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:mTOR regulates mRNA translation. Whereas ribosome-profiling suggested that mTOR exclusively stimulates translation of TOP (containing a 5’-terminal oligopyrimidine [5’TOP] motif) and TOP-like mRNAs, polysome-profiling implied that mTOR also modulates translation of non-TOP mRNAs. We show that ribosome-, but not polysome-profiling, is biased towards identification of TOP mRNAs as differentially translated while obscuring detection of changes in non-TOP mRNA translation. Transcription start site profiling by Nano-Cap Analysis of Gene Expression (nanoCAGE) revealed that many mTOR-sensitive mRNAs do not have 5’TOP motifs. Moreover, nanoCAGE showed that 5’ UTR features distinguish two functionally and translationally distinct subsets of mTOR-sensitive mRNAs: i) those with short 5’ UTRs enriched for mitochondrial functions such as respiration, that are translated in an eIF4E, but not eIF4A1-dependent manner and ii) mRNAs encoding proliferation- and survival-promoting proteins, that harbor long 5’ UTRs, and require both eIF4E and eIF4A1 for their efficient translation. Selective inhibition of translation of mRNAs harboring long 5’ UTRs via suppression of eIF4A leads to uncoupling of expression of proteins involved in respiration (e.g. ATP5O) from those protecting mitochondrial integrity (e.g. BCL-2) ultimately resulting in apoptosis. Conversely, simultaneous translational downregulation of both long and short 5’ UTR mRNAs by mTOR inhibitors results in suppression of mitochondrial respiration and predominantly cytostatic effects. Therefore, 5’ UTR features define differential modes of translation of functionally distinct mTOR-sensitive mRNAs, which explains discrepancies between the effects of mTOR and eIF4A inhibitors on neoplastic cells. Determination of 5'UTR lengths using nanoCAGE in MCF7 cells

Project description:It has been shown that in mammalian cells alternative transcription initiation is extensively regulated during development and across cell-types, which confers dynamic transcript 5’UTR repertoire. However it is underexplored how the heterogeneity of 5’UTR isoforms would affect the downstream steps for protein expression, such as translation. To this end, we globally compared the translational profile of distinct mRNA TSS isoforms in mouse fibroblast cells, by combining deep-sequencing based mRNA 5’ends profiling and polysome fractionation. We demonstrated the extensive translation regulation conferred by TSS heterogeneity. 5'end sequencing in seven polysome fractions, in two replicates, using Illumina Hiseq2000

Project description:Cells transiently adapt to hypoxia by globally decreasing protein translation. However, specific proteins needed to respond to hypoxia evade this translational repression. The mechanisms of this phenomenon remain unclear. We screened for and identified small molecules that selectively decrease HIF-2a translation in an mTOR independent manner, by enhancing the binding of Iron Regulatory Protein 1 (IRP1) to a recently reported Iron-Responsive Element (IRE) within the 5’-untranslated region (UTR) of the HIF-2a message. Knocking down the expression of IRP1 by shRNA abolished the effect of the compounds. Hypoxia de-represses HIF-2a translation by disrupting the IRP1- HIF-2a IRE interaction. Thus, this chemical genetic analysis describes a molecular mechanism by which translation of the HIF-2a message is maintained during conditions of cellular hypoxia through inhibition of IRP-1 dependent repression. It also provides the chemical tools for studying this phenomenon. Experiment Overall Design: 3 replicate samples of 786-O human Clear Cell Renal Carcinoma cells untreated, mock treated with DMSO or treated with either of 4 HIF-2a inhibitor compounds identified by chemical genetic screening.

Project description:It has been shown that in mammalian cells alternative transcription initiation is extensively regulated during development and across cell-types, which confers dynamic transcript 5’UTR repertoire. However it is underexplored how the heterogeneity of 5’UTR isoforms would affect the downstream steps for protein expression, such as translation. To this end, we globally compared the translational profile of distinct mRNA TSS isoforms in mouse fibroblast cells, by combining deep-sequencing based mRNA 5’ends profiling and polysome fractionation. We demonstrated the extensive translation regulation conferred by TSS heterogeneity.

Project description:mTOR regulates mRNA translation. Whereas ribosome-profiling suggested that mTOR exclusively stimulates translation of TOP (containing a 5’-terminal oligopyrimidine [5’TOP] motif) and TOP-like mRNAs, polysome-profiling implied that mTOR also modulates translation of non-TOP mRNAs. We show that ribosome-, but not polysome-profiling, is biased towards identification of TOP mRNAs as differentially translated while obscuring detection of changes in non-TOP mRNA translation. Transcription start site profiling by Nano-Cap Analysis of Gene Expression (nanoCAGE) revealed that many mTOR-sensitive mRNAs do not have 5’TOP motifs. Moreover, nanoCAGE showed that 5’ UTR features distinguish two functionally and translationally distinct subsets of mTOR-sensitive mRNAs: i) those with short 5’ UTRs enriched for mitochondrial functions such as respiration, that are translated in an eIF4E, but not eIF4A1-dependent manner and ii) mRNAs encoding proliferation- and survival-promoting proteins, that harbor long 5’ UTRs, and require both eIF4E and eIF4A1 for their efficient translation. Selective inhibition of translation of mRNAs harboring long 5’ UTRs via suppression of eIF4A leads to uncoupling of expression of proteins involved in respiration (e.g. ATP5O) from those protecting mitochondrial integrity (e.g. BCL-2) ultimately resulting in apoptosis. Conversely, simultaneous translational downregulation of both long and short 5’ UTR mRNAs by mTOR inhibitors results in suppression of mitochondrial respiration and predominantly cytostatic effects. Therefore, 5’ UTR features define differential modes of translation of functionally distinct mTOR-sensitive mRNAs, which explains discrepancies between the effects of mTOR and eIF4A inhibitors on neoplastic cells.