Silencing In Human Cells Research Articles

CRISPRoff epigenetic editing for programmable gene silencing in human cells without DNA breaks.

The advent of CRISPR-based technologies has enabled the rapid advancement of programmable gene manipulation in cells, tissues, and whole organisms. An emerging platform for targeted gene perturbation is epigenetic editing, the direct editing of chemical modifications on DNA and histones that ultimately results in repression or activation of the targeted gene. In contrast to CRISPR nucleases, epigenetic editors modulate gene expression without inducing DNA breaks or altering the genomic sequence of host cells. Recently, we developed the CRISPRoff epigenetic editing technology that simultaneously establishes DNA methylation and repressive histone modifications at targeted gene promoters. Transient expression of CRISPRoff and the accompanying single guide RNAs in mammalian cells results in transcriptional repression of targeted genes that is memorized heritably by cells through cell division and differentiation. Here, we describe our protocol for the delivery of CRISPRoff through plasmid DNA transfection, as well as the delivery of CRISPRoff mRNA, into transformed human cell lines and primary immune cells. We also provide guidance on evaluating target gene silencing and highlight key considerations when utilizing CRISPRoff for gene perturbations. Our protocols are broadly applicable to other CRISPR-based epigenetic editing technologies, as programmable genome manipulation tools continue to evolve rapidly.

Small Interfering RNAs Targeting a Chromatin-Associated RNA Induce Its Transcriptional Silencing in Human Cells.

Transcriptional gene silencing by small interfering RNAs (siRNAs) has been widely described in various species, including plants and yeast. In mammals, its extent remains somewhat debated. Previous studies showed that siRNAs targeting gene promoters could induce the silencing of the targeted promoter, although the involvement of off-target mechanisms was also suggested. Here, by using nascent RNA capture and RNA polymerase II chromatin immunoprecipitation, we show that siRNAs targeting a chromatin-associated noncoding RNA induced its transcriptional silencing. Deletion of the sequence targeted by one of these siRNAs on the two alleles by genome editing further showed that this silencing was due to base-pairing of the siRNA to the target. Moreover, by using cells with heterozygous deletion of the target sequence, we showed that only the wild-type allele, but not the deleted allele, was silenced by the siRNA, indicating that transcriptional silencing occurred only in cis. Finally, we demonstrated that both Ago1 and Ago2 are involved in this transcriptional silencing. Altogether, our data demonstrate that siRNAs targeting a chromatin-associated RNA at a distance from its promoter induce its transcriptional silencing. Our results thus extend the possible repertoire of endogenous or exogenous interfering RNAs.

Natural molecules as modulators of epigenetic silencing in human cells for cancer care and aging

The etiology and pathogenesis of malignant tumor growth are associated with impaired gene expression, leading to accelerated proliferation, evasion of apoptosis, and metabolic deregulations with abnormal blood supply and innervation. Currently, hundreds of tumor suppressor genes and proto-oncogenes are known. Mutations, epigenetic alterations, exposure to viruses, and other environmental factors can cause pathological changes in gene expression. The key mechanisms of carcinogenesis are now considered to be linked to epigenetic events. A better understanding of epigenetic targets and pathways is needed to develop new strategies in antitumor chemotherapy. The majority of modern cancer drugs were taken from nature, yet only a small fraction of natural molecular diversity has been explored to date. Therefore, there is great interest in identifying new natural molecules for modulating gene expression by rewiring epigenetic pathways. This review is focused on examples of known natural molecules available to biomedicine, especially ones capable of modulating epigenetic landscapes and therefore relevant for cancer prevention and aging.

PDS5 proteins are required for proper cohesin dynamics and participate in replication fork protection

Cohesin is a chromatin-bound complex that mediates sister chromatid cohesion and facilitates long-range interactions through DNA looping. How the transcription and replication machineries deal with the presence of cohesin on chromatin remains unclear. The dynamic association of cohesin with chromatin depends on WAPL cohesin release factor (WAPL) and on PDS5 cohesin-associated factor (PDS5), which exists in two versions in vertebrate cells, PDS5A and PDS5B. Using genetic deletion in mouse embryo fibroblasts and a combination of CRISPR-mediated gene editing and RNAi-mediated gene silencing in human cells, here we analyzed the consequences of PDS5 depletion for DNA replication. We found that either PDS5A or PDS5B is sufficient for proper cohesin dynamics and that their simultaneous removal increases cohesin's residence time on chromatin and slows down DNA replication. A similar phenotype was observed in WAPL-depleted cells. Cohesin down-regulation restored normal replication fork rates in PDS5-deficient cells, suggesting that chromatin-bound cohesin hinders the advance of the replisome. We further show that PDS5 proteins are required to recruit WRN helicase-interacting protein 1 (WRNIP1), RAD51 recombinase (RAD51), and BRCA2 DNA repair associated (BRCA2) to stalled forks and that in their absence, nascent DNA strands at unprotected forks are degraded by MRE11 homolog double-strand break repair nuclease (MRE11). These findings indicate that PDS5 proteins participate in replication fork protection and also provide insights into how cohesin and its regulators contribute to the response to replication stress, a common feature of cancer cells.

