Multisubunit Complex Research Articles

Abstract B059: RNA exosome component EXOSC4 amplified in multiple cancer types is required for the pancreatic cancer cell survival via the regulation of BIK and SESN2 mRNA

Abstract RNA decay plays a crucial role in the post-transcriptional regulation of gene expression. The RNA exosome is a multi-subunit ribonuclease complex that is evolutionally conserved and the major cellular machinery for the surveillance, processing, degradation, and turnover of diverse RNAs essential for cell viability. The RNA exosome is composed of a catalytically inactive barrel structure of nine core subunits (known as EXO9) that achieves its catalytic activity via the interaction with the exoribonuclease exosome component 10 (EXOSC10), the exo/endo-ribonuclease DIS3, and the two DIS3-like proteins (the exoribonucleases DIS3L and DIS3L2). Moreover, exosome activity is regulated by associated co-factors and RNA-binding adaptor proteins that recruit the exosome to its many targets. Here we performed integrated genomic and clinicopathological analyses of 27 RNA exosome components across 32 tumor types using The Cancer Genome Atlas PanCancer Atlas Studies’ datasets. We discovered that the EXOSC4 gene, which encodes a barrel component of the RNA exosome, was amplified across multiple cancer types. We further found that EXOSC4 alteration is associated with a poor prognosis in pancreatic cancer patients. Moreover, we demonstrated that EXOSC4 is required for the survival of pancreatic cancer cells. EXOSC4 also repressed BIK expression and destabilized SESN2 mRNA by promoting its degradation. Furthermore, knockdown of BIK and SESN2 could partially rescue pancreatic cells from the reduction in cell viability caused by EXOSC4 knockdown. Our study provides evidence for EXOSC4-mediated regulation of BIK and SESN2 mRNA in the survival of pancreatic tumor cells. Citation Format: Kenzui Taniue, Yusuke Mizukami, Nobuyoshi Akimitsu. RNA exosome component EXOSC4 amplified in multiple cancer types is required for the pancreatic cancer cell survival via the regulation of BIK and SESN2 mRNA [abstract]. In: Proceedings of the AACR Special Conference on Pancreatic Cancer; 2022 Sep 13-16; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2022;82(22 Suppl):Abstract nr B059.

