Project description:The mRNA cap structure is a major site of dynamic mRNA methylation. mRNA caps exist in either the Cap1 or Cap2 form, depending on the presence of 2’-O-methylation on the first, or both the first and second transcribed nucleotide, respectively. However, the identity of Cap2-containing mRNAs and the function of Cap2 are unclear. Here we describe CLAM-Cap-Seq, a method for transcriptome-wide mapping and quantification of Cap2. We find that unlike other epitranscriptomic modifications, Cap2 can occur on all mRNAs. Cap2 is formed through a slow continuous conversion of mRNAs from Cap1 to Cap2 as mRNAs age in the cytosol. As a result, Cap2 is enriched on long-lived mRNAs. We find that large increases in the abundance of Cap1 leads to activation of RIG-I, especially in conditions where RIG-I expression is increased. The methylation of Cap1 to Cap2 markedly reduces the ability of RNAs to bind and activate RIG-I. We find that the slow Cap2 methylation rate allows Cap2 to accumulate on host mRNAs yet ensures that low Cap2 levels occur on newly expressed viral RNAs. Overall, these results reveal an immunostimulatory role for Cap1, and that Cap2 functions to reduce activation of the innate immune response.

Project description:The mRNA cap structure consists of the m7G "cap0" linked to the 5'-most nucleotide of the initial mRNA. The first two nucleotides of mRNA can be 2'-O-Ribose modified to form cap1 or cap2 structures. Here, mRNA was sequenced after CLIP with tagged recombinant CMTR1 and compared to input RNA.

Project description:Eukaryotic mRNA 5’ end is decorated with cap structure which plays multiple roles in the cell. Most importantly, protects transcript from exonucleolytic degradation and enables translation of encoded protein conducted by cap-dependent machinery. This is also a key feature in the process of recognizing RNA as self or non-self molecule by cellular innate immune system. Cap is composed of 7-methylguanosine linked by a 5′,5′-triphosphate chain to the first transcribed nucleotide, and is formed enzymatically during transcription. This m7GpppN structure, called cap0, can be further modified by CMTR1 methyltransferase to cap1 (m7GpppNm), which predominates in eukaryotic cells. Cap2, with additional 2′-O-methylation at the second transcribed nucleotide (m7GpppNmpNm) added by another methyltransferase CMTR2, also can be found at mRNA 5’ end. We present new tools allowing for in vitro synthesis of RNAs possessing cap2, i.e tetranucleotide cap analogues. Utilizing these for in vitro transcription reactions we obtained RNAs with 2′-O-methylation present at the second transcribed nucleotide. Due to that we investigated the role of cap2 in protein production from reporter mRNA protected with this structure in different conditions, normal or stress ones, or with CMTR1/2 down regulated level. We also assessed the affinity of eIF4E protein to differentially capped RNAs. Furthermore, we verified whether an additional 2′-O-methylation presence in capped RNA makes transcript more resistant to decapping enzyme action.

Project description:Eukaryotic mRNA 5’ end is decorated with cap structure which plays multiple roles in the cell. Most importantly, protects transcript from exonucleolytic degradation and enables translation of encoded protein conducted by cap-dependent machinery. This is also a key feature in the process of recognizing RNA as self or non-self molecule by cellular innate immune system. Cap is composed of 7-methylguanosine linked by a 5′,5′-triphosphate chain to the first transcribed nucleotide, and is formed enzymatically during transcription. This m7GpppN structure, called cap0, can be further modified by CMTR1 methyltransferase to cap1 (m7GpppNm), which predominates in eukaryotic cells. Cap2, with additional 2′-O-methylation at the second transcribed nucleotide (m7GpppNmpNm) added by another methyltransferase CMTR2, also can be found at mRNA 5’ end. We present new tools allowing for in vitro synthesis of RNAs possessing cap2, i.e tetranucleotide cap analogues. Utilizing these for in vitro transcription reactions we obtained RNAs with 2′-O-methylation present at the second transcribed nucleotide. Due to that we investigated the role of cap2 in protein production from reporter mRNA protected with this structure in different conditions, normal or stress ones, or with CMTR1/2 down regulated level. We also assessed the affinity of eIF4E protein to differentially capped RNAs. Furthermore, we verified whether an additional 2′-O-methylation presence in capped RNA makes transcript more resistant to decapping enzyme action.

