Project description:RNA recognition motifs (RRMs) are widespread RNA-binding protein domains in eukaryotes, which represent promising synthetic biology tools due to their compact structure and efficient activity. Yet, their use in prokaryotes is limited and their functionality poorly characterized. Recently, we repurposed a mammalian Musashi protein containing two RRMs as a translation regulator in Escherichia coli. Here, employing high-throughput RNA sequencing, we explored the impact of Musashi expression on the transcriptomic and translatomic profiles of E. coli, revealing certain metabolic interference, induction of post-transcriptional regulatory processes, and spurious protein-RNA interactions. Engineered Musashi protein mutants displayed compromised regulatory activity, emphasizing the importance of both RRMs for specific and sensitive RNA binding. We found that a mutation known to impede allosteric regulation led to similar translation control activity. Evolutionary experiments disclosed a loss of function of the synthetic circuit in about 40 generations, with the gene coding for the Musashi protein showing a stability comparable to other heterologous genes. Overall, this work expands our understanding of RRMs for post-transcriptional regulation in prokaryotes and highlight their potential for biotechnological and biomedical applications.

Project description:The Musashi family of mRNA translational regulators control both physiological and pathological stem cell self-renewal primarily by repressing targets that promote differentiation. In response to differentiation cues, Musashi can switch from a repressor to an activator of target mRNA translation. However, the molecular events that distinguish Musashi-mediated translational activation from repression are not understood. We have previously reported that Musashi function is required for the maturation of Xenopus oocytes, and specifically for translational activation of specific dormant maternal mRNAs. Here, we employed mass spectrometry to identify cellular factors necessary for Musashi-dependent mRNA translational activation. We report a requirement for association of Musashi1 with the embryonic poly(A) binding protein (ePABP) or the canonical somatic cell poly(A) binding protein PABPC1 for activation of Musashi target mRNA translation. Co-immunoprecipitation studies demonstrated an increased Musashi1 interaction with ePABP during oocyte maturation. Attenuation of endogenous ePABP activity severely compromised Musashi function, preventing downstream signaling and blocking oocyte maturation. Recovery of Musashi-dependent mRNA translational activation and maturation of ePABP attenuated oocytes was achieved through ectopic expression of either ePABP or PABPC1. Consistent with the findings in Xenopus oocytes, PABPC1 remained associated with Musashi under conditions of Musashi target mRNA de-repression and translation during mammalian stem cell differentiation. Since association of Musashi1 with poly(A) binding proteins has previously only been implicated in repression of Musashi target mRNAs, our findings reveal distinct context-dependent roles for the interaction of Musashi with poly[A] binding protein family members in response to extracellular cues that control cell fate.

Project description:The high energetic cost of reproduction requires that female fertility be closely linked to metabolic status. However, the mechanisms by which the metabolic and reproductive systems communicate is still largely undefined. We have previously reported that signaling through the major metabolic cytokine leptin controls levels of the pituitary maturation determinant POU1F1 (also referred to as Pit1) that is required for optimal reproductive function. These studies further indicated that leptin increases POU1F1levels in females by promoting Pou1f1 mRNA translation, although the mechanism ofPou1f1 mRNA translation control is unknown. In this study, we report that the stem cell marker and mRNA translational control protein, Musashi, represses translation of the Pou1f1 mRNA. In FACS-sorted purified female somatotropes, Msi1 mRNA and Musashi protein levels are increased in the mouse model that lacks leptin signaling (Gh-CRE leprLepr-null), coincident with the observed attenuation of Pou1f1 mRNA translation. Single-cell RNA sequencing of pituitary cells from control female animals indicates that Msi1 and Pou1f1 mRNAs are co-expressed in Gh-expressing cells and immunocytochemistry analyses of these cells confirms that Musashi protein is present in the GH-containing somatotrope population. We demonstrate that Musashi interacts directly with the Pou1f1 mRNA 3’ UTR and exerts translational repression of a Pou1f1 mRNA translation reporter in vitro, and interacts with the Pou1f1 mRNA in vivo. These findings indicate a critical role for Musashi-mediated mRNA translational regulation in the coordination between metabolic status and the maturation of pituitary somatotropes that is required for optimized reproductive function .

Project description:Biomolecular condensates composed of proteins and RNA are one approach by which cells regulate post-transcriptional gene expression. Their formation typically involves the phase separation of intrinsically disordered proteins with a target mRNA, sequestering the mRNA into a liquid condensate. This sequestration regulates gene expression by modulating translation or facilitating RNA processing. Here, we engineer synthetic condensates using a fusion of an RNA-binding protein, the human Pumilio2 homology domain, and a synthetic intrinsically disordered protein, an elastin-like polypeptide, that can bind and sequester a target mRNA transcript. In protocells, sequestration of a target mRNA largely limits its translation. Conversely, in E. Coli, sequestration of the same target mRNA increases its translation. We characterize the Pum2-ELP condensate system using microscopy, biophysical and biochemical assays, and RNA-seq. This approach enables modulation of cell function via the formation of synthetic biomolecular condensates that upregulate the expression of a target protein.