Mechanisms of Polycomb Group Protein-Mediated Fetal Hemoglobin Silencing

Reactivation of fetal hemoglobin (HbF) is beneficial for patients with β-globin gene disorders, such as sickle cell disease and β-thalassemia. Polycomb repressive complex 1 (PRC1) and 2 (PRC2) are multi-subunit protein complexes that function as transcriptional repressors to maintain lineage-specific gene expression programs. Prior works showed that genetic or pharmacologic manipulation of select PRC2 subunits can induce HbF expression in adult erythroid cells, and an inhibitor targeting the EED subunit of PRC2 has entered a clinical trial. Yet the molecular basis underlying HbF regulation by PRC1/2 complexes is unknown. Using a CRISPR-Cas9-based genetic screen, we identified BMI1, a subunit of the PRC1 complex as novel HbF repressor. Disrupting BMI1 in the adult-type erythroid cell line HUDEP2 or primary human erythroblast cells robustly increased HbF production. We failed to detect BMI1 binding at the β-globin gene locus by CUT&RUN, indicating that BMI1 functions via an indirect mechanism. RNA-seq analysis of BMI1-deficient HUDEP2 cells uncovered upregulation of two known HbF regulators: IGF2BP1 and LIN28B, both of which induce HbF when forcibly expressed in adult erythroid cells. Depletion of either IGF2BP1 or LIN28B partially restored HbF silencing in BMI1-deficient HUDEP2 cells, whereas simultaneous depletion of IGF2BP1 and LIN28B lowered HbF production virtually to basal levels in these cells. In primary erythroid cells, IGF2BP3, which is functionally related to IGF2BP1, also contributes to the effects of BMI1 depletion. Together, these data indicate that IGF2BP1, IGF2BP3, and LIN28B are the critical BMI1 targets in human erythroid cells. Since BMI1 functions in two distinct PRC1 complexes (cPRC1 and ncPRC1), we aimed to define which of these is critical for HbF regulation. cPRC1 is defined by the presence of CBX proteins 2, 4, 6, 7, and 8, while ncPRC1 contains RYBP or its homolog YAF2. ncPRC1 and cPRC1 deposit the histone mark H2AK119ub1, and facilitate chromatin compaction, respectively. Disruption of CBX2/4/7/8 proteins but not RYAP/YAF2 in HUDEP2 cells activated HbF to levels similar to those observed upon BMI1 depletion, implicating cPRC1 in HbF control. Accordingly, CUT&RUN analysis in adult erythroid cells revealed a strong genome-wide co-localization of BMI1 and CBX2/4/7/8, including at the IGF2BP1, IGF2BP3, and LIN28B genes. Finally, BMI1 depletion does not lead to significant changes in H2AK119ub1 at these genes, in line with the fact that the repressive activity of the cPRC1 complex does not rely on its H2A ubiquitination activity. Together these results indicate that BMI1 represses HbF via the cPRC1 complex in adult erythroid cells. The BMI1-containing cPRC1 complex is known to repress transcription in conjunction with the PRC2 complex which deposits the histone mark H3K27me3. CUT&RUN profiling studies revealed focal loss of H3K27me3 in BMI1-deficient HUDEP2 cells, including at the CG-rich regions near the promoters of the IGF2BP1 and LIN28B genes. Therefore, we tested whether cPRC1 and PRC2 complexes converge on HbF regulation by regulating IGF2BP1 and LIN28B. Disruption in HUDEP2 cells of EZH2, the catalytic component of PRC2, led to global depletion of H3K27me3 along with upregulation of IGF2BP1 and LIN28B. Co-depletion of IGF2BP1 and LIN28B largely restored the EZH2 depletion-induced HbF upregulation. In summary, our studies further define the nature of PRC complexes involved in HbF regulation and identify the IGF2BP1, IGF2BP3, and LIN28B genes as critical links between PcG activity and HbF silencing. Our results may guide the development of improved PRC inhibitors for the treatment of β-globin disorders.

Aspergillus fumigatus Elongator complex subunit 3 affects hyphal growth, adhesion and virulence through wobble uridine tRNA modification.

The eukaryotic multisubunit Elongator complex has been shown to perform multiple functions in transcriptional elongation, histone acetylation and tRNA modification. However, the Elongator complex plays different roles in different organisms, and the underlying mechanisms remain unexplored. Moreover, the biological functions of the Elongator complex in human fungal pathogens remain unknown. In this study, we verified that the Elongator complex of the opportunistic fungal pathogen Aspergillus fumigatus consists of six subunits (Elp1-6), and the loss of any subunit results in similarly defective colony phenotypes with impaired hyphal growth and reduced conidiation. The catalytic subunit-Elp3 of the Elongator complex includes a S-adenosyl methionine binding (rSAM) domain and a lysine acetyltransferase (KAT) domain, and it plays key roles in the hyphal growth, biofilm-associated exopolysaccharide galactosaminogalactan (GAG) production, adhesion and virulence of A. fumigatus; however, Elp3 does not affect H3K14 acetylation levels in vivo. LC-MS/MS chromatograms revealed that loss of Elp3 abolished the 5-methoxycarbonylmethyl-2-thiouridine (mcm5s2U) modification of tRNA wobble uridine (U34), and the overexpression of tRNAGlnUUG and tRNAGluUUC, which normally harbor mcm5s2U modifications, mainly rescues the defects of the Δelp3 mutant, suggesting that tRNA modification rather than lysine acetyltransferase is responsible for the primary function of Elp3 in A. fumigatus. Strikingly, global proteomic comparison analyses showed significantly upregulated expression of genes related to amino acid metabolism in the Δelp3 mutant strain compared to the wild-type strain. Western blotting showed that deletion of elp3 resulted in overexpression of the amino acid starvation-responsive transcription factor CpcA, and deletion of CpcA markedly reversed the defective phenotypes of the Δelp3 mutant, including attenuated virulence. Therefore, the findings of this study demonstrate that A. fumigatus Elp3 functions as a tRNA-modifying enzyme in the regulation of growth, GAG production, adhesion and virulence by maintaining intracellular amino acid homeostasis. More broadly, our study highlights the importance of U34 tRNA modification in regulating cellular metabolic states and virulence traits of fungal pathogens.

