mouse model, spontaneous PDAC mice model and human tissue microarray. The downstream genes and signaling pathways regulated by NUSAP1 were explored by RNA-Seq. And the regulation of NUSAP1 on Lactate dehydrogenase A (LDHA)-mediated glycolysis and its underlying mechanism was further clarified by CHIP-seq. NUSAP1 was an independent unfavorable predictor of PDAC prognosis that playing a critical role in metastasis of PDAC by regulating LDHA-mediated glycolysis. Mechanically, NUSAP1 could bind to c-Myc and HIF-1α that forming a transcription regulatory complex localized to LDHA promoter region and enhanced its expression. Intriguingly, lactate upregulated NUSAP1 expression by inhibiting NUSAP1 protein degradation through lysine lactylated (Kla) modification, thus forming a NUSAP1-LDHA-glycolysis-lactate feedforward loop. The NUSAP1-LDHA-glycolysis-lactate feedforward loop is one of the underlying mechanisms to explain the metastasis and glycolytic metabolic potential in PDAC, which also provides a novel insights to understand the Warburg effect in cancer. Targeting NUSAP1 would be an attractive paradigm for PDAC treatment.

MiR-136-5p/FZD4 axis is critical for Wnt signaling-mediated myogenesis and skeletal muscle regeneration.

Skeletal muscle can undergo a regenerative process in response to injury or disease to maintain muscle quality and function. Myogenesis depends on the proliferation and differentiation of myoblasts, and miRNAs can maintain the balance between them by precisely regulating many key factors in the myogenic network. Here, we found that miR-136-5p was significantly upregulated during the proliferation and differentiation of C2C12 cells. We demonstrate that miR-136-5p acts as a myogenic negative regulator during the development of mouse C2C12 myoblasts. In terms of mechanism, miR-136-5p inhibits the formation of β-catenin/LEF/TCF DNA-binding factor transcriptional regulatory complex by targeting FZD4, a gating protein in the Wnt signaling pathway, thereby enhancing downstream myogenic factors and finally promoting myoblast proliferation and differentiation. In addition, in BaCl2 -induced muscle injury mouse model, miR-136-5p knockdown accelerated the regeneration of skeletal muscle after injury, and further led to the improvement of gastrocnemius muscle mass and muscle fiber diameter, while being suppressed by shFZD4 lentivirus infection. In summary, these results demonstrate the essential role of miR-136-5p/FZD4 axis in skeletal muscle regeneration. Given the conservation of miR-136-5p among species, miR-136-5p may be a new target for treating human skeletal muscle injury and improving the production of animal meat products.

Structural basis of dual activation of cell division by the actinobacterial transcription factors WhiA and WhiB

Studies of transcriptional initiation in different bacterial clades reveal diverse molecular mechanisms regulating this first step in gene expression. The WhiA and WhiB factors are both required to express cell division genes in Actinobacteria and are essential in notable pathogens such as Mycobacterium tuberculosis. The WhiA/B regulons and binding sites have been elucidated in Streptomyces venezuelae (Sven), where they coordinate to activate sporulation septation. However, how these factors cooperate at the molecular level is not understood. Here we present cryoelectron microscopy structures of Sven transcriptional regulatory complexes comprising RNA polymerase (RNAP) σA-holoenzyme and WhiA and WhiB, in complex with the WhiA/B target promoter sepX. These structures reveal that WhiB binds to domain 4 of σA (σA4) of the σA-holoenzyme, bridging an interaction with WhiA while making non-specific contacts with the DNA upstream of the -35 core promoter element. The N-terminal homing endonuclease-like domain of WhiA interacts with WhiB, while the WhiA C-terminal domain (WhiA-CTD) makes base-specific contacts with the conserved WhiA GACAC motif. Notably, the structure of the WhiA-CTD and its interactions with the WhiA motif are strikingly similar to those observed between σA4 housekeeping σ-factors and the -35 promoter element, suggesting an evolutionary relationship. Structure-guided mutagenesis designed to disrupt these protein-DNA interactions reduces or abolishes developmental cell division in Sven, confirming their significance. Finally, we compare the architecture of the WhiA/B σA-holoenzyme promoter complex with the unrelated but model CAP Class I and Class II complexes, showing that WhiA/WhiB represent a new mechanism in bacterial transcriptional activation.

