Project description:Background: LINE-1 elements make up the most abundant retrotransposon family in the human genome. Full-length LINE-1 elements encode their own reverse transcriptase (RT). They are expressed at low levels in normal cells and abundantly in cancer cells. RT down-regulation, by either RNA interference to LINE-1 elements, or by RT inhibitory drugs, was previously found to reduce proliferation and promote differentiation in cancer cells and to antagonize tumor growth in animal models. Results: We report that the RT inhibitor efavirenz effectively inhibit proliferation of a variety of human tumorigenic cell lines while only slightly affecting the proliferation of human normal fibroblast cell line, a difference that nicely matches RT expression in the former cell lines and its lack in the latter. The finding of Alu and LINE-1 containing DNA:RNA hybrid molecules - identified by CsCl density gradients - selectively in cancer but not in normal cells, suggests that RNA transcripts from these retroelements are candidate substrates for reverse transcription. These hybrids disappear in tumor cells treated with efavirenz, under the same conditions which induce an extensive reprogrammed expression profiles for protein-coding genes, microRNAs (miRNAs) and ultraconserved regions (UCRs). The RT-sensitive miRNAs and UCRs are significantly associated with Alus sequences. Conclusions: A novel RT-dependent mechanism governs the balance between single-stranded and double-stranded RNA production. In cancer cells, the abundant LINE-1-encoded RT reverse-transcribes retroelement-derived mRNAs, generating RNA:DNA hybrids. We propose that this impairs the formation of double-stranded RNAs and the ensuing production of small regulatory RNAs, with a direct impact on gene expression. RT inhibition restores the M-^QnormalM-^R small RNA profile and the regulatory networks that depend on them. Thus, the retrotransposon-encoded RT drives an epigenetic mechanism crucial to maintenance of the transformed state in tumor cells.

Project description:Background: LINE-1 elements make up the most abundant retrotransposon family in the human genome. Full-length LINE-1 elements encode their own reverse transcriptase (RT). They are expressed at low levels in normal cells and abundantly in cancer cells. RT down-regulation, by either RNA interference to LINE-1 elements, or by RT inhibitory drugs, was previously found to reduce proliferation and promote differentiation in cancer cells and to antagonize tumor growth in animal models. Results: We report that the RT inhibitor efavirenz effectively inhibit proliferation of a variety of human tumorigenic cell lines while only slightly affecting the proliferation of human normal fibroblast cell line, a difference that nicely matches RT expression in the former cell lines and its lack in the latter. The finding of Alu and LINE-1 containing DNA:RNA hybrid molecules - identified by CsCl density gradients - selectively in cancer but not in normal cells, suggests that RNA transcripts from these retroelements are candidate substrates for reverse transcription. These hybrids disappear in tumor cells treated with efavirenz, under the same conditions which induce an extensive reprogrammed expression profiles for protein-coding genes, microRNAs (miRNAs) and ultraconserved regions (UCRs). The RT-sensitive miRNAs and UCRs are significantly associated with Alus sequences. Conclusions: A novel RT-dependent mechanism governs the balance between single-stranded and double-stranded RNA production. In cancer cells, the abundant LINE-1-encoded RT reverse-transcribes retroelement-derived mRNAs, generating RNA:DNA hybrids. We propose that this impairs the formation of double-stranded RNAs and the ensuing production of small regulatory RNAs, with a direct impact on gene expression. RT inhibition restores the M-^QnormalM-^R small RNA profile and the regulatory networks that depend on them. Thus, the retrotransposon-encoded RT drives an epigenetic mechanism crucial to maintenance of the transformed state in tumor cells.

Project description:LINE-1/L1 retrotransposon sequences compose 17% of the human genome. Among the many classes of mobile genetic elements, L1 is the only autonomous retrotransposon that still drives human genomic plasticity today. Through its co-evolution with the human genome, L1 has intertwined itself with host cell biology to aid its proliferation.