Genome-wide identification and expression analysis of anaphase promoting complex/cyclosome (APC/C) in rose

The anaphase promoting complex/cyclosome (APC/C) is a large multi-subunit complex, regulating plant development and cell cycle. In plants, the APC/C gene family has been identified in Arabidopsis, rice, and maize. The APC/Cs in rose has not yet been reported. In this study, a total of 19 APC/C genes were identified in rose. Furthermore, we also investigated phylogenetic relationships, chromosomal distribution, gene structure, motif analysis, promoter sequence analysis and expression pattern of RhAPC/C genes. Synteny analysis indicated that AtAPC/Cs and RhAPC/Cs show a high degree of conservation. RhAPC/C promoters contains numerous cis-elements involved in plant morphogenesis, hormone response and stress response. Based on the transcription of RhAPC/Cs in different tissues and developmental stages, it appears that RhAPC/Cs may play a variety of roles in rose growth and development. RhAPC/Cs have limitations in the time and space during which they respond to hormones and abiotic stress. RhAPC5, RhAPC11d, RhAPC13a and RhAPC13c may play a role in rose responding to abiotic stress. The expression of RhAPC10 was altered by infection with fungal pathogen. Our study will serve as a basis for determining the functional role of APC/C genes in roses and help future research on woody plants.

Involvement of the SAGA and TFIID coactivator complexes in transcriptional dysregulation caused by the separation of core and tail Mediator modules.

Regulation of RNA polymerase II transcription requires the concerted efforts of several multisubunit coactivator complexes, which interact with the RNA polymerase II preinitiation complex to stimulate transcription. We previously showed that separation of the Mediator core from Mediator's tail module results in modest overactivation of genes annotated as highly dependent on TFIID for expression. However, it is unclear if other coactivators are involved in this phenomenon. Here, we show that the overactivation of certain genes by Mediator core/tail separation is blunted by disruption of the Spt-Ada-Gcn5-Acetyl transferase complex through the removal of its structural Spt20 subunit, though this downregulation does not appear to completely depend on reduced Spt-Ada-Gcn5-Acetyl transferase association with the genome. Consistent with the enrichment of TFIID-dependent genes among genes overactivated by Mediator core/tail separation, depletion of the essential TFIID subunit Taf13 suppressed the overactivation of these genes when Med16 was simultaneously removed. As with Spt-Ada-Gcn5-Acetyl transferase, this effect did not appear to be fully dependent on the reduced genomic association of TFIID. Given that the observed changes in gene expression could not be clearly linked to alterations in Spt-Ada-Gcn5-Acetyl transferase or TFIID occupancy, our data may suggest that the Mediator core/tail connection is important for the modulation of Spt-Ada-Gcn5-Acetyl transferase and/or TFIID conformation and/or function at target genes.

Advances in the study of nicotinamide adenine dinucleotide phosphate oxidase in myocardial remodeling.

Myocardial remodeling is a key pathophysiological basis of heart failure, which seriously threatens human health and causes a severe economic burden worldwide. During chronic stress, the heart undergoes myocardial remodeling, mainly manifested by cardiomyocyte hypertrophy, apoptosis, interstitial fibrosis, chamber enlargement, and cardiac dysfunction. The NADPH oxidase family (NOXs) are multisubunit transmembrane enzyme complexes involved in the generation of redox signals. Studies have shown that NOXs are highly expressed in the heart and are involved in the pathological development process of myocardial remodeling, which influences the development of heart failure. This review summarizes the progress of research on the pathophysiological processes related to the regulation of myocardial remodeling by NOXs, suggesting that NOXs-dependent regulatory mechanisms of myocardial remodeling are promising new therapeutic targets for the treatment of heart failure.

