Project description:Ribosome pausing plays a crucial role in the collapse of proteostasis, which is a prominent characteristic of cellular senescence. However, the understanding of ribosome pausing in senescent cells remains limited. In this study, we utilized ribosome profiling and G-quadruplex RNA immunoprecipitation sequencing techniques to investigate the impact of RNA G-quadruplex (rG4) on the translation efficiency of genes in senescent cells. Our findings reveal a decrease in the translation efficiency of genes enriched with rG4 in senescent cells. Meanwhile, we developed a dual fluorescence reporter system to demonstrate the ability of rG4 to halt ribosome translation both in vivo and in vitro. Moreover, a noteworthy augmentation in the prevalence of rG4 abundance was observed in senescent cells, and the reinforcement of the rG4 structure further exacerbates the process of cellular senescence. Additionally, the RNA helicase DHX9 was identified as a crucial regulator of rG4 abundance, and its reduced expression in senescent cells exacerbates the occurrence of ribosome pausing. Intriguingly, we also observed an augmented abundance of rG4, an imbalance in protein homeostasis, and a decrease in DHX9 expression in the fibroblast cells and highly aged tissues of aging mice. In summary, our findings reveal a novel biological role of rG4 and DHX9 in the regulation of ribosome translation and proteostasis, potentially providing implications for the postponement of cellular senescence and ageing.

Project description:Ribosome pausing plays a crucial role in the collapse of proteostasis, which is a prominent characteristic of cellular senescence. However, the understanding of ribosome pausing in senescent cells remains limited. In this study, we utilized ribosome profiling and G-quadruplex RNA immunoprecipitation sequencing techniques to investigate the impact of RNA G-quadruplex (rG4) on the translation efficiency of genes in senescent cells. Our findings reveal a decrease in the translation efficiency of genes enriched with rG4 in senescent cells. Meanwhile, we developed a dual fluorescence reporter system to demonstrate the ability of rG4 to halt ribosome translation both in vivo and in vitro. Moreover, a noteworthy augmentation in the prevalence of rG4 abundance was observed in senescent cells, and the reinforcement of the rG4 structure further exacerbates the process of cellular senescence. Additionally, the RNA helicase DHX9 was identified as a crucial regulator of rG4 abundance, and its reduced expression in senescent cells exacerbates the occurrence of ribosome pausing. Intriguingly, we also observed an augmented abundance of rG4, an imbalance in protein homeostasis, and a decrease in DHX9 expression in the fibroblast cells and highly aged tissues of aging mice. In summary, our findings reveal a novel biological role of rG4 and DHX9 in the regulation of ribosome translation and proteostasis, potentially providing implications for the postponement of cellular senescence and ageing.

Project description:Translational control is a key determinant of protein abundance, which in turns defines the physiology and pathology of human cells. Initiation of translation is highly regulated in eukaryotes and is considered as the rate-limiting step of protein synthesis. mRNA secondary structures in 5’ untranslated region (UTR) and associated helicases have been characterised as key determinants of translation initiation. Nevertheless the transcriptome-wide contribution of non-canonical secondary structures, such as RNA G-quadruplexes (rG4s), to the translation of human mRNAs remains largely unappreciated. Here we use a ribosome profiling strategy to investigate the translational landscape associated to rG4s-containing mRNAs and the contribution of two rG4s-specialised DExH-box helicases, DHX9 and DHX36, to translation initiation in human cells. We show that rG4-forming sequences in 5’-UTR is associated with decreased translation efficiency which correlate with an increased ribosome density within the 5’-UTRs. We found that rG4s contribute to the translation of upstream open reading frames, and as a consequence, thwart the translation of the associated protein coding sequences (CDS). Depletion of the DHX36 and DHX9 helicases demonstrated that the formation of the rG4 structural motif rather than its nucleotide sequence mediate translation initiation. Our findings unveil a role for non-canonical structures in defining alternative 5’ starts for human mRNAs translation initiation.

Project description:Increased protein misfolding and aggregation are key hallmarks of ageing and many age-related diseases. As generating and maintaining a functional proteome (proteostasis) is crucial to every cellular process, this age-related decline in proteostasis is suggested to play a primary role in the breakdown of diverse cellular subsystems during ageing. Indeed, augmented proteostasis pathways are associated with extended lifespan across different species. With the ribosome as the earliest proteostasis checkpoint, decreased protein synthesis is also a conserved mechanism that extends lifespan. Yet, it remains unclear whether ageing impacts translation after initiation. Here, we use worms and yeast to investigate how ageing influences translation elongation. We show an age-dependent increase in ribosome pausing at diverse positions in coding sequences. This pausing is conserved in both worms and yeast, particularly at Arg and polybasic regions. We further show that such pausing is associated with the age-dependent aggregation of truncated nascent proteins involved in proteostasis pathways, notably aminoacyl tRNA synthetases. Moreover, we find that impairment in clearing truncated nascent proteins is associated with decreased lifespan. These data establish elongation kinetics and co-translational quality control as critical contributors of the age-related proteostasis collapse, which may precipitate the systemic decline observed during ageing.