The Emerging Role of Super-enhancers as Therapeutic Targets in The Digestive System Tumors.

Digestive system tumors include malignancies of the stomach, pancreas, colon, rectum, and the esophagus, and are associated with high morbidity and mortality. Aberrant epigenetic modifications play a vital role in the progression of digestive system tumors. The aberrant transcription of key oncogenes is driven by super-enhancers (SEs), which are characterized by large clusters of enhancers with significantly high density of transcription factors, cofactors, and epigenetic modulatory proteins. The SEs consist of critical epigenetic regulatory elements, which modulate the biological characteristics of digestive system tumors including tumor cell identity and differentiation, tumorigenesis, environmental response, immune response, and chemotherapeutic resistance. The core transcription regulatory loop of the digestive system tumors is complex and a high density of transcription regulatory complexes in the SEs and the crosstalk between SEs and the noncoding RNAs. In this review, we summarized the known characteristics and functions of the SEs in the digestive system tumors. Furthermore, we discuss the oncogenic roles and regulatory mechanisms of SEs in the digestive system tumors. We highlight the role of SE-driven genes, enhancer RNAs (eRNAs), lncRNAs, and miRNAs in the digestive system tumor growth and progression. Finally, we discuss clinical significance of the CRISPR-Cas9 gene editing system and inhibitors of SE-related proteins such as BET and CDK7 as potential cancer therapeutics.

Quantifying the Binding and Target-Search Kinetics of Transcriptional Regulatory Factors by Live-Cell Single-Molecule Tracking.

Eukaryotic transcriptional regulatory factors, such as transcription factors and epigenetic regulatory factors, must locate, bind, and assemble at specific genomic regions to execute functions within the complex and crowded environment of the nucleus. These dynamic processes are typically at nonequilibrium, so quantifying their binding and target-search processes within the native environment is essential for understanding transcriptional mechanisms. Live-cell single-molecule tracking (SMT) is an emerging technique that can be utilized to observe molecular trajectories of individual transcriptional regulatory complexes within the nucleus. Here, we describe the use of live-cell SMT to observe trajectories of individual transcriptional regulatory complexes. We delineate the imaging analysis to obtain chromatin-bound fraction and residence time. Finally, we elaborate on the kinetic modeling to estimate target-search parameters. These binding and target-search parameters facilitate the understanding of how transcription is spatially and temporally regulated under physiological and pathological conditions.