Nitric oxide-driven modifications of lipoic arm inhibit α-ketoacid dehydrogenases

Pyruvate dehydrogenase complex (PDHC) and oxoglutarate dehydrogenase complex (OGDC), which belong to the mitochondrial α-ketoacid dehydrogenase family, play crucial roles in cellular metabolism. These multi-subunit enzyme complexes use lipoic arms covalently attached to their E2 subunits to transfer an acyl group to coenzyme A (CoA). Here, we report a novel mechanism capable of substantially inhibiting PDHC and OGDC: reactive nitrogen species (RNS) can covalently modify the thiols on their lipoic arms, generating a series of adducts that block catalytic activity. S-Nitroso-CoA, a product between RNS and the E2 subunit’s natural substrate, CoA, can efficiently deliver these modifications onto the lipoic arm. We found RNS-mediated inhibition of PDHC and OGDC occurs during classical macrophage activation, driving significant rewiring of cellular metabolism over time. This work provides a new mechanistic link between RNS and mitochondrial metabolism with potential relevance for numerous physiological and pathological conditions in which RNS accumulate.

Modulation of the high-order chromatin structure by Polycomb complexes.

The multi-subunit Polycomb Repressive Complex (PRC) 1 and 2 act, either independently or synergistically, to maintain and enforce a repressive state of the target chromatin, thereby regulating the processes of cell lineage specification and organismal development. In recent years, deep sequencing-based and imaging-based technologies, especially those tailored for mapping three-dimensional (3D) chromatin organization and structure, have allowed a better understanding of the PRC complex-mediated long-range chromatin contacts and DNA looping. In this review, we review current advances as for how Polycomb complexes function to modulate and help define the high-order chromatin structure and topology, highlighting the multi-faceted roles of Polycomb proteins in gene and genome regulation.

Algal photosystem I dimer and high-resolution model of PSI-plastocyanin complex

Photosystem I (PSI) enables photo-electron transfer and regulates photosynthesis in the bioenergetic membranes of cyanobacteria and chloroplasts. Being a multi-subunit complex, its macromolecular organization affects the dynamics of photosynthetic membranes. Here we reveal a chloroplast PSI from the green alga Chlamydomonas reinhardtii that is organized as a homodimer, comprising 40 protein subunits with 118 transmembrane helices that provide scaffold for 568 pigments. Cryogenic electron microscopy identified that the absence of PsaH and Lhca2 gives rise to a head-to-head relative orientation of the PSI–light-harvesting complex I monomers in a way that is essentially different from the oligomer formation in cyanobacteria. The light-harvesting protein Lhca9 is the key element for mediating this dimerization. The interface between the monomers is lacking PsaH and thus partially overlaps with the surface area that would bind one of the light-harvesting complex II complexes in state transitions. We also define the most accurate available PSI–light-harvesting complex I model at 2.3 Å resolution, including a flexibly bound electron donor plastocyanin, and assign correct identities and orientations to all the pigments, as well as 621 water molecules that affect energy transfer pathways.

Inositol hexakisphosphate is required for Integrator function

Integrator is a multi-subunit protein complex associated with RNA polymerase II (Pol II), with critical roles in noncoding RNA 3′-end processing and transcription attenuation of a broad collection of mRNAs. IntS11 is the endonuclease for RNA cleavage, as a part of the IntS4-IntS9-IntS11 Integrator cleavage module (ICM). Here we report a cryo-EM structure of the Drosophila ICM, at 2.74 Å resolution, revealing stable association of an inositol hexakisphosphate (IP6) molecule. The IP6 binding site is located in a highly electropositive pocket at an interface among all three subunits of ICM, 55 Å away from the IntS11 active site and generally conserved in other ICMs. We also confirmed IP6 association with the same site in human ICM. IP6 binding is not detected in ICM samples harboring mutations in this binding site. Such mutations or disruption of IP6 biosynthesis significantly reduced Integrator function in snRNA 3′-end processing and mRNA transcription attenuation. Our structural and functional studies reveal that IP6 is required for Integrator function in Drosophila, humans, and likely other organisms.