Targeting of Liver Mannan-Binding Lectin-Associated Serine Protease-3 with RNA Interference Ameliorates Disease in a Mouse Model of Rheumatoid Arthritis.

Mannan-binding lectin–associated serine protease 3 (MASP-3) regulates the alternative pathway of complement and is predominantly synthesized in the liver. The role of liver-derived MASP-3 in the pathogenesis of rheumatoid arthritis (RA) is unknown. We hypothesized that liver-derived MASP-3 is essential for the development of joint damage and that targeted inhibition of MASP-3 in the liver can attenuate arthritis. We used MASP-3–specific small interfering RNAs (siRNAs) conjugated to N-acetylgalactosamine (GalNAc) to specifically target the liver via asialoglycoprotein receptors. Active GalNAc–MASP3–siRNA conjugates were identified, and in vivo silencing of liver MASP-3 mRNA was demonstrated in healthy mice. The s.c. treatment with GalNAc–MASP-3–siRNAs specifically decreased the expression of MASP-3 in the liver and the level of MASP-3 protein in circulation of mice without affecting the levels of the other spliced products. In mice with collagen Ab–induced arthritis, s.c. administration of GalNAc–MASP-3–siRNA decreased the clinical disease activity score to 50% of controls, with decrease in histopathology scores and MASP-3 deposition. To confirm the ability to perform MASP-3 gene silencing in human cells, we generated a lentivirus expressing a short hairpin RNA specific for human MASP-3 mRNA. This procedure not only eliminated the short-term (at day 15) expression of MASP-3 in HepG2 and T98G cell lines but also diminished the long-term (at day 60) synthesis of MASP-3 protein in T98G cells. Our study demonstrates that isoform-specific silencing of MASP-3 in vivo modifies disease activity in a mouse model of RA and suggests that liver-directed MASP3 silencing may be a therapeutic approach in human RA.

Impaired telomere maintenance in Alazami syndrome patients with LARP7 deficiency.

BackgroundLoss of function in genes required for telomere maintenance result in disorders known as telomeropathies, which are characterized by a pattern of symptoms including generalized and specific lymphocytopenias as well as very short telomere length and disease anticipation.MethodsBecause human LARP7 is the most likely ortholog of the Tetrahymena p65 protein, which is required for telomerase activity in that organism, we investigated the effects of LARP7 silencing in human cells as well as in two distinct families with Alazami syndrome (loss of function of LARP7).ResultsDepletion of LARP7 caused a reduction in telomerase enzymatic activity and progressively shorter telomeres in human cancer cell lines. Alazami syndrome patients from two separate cohorts exhibited very short lymphocyte telomeres. Further, wild-type offspring of LARP7 mutant individuals also had very short telomeres, comparable to what is observed in telomerase (hTERT) mutant cohorts.ConclusionsTogether, these experiments demonstrate that in addition to the readily apparent developmental disorder associated with LARP7 deficiency, an underlying telomeropathy exists even in unaffected siblings of these individuals.

Transcriptional gene silencing in humans.

It has been over a decade since the first observation that small non-coding RNAs can functionally modulate epigenetic states in human cells to achieve functional transcriptional gene silencing (TGS). TGS is mechanistically distinct from the RNA interference (RNAi) gene-silencing pathway. TGS can result in long-term stable epigenetic modifications to gene expression that can be passed on to daughter cells during cell division, whereas RNAi does not. Early studies of TGS have been largely overlooked, overshadowed by subsequent discoveries of small RNA-directed post-TGS and RNAi. A reappraisal of early work has been brought about by recent findings in human cells where endogenous long non-coding RNAs function to regulate the epigenome. There are distinct and common overlaps between the proteins involved in small and long non-coding RNA transcriptional regulatory mechanisms, suggesting that the early studies using small non-coding RNAs to modulate transcription were making use of a previously unrecognized endogenous mechanism of RNA-directed gene regulation. Here we review how non-coding RNA plays a role in regulation of transcription and epigenetic gene silencing in human cells by revisiting these earlier studies and the mechanistic insights gained to date. We also provide a list of mammalian genes that have been shown to be transcriptionally regulated by non-coding RNAs. Lastly, we explore how TGS may serve as the basis for development of future therapeutic agents.