Project description:Retrotransposable elements are genomic parasites that are both key drivers of evolution and the ancestors of retroviruses. Although host cells have developed numerous mechanisms to keep these elements in check, there is also evidence from yeast to mammals that stressed cells sometimes activate transposition. Here we show that the fission yeast tf2 retrotransposons are regulated by alternative transcription start site (TSS) usage. Which TSS is used is determined by nucleosome positioning, which is in turn controlled by the Fun30 chromatin remodelers Fft2 and Fft3. By maintaining a high level of nucleosome occupancy at retrotransposon-flanking Long Terminal Repeat (LTR) elements, Fft2 and Fft3 promote the use of a downstream TSS and the production of RNA incapable of reverse transcription and retrotransposition. More generally, we show that Fft2 and Fft3 are involved in repressing the transcriptional response to stress, of which retrotransposon activation is a part. Finally, we show that in stressed cells retrotransposon TSS usage switches, allowing the production of full-length retrotransposon RNA. We propose that allowing retrotransposon transcription from a nonproductive TSS allows for the rapid activation of these elements in times of stress, while preventing their uncontrolled proliferation in the genome.

Project description:Retrotransposable elements are genomic parasites that are both key drivers of evolution and the ancestors of retroviruses. Although host cells have developed numerous mechanisms to keep these elements in check, there is also evidence from yeast to mammals that stressed cells sometimes activate transposition. Here we show that the fission yeast tf2 retrotransposons are regulated by alternative transcription start site (TSS) usage. Which TSS is used is determined by nucleosome positioning, which is in turn controlled by the Fun30 chromatin remodelers Fft2 and Fft3. By maintaining a high level of nucleosome occupancy at retrotransposon-flanking Long Terminal Repeat (LTR) elements, Fft2 and Fft3 promote the use of a downstream TSS and the production of RNA incapable of reverse transcription and retrotransposition. More generally, we show that Fft2 and Fft3 are involved in repressing the transcriptional response to stress, of which retrotransposon activation is a part. Finally, we show that in stressed cells retrotransposon TSS usage switches, allowing the production of full-length retrotransposon RNA. We propose that allowing retrotransposon transcription from a nonproductive TSS allows for the rapid activation of these elements in times of stress, while preventing their uncontrolled proliferation in the genome.

Project description:Existing single-cell RNA sequencing (scRNA-seq) methods rely on reverse transcription (RT) and second-strand synthesis (SSS) to convert single-stranded RNA into double-stranded DNA prior to amplification, with the limited RT/SSS efficiency compromising RNA detectability. Here, we develop a new scRNA-seq method, Linearly Amplified Single-stranded-RNA-derived Transcriptome sequencing (LAST-seq), which directly amplifies the original single-stranded RNA molecules without prior RT/SSS. LAST-seq offers a high single-molecule capture efficiency and a low level of technical noise for single-cell transcriptome analyses. Using LAST-seq, we characterize transcriptional bursting kinetics in human cells, revealing a role of topologically associating domains in transcription regulation.

Project description:Whereas techniques to map chromatin-bound proteins are well-developed, mapping chromatin-associated RNAs remains a challenge. Here we describe Reverse Transcribe & Tagment (RT&Tag), in which RNAs associated with a chromatin epitope are targeted by an antibody followed by a protein A-Tn5 transposome. Localized reverse transcription generates and the Tn5 transposase tagments RNA/cDNA hybrids. We demonstrate the utility of RT&Tag in Drosophila cells for capturing the noncoding RNA roX2 with the dosage compensation complex and maturing transcripts associated with silencing histone modifications. We also show that RT&Tag can detect N6-methyladenosine (m6A)-modified mRNAs, and show that genes producing methylated transcripts are characterized by extensive promoter pausing of RNA polymerase II. The high efficiency of in situ antibody tethering and tagmentation makes RT&Tag especially suitable for rapid low-cost profiling chromatin-associated RNAs from small samples.