Characterization of the self-targeting Type IV CRISPR interference system in Pseudomonas oleovorans.

Bacterial Type IV CRISPR-Cas systems are thought to rely on multi-subunit ribonucleoprotein complexes to interfere with mobile genetic elements, but the substrate requirements and potential DNA nuclease activities for many systems within this type are uncharacterized. Here we show that the native Pseudomonas oleovorans Type IV-A CRISPR-Cas system targets DNA in a PAM-dependent manner and elicits interference without showing DNA nuclease activity. We found that the first crRNA of P. oleovorans contains a perfect match in the host gene coding for the Type IV pilus biogenesis protein PilN. Deletion of the native Type IV CRISPR array resulted in upregulation of pilN operon transcription in the absence of genome cleavage, indicating that Type IV-A CRISPR-Cas systems can function in host gene regulation. These systems resemble CRISPR interference (CRISPRi) methodology but represent a natural CRISPRi-like system that is found in many Pseudomonas and Klebsiella species and allows for gene silencing using engineered crRNAs.

Condensin I and condensin II proteins form a LINE-1 dependent super condensin complex and cooperate to repress LINE-1.

Condensin I and condensin II are multi-subunit complexes that are known for their individual roles in genome organization and preventing genomic instability. However, interactions between condensin I and condensin II subunits and cooperative roles for condensin I and condensin II, outside of their genome organizing functions, have not been reported. We previously discovered that condensin II cooperates with Gamma Interferon Activated Inhibitor of Translation (GAIT) proteins to associate with Long INterspersed Element-1 (LINE-1 or L1) RNA and repress L1 protein expression and the retrotransposition of engineered L1 retrotransposition in cultured human cells. Here, we report that the L1 3′UTR is required for condensin II and GAIT association with L1 RNA, and deletion of the L1 RNA 3′UTR results in increased L1 protein expression and retrotransposition. Interestingly, like condensin II, we report that condensin I also binds GAIT proteins, associates with the L1 RNA 3′UTR, and represses L1 retrotransposition. We provide evidence that the condensin I protein, NCAPD2, is required for condensin II and GAIT protein association with L1 RNA. Furthermore, condensin I and condensin II subunits interact to form a L1-dependent super condensin complex (SCC) which is located primarily within the cytoplasm of both transformed and primary epithelial cells. These data suggest that increases in L1 expression in epithelial cells promote cytoplasmic condensin protein associations that facilitate a feedback loop in which condensins may cooperate to mediate L1 repression.

Abstract B026: Expression levels of chaperonin containing TCP1 in cancer are among the highest in sarcomas

Abstract Protein folding complexes are essential for oncogenesis. Of these, the multi-subunit complex, Chaperonin-Containing TCP-1 (CCT or TRiC), is upregulated across a spectrum of cancers and folds many of the oncoproteins that drive cancer growth. Using the UCSC Xena online database, which includes datasets from TCGA, TARGET, GTEx, and KidsFirst, we found significant increases in gene expression of the subunits (CCT1-8) that form the chaperonin complex in sarcomas, both adult and pediatric, as compared to other cancers like invasive breast carcinoma, lung carcinoma, glioblastoma multiforme, or prostate cancer. Most notably was the high expression of the second subunit (CCT2) in Rhabdomyosarcoma compared to other pediatric cancers. These findings were confirmed with other databases (e.g., Oncomine). Expression of CCT subunits, like CCT2, was decreased in normal tissues, such as muscle, kidney, and uterus, as compared to sarcoma tissues. Bioinformatic data was confirmed by finding detectable staining of CCT2 protein in sarcoma tissues. This was supported by data from the human protein atlas showing minimal staining for CCT2 in normal smooth and skeletal muscle. Cancer adjacent tissues from a metastatic breast cancer patient study had minimal staining for CCT2 in muscle, fat, and bone. These data show that CCT is increased in sarcomas, while decreased in normal tissues, and has potential for further study as a driver of sarcoma development and a target for therapeutic intervention. Citation Format: Amanda J. Cox, Annette Khaled. Expression levels of chaperonin containing TCP1 in cancer are among the highest in sarcomas [abstract]. In: Proceedings of the AACR Special Conference: Sarcomas; 2022 May 9-12; Montreal, QC, Canada. Philadelphia (PA): AACR; Clin Cancer Res 2022;28(18_Suppl):Abstract nr B026.