DDB1 and CUL4 Associated Factor 7 (DCAF7) Is Essential for Hematopoiesis

Mutations in DDB1 And CUL4 Associated Factor 7 (DCAF7) have been detected in a subset of patients with Myeloid Leukemia in Down syndrome. DCAF7 is a highly conserved WD40 domain protein with 100% homology among vertebrates and is a prominent binding partner of DYRK1A, a kinase located on chromosome 21. Analysis of the DepMap database revealed that hematopoietic cell lines are highly dependent on DCAF7 compared to cell lines from other tumors. However, the function of DCAF7 during normal hematopoiesis is currently unknown. Thus, we aimed to study its function in hematopoietic cell lines and in a conditional knockout mouse model. We first deleted DCAF7 from a panel of hematopoietic cell lines by CRISPR/Cas9 editing and observed its absence led to cell cycle arrest and decreased proliferation. Rescue experiments in which a CRISPR resistant DCAF7 allele was expressed in the targeted clones restored proliferation and cell cycling. A comparison of RNA-seq data between parental HEL cells and those without DCAF7 showed decreased expression of genes involved in differentiation, TNF signaling and the IFN pathway, indicating that DCAF7 is important for cell differentiation. Next, we created a Dcaf7 conditionally targeted mouse strain (Dcaf7F/F Mx-1 Cre) and assessed its role in hematopoiesis in vivo. Following Cre induction by pIpC, we observed a decrease in white blood cells, hemoglobin and platelet counts in KO mice. Analysis of the bone marrow showed an accumulation of LT-HSCs and multipotent progenitors. In addition, we observed a defect in the generation of B-cells, reminiscent of the phenotype observed upon Dyr1ka deletion. We then tested the recovery of Dcaf7 KO hematopoietic cells after different types of stress, which included ex-vivo culture, transplantation, and myelosuppression. Dcaf7 deficient HSCs showed defective expansion in PVA-containing media and poor differentiation in single cell colony assays in methylcellulose. In non-competitive transplants, KO cells reconstituted hematopoiesis although the number of mature myeloid and lymphoid cells was dramatically decreased. In competitive transplants, Dcaf7 KO cells were outcompeted by wild-type cells. Lastly, upon myelosuppression with 5-FU, Dcaf7 deficient mice were not able to recover and died acutely. Overall, these results indicate that DCAF7 plays a critical role in HSCs during homeostasis and regeneration. To uncover the mechanisms by which DCAF7 contributes to hematopoiesis, we performed IP-MS using tagged DCAF7 as bait in a hematopoietic cell line. In addition to DYRK1A, we found that DCAF7 interacts with multiple components of the polycomb repressive complex1 (PRC1), specifically the non-canonical PRC1.5 complex, which has been previously implicated in gene activation and transcription. We confirmed that DCAF7 engages in the PRC1.5 complex by glycerol gradient centrifugation. Upon DCAF7 absence the size the PRC1 complex shifts towards a lower molecular weight, indicating that DCAF7 is a core subunit of the complex. We then performed RNASeq analysis in sorted LT-HSCs (Lin-cKit+Sca1+CD48-CD150+) and found that 70% of the differentially expressed genes were downregulated in KO cells. These downregulated genes were associated with diminished activation of GATA1, GATA2, RUNX1 and SP1 target genes, in agreement with the functional role of the PRC1.5 complex in gene activation and cell differentiation. Together our results reveal that DCAF7 regulates hematopoiesis by participating in transcriptional regulatory complexes, and we predict that DCAF7 mutations contribute to leukemia by cooperating with DYRK1A and altering the activity of the PRC1 complex.

Bromodomain Interactions with Acetylated Histone 4 Peptides in the BRD4 Tandem Domain: Effects on Domain Dynamics and Internal Flexibility.

The bromodomain and extra-terminal (BET) protein BRD4 regulates gene expression via recruitment of transcriptional regulatory complexes to acetylated chromatin. Like other BET proteins, BRD4 contains two bromodomains, BD1 and BD2, that can interact cooperatively with target proteins and designed ligands, with important implications for drug discovery. Here, we used nuclear magnetic resonance (NMR) spectroscopy to study the dynamics and interactions of the isolated bromodomains, as well as the tandem construct including both domains and the intervening linker, and investigated the effects of binding a tetra-acetylated peptide corresponding to the tail of histone 4. The peptide affinity is lower for both domains in the tandem construct than for the isolated domains. Using 15N spin relaxation, we determined the global rotational correlation times and residue-specific order parameters for BD1 and BD2. Isolated BD1 is monomeric in the apo state but apparently dimerizes upon binding the tetra-acetylated peptide. Isolated BD2 partially dimerizes in both the apo and peptide-bound states. The backbone order parameters reveal marked differences between BD1 and BD2, primarily in the acetyl-lysine binding site where the ZA loop is more flexible in BD2. Peptide binding reduces the order parameters of the ZA loop in BD1 and the ZA and BC loops in BD2. The AB loop, located distally from the binding site, shows variable dynamics that reflect the different dimerization propensities of the domains. These results provide a basis for understanding target recognition by BRD4.

