Project description:It is currently unknown how extensively the double-stranded RNA binding protein Staufen (Stau)1 is utilized by mammalian cells to regulate gene expression. To date, Stau1 binding to the 3’ untranslated region (3’UTR) of ARF1 mRNA has been shown to target ARF1 mRNA for Stau1-mediated mRNA decay (SMD). ARF1 SMD depends on translation and recruitment of the nonsense-mediated mRNA decay factor Upf1 to the ARF1 3’UTR by Stau1. Here, we use microarray analyses to examine changes in the abundance of cellular mRNAs that occur when Stau1 is depleted. Results indicate that 1.1% and 1.0% of the 11,569 HeLa-cell transcripts that were analyzed are, respectively, upregulated and downregulated at least two-fold in three independently performed experiments. Additionally, we localize the Stau1 binding site to the 3’UTR of four mRNAs that we define as natural SMD targets. Together, these and substantiating results suggest that Stau1 influences the expression of a wide variety of physiologic transcripts and metabolic pathways. Keywords: Staufen1-mediated mRNA decay; Stau1 downregulation by siRNA.

Project description:It is currently unknown how extensively the double-stranded RNA binding protein Staufen (Stau)1 is utilized by mammalian cells to regulate gene expression. To date, Stau1 binding to the 3’ untranslated region (3’UTR) of ARF1 mRNA has been shown to target ARF1 mRNA for Stau1-mediated mRNA decay (SMD). ARF1 SMD depends on translation and recruitment of the nonsense-mediated mRNA decay factor Upf1 to the ARF1 3’UTR by Stau1. Here, we use microarray analyses to examine changes in the abundance of cellular mRNAs that occur when Stau1 is depleted. Results indicate that 1.1% and 1.0% of the 11,569 HeLa-cell transcripts that were analyzed are, respectively, upregulated and downregulated at least two-fold in three independently performed experiments. Additionally, we localize the Stau1 binding site to the 3’UTR of four mRNAs that we define as natural SMD targets. Together, these and substantiating results suggest that Stau1 influences the expression of a wide variety of physiologic transcripts and metabolic pathways. Experiment Overall Design: We report the results of three independently performed microarray analyses that examined changes in the abundance of transcripts from HeLa-cell genes upon Stau1 depletion. HeLa cells were transiently transfected with either a nonspecific Control small interfering (si)RNA or Stau1 siRNA. Stau1 siRNA reduced the level of cellular Stau1 to as little as 4% of normal, where normal is defined as the level in the presence of Control siRNA (data not shown). RNA from three independently performed transfections was separately hybridized to microarrays.

Project description:UPF1-mediated decay entails several mRNA surveillance pathways that play a crucial role in cellular homeostasis. However, the precise role of UPF1 in postmitotic neurons remains unresolved, as does its activity in amyotrophic lateral sclerosis (ALS), a devastating neurodegenerative disease characterized by TDP-43 pathology and disrupted mRNA metabolism. Here, we used human iPSC-derived spinal motor neurons (MNs) to identify mRNAs subject to UPF1 degradation by integrating RNA-seq before and after UPF1 knockdown with RIP-seq to identify RNAs that co-immunoprecipitate with the active form of phosphorylated UPF1. We define a stringent set of bona fide UPF1 targets in MNs that are functionally enriched for autophagy and structurally enriched for GC-rich and long 3' UTRs but not for premature termination codon (PTC)-containing transcripts. TDP-43 depletion in iPSC-derived MNs reduces UPF1 phosphorylation and consequently post-transcriptional upregulation of UPF1 targets, suggesting that TDP-43 dysfunction compromises UPF1-mediated mRNA surveillance. Intriguingly, our datasets reveal that UPF1 and TDP-43 regulate alternative polyadenylation and 3'UTR length of mRNAs associated with synaptic and axonal function, a process that we find to be compromised in ALS models in vitro and ALS patient tissue. Our study provides a comprehensive description of UPF1-mediated mRNA decay activity in neurons, reveals overlapping roles between UPF1 and TDP-43 in regulating 3'UTR length, and offers novel insight into the intricate interplay between RNA metabolism and neurodegeneration in ALS.