Chaperonin containing TCP-1 (CCT/TRiC) is a novel therapeutic and diagnostic target for neuroblastoma.

Chaperonin containing TCP1 (CCT/TRiC) is a multi-subunit protein folding complex that enables the cancer phenotype to emerge from the mutational landscape that drives oncogenesis. We and others linked increased expression of CCT subunits to advanced tumor stage and invasiveness that inversely correlates with cancer patient outcomes. In this study, we examined the expression of the second CCT subunit, CCT2, using genomic databases of adult and pediatric tumors and normal tissues, and found that it was highly expressed in pediatric cancers, showing a significant difference compared to normal tissues. Histologic staining confirmed that CCT subunits are highly expressed in tumor tissues, which was exemplified in neuroblastoma. Using two neuroblastoma cells, MYCN-amplified, IMR-32 cells, and non-amplified, SK-N-AS cells, we assessed baseline levels for CCT subunits and found expressions comparable to the highly invasive triple-negative breast cancer (TNBC) cell line, MDA-MB-231. Exogenous expression of CCT2 in both SK-N-AS and IMR-32 cells resulted in morphological changes, such as larger cell size and increased adherence, with significant increases in the CCT substrates, actin, and tubulin, as well as increased migration. Depletion of CCT2 reversed these effects and reduced cell viability. We evaluated CCT as a therapeutic target in IMR-32 cells by testing a novel peptide CCT inhibitor, CT20p. Treatment with CT20p induced cell death in these neuroblastoma cells. The use of CCT2 as a biological indicator for detection of neuroblastoma cells shed in blood was examined by spiking IMR-32 cells into human blood and using an anti-CCT2 antibody for the identification of spiked cancer cells with the CellSearch system. Results showed that using CCT2 for the detection of neuroblastoma cells in blood was more effective than the conventional approach of using epithelial markers like cytokeratins. CCT2 plays an essential role in promoting the invasive capacity of neuroblastoma cells and thus offers the potential to act as a molecular target in the development of novel therapeutics and diagnostics for pediatric cancers.

Abstract B010: The NuRD subunit CHD4 is essential for ewing sarcoma cell survival as it regulates global chromatin architecture

