Project description:N6–methyladenosine (m6A) is the most abundant internal mRNA modification in eukaryotes, and it plays an important role in RNA metabolism and function. Recent studies have revealed that viral RNA m6A modification can play an anti-viral or pro-viral role depending on the virus. However, whether m6A methylation can modulate replication of coronaviruses, which cause some severe human and animal diseases such as Coronavirus Disease 2019 (COVID-19), remains unknown. Here, we determined that m6A modifications of porcine epidemic diarrhea coronavirus (PEDV) are exclusively located in the N gene at the 3’-end of the genome, and that PEDV infection alters the expression pattern of some host proteins involved in m6A modification. Depletion of m6A demethylases significantly increased PEDV replication and gene expression whereas knockdown of m6A methyltransferases slightly decreased PEDV infection. Interestingly, m6A binding proteins YTHDF 2 and 3 significantly inhibited PEDV replication whereas YTHDF1 has the opposite effect. When the major m6A sites in the N gene were mutated, the resultant recombinant PEDVs and PEDV replicons had a significant increase in replication and gene expression. This study illustrates that (i) addition of m6A to PEDV RNA inhibits viral replication, and (ii) both host and viral m6A machinery regulate coronavirus replication.

Project description:Swine coronavirus-porcine epidemic diarrhea virus (PEDV) with specific susceptibility to pigs has existed for decades, and recurrent epidemics caused by mutant strains have swept the world again since 2010. Here, single-cell RNA-sequencing was used to perform a systematic analysis of pig small intestines infected with PEDV for the first time. Multiple cell types were identified by representative markers, including the unique marker DNAH11 of tuft cells. Meanwhile, the goblet and tuft cells were also susceptible to PEDV except enterocytes. PEDV infection obviously upregulated REG3G, which significantly inhibited virus replication. Notably, IFN-DELTAs in goblet and enterocyte progenitor cells were increased in virus infected piglet, and IFN-DELTA5 could induce GBP1, ISG15, OAS2 and IFITM1 dramatically raised in IPEC-J2 cells and restricted PEDV replication. Complement molecules were mainly expressed in intestinal cells excepting tuft cells, but PEDV decreased C3, C4A, and C5 in enterocytes, thus escaping the antiviral effect of C3. Finally, enterocytes expressed almost all coronavirus entry factors, and PEDV infection caused significant upregulation of the coronavirus receptor ACE2 in porcine enterocyte cells. In summary, this study systematically studied the response of different cell types in small intestine of pigs after PEDV infection, which deepened the understanding of viral pathogenesis.

Project description:Viruses employ various strategies to evade innate immunity. Despite many studies on host or viral gene expression, how the cellular proteome responds to internal or external cues, has not been fully investigated. Using a Hepatitis B Virus (HBV) replication model, we performed proteomic analyses of HBV-replicating cells in G1/S and G2/M phases, as a function of IFN-alpha, providing specific information of how HBV infection, in combination with IFN-alpha, alters the hepatocyte proteome. We identified the conserved LSm (Like-Sm1-8) proteins were differentially expressed as a function of HBV replication and IFN-alpha. Specifically, in G2/M, IFN-alpha increased protein level of LSm1, the unique subunit of cytoplasmic LSm1-7 complex involved in mRNA decay. By contrast, IFN-alpha decreased LSm8, the unique subunit of nuclear LSm2-8 complex, a chaperone of U6 spliceosomal RNA. These results suggest cytoplasmic LSm1-7 has antiviral role, whereas nuclear LSm2-8 complex is pro-viral. Employing HBV replication and infection models, siRNA-mediated knockdown of LSm1 increased the level of all viral RNAs. Conversely, knockdown of LSm8 reduced viral RNA levels, dependent on N6-adenosine methylation (m6A) of the epsilon stem-loop at the 5 end of pre-Core/pregenomic (preC/pg) RNA. Methylated RNA immunoprecipitation (MeRIP) assays demonstrated reduced viral RNA methylation upon LSm8 knockdown, dependent on the m6A modification, suggesting the LSm2-8 complex has a role in mediating this modification. Interestingly, splicing inhibitor Cp028 acting upstream of LSm2-8 complex, suppressed levels of viral RNAs without reducing the m6A modification. This observation suggests Cp028 has novel antiviral effects, likely potentiating IFN-alpha -mediated suppression of HBV biosynthesis.