Project description:UPF1-mediated decay entails several mRNA surveillance pathways that play a crucial role in cellular homeostasis. However, the precise role of UPF1 in postmitotic neurons remains unresolved, as does its activity in amyotrophic lateral sclerosis (ALS), a devastating neurodegenerative disease characterized by TDP-43 pathology and disrupted mRNA metabolism. Here, we used human iPSC-derived spinal motor neurons (MNs) to identify mRNAs subject to UPF1 degradation by integrating RNA-seq before and after UPF1 knockdown with RIP-seq to identify RNAs that co-immunoprecipitate with the active form of phosphorylated UPF1. We define a stringent set of bona fide UPF1 targets in MNs that are functionally enriched for autophagy and structurally enriched for GC-rich and long 3' UTRs but not for premature termination codon (PTC)-containing transcripts. TDP-43 depletion in iPSC-derived MNs reduces UPF1 phosphorylation and consequently post-transcriptional upregulation of UPF1 targets, suggesting that TDP-43 dysfunction compromises UPF1-mediated mRNA surveillance. Intriguingly, our datasets reveal that UPF1 and TDP-43 regulate alternative polyadenylation and 3'UTR length of mRNAs associated with synaptic and axonal function, a process that we find to be compromised in ALS models in vitro and ALS patient tissue. Our study provides a comprehensive description of UPF1-mediated mRNA decay activity in neurons, reveals overlapping roles between UPF1 and TDP-43 in regulating 3'UTR length, and offers novel insight into the intricate interplay between RNA metabolism and neurodegeneration in ALS.

Project description:UPF1-mediated decay entails several mRNA surveillance pathways that play a crucial role in cellular homeostasis. However, the precise role of UPF1 in postmitotic neurons remains unresolved, as does its activity in amyotrophic lateral sclerosis (ALS), a devastating neurodegenerative disease characterized by TDP-43 pathology and disrupted mRNA metabolism. Here, we used human iPSC-derived spinal motor neurons (MNs) to identify mRNAs subject to UPF1 degradation by integrating RNA-seq before and after UPF1 knockdown with RIP-seq to identify RNAs that co-immunoprecipitate with the active form of phosphorylated UPF1. We define a stringent set of bona fide UPF1 targets in MNs that are functionally enriched for autophagy and structurally enriched for GC-rich and long 3' UTRs but not for premature termination codon (PTC)-containing transcripts. TDP-43 depletion in iPSC-derived MNs reduces UPF1 phosphorylation and consequently post-transcriptional upregulation of UPF1 targets, suggesting that TDP-43 dysfunction compromises UPF1-mediated mRNA surveillance. Intriguingly, our datasets reveal that UPF1 and TDP-43 regulate alternative polyadenylation and 3'UTR length of mRNAs associated with synaptic and axonal function, a process that we find to be compromised in ALS models in vitro and ALS patient tissue. Our study provides a comprehensive description of UPF1-mediated mRNA decay activity in neurons, reveals overlapping roles between UPF1 and TDP-43 in regulating 3'UTR length, and offers novel insight into the intricate interplay between RNA metabolism and neurodegeneration in ALS.

Project description:A majority of metazoan mRNAs are under microRNA (miRNA)/Argonaute (Ago)-mediated control of RNA stability at the post-transcriptional level. Although the molecular mechanism of the miRNA-mediated repression of target mRNAs through Ago/TNRC6 pathway have been largely elucidated, however, the existence of alternative TNRC6-independent miRNA-mediated post-transcriptional gene regulation pathway remains unknown. Here, we suggest that endogenous miRNAs (endo-miRNAs) can downregulate the target mRNAs via the alternative molecular pathway, Ago-associated UPF1/SMG7, core mediators of nonsense-mediated mRNA decay. Global analyses of mRNAs in a response to UPF1 RNA interference in miRNA-deficient cells reveal that 3’UTR-length-dependent mRNA decay by UPF1 requires endo-miRNA targeting via CUG motif. The repression of miRNA targets is more additively or synergistically accomplished by combination of Ago2 and UPF1 through UPF1-associated SMG7, recruiting CCR4-NOT deadenylase complex, in TNRC6-independent manner. We expect that the new miRNA-mediated mRNA decay pathway enables the miRNA targeting to become more predictable and expand the miRNA-mRNA regulatory network.