Abstract Ewing sarcoma tumorigenesis is tightly linked to epigenetic deregulation. Indeed, the aberrant fusion transcription factor and tumor driver EWS-FLI1 produces extensive rewiring of the cancer cell epigenome. At enhancers containing canonical ETS motifs, the fusion protein represses gene expression but, when binding to GGAA repeats, EWS-FLI1 induces transcription by recruiting activating epigenetic regulators such as the acetyltransferase p300 and the BAF chromatin remodeling complex. The nucleosome remodeling and deacetylase (NuRD) complex is an ATP-dependent multi-subunit complex that modulates chromatin architecture and regulates DNA damage repair, genome stability and gene expression. In Ewing sarcoma, NuRD subunits, such as LSD1, have been suggested to interfere with EWS-FLI1 activity and prevent tumor progression. Hence, we here aimed to comprehensively study the role of NuRD in Ewing sarcoma pathogenesis. First, we performed a NuRD-centered, negative selection, CRISPR/Cas9 screen and identified the chromatin remodeling helicase CHD4 as essential for Ewing sarcoma tumor cell survival. Validation assays using two doxycycline-inducible shRNAs targeting CHD4 demonstrated that silencing of this remodeler in fact drastically reduces tumor cell proliferation and completely prevents colony formation. This cell proliferation impairment was caused by an induction of cell death by apoptosis and not by cell cycle arrest. Surprisingly, this cell death phenotype was not linked to impaired fusion protein activity. CHD4 and NuRD, despite primarily locating to enhancers and super-enhancers in Ewing sarcoma cells, did not preferentially localize to GGAA repeats, unlike EWS-FLI1. Moreover, RNA sequencing assays performed upon CHD4 silencing showed that this ATPase does not regulate the EWS-FLI1 signature. As CHD4 is a chromatin remodeler able to move nucleosomes along the DNA, we performed ATAC sequencing experiments to investigate changes in chromatin status that could explain the dependency of Ewing sarcoma cells on CHD4 for survival. We observed that CHD4 depletion from Ewing sarcoma cells causes a drastic and global chromatin relaxation which renders tumor cells prone to DNA damage and increasingly sensitive to DNA damaging agents. Interestingly, augmented sensitivity to DNA damage was not observed by silencing CHD4 in non-tumorigenic human fibroblasts. Finally, CHD4 depletion also reduced Ewing sarcoma tumor growth in vivo and prolonged mice survival. In conclusion, we demonstrate for the first time that CHD4 is crucial for Ewing sarcoma cell survival and highlight this helicase as a promising therapeutic target for Ewing sarcoma with potential for combination therapy with drugs inducing DNA damage. Importantly, this work has initiated ongoing efforts to develop first-in-class small molecules specifically targeting CHD4 which will be crucial for the future validation of this ATPase as a viable target with clinical application. Citation Format: Joana Graca Marques, Blaz Pavlovic, Quy Ai Ngo, Gloria Pedot, Michaela Roemmele, Larissa Volken, Marco Wachtel, Beat W. Schäfer. The NuRD subunit CHD4 is essential for ewing sarcoma cell survival as it regulates global chromatin architecture [abstract]. In: Proceedings of the AACR Special Conference: Sarcomas; 2022 May 9-12; Montreal, QC, Canada. Philadelphia (PA): AACR; Clin Cancer Res 2022;28(18_Suppl):Abstract nr B010.

The PCI domains are "winged" HEAT domains.

The HEAT domains are a family of helical hairpin repeat domains, composed of four or more hairpins. HEAT is derived from the names of four family members: huntingtin, eukaryotic translation elongation factor 3 (eEF3), protein phosphatase 2 regulatory A subunit (PP2A), and mechanistic target of rapamycin (mTOR). HEAT domain-containing proteins play roles in a wide range of cellular processes, such as protein synthesis, nuclear transport and metabolism, and cell signaling. The PCI domains are a related group of helical hairpin domains, with a “winged-helix” (WH) subdomain at their C-terminus, which is responsible for multi-subunit complex formation with other PCI domains. The name is derived from the complexes, where these domains are found: the 26S Proteasome “lid” regulatory subcomplex, the COP9 signalosome (CSN), and eukaryotic translation initiation factor 3 (eIF3). We noted that in structure similarity searches using HEAT domains, sometimes PCI domains appeared in the search results ahead of other HEAT domains, which indicated that the PCI domains could be members of the HEAT domain family, and not a related but separate group, as currently thought. Here, we report extensive structure similarity analysis of HEAT and PCI domains, both within and between the two groups of proteins. We present evidence that the PCI domains as a group have greater structural similarity with individual groups of HEAT domains than some of the HEAT domain groups have among each other. Therefore, our results indicate that the PCI domains have evolved from a HEAT domain that acquired a WH subdomain. The WH subdomain in turn mediated self-association into a multi-subunit complex, which eventually evolved into the common ancestor of the Proteasome lid/CSN/eIF3.

Polycistronic Expression of Multi-Subunit Complexes in the Eukaryotic Environment: A Narrative Review.