Dicer-TRBP Complex Formation Ensures Accurate Mammalian MicroRNA Biogenesis

RNA-mediated gene silencing in human cells requires the accurate generation of ∼22 nt microRNAs (miRNAs) from double-stranded RNA substrates by the endonuclease Dicer. Although the phylogenetically conserved RNA-binding proteins TRBP and PACT are known to contribute to this process, their mode of Dicer binding and their genome-wide effects on miRNA processing have not been determined. We solved the crystal structure of the human Dicer-TRBP interface, revealing the structural basis of the interaction. Interface residues conserved between TRBP and PACT show that the proteins bind to Dicer in a similar manner and by mutual exclusion. Based on the structure, a catalytically active Dicer that cannot bind TRBP or PACT was designed and introduced into Dicer-deficient mammalian cells, revealing selective defects in guide strand selection. These results demonstrate the role of Dicer-associated RNA binding proteins in maintenance of gene silencing fidelity.

Human DDX6 effects miRNA-mediated gene silencing via direct binding to CNOT1.

MicroRNAs (miRNAs) play critical roles in a variety of biological processes through widespread effects on protein synthesis. Upon association with the miRNA-induced silencing complex (miRISC), miRNAs repress target mRNA translation and accelerate mRNA decay. Degradation of the mRNA is initiated by shortening of the poly(A) tail by the CCR4-NOT deadenylase complex followed by the removal of the 5' cap structure and exonucleolytic decay of the mRNA. Here, we report a direct interaction between the large scaffolding subunit of CCR4-NOT, CNOT1, with the translational repressor and decapping activator protein, DDX6. DDX6 binds to a conserved CNOT1 subdomain in a manner resembling the interaction of the translation initiation factor eIF4A with eIF4G. Importantly, mutations that disrupt the DDX6-CNOT1 interaction impair miRISC-mediated gene silencing in human cells. Thus, CNOT1 facilitates recruitment of DDX6 to miRNA-targeted mRNAs, placing DDX6 as a downstream effector in the miRNA silencing pathway.

Senescence is an endogenous trigger for microRNA-directed transcriptional gene silencing in human cells

Cellular senescence is a tumour-suppressor mechanism that is triggered by cancer-initiating or promoting events in mammalian cells. The molecular underpinnings for this stable arrest involve transcriptional repression of proliferation-promoting genes regulated by the retinoblastoma (RB1)/E2F repressor complex. Here, we demonstrate that AGO2, RB1 and microRNAs (miRNAs), as exemplified here by let-7, physically and functionally interact to repress RB1/E2F-target genes in senescence, a process that we call senescence-associated transcriptional gene silencing (SA-TGS). Herein, AGO2 acts as the effector protein for let-7-directed implementation of silent-state chromatin modifications at target promoters, and inhibition of the let-7/AGO2 effector complex perturbs the timely execution of senescence. Thus, we identify cellular senescence as the an endogenous signal of miRNA/AGO2-mediated TGS in human cells. Our results suggest that miRNA/AGO2-mediated SA-TGS may contribute to tumour suppression by stably repressing proliferation-promoting genes in premalignant cancer cells.

The ribosomal protein RACK1 is required for microRNA function in both C. elegans and humans.

Despite the importance of microRNAs (miRNAs) in gene regulation, it is unclear how the miRNA-Argonaute complex--or miRNA-induced silencing complex (miRISC)--can regulate the translation of their targets in such diverse ways. We demonstrate here a direct interaction between the miRISC and the ribosome by showing that a constituent of the eukaryotic 40S subunit, receptor for activated C-kinase (RACK1), is important for miRNA-mediated gene regulation in animals. In vivo studies demonstrate that RACK1 interacts with components of the miRISC in nematodes and mammals. In both systems, the alteration of RACK1 expression alters miRNA function and impairs the association of the miRNA complex with the translating ribosomes. Our data indicate that RACK1 can contribute to the recruitment of miRISC to the site of translation, and support a post-initiation mode of miRNA-mediated gene repression.