Project description:Rifampicin and efavirenz are commonly used medicines to treat tuberculosis (rifampicin) and HIV/AIDS (efavirenz). Rifampicin and efavirenz are metabolized in the liver and exposure to these medicines can alter microRNA expression in hepatocytes. Changes in microRNA expression may affect metabolism of these medicines and potentially influence how patient's respond to therapy. It is important to understand changes in microRNA expression in a hepatic cell-based model. Differentiated HepaRG cells were used because mRNA expression and induction of drug metabolizing enzymes are comparable to that of primary human hepatocytes yet differentiated HepaRG cells have an extended lifespan. Differentiated HepaRG cells were obtained from Merck Millipore and cultured as an adherent cell line at a density of 315000 cells/well using collagen I coated 24-well plates. Clinically relevant concentrations of rifampicin and efavirenz were selected as 6.4uM efavirenz (dissolved in 100% dimethyl sulfoxide) and 24.4uM rifampicin (dissolved in 100% dimethyl sulfoxide), while 0.02% dimethyl sulfoxide was used as control to minimize toxicity. HepaRG serum-free induction medium was used to dilute efavirenz and rifampicin. On day 7 since thawing differentiated HepaRG cells, these cells were treated with 6.4uM efavirenz or 24.4uM rifampicin or 0.02% dimethyl sulfoxide for a period of 24 hours. Three biological replicates were available for each treatment condition. Total RNA was isolated from the cells, after treatment, using the Quick-RNATM MiniPrep Kit from Zymo Research Corporation. MicroRNA expression profiling was performed using the TaqMan® OpenArray® Human MicroRNA Panel and QuantStudioTM 12K Flex system. The R/Bioconductor package “Automated Analysis of High-Throughput qPCR Data” were used for data analyses. CT values were used for differential expression analysis and microRNAs with a CT value > 35 was considered undetected. MicroRNAs undetected in any of the replicate samples or microRNAs with AmpScore < 1.24 or CqConf < 0.8 were excluded. Quantile normalization was followed by limma analyses to identify differentially expressed microRNAs for efavirenz versus dimethyl sulfoxide and rifampicin versus dimethyl sulfoxide.

Project description:Although high-risk human papillomavirus (HPV) infection plays a major role in the development of cervical cancer, additive oncogenic events are involved as well. One key event involves increased activity of telomerase resulting from a deregulated expression of its catalytic subunit hTERT. Our previous microcell-mediated chromosome transfer studies revealed that introduction of human chromosome 6 in the HPV16 immortalized keratinocyte cell line FK16A and in the HPV16 containing cervical cancer cell line SiHa induced growth arrest, resulting from a repression of hTERT mRNA expression and telomerase activity. Here, this model was used to analyze expression profiles associated with hTERT deregulation in HPV transformed cells. Microarray expression analysis of 12 FK16A/chromosome 6 hybrids, four of which were negative for endogenous hTERT and 8 of which were positive for endogenous hTERT, resulted in the identification of 164 differentially expressed genes. Differential expression of a selection of 5 genes was verified by real-time RT-PCR. Of these 164 genes, 32 were also differentially expressed in other HPV transformed cells with deregulated hTERT. For 2 of these genes, encoding AQP3 and MGP, altered expression in hTERT positive cervical carcinomas was confirmed by real-time RT-PCR and immunohistochemistry, respectively. In summary we identified 32 candidate biomarkers for deregulated hTERT mRNA expression which may enable the identification of cervical premalignant lesions that are at highest risk to progress to invasive cancer. Keywords: microarray expression analysis, hTERT, cervical cancer 12 previously established cell hybrids, all carrying the same genetic background were subjected to microarray expression analysis. These hybrids were generated by the introduction of chromosome 6 in the HPV16 immortalized cell line FK16A, which resulted in a suppression of hTERT expression and telomerase activity. 8 hybrids were endogenous hTERT positive and 8 hybrids were hTERT negative. Additionally primary keratinocytes (hTERT negative), parental cell line FK16A and cervical cancer cell line SiHa (both hTERT positive) were hybridized.

Project description:The Human Silencing Hub (HuSH) complex is a complex that silences retrotransposable elements invertebrates. Here, we identify a second HuSH complex, designated HuSH2, which is centered aroundTASOR2, a paralog of the core TASOR protein in HuSH. Our findings reveal that HuSH and HuSH2 localize todistinct and non-overlapping genomic loci. Specifically, HuSH localizes to and represses LINE-1retrotransposons, whereas HuSH2 targets and represses KRAB-ZNFs and interferon signaling and responsegenes. We use in silico protein structure predictions to simulate MPP8 interactions with TASOR paralogs,guiding amino acid substitutions that disrupted binding to HuSH complexes. These MPP8 transgenes andother constructs reveal the importance of HuSH complex quantities in regulating LINE-1 activity. Furthermore,our results suggest that dynamic changes in TASOR and TASOR2 expression enable cells to finely tuneHuSH-mediated silencing. This study offers insights into the interplay of HuSH complexes, highlighting theirvital role in retrotransposon regulation.