Project description:The Puf family of RNA-binding proteins regulates gene expression by controlling protein synthesis or stimulating RNA decay. Puf3p is one of six related proteins in Saccharomyces cerevisiae characterised as targeting and regulating decay of nuclear-encoded mRNAs specifying mitochondrial proteins. Much prior work has examined how Puf3p regulates COX17 mRNA. We undertook a genome-wide approach to quantitatively assess the impact of loss of PUF3 on gene expression using polysome profiling. Our translatomic study suggests that loss of Puf3p has widespread, but modest, impact on mRNA translation.

Project description:Deciphering the mechanism of secondary cell wall/SCW formation in vascular plants is key to understanding their development and the molecular basis of biomass recalcitrance. A sophisticated network of transcription factors has been implicated in SCW synthesis in plants, but little is known about the implication of RNA-binding proteins in this process. Here we report that two RNA-binding proteins homologous to the animal translational regulator Musashi, Musashi-Like2/MSIL2 and Musashi-Like4/MSIL4, function redundantly to control SCW formation in interfascicular fibers and the setting of biomass recalcitrance. We show that the disruption of MSIL2/4 decreases the abundance of lignin in fibers and triggers an hypermethylation of glucuronoxylan that is linked to an over-accumulation of GlucuronoXylan Methyltransferase1/3 (GXM1/3) proteins. We demonstrate that MSIL4 binds to the GXM1/3 mRNAs, likely repressing their translation in wild-type plants. Our results reveal cell-type-specific mechanisms underlying SCW formation in Arabidopsis and point to a novel aspect of SCW regulation linking translational repression to regulation of glucuronoxylan methylation.

Project description:We report the application of polysome profiling sequencing technology for high-throughput transcriptomics and translatomics in mammalian cells. We compare reduction of Dap5 to control in metastatic breast cancer cells in transcription and polysome enriched translation using RNA sequencing. Genome-wide transcriptomic and translatomic analyses indicate that DAP5 is required for translation of many transcription factor and receptor capped mRNAs and their mRNA targets involved in cell survival, motility, DNA repair and translation initiation, among other mRNAs.

Project description:The identification of RNAs that are recognized by RNA-binding proteins (RNA-BPs) using techniques such as Crosslinking and Immunoprecipitation (CLIP) has revolutionized the genome-wide discovery of RNA-BP RNA targets. Among the different versions of CLIP that have been developed, the use of photoactivable nucleoside analogs has resulted in high efficiency photoactivable ribonucleoside-enhanced CLIP (PAR-CLIP) in vivo. Nonetheless, PAR-CLIP has not yet been applied in prokaryotes. To determine if PAR-CLIP can be used in prokaryotes, we determined suitable conditions for the incorporation of 4-thiouridine (4SU), a photoactivable nucleoside, into E. coli RNA and for the isolation of RNA crosslinked to RNA-BPs of interest. Applying this technique to Hfq, a well-characterized regulator of small RNA (sRNA)-messenger RNA (mRNA) interactions, we showed that PAR-CLIP identified most of the known sRNA targets of Hfq, as well as functionally relevant sites of Hfq-mRNA interactions at nucleotide resolution. Based on our findings, PAR-CLIP represents an improved method to identify both the RNAs and the specific regulatory sites that are recognized by RNA-BPs in prokaryotes.

Project description:TIA-1 related protein (TIAR) is a RNA-binding protein involved in several steps of gene expression such RNA splicing and translation. TIAR contains three RNA recognition motifs (RRMs) allowing its interaction with specific sequences localized in the untranslated regions (UTRs) of several mRNAs. In myeloid cells, TIAR has been shown to bind and regulate the translation and stability of various mRNAs encoding proteins important for the inflammatory response, such as TNFα, Cox-2 or IL-8 . Here, we generated two macrophage-like RAW 264.7 cell lines expressing either a tagged full-length TIAR protein or a RRM2-truncated mutant unable to bind RNA with high affinity . By a combination of RNA-IP and microarray analysis (RIP-chip), we identified mRNAs specifically bound by the full-length protein both in basal conditions and in response to LPS.

Project description:The synthetic flexicate compound Λ-5b shows potent antimicrobial activity against E. coli. In this study we investigated the transcriptomic response of a clinically relevant E. coli, EHEC O157:H7, to a sublethal concentration of the compound.