Abstract 2362: Pax3-foxo1 coordinates enhancer architecture, eRNA transcription, and RNA polymerase pause release at select gene targets

Abstract Background: Gene expression networks are perturbed in every human malignancy. One common way that this occurs is through chromosomal translocations such as the the t(2;13)(q35;q14), which creates the oncogenic transcription factor, PAX3-FOXO1, in alveolar rhabdomyosarcoma (aRMS). Identification of the direct transcriptional targets and mechanisms of control by translocated transcription factors is critical to our understanding of disease etiology and the development of targeted therapeutic approaches. However, defining the genes directly controlled by DNA binding proteins and the mechanisms of regulation at those direct target genes is challenging, because traditional genetic approaches to inactivate transcription factors cannot distinguish direct from indirect changes in gene expression. Methods: A CRISPR-based approach was used to engineer the endogenous PAX3-FOXO1 locus to incorporate the FKBP12F36V degron tag. This allowed degradation of PAX3-FOXO1 within 2 hr of treatment with the proteolysis targeting chimera, dTAG-47. We performed short time courses to analyze nascent transcription (precision nuclear run-on sequencing; PRO-seq), chromatin accessibility (ATAC-seq), and genome-wide mapping of transcriptional complexes (CUT&RUN). This identified a small cohort of high-confidence PAX3-FOXO1 gene targets and associated PAX3-FOXO1-regulated enhancer elements. In addition, we used CRISPR editing to add APEX2 and 3XFLAG tags to PAX3-FOXO1 to enable deep proteomics to identify PAX3-FOXO1-associated transcriptional complexes in aRMS cell lines. Results: Degradation of PAX3-FOXO1-FKBP12F36V led to growth inhibition, hallmarks of myogenic differentiation, and reduced growth in soft agar. PAX3-FOXO1 binding was detected at over 44,000 sites throughout the genome using CUT&RUN, and loss of chromatin bound PAX3-FOXO1 was observed within 2-4hr of PAX3-FOXO1 degradation. PRO-seq analysis defined a core transcriptional network that rapidly collapsed upon PAX3-FOXO1 degradation. Unexpectedly, loss of PAX3-FOXO1 impaired RNA polymerase pause release and transcription elongation at regulated gene targets. Deep proteomic analysis showed that PAX3-FOXO1 was in close proximity to many transcriptional regulatory complexes, but appeared to coordinate the activity of these complexes at only a few hundred sites. Moreover, the continued presence of PAX3-FOXO1 at these elements was required to maintain chromatin accessibility. Conclusion: This work demonstrates the utility of using rapid degradation of endogenous transcription factors to define their direct transcription targets and the mechanisms by which these factors control gene expression. Overall, this work provides a detailed mechanism by which PAX3-FOXO1 maintains an oncogenic transcriptional regulatory network, and emphasizes the utility of PAX3-FOXO1 as a therapeutic target in aRMS. Citation Format: Susu Zhang, Jing Wang, Qi Liu, Hayes McDonald, Monica Bomber, Hillary Layden, Jacob Ellis, Scott Borinstein, Scott Hiebert, Kristy Stengel. Pax3-foxo1 coordinates enhancer architecture, eRNA transcription, and RNA polymerase pause release at select gene targets [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2362.

DDX55 promotes hepatocellular carcinoma progression by interacting with BRD4 and participating in exosome-mediated cell-cell communication.

The involvement of DEAD‐box helicase 55 (DDX55) in oncogenesis has been suggested, but its biological role in hepatocellular carcinoma (HCC) remains unknown. The present study verified the upregulation of DDX55 in HCC tissues compared with non‐tumor controls. DDX55 displayed the highest prognostic values among the DEAD‐box protein family for recurrence‐free survival and overall survival of HCC patients. In addition, the effects of DDX55 in the promotion of HCC cell proliferation, migration, and invasion were determined ex vivo and in vivo. Mechanistically, we revealed that DDX55 could interact with BRD4 to form a transcriptional regulatory complex that positively regulated PIK3CA transcription. Following that, β‐catenin signaling was activated in a PI3K/Akt/GSK‐3β dependent manner, thus inducing cell cycle progression and epithelial–mesenchymal transition. Intriguingly, both DDX55 mRNA and protein were identified in the exosomes derived from HCC cells. Exosomal DDX55 was implicated in intercellular communication between HCC cells with high or low DDX55 levels and between HCC cells and endothelial cells, thereby promoting the malignant phenotype of HCC cells and angiogenesis. In conclusion, DDX55 may be a valuable prognostic biomarker and therapeutic target in HCC.