Project description:Nonsense-mediated mRNA decay (NMD) controls the quality of eukaryotic gene expression and also degrades physiologic mRNAs. How NMD targets are identified is incompletely understood. A central NMD factor is the ATP-dependent RNA helicase UPF1. Neither the distance in space between the termination codon and the poly(A) tail nor the binding of steady-state, largely hypophosphorylated UPF1 is a discriminating marker of cellular NMD targets, unlike for PTC-containing reporter mRNAs when compared to their PTC-free counterparts. Here, we map phosphorylated UPF1 (p-UPF1) binding sites using transcriptome-wide footprinting or DNA oligonucleotide-directed mRNA cleavage to report that p-UPF1 provides the first reliable cellular NMD-target marker. p-UPF1 is enriched on NMD target 3'UTRs along with SMG5 and SMG7 but not SMG1 or SMG6. Immunoprecipitations of UPF1 variants deficient in various aspects of the NMD process in parallel with FRET experiments reveal that ATPase/helicase-deficient UPF1 manifests high levels of RNA binding and disregulated hyperphosphorylation, whereas wild-type UPF1 releases from nonspecific RNA interactions in an ATP hydrolysis-dependent mechanism until an NMD target is identified. 3'UTR-associated UPF1 undergoes regulated phosphorylation on NMD targets, providing a binding platform for mRNA degradative activities. p-UPF1 binding to NMD target 3'UTRs is stabilized by SMG5 and SMG7. Our results help to explain why steady-state UPF1 binding is not a marker for cellular NMD substrates and how this binding is transformed to induce mRNA decay. RIP-seq experiments for p-UPF1, control IPs using rabbit IgG and additional control sample without IP were performed in duplicates

Project description:The presence of an exon junction more than 55nt downstream of a stop codon is generally considered to be a trigger for nonsense-mediated decay (NMD). Thus, transcripts containing 3’UTR introns (3UIs) are often considered as transcriptional noise. Interestingly, upon knockdown of NMD factor UPF1 we see examples of both increased and decreased expression of the 3UI-spliced isoforms. In the oncogene HRAS, upon UPF1 knockdown, we see the 3UI-retaining isoform increases in expression where the spliced isoform decreases, suggesting that 3UI splicing protects the transcript against UPF1-mediated degradation.

Project description:RNA sequencing of heterozygote or Tudor domain contian protein 6 (TDRD6) knockout round spermatid cells. Chromatoid bodies (CBs) are germ cell-specific organelles of largely unknown function. CBs harbor various RNA species, RNA-associated proteins and proteins of the tudor domain family such as TDRD6. Proteome analysis of purified CBs revealed components of the nonsense-mediated mRNA decay machinery such as UPF1. TDRD6 is essential for UPF1 localization to CBs, for UPF1-UPF2 interaction, and for assembly of UPFs and other RNA binding proteins into super-complexes. In absence of TDRD6, the association of some mRNAs with UPF1 is impaired, and the long 3’ UTR-stimulated but not the exon junction complex-stimulated pathway of NMD is distorted. Reduced association of mRNAs with UPF1 correlated with increased stability and presence in polysome fractions, i.e. enhanced translational activity. Thus, we define CBs as sites of UPF1-dependent mRNA degradation and provide evidence for the requirement for NMD in spermiogenesis. This function of CBs depends on TDRD6-promoted assembly of mRNA decay enzymes within mRNPs.

Project description:Several of the thousands of human long non-coding RNAs (lncRNAs) have been functionally characterized; however, potential roles for lncRNAs in somatic tissue differentiation remain poorly understood. Here we show that a 3.7kb lncRNA, terminal differentiation-induced ncRNA (TINCR), controls human epidermal differentiation by a post-transcriptional mechanism. TINCR is required for high mRNA abundance of key differentiation genes, many of which are mutated in human skin diseases, including FLG, LOR, ALOXE3, ALOX12B, ABCA12, CASP14 and ELOVL3. TINCR-deficient epidermis lacked terminal differentiation ultrastructure, including keratohyalin granules and intact lamellar bodies. Genome-scale RNA interactome analysis revealed that TINCR interacts with a suite of differentiation mRNAs. TINCR-mRNA interaction occurs through a 25 nucleotide M-bM-^@M-^\TINCR boxM-bM-^@M-^] motif which is strongly enriched in interacting mRNAs and required for TINCR binding. A high-throughput screen to analyze TINCR binding capacity to ~9,400 human recombinant proteins revealed direct binding of TINCR RNA to the Staufen1 (STAU1) protein. STAU1-deficient tissue recapitulated the impaired differentiation seen with TINCR depletion. Loss of UPF1 and UPF2, both of which are required for STAU1-mediated RNA decay (SMD), however, lacked differentiation impacts. Instead, the TINCR/STAU1 complex seems to mediate stabilization of differentiation mRNAs, such as KRT80. These data identify TINCR as a key lncRNA required for somatic tissue differentiation, which occurs through inducible lncRNA binding to differentiation mRNAs to ensure their expression. Examination of TINCR-binding RNAs using two independent pools of TINCR-targeting oligos