Project description:Proteostasis collapse, the diminished ability to maintain protein homeostasis, has been established as a hallmark of nematode aging. However, whether proteostasis collapse occurs in humans has remained unclear. Here, we demonstrate that proteostasis decline is intrinsic to human senescence. Using transcriptome-wide characterization of gene expression, splicing, and translation, we found a significant deterioration in the transcriptional activation of the heat shock response in stressed senescent cells. Furthermore, phosphorylated HSF1 nuclear localization and distribution were impaired in senescence. Interestingly, alternative splicing regulation was also dampened. Surprisingly, we found a decoupling between different unfolded protein response (UPR) branches in stressed senescent cells. While young cells initiated UPR-related translational and transcriptional regulatory responses, senescent cells showed enhanced translational regulation and endoplasmic reticulum (ER) stress sensing; however, they were unable to trigger UPR-related transcriptional responses. This was accompanied by diminished ATF6 nuclear localization in stressed senescent cells. Finally, we found that proteasome function was impaired following heat stress in senescent cells, and did not recover upon return to normal temperature. Together, our data unraveled a deterioration in the ability to mount dynamic stress transcriptional programs upon human senescence with broad implications on proteostasis control and connected proteostasis decline to human aging.

Project description:Following meiosis resumption, the transcription was silencing; and large number of maternal mRNA was actively translated and degraded during oocyte maturation. However, due to the limitation of sample number and technology, the dynamic distribution of RNA structure and its correlation with RNA dynamic change have never been revealed. RNA G-quadruplex (rG4) was a four-stranded RNA secondary structure related to translation regulation and RNA stability. In this study, we developed a low-input technique of rG4 detection (G4-lace-seq), and found that rG4s were highly abundant in fully grown oocytes and reduced during oocyte maturation. We ingeniously applied rG4 stable ligand BYBX in aim to eliminate the DNA G-quadruplex obstruction, and phenotypic analysis showed that rG4 accumulation severely impaired oocytes maturation. Above all, RBPs proteomic spectra revealed RNA structure change caused by G4 accumulation directly weakened the binding of RBPs to RNA, especially the enrichment of G4s affect the RBP binding associated with RNA metabolism, and G4s on the 5′-UTR hindered 40s ribosome movement and binding of 60s ribosome eukaryotic translation initiation factors to RNA. Combined analysis of G4-Lace-seq with Ribo-lite and RNA-seq, further proved that rG4s accumulation on UTRs disrupted translational efficiency and maternal mRNA degradation during oocyte maturation. Overexpression of DHX36, a G4s helicase, rescued the defects caused by BYBX to oocytes and restored the development rates. Jointly analyzing the function and distribution of rG4s and the metabolic signature of maternal mRNA, we hypothesized that a large amount of rG4s present before meiosis resumption is necessary to protect long-term mRNA stability from degradation in a state of poor efficiency translation. Following meiosis resumption, rG4s were cleaned up, translation efficiency increased, and the mRNA became unstable and was rapidly degraded. Collectively, our results announced for the first time that G4, as a secondary structure, had a hand in in the special dynamic rule of RNA content and translation. rG4s clearance determined the fate of cytoplasmic maturation during oocyte maturation.

Project description:Following meiosis resumption, the transcription was silencing; and large number of maternal mRNA was actively translated and degraded during oocyte maturation. However, due to the limitation of sample number and technology, the dynamic distribution of RNA structure and its correlation with RNA dynamic change have never been revealed. RNA G-quadruplex (rG4) was a four-stranded RNA secondary structure related to translation regulation and RNA stability. In this study, we developed a low-input technique of rG4 detection (G4-lace-seq), and found that rG4s were highly abundant in fully grown oocytes and reduced during oocyte maturation. We ingeniously applied rG4 stable ligand BYBX in aim to eliminate the DNA G-quadruplex obstruction, and phenotypic analysis showed that rG4 accumulation severely impaired oocytes maturation. Above all, RBPs proteomic spectra revealed RNA structure change caused by G4 accumulation directly weakened the binding of RBPs to RNA, especially the enrichment of G4s affect the RBP binding associated with RNA metabolism, and G4s on the 5′-UTR hindered 40s ribosome movement and binding of 60s ribosome eukaryotic translation initiation factors to RNA. Combined analysis of G4-Lace-seq with Ribo-lite and RNA-seq, further proved that rG4s accumulation on UTRs disrupted translational efficiency and maternal mRNA degradation during oocyte maturation. Overexpression of DHX36, a G4s helicase, rescued the defects caused by BYBX to oocytes and restored the development rates. Jointly analyzing the function and distribution of rG4s and the metabolic signature of maternal mRNA, we hypothesized that a large amount of rG4s present before meiosis resumption is necessary to protect long-term mRNA stability from degradation in a state of poor efficiency translation. Following meiosis resumption, rG4s were cleaned up, translation efficiency increased, and the mRNA became unstable and was rapidly degraded. Collectively, our results announced for the first time that G4, as a secondary structure, had a hand in in the special dynamic rule of RNA content and translation. rG4s clearance determined the fate of cytoplasmic maturation during oocyte maturation.