Protein complexes are involved in many vital biological processes. Therefore, researchers need these protein complexes for biochemical and biophysical studies. Several methods exist for expressing multi-subunit proteins in eukaryotic cells, such as 2A sequences, IRES, or intein. Nevertheless, each of these elements has several disadvantages that limit their usage. In this article, we suggest a new system for expressing multi-subunit proteins, which have several advantages over existing methods meanwhile it, lacks most of their disadvantages. Leishmania is a unicellular eukaryote and member of the Trypanosomatidae family. In the expression system of Leishmania, pre-long RNAs that contain several protein sequences transcribe. Then these long RNAs separate into mature mRNAs in the process named trans splicing. For producing multi-subunit protein, Leishmania transformed with a vector containing the sequences of all subunits. Therefore, those subunits translate and form the complex under eukaryotic cell conditions. The sequence of each protein must separate by the spatial sequence needed for trans splicing. Based on a Leishmania expression pattern, not only is it possible to produce the complexes with the correct structures and post-translational modifications, but also it is possible to overcome previous method problems.

Assembly of the Multi-Subunit Cytochrome bc1 Complex in the Yeast Saccharomyces cerevisiae.

The cytochrome bc1 complex is an essential component of the mitochondrial respiratory chain of the yeast Saccharomyces cerevisiae. It is composed of ten protein subunits, three of them playing an important role in electron transfer and proton pumping across the inner mitochondrial membrane. Cytochrome b, the central component of this respiratory complex, is encoded by the mitochondrial genome, whereas all the other subunits are of nuclear origin. The assembly of all these subunits into the mature and functional cytochrome bc1 complex is therefore a complicated process which requires the participation of several chaperone proteins. It has been found that the assembly process of the mitochondrial bc1 complex proceeds through the formation of distinct sub-complexes in an ordered sequence. Most of these sub-complexes have been thoroughly characterized, and their molecular compositions have also been defined. This study critically analyses the results obtained so far and highlights new possible areas of investigation.

Polycomb Directed Cell Fate Decisions in Development and Cancer.

The polycomb group (PcG) proteins are a subset of transcription regulators highly conserved throughout evolution. Their principal role is to epigenetically modify chromatin landscapes and control the expression of master transcriptional programs to determine cellular identity. The two mayor PcG protein complexes that have been identified in mammals to date are Polycomb Repressive Complex 1 (PRC1) and 2 (PRC2). These protein complexes selectively repress gene expression via the induction of covalent post-translational histone modifications, promoting chromatin structure stabilization. PRC2 catalyzes the histone H3 methylation at lysine 27 (H3K27me1/2/3), inducing heterochromatin structures. This activity is controlled by the formation of a multi-subunit complex, which includes enhancer of zeste (EZH2), embryonic ectoderm development protein (EED), and suppressor of zeste 12 (SUZ12). This review will summarize the latest insights into how PRC2 in mammalian cells regulates transcription to orchestrate the temporal and tissue-specific expression of genes to determine cell identity and cell-fate decisions. We will specifically describe how PRC2 dysregulation in different cell types can promote phenotypic plasticity and/or non-mutational epigenetic reprogramming, inducing the development of highly aggressive epithelial neuroendocrine carcinomas, including prostate, small cell lung, and Merkel cell cancer. With this, EZH2 has emerged as an important actionable therapeutic target in such cancers.

Recent advances of the mammalian target of rapamycin signaling in mesenchymal stem cells.

Mammalian target of rapamycin (mTOR) is a serine/threonine kinase involved in a variety of cellular functions, such as cell proliferation, metabolism, autophagy, survival and cytoskeletal organization. Furthermore, mTOR is made up of three multisubunit complexes, mTOR complex 1, mTOR complex 2, and putative mTOR complex 3. In recent years, increasing evidence has suggested that mTOR plays important roles in the differentiation and immune responses of mesenchymal stem cells (MSCs). In addition, mTOR is a vital regulator of pivotal cellular and physiological functions, such as cell metabolism, survival and ageing, where it has emerged as a novel therapeutic target for ageing-related diseases. Therefore, the mTOR signaling may develop a large impact on the treatment of ageing-related diseases with MSCs. In this review, we discuss prospects for future research in this field.