Abstract 3008: Genome-wide siRNA screening identifies epigenetic silencing factor networks as potential targets for cancer therapy

Abstract Epigenetic processes control the binary on-off states of specific gene sets, thereby creating heritable transcription patterns that drive development, and maintain cellular identity. The prominent epigenetic regulatory marks on eukaryotic chromatin are histone modifications and DNA cytosine methylation (5meCpG). These marks are placed by protein complexes, including members of the histone modifying and DNA methyltransferase (DNMT) enzyme families. It is hypothesized that errors in placement, removal, or reading of epigenetic marks can cause human disease through inappropriate silencing of specific genes. As the epigenetic marks that mediate gene silencing are reversible, there is interest in devising therapeutic strategies to reactivate epigenetically silent genes. Inhibitors of DNA methyltransferase (DNMT) and histone deacetylase (HDAC) enzyme families can reverse epigenetic silencing and produce anti-tumor effects, possibly through reactivation of silent tumor suppressor genes (so-called epigenetic therapy). As these inhibitors show limited specificity within enzyme families, their precise mechanisms of action are not well understood. To identify cellular factors involved in maintenance of epigenetic silencing, we constructed a population of human cells harboring epigenetically silent GFP reporter genes. Using this cell population we have implemented a GFP reporter-based siRNA knockdown screen to identify novel factors and networks that maintain epigenetic silencing in human cells. We have now completed a genome-wide, high throughput siRNA-based screen (21,122 siRNA targets). The screen has produced 128 gene hits that have satisfied several validating criteria. The output of this screen was of high quality, as several of the factors were identified in an earlier independent screen. Among the newly identified hits, there was a significant enrichment for factors that mediate SUMOylation, as well as 25 factors corresponding to novel genes, including 9 with no predicted functions. This screen has the potential to identify novel cellular pathways and reveal new targets for epigenetic therapy of cancer and other diseases. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 3008. doi:10.1158/1538-7445.AM2011-3008

MCM-BP regulates unloading of the MCM2–7 helicase in late S phase

Origins of DNA replication are licensed by recruiting MCM2-7 to assemble the prereplicative complex (pre-RC). How MCM2-7 is inactivated or removed from chromatin at the end of S phase is still unclear. Here, we show that MCM-BP can disassemble the MCM2-7 complex and might function as an unloader of MCM2-7 from chromatin. In Xenopus egg extracts, MCM-BP exists in a stable complex with MCM7, but is not associated with the MCM2-7 hexameric complex. MCM-BP accumulates in nuclei in late S phase, well after the loading of MCM2-7 onto chromatin. MCM-BP immunodepletion in Xenopus egg extracts inhibits replication-dependent MCM dissociation without affecting pre-RC formation and DNA replication. When excess MCM-BP is incubated with Xenopus egg extracts or immunopurified MCM2-7, it binds to MCM proteins and promotes disassembly of the MCM2-7 complex. Recombinant MCM-BP also releases MCM2-7 from isolated late-S-phase chromatin, but this activity is abolished when DNA replication is blocked. MCM-BP silencing in human cells also delays MCM dissociation in late S phase. We propose that MCM-BP plays a key role in the mechanism by which pre-RC is cleared from replicated DNA in vertebrate cells.

Removal of Spindly from microtubule-attached kinetochores controls spindle checkpoint silencing in human cells

The spindle checkpoint generates a "wait anaphase" signal at unattached kinetochores to prevent premature anaphase onset. Kinetochore-localized dynein is thought to silence the checkpoint by transporting checkpoint proteins from microtubule-attached kinetochores to spindle poles. Throughout metazoans, dynein recruitment to kinetochores requires the protein Spindly. Here, we identify a conserved motif in Spindly that is essential for kinetochore targeting of dynein. Spindly motif mutants, expressed following depletion of endogenous Spindly, target normally to kinetochores but prevent dynein recruitment. Spindly depletion and Spindly motif mutants, despite their similar effects on kinetochore dynein, have opposite consequences on chromosome alignment and checkpoint silencing. Spindly depletion delays chromosome alignment, but Spindly motif mutants ameliorate this defect, indicating that Spindly has a dynein recruitment-independent role in alignment. In Spindly depletions, the checkpoint is silenced following delayed alignment by a kinetochore dynein-independent mechanism. In contrast, Spindly motif mutants are retained on microtubule-attached kinetochores along with checkpoint proteins, resulting in persistent checkpoint signaling. Thus, dynein-mediated removal of Spindly from microtubule-attached kinetochores, rather than poleward transport per se, is the critical reaction in checkpoint silencing. In the absence of Spindly, a second mechanism silences the checkpoint; this mechanism is likely evolutionarily ancient, as fungi and higher plants lack kinetochore dynein.

