Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:Stress adaptation entails perturbations in transcriptional and post-transcriptional mechanisms of regulation of gene expression, but how these programs are coordinated remains largely unknown. To address this, we systematically interrogated the effects of hypoxia on transcriptomes, epigenomes and translatomes of T47D breast cancer cells and H9 human embryonic stem cells. This revealed that hypoxia-induced alterations in H3K4me3 exert unexpectedly minimal effects on transcript abundances. Instead, they were associated with pervasive changes in the transcription start site (TSS) selection, subsequent 5’UTR remodeling, and reshaping of translational landscapes. Importantly, this epigenetically-driven reprograming of translation is distinct from HIF1-dependent transcriptional mechanisms or integrated stress response- or mTOR-guided translational reprogramming. Indeed, comparable effects on TSS selection and 5'UTR remodeling were observed when H3K4me3 was pharmacologically stimulated in the absence of induction of HIF, ISR or modulation of mTOR signaling. These results demonstrate a previously unappreciated physiologically relevant mechanism of translational regulation driven by epigenetic reprograming of the 5’UTRome which is orchestrated with other hypoxia-triggered adaptive mechanisms.

Project description:This data is apart of a project assessing transcriptional start site switching and UTR switching at translational level following hypoxia.

Project description:Integrated Stress Response (ISR) is a homeostatic mechanism induced by endoplasmic reticulum (ER) stress. With acute/transient ER stress, decreased global protein synthesis and increased uORF mRNA translation are followed by translation normalization. Here, we report a dramatically different response during more physiologically relevant chronic ER stress. This unique ISR program is characterized by persistently elevated uORF mRNA translation and concurrent gene expression reprogramming, which permits simultaneous stress sensing and proteostasis. PERK-dependent switching from eIF4F/eIF2B- to eIF3D/GADD34-regulated translation initiation results in partial but not complete translation recovery, and together with transcriptional reprogramming, selectively bolsters expression of proteins with ER functions. Coordination of these transcriptional and translational changes prevents ER dysfunction and inhibits “foamy cell” development, thus establishing a molecular basis for understanding human diseases associated with ER dysfunction.

Project description:Genome-wide analysis of translation has the potential to provide major contributions in understanding the pathophysiology of infection processes, given the complex interplay between pathogens and host cells. This study uncovers the reshaping undergoing in the translational control system of the host in response to staphylococcal α-hemolysin oligomers (rAHL). Keywords: translatome profiling, polysomal profiling, polysomal RNA, translational control, translational profiling, polysome profiling, post-transcriptional regulation, staphylococcal α-hemolysin, pore forming toxins, PTF.

Project description:Genome-wide analysis of translation has the potential to provide major contributions in understanding the pathophysiology of infection processes, given the complex interplay between pathogens and host cells. Informations about the translational state of mRNAs or the activity of RNA binding proteins and ncRNAs after treatment with sublytic doses of pore forming toxins are completely missing. This study uncovers the reshaping undergoing in the translational control system of the host in response to sublytic doses of staphylococcal α-hemolysin (AHL). Keywords: translatome profiling, polysomal profiling, polysomal RNA, translational control, translational profiling, polysome profiling, post-transcriptional regulation, staphylococcal α-hemolysin, pore forming toxins, PTF.