Project description:N6-methyladenosine (m6A) is an essential internal RNA modification that is critical for gene expression control in most organisms. Proteins with a YTH domain recognize m6A marks and are mediators of molecular functions like RNA splicing, mRNA decay and translation control. Here we demonstrate that YTH domain-containing 2 (YTHDC2) is an m6A reader that is essential for male and female fertility in mice. In mutant males, mitotic spermatogonia fail to differentiate into meiotic spermatocytes. Analysis identifies transcripts upregulated in the Yhtdc2 mutant testes to be those that are expressed in purified spermatogonia, while high-throughput mapping of the m6A transcriptome in the mouse male germline demonstrates the upregulated transcripts to be those that are enriched in m6A marks. Our biochemical studies indicate that YTHDC2 is an RNAinduced ATPase that fuels its 3ʹ→5ʹ RNA helicase activity. Interestingly, we find an RNA-independent interaction between the 5ʹ→3ʹ exoribonuclease XRN1 and the Ankyrin repeat of YTHDC2 that is wedged in between the two RecA helicase domains. Our studies reveal a role for YTHDC2 in modulating the levels of m6A-modified germline transcripts that is essential for successful meiosis.

Project description:The functional consequence of N6-methyladenosine (m6A) RNA modification is mediated by ‘reader’ proteins like those of the YTH family that recruit additional factors to alter splicing, RNA stability or translation. Germline-specific YTH domain-containing 2 (YTHDC2) is essential for mammalian fertility, but its molecular function is poorly understood. Here we use a tagged mouse line to identify U-rich motifs as binding sites of YTHDC2 on 3′ UTRs of testicular RNA targets. Although its YTH domain is an m6A-binder in vitro, the YTH point mutant mouse lacking this ability displays no obvious phenotypes. Its 3′→5′ RNA helicase activity is essential for fertility, with the catalytic-dead mutation being dominant-negative. Single-cell transcriptomics reveal that Ythdc2 mutant mitotic testicular germ cells transition into meiosis but accumulate a transcriptome with mixed mitotic/meiotic identity. We also reveal a conserved role for YTHDC2 in animal fertility.

Project description:In the germline stem cell lineage, proliferating gonial cells switch from mitotic proliferation to meiotic prophase, marked by the onset of a cell-type-specific transcription program and a specialized cell cycle required to generate haploid gametes. The Drosophila gene benign gonial cell neoplasm (bgcn) encodes an RNA binding translational repressor required in fly testes for spermatogonia to stop dividing and transition to the spermatocyte state and meiosis. Here we show that the mammalian bgcn ortholog, YTHDC2, plays a key role in allowing a clean transition from mitosis to meiosis in both male and female germ cells in mouse, pointing towards a conserved role of post-transcriptional control of RNA translation and/or stability in this critical cell fate transition. Ythdc2-/- male germ cells undergo mitotic divisions but fail to properly execute meiotic prophase, instead attempting a mitotic-like division then undergoing cell death. Many meiotic markers were only weakly expressed in Ythdc2-/- testes compared to wild-type controls. Strikingly, the mitotic cyclin Cyclin A2, which is down-regulated prior to entry into meiotic prophase in wild-type, remained high in Ythdc2-/- germ cells that also expressed the meiotic marker SYCP3, suggesting that the mutant germ cells attempting to enter meiotic prophase have a mixed identity. YTHDC2 binds RNAs involved in both the mitotic cell cycle, including the mRNA Ccna2 that encodes Cyclin A2, as well as specific piRNA precursor RNAs and transcripts required for later stages of germ cell differentiation. YTHDC2-bound RNAs in testes were enriched for the m6A modification, suggesting that YTHDC2 may selectively regulate multiple target RNAs marked with m6A, to promote a clean transition from mitosis to meiosis and terminal differentiation.