Removal of Spindly from microtubule-attached kinetochores controls spindle checkpoint silencing in human cells

Removal of Spindly from microtubule-attached kinetochores controls spindle checkpoint silencing in human cells

RNAi and iTRAQ reagents united: targeted quantitation of siRNA-mediated protein silencing in human cells

Bridging the gap between functional genomics and traditional molecular cell biology is a challenge of the next decade. Here, we are aiming to find routines for targeted quantitation of protein silencing in response to RNAi based on complex cellular lysates. A workflow was established adapting siRNA treatment, processing the sample, generating isobaric iTRAQ-reagent-labeled peptides, and analyzing the sample applying MRM-based peptide quantitation to verify protein silencing on a 4000 QTRAP LC/MS/MS mass spectrometer. Subsequently, eight targets were analyzed, mostly with two siRNA designs. Although transcript and protein silencing correlated, the downregulation on the protein level was less pronounced. A time-course analysis of the chaperon HSPA9/mortalin indicated a delayed kinetic of protein versus transcript silencing. Further, the analysis of the functional response on the example of HSD17B4, a multifunctional enzyme essential to generate precursors for cholesterol biosynthesis, confirmed that strong silencing on the transcript level accompanied by moderate reduction of protein is sufficient to generate a physiological significant response. Fifty percent protein silencing resulted in a 3.5-fold induction of low-density lipoprotein and therefore cholesterol uptake in human liver cells. The established routines pave the way for the development of targeted protein quantitation assays suitable for target and biomarker validation.

Promoter targeted small RNAs induce long-term transcriptional gene silencing in human cells

Small RNAs targeted to gene promoters in human cells can mediate transcriptional gene silencing (TGS) by directing silent state epigenetic modifications to targeted loci. Many mechanistic details of this process remain poorly defined, and the ability to stably modulate gene expression in this manner has not been explored. Here we describe the mechanisms of establishment and maintenance of long-term transcriptional silencing of the human ubiquitin C gene (UbC). Sustained targeting of the UbC promoter with a small RNA for a minimum of 3 days resulted in long-term silencing which correlated with an early increase in histone methylation and a later increase in DNA methylation at the targeted locus. Transcriptional silencing of UbC required the presence of a promoter-associated RNA. The establishment and maintenance of the TGS were shown to require distinct protein factors. Argonaute 1 (Ago1), DNA methyltransferase 3a (DNMT3a) and histone deacetylase 1 (HDAC1) were required for the initiation of silencing, and DNA methyltransferase 1 (DNMT1) was necessary for maintenance. Taken together the data presented here highlight the cellular pathway with which noncoding RNAs interact to epigenetically regulate gene expression in human cells.

Consequence of single break near telomere in human cells

Low dose radiation effects remain an open question, mainly due to the lack of models that permit to address it. Using human cells tagged with a plasmid integrated on end of a “marker” chromosome, we demonstrated that a single break near the telomere has dramatic consequences on the genome stability, inducing the panel of chromosomal instability detected in cancer cells including gene amplification and large chromosome imbalances (LOH up to 100 Mb), Sabatier et al, Mol Cancer Res 2005. One of the consequences of the chromosome instability induced by a single telomere loss is to let emerge cells with high proliferative advantages. An increase of the tumorigenicity of these cells is observed when transplanted on nude mice. Such cell models would be very informative to characterize the role of the modulation of DNA damage repair (NHEJ and HR) in the consequence of single chromosome break. First we tested the feasibility of using replicative small interfering vectors for efficient and long term silencing in human cells. We silenced NHEJ protein -DNAPK, LigIV, and XRCC4- and HR protein -Rad51/Rad52/Rad54- in Hela cells. Our data suggested that the major effect of NHEJ on telomere maintenance is indirect via misrepaired breaks in subtelomeric and telomeric whereas the major effect of HR on telomere maintenance is direct via telomere replication and telomere recombination. We are working on the invalidation of DNA repair genes in telomere tagged models. Having demonstrated that a single break near telomere could have such consequences we now address the question of radiation-induced chromosome breaks that will occur at low doses (25 mGy -> 1DSB per cell), stuying clonogenic survival and the emergence of resistant clones due to chromosome breakage.

Small interfering RNA induced transcriptional gene silencing in human cells

Small interfering RNA induced transcriptional gene silencing in human cells

RNAi

RNAi