Project description:N6-methyladenosine (m6A) is a dynamic and reversible nucleotide modification in mRNA. m6A alters mRNA fate, but it is unclear why the effects of m6A can vary in different cellular contexts. Here we show that methylated mRNAs are catalysts for liquid-liquid phase separation of the YTHDF family of m6A-binding proteins. RNAs that contain multiple, but not single, m6A residues recruit multiple YTHDF proteins, causing them to undergo a proximity-induced phase separation. YTHDF proteins show liquid-like properties upon binding polymethylated mRNAs in cells, and partition into endogenous phase-separated compartments, such as P-bodies, neuronal RNA granules, and stress granules. The complexes of YTHDF proteins and polymethylated mRNAs are targeted to different compartments depending on the cell context, leading to different effects on m6A mRNAs. These studies reveal a role for nucleotide modifications in regulating phase separation and indicate that the cellular properties of m6A-modified mRNAs can be explained by liquid-liquid phase separation principles.

Project description:N6-methyladenosine (m6A) is the most abundant internal modification in eukaryotic messenger RNAs (mRNAs), and plays important roles in cell differentiation and organism development. It regulates multiple steps throughout the RNA life cycle including RNA processing, translation, and metabolism, via the recognition by selective binding proteins. In cytoplasm, m6A binding protein YTHDF1 facilitates translation of m6A-modified mRNAs, and YTHDF2 accelerates the decay of m6A-modified transcripts. The biological function of YTHDF3, another cytoplasmic m6A binder of the YTH domain family, remains unknown. Here, we report that YTHDF3 promotes protein synthesis in synergy with YTHDF1, and affects methylated mRNA decay mediated by YTHDF2. Cells deficient in all of YTHDF proteins experience the most dramatic accumulation of the m6A-methylated transcripts. These results indicate that in cytoplasm, YTHDF proteins act in an integrated and cooperative network to accelerate metabolism of m6A-modified mRNAs. The combinative and dynamic nature of YTHDF proteins may collectively impact fundamental biological processes and diseases related to m6A RNA methylation.

Project description:N6-methyladenosine (m6A) is the most abundant internal mRNA nucleotide modification in mammals, regulating critical aspects of cell physiology and differentiation. The YTHDF proteins are the primary readers of m6A modifications and exert physiological functions of m6A in the cytosol. Elucidating the regulatory mechanisms of YTHDF proteins is critical to understanding m6A biology. Here, we report a mechanism that protein post-translational modifications control the biological functions of the YTHDF proteins. We find that YTHDF1 and YTHDF3, but not YTHDF2, carry high levels of nutrient-sensing O-GlcNAc modifications. O-GlcNAc modification attenuates the translation promoting function of YTHDF1 and YTHDF3 by blocking their interactions with proteins associated with mRNA translation. We further demonstrate that O-GlcNAc modifications on YTHDF1 and YTHDF2 regulate the assembly, stability, and disassembly of stress granule, facilitating rapid exchange of m6A-modified mRNAs in stress granules for recovery from stress. Therefore, our results discover an important regulatory pathway of YTHDF functions, adding an additional layer of complexity to the post-transcriptional regulation function of mRNA m6A.

Project description:Porcine epidemic diarrhea virus (PEDV) is a deadly coronavirus for neonatal piglets and no effective vaccines are available. Transcriptional regulatory sequences (TRSs) are critical in regulating coronavirus discontinuous transcription. Also, TRSs contribute to a high recombination rate of coronaviruses, leading to difficulty in developing safe live vaccines. We hypothesize that recoding the TRS core sequences (TRS-CS) of PEDV can make the recombination impossible between the engineered vaccine virus and field strains or wildtype viruses. We used an infectious clone-derived reporter PEDV, dORF3-EGFP, as the backbone to generate a remodeled TRS (RMT) mutant that carries the recoded leader and body TRS-CSs. The RMT and dORF3-EGFP showed comparable replication efficiency in Vero cells. However, the incompatibility between the rewired and wildtype TRS-CSs led to few EGFP in RMT-infected cells. Furthermore, RMT and dORF3-EGFP had a similar attenuated phenotype, replication efficiency, and protective immunogenicity in neonatal pigs. RNA sequencing analysis indicated that EGFP transcription directed by the heterogenous TRS-CSs was significantly reduced to an extremely low level. Meanwhile, recombinant viruses were not detected in Vero cells and in pigs that were co-infected with RMT and a PEDV S-INDEL strain, Iowa106. In vitro and in vivo passaging of the RMT did not result in reversion mutations in the rewired TRS-CSs, introduced gaps, and disrupted wildtype TRSs. In summary, the RMT mutant was resistant to recombination and genetically stable and can be further optimized (e.g., deletion of the EGFP) to serve as a platform to develop safe PEDV live attenuated vaccines.