Project description:The response to mRNA vaccines needs to be sufficient for immune cell activation and recruitment but moderate enough to ensure efficacious antigen expression. The choice of the cap structure and use of N1-methylpseudouridine (m1Ψ) instead of uridine, which have been shown to reduce RNA sensing by the cellular innate immune system, has led to improved efficacy of mRNA vaccine platforms. Understanding how RNA modifications influence the cell intrinsic immune response may help in the development of more effective mRNA vaccines. In the current study, we compared mRNA vaccines in mice against influenza virus using three different mRNA formats: uridine-containing mRNA (D1-uRNA), m1Ψ- modified mRNA (D1-modRNA), and m1Ψ-modified mRNA with a cap1 structure (cC1-modRNA). D1-uRNA vaccine induced a significantly different gene expression profile to the modified mRNA vaccines, with an upregulation of Stat1 and RnaseL, and increased systemic inflammation. This correlated with a significantly reduced antigen specific antibody responses and reduced protection against influenza virus infection compared to D1-modRNA and cC1-modRNA. Incorporation of m1Ψ alone without cap1 improved antibodies, but both modifications were required for the optimum response. Therefore, the incorporation of m1Ψ and cap1 alters protective immunity from mRNA vaccines by altering the innate immune response to the vaccine material

Project description:The mRNA cap structure consists of the m7G "cap0" linked to the 5'-most nucleotide of the initial mRNA. The first two nucleotides of mRNA can be 2'-O-Ribose modified to form cap1 or cap2 structures. Here, mRNA was sequenced after CLIP with tagged recombinant CMTR2 enzyme and compared to input RNA.

Project description:Serum response factor (SRF) is a ubiquitously expressed transcription factor that is essential for brain development and function. SRF activity is controlled by two competing classes of coactivators, myocardin-related transcription factors (MRTF) and ternary complex factors, which introduce specificity into gene expression programs. Here, we explored the MRTF-mediated regulatory mechanism in mouse cortical neurons. Using gene-reporter assays and pharmacological and genetic approaches in isolated mouse cortical neurons, we found that cyclase-associated protein 1 (CAP1) repressed neuronal MRTF-SRF activity. CAP1 promoted cytosolic retention of MRTF by controlling cytosolic G-actin levels that required its helical folded domain and its CARP domain. This function of CAP1 was not redundant with that of its homolog CAP2 and was independent of cofilin1 and actin-depolymerizing factor. Deep RNA sequencing and mass spectrometry in cerebral cortex lysates from CAP1 knockout (CAP1-KO) mice supported the in vivo relevance for the CAP1-actin-MRTF-SRF signaling axis. Our study identified CAP1 as a repressor of neuronal gene expression and led to the identification of likely MRTF-SRF target genes in the developing cerebral cortex, whose dysregulation may contribute to impaired formation of neuronal networks in CAP1-KO mice. Together with our previous studies that implicated CAP1 in actin dynamics in axonal growth cones or excitatory synapses, we established CAP1 as a crucial actin regulator in neurons.

Project description:CMTR1, also called IFN-stimulated gene 95 kDa protein (ISG95), is elevated by viral infection in a variety of cells. However, the function of CMTR1 in colorectal cancer (CRC), especially its role in tumorigenesis and immune regulation, remains unclear. Here, we first identified CMTR1 as a novel oncogene in colorectal cancer. Based on The Cancer Genome Atlas (TCGA) database exploration and human tissue microarray (TMA) analysis, we found that CMTR1 expression was markedly higher in colorectal cancer tissues compared to that in adjacent normal tissues. High CMTR1 was correlated with poor prognosis of colorectal cancer patients. Knockdown (KD) of CMTR1 significantly suppressed cell proliferation and tumorigenicity both in vitro and in vivo, whereas overexpression of CMTR1 exhibited the opposite effects. KEGG analysis revealed that the JAK/STAT signaling pathway was differentially enriched in colorectal cancer cells with CMTR1 KD. Mechanistically, repression of CMTR1 influenced RNAPII recruitment to the TSS and repression of STAT3 expression and activation. Furthermore, PD1 blockade immunotherapy was prominently enhanced with CMTR1 KD by increased infiltration of CD8+ T cells into tumor microenvironment. Overall, it appears that CMTR1 plays a key role in regulating tumor cell proliferation and antitumor immunity.

Project description:Here we report that exogenous IL-1β induces TBK1-mediated interferon regulatory factor 3 (IRF3) activation and autophagic flux in human myeloid and epithelial cells. IL-1β-induced innate immune activation is dependent upon the DNA sensing pathway adaptor, stimulator of interferon genes (STING), through the recognition of mitochondrial DNA by cyclic GMP-AMP synthase (cGAS). Thus, IL-1β potentiates pathogen-induced interferon production and signal transducer and activator of transcription (STAT) signaling to amplify innate immune responses.

Project description:In this study, we performed a genome-wide CRISPR screen in A549 cells to identify host genes that are required forInfluenza A virus (IAV) infection.Amongst the identified genes, WDR7, CCDC115, TMEM199 and CMTR1 conferred strong protection against IAV infection when they were CRISPR-deleted without impacting host cell fitness. To investigate the roles of these genes on the transciptomic states of the cell, we performed bulk RNA-sequencing of WDR7, CCDC115, TMEM199 and CMTR1 polyclonal knockout cells. We found that cells lacking WDR7, CCDC115 or TMEM199 up-regulates expression of lysosomal genes due to increased nuclear translocation of Transcription factor EB (TFEB), which hampers IAV entry. In addition,we report that CRISPR deletion of CMTR1 results in increased expression of Interferon-stimulated genes (ISGs) that also plays a role inblocking IAV infection.