Project description:In the germline stem cell lineage, proliferating gonial cells switch from mitotic proliferation to meiotic prophase, marked by the onset of a cell-type-specific transcription program and a specialized cell cycle required to generate haploid gametes. The Drosophila gene benign gonial cell neoplasm (bgcn) encodes an RNA binding translational repressor required in fly testes for spermatogonia to stop dividing and transition to the spermatocyte state and meiosis. Here we show that the mammalian bgcn ortholog, YTHDC2, plays a key role in allowing a clean transition from mitosis to meiosis in both male and female germ cells in mouse, pointing towards a conserved role of post-transcriptional control of RNA translation and/or stability in this critical cell fate transition. Ythdc2-/- male germ cells undergo mitotic divisions but fail to properly execute meiotic prophase, instead attempting a mitotic-like division then undergoing cell death. Many meiotic markers were only weakly expressed in Ythdc2-/- testes compared to wild-type controls. Strikingly, the mitotic cyclin Cyclin A2, which is down-regulated prior to entry into meiotic prophase in wild-type, remained high in Ythdc2-/- germ cells that also expressed the meiotic marker SYCP3, suggesting that the mutant germ cells attempting to enter meiotic prophase have a mixed identity. YTHDC2 binds RNAs involved in both the mitotic cell cycle, including the mRNA Ccna2 that encodes Cyclin A2, as well as specific piRNA precursor RNAs and transcripts required for later stages of germ cell differentiation. YTHDC2-bound RNAs in testes were enriched for the m6A modification, suggesting that YTHDC2 may selectively regulate multiple target RNAs marked with m6A, to promote a clean transition from mitosis to meiosis and terminal differentiation.

Project description:Mouse testes samples from P8, P10, adult, and Ythdc2-WLA homozygous mutant mice were subjected to CLIP assays to generate YTHDC2-RNA interaction maps.

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:Dynamic mRNA modification in the form of N6-methyladenosine (m6A) adds considerable richness and sophistication to gene regulation. The m6A mark is asymmetrically distributed along mature mRNAs, with a strong preference around the stop codon and 3’UTR. Nevertheless, approximately 35% of m6A residues are located within the coding region (CDS). It has been suggested that methylation in CDS slows down translation elongation by interfering the decoding process. However, neither the decoding feature of endogenous mRNAs nor the physiological significance of CDS m6A has been clearly defined. By integrating Ribo-seq and m6A-seq data sets, we found that CDS m6A methylation leads to ribosome pausing in a codon-specific manner. Unexpectedly, removing CDS m6A modification from these transcripts results in a further decrease of translation. A systemic analysis of RNA structural datasets revealed that CDS m6A methylation positively regulates translation by resolving mRNA secondary structures. We further demonstrate that the elongation-promoting effect of CDS methylation requires the RNA helicase-containing m6A reader YTHDC2. Our findings established the physiological significance of CDS methylation and uncovered non-overlapping function of m6A reader proteins.

Project description:N6-methyladenosine (m6A) is the most abundant internal messenger (mRNA) modification in mammalian mRNA. This modification is reversible and non-stoichiometric, which potentially adds an additional layer of variety and dynamic control of mRNA metabolism. The m6A-modified mRNA can be selectively recognized by the YTH family “reader” proteins. The preferential binding of m6A-containing mRNA by YTHDF2 is known to reduce the stability of the target transcripts; however, the exact effects of m6A on translation has yet to be elucidated. Here we show that another m6A reader protein, YTHDF1, promotes ribosome loading of its target transcripts. YTHDF1 forms a complex with translation initiation factors to elevate the translation efficiency of its bound mRNA. In a unified mechanism of translation control through m6A, the YTHDF2-mediated decay controls the lifetime of target transcripts; whereas, the YTHDF1-based translation promotion increases the translation efficiency to ensure effective protein production from relatively short-lived transcripts that are marked by m6A. PAR-CLIP and RIP was used to identify YTHDF1 binding sites followed by ribosome profling and RNA seq to assess the consequences of YTHDF1 siRNA knock-down

Project description:m6A in mRNA coding regions promotes translation via the RNA helicase-containing YTHDC2

Project description:Mechanisms regulating mammalian meiotic progression are poorly understood. Here we identify mouse YTHDC2 as a critical component. A screen yielded a sterile mutant, “ketu”, caused by a Ythdc2 missense mutation. Mutant germ cells enter meiosis but proceed prematurely to aberrant metaphase and apoptosis, and display defects in transitioning from spermatogonial to meiotic gene expression programs. ketu phenocopies mutants lacking MEIOC, a YTHDC2 partner. Consistent with roles in post-transcriptional regulation, YTHDC2 is cytoplasmic, has 3’ to 5’ RNA helicase activity in vitro, and has similarity within its YTH domain to an N6-methyladenosine recognition pocket. Orthologs are present throughout metazoans, but are diverged in nematodes and, more dramatically, Drosophilidae, where Bgcn is descended from a Ythdc2 gene duplication. We also uncover similarity between MEIOC and Bam, a Bgcn partner unique to schizophoran flies. We propose that regulation of gene expression by YTHDC2-MEIOC is an evolutionarily ancient strategy for controlling the germline transition into meiosis.