Project description:Following meiosis resumption, the transcription was silencing; and large number of maternal mRNA was actively translated and degraded during oocyte maturation. However, due to the limitation of sample number and technology, the dynamic distribution of RNA structure and its correlation with RNA dynamic change have never been revealed. RNA G-quadruplex (rG4) was a four-stranded RNA secondary structure related to translation regulation and RNA stability. In this study, we developed a low-input technique of rG4 detection (G4-lace-seq), and found that rG4s were highly abundant in fully grown oocytes and reduced during oocyte maturation. We ingeniously applied rG4 stable ligand BYBX in aim to eliminate the DNA G-quadruplex obstruction, and phenotypic analysis showed that rG4 accumulation severely impaired oocytes maturation. Above all, RBPs proteomic spectra revealed RNA structure change caused by G4 accumulation directly weakened the binding of RBPs to RNA, especially the enrichment of G4s affect the RBP binding associated with RNA metabolism, and G4s on the 5′-UTR hindered 40s ribosome movement and binding of 60s ribosome eukaryotic translation initiation factors to RNA. Combined analysis of G4-Lace-seq with Ribo-lite and RNA-seq, further proved that rG4s accumulation on UTRs disrupted translational efficiency and maternal mRNA degradation during oocyte maturation. Overexpression of DHX36, a G4s helicase, rescued the defects caused by BYBX to oocytes and restored the development rates. Jointly analyzing the function and distribution of rG4s and the metabolic signature of maternal mRNA, we hypothesized that a large amount of rG4s present before meiosis resumption is necessary to protect long-term mRNA stability from degradation in a state of poor efficiency translation. Following meiosis resumption, rG4s were cleaned up, translation efficiency increased, and the mRNA became unstable and was rapidly degraded. Collectively, our results announced for the first time that G4, as a secondary structure, had a hand in in the special dynamic rule of RNA content and translation. rG4s clearance determined the fate of cytoplasmic maturation during oocyte maturation.

Project description:We applied in parallel RNA-Seq and Ribosome-profiling analyses to immortalized human primary BJ fibroblast cells under the following conditions: normal proliferation, quiescence (induced by serum depletion), senescence (induced by activation of the oncogenic RASG12V gene, and examined at early (5 days; pre-senescent state) and late (14 days; fully senescent state) time points), and neoplastic transformation (induced by RASG12V in the background of stable p53 and p16INK4A knockdowns and SV40 small-T expression. RNA-seq, using Illumina HiSeq 2000, was applied to BJ cells under 5 conditions: proliferation, quiescence, pre-senescence, full-senescence, and transfomed. Ribosome profiling, using Illumina HiSeq 2000, was applied to BJ cells under 5 conditions: proliferation, quiescence, pre-senescence, full-senescence, and transfomed.

Project description:Protein synthesis by ribosomes takes place on a linear substrate but at variable speeds. Transient pausing of ribosomes can impact a variety of co-translational processes, including protein targeting and folding. These pauses are influenced by the sequence of the mRNA. Thus redundancy in the genetic code allows the same protein to be translated at different rates. However, our knowledge of both the position and the mechanism of translational pausing in vivo is highly limited. Here we present a genome-wide analysis of translational pausing in bacteria using ribosome profiling-deep sequencing of ribosome-protected mRNA fragments. This approach enables high-resolution measurement of ribosome density profiles along most transcripts at unperturbed, endogenous expression levels. Unexpectedly, we found that codons decoded by rare tRNAs do not lead to slow translation under nutrient-rich conditions. Instead, Shine-Dalgarno-(SD) like features within coding sequences cause pervasive translational pausing. Using an orthogonal ribosome possessing an altered anti-SD sequence, we demonstrated that pausing is due to hybridization between mRNA and the 16S rRNA of the translating ribosome. In protein coding sequences, internal SD sequences are disfavoured, which leads to biased usage, avoiding codons and codon pairs that resemble canonical SD sites. Our results indicate that internal SD-like sequences are a major determinant of translation rates and a global driving force for the coding of bacterial genomes. Identification of translation pause sites in vivo using ribosome profiling