Project description:N6-methyladenosine (m6A) is the most prevalent internal modification of mRNAs in most eukaryotes. Likewise, viral RNAs may acquire m6A methylation during replication within these cells. Here we show that RNAs of human respiratory syncytial virus (RSV), a medically important non-segmented negative-sense (NNS) RNA virus, are modified by m6A within discreet regions and that these modifications enhance viral replication and pathogenesis. Overexpression of m6A binding proteins significantly enhanced RSV replication and gene expression. Knockdown of m6A methyltransferases decreased viral replication and gene expression whereas knockdown of m6A demethylases had the opposite effect. The G gene contained the most abundant m6A modifications. Recombinant RSV expressing a G gene lacking different m6A sites, resulted in RSVs with various degrees of defects in replication in A549 cells, primary well differentiated human airway epithelial (HAE) cultures, upper and lower respiratory tract of cotton rats, and were also less pathogenic to the lungs of cotton rats. One of the m6A-deficient rgRSVs, rgRSV-G12, was completely attenuated yet retained high immunogenicity in cotton rats. Moreover, a small molecule that inhibits S-adenosyl-L-homocysteine (SAH) hydrolase, thereby reducing the cellular SAH pool and viral RNA m6A, also inhibited RSV replication in HAE cells. Collectively, our results demonstrate viral m6A methylation upregulates RSV replication and pathogenesis and identify viral m6A methylation as a target for rational design of live attenuated vaccine candidates and for novel antiviral therapeutic agents for RSV.

Project description:It is urgent and important to understand the relationship of the widespread severe acute respiratory syndrome coronavirus clade 2 (SARS-CoV-2) with host immune response and study the underlying molecular mechanism. RNA modification landscape of SARS-CoV-2 and its functional relevance to host cell innate immune response remain unknown. N6-methylation of adenosine (m6A) in RNA regulates many physiological and disease processes. Here, we investigated m6A modification of SARS-CoV-2 gene in regulating host cell innate immune response. Our data showed that SARS-CoV-2 virus has m6A modification enriched in 3' region of the viral genome. We also found that host cell m6A methyltransferase METTL3 depletion reduced viral load in infected cells, decreased m6A levels in SARS-CoV-2 and host genes, and m6A reduction in viral RNA increased RIG-1 binding and subsequently enhanced downstream innate immune signaling pathway and inflammatory gene expression. METTL3 expression is reduced and inflammatory genes are induced in severe COVID-19 patients. These findings will aid to understand the COVID-19 pathogenesis and help in designing future studies of regulating innate immunity for COVID-19 treatment.

Project description:The internal N6-methyladenosine (m6A) methylation of eukaryotic nuclear RNA controls post-transcriptional gene expression, which is regulated by methyltransferases (writers), demethylases (erasers), and m6A-binding proteins (readers) in cells. The YTH domain family proteins (YTHDF1–3) bind to m6A-modified cellular RNAs and affect RNA metabolism and processing. Here, we show that YTHDF1–3 proteins recognize m6A-modified HIV-1 RNA and inhibit HIV-1 infection in cell lines and primary CD4+ T-cells. We further mapped the YTHDF1–3 binding sites in HIV-1 RNA from infected cells. We found that the overexpression of YTHDF proteins in cells inhibited HIV-1 infection mainly by decreasing HIV-1 reverse transcription, while knockdown of YTHDF1–3 in cells had the opposite effects. Moreover, silencing the m6A writers decreased HIV-1 Gag protein expression in virus-producing cells, while silencing the m6A erasers increased Gag expression. Our findings suggest an important role of m6A modification of HIV-1 RNA in viral infection and HIV-1 protein synthesis.