Project description:METTL14 forms a protein complex that induces m6A methylation on RNA but its roles in mouse limb development remains elusive. We knocked out Mettl14 in a limb bud-specific manner with the Prx1 promoter-driven Cre. The resulting Prx1-cre;Mettl14 flox/flox (conditional KO or cKO) mice showed shorter limbs with disrupted bone and cartilage development compared with the heterozygous Prx1-cre;Mettl14 wild type/flox (cHet) control mice. To understand the molecular basis for the abnormalities, we applied total RNA from day 12.5 (E12.5) embryonic limb buds to m6A-seq.

Project description:Mettl14 forms a protein complex that induces m6A methylation on RNA but its roles in mouse limb development remains elusive. Here, the Mettl14 gene was knocked out in a limb bud-specific manner in Mettl14 flox/flox mice with the Prx1 promoter-driven cre. Dissociated cells from day 12.5 (E12.5) embryonic limb buds were applied to scRNA-seq to identify differentially expressed genes in a cell type-specific manner. Samples prepared from Per1cre;Mettl14 wild type/flox and Per1cre;Mettl14 flox/flox mice were labeled as cHet and cKO, respectively.

Project description:METTL14 forms a protein complex that induces m6A methylation on RNA but its roles in mouse limb development remains elusive. We knocked out Mettl14 in a limb bud-specific manner with the Prx1 promoter-driven Cre. The resulting Prx1-cre;Mettl14 flox/flox (conditional KO or cKO) mice showed shorter limbs with disrupted bone and cartilage development compared with the heterozygous Prx1-cre;Mettl14 wild type/flox (cHet) control mice. To understand the molecular basis for the abnormalities, we analyzed polysome RNA prepared from day 12.5 (E12.5) embryonic limb buds with RNA-seq.

Project description:Mettl14, a key component of the m6A methyltransferase complex, plays a crucial role in regulating mRNA stability and splicing. Reduced expression of Mettl14 is associated with hepatocellular carcinoma and liver regeneration, yet the molecular mechanisms by which it regulates the hepatocyte cell cycle remain unclear. Using RNA-Seq and MeRIP-Seq in liver-specific Mettl14 knockout mice, we found that Mettl14 deficiency stabilizes Fam32a mRNA through m6A modifications, resulting in increased Fam32a protein levels. Elevated Fam32a expression accelerates the G1/S transition by modulating Cdkn1a splicing, specifically downregulating its variant 2. These findings uncover a novel m6A-dependent mechanism that regulates hepatocyte cell cycle progression and highlight the previously unrecognized role of Fam32a in promoting the G1/S transition.

Project description:SOCS2 Ensures Metabolic Function and Mass Restoration During Liver Regeneration - SOCS2 plays distinct and contrasting roles during liver regeneration. Early after injury, SOCS2 expression increases and limits the rate of regeneration, preserving metabolic activity. Surprisingly, at later times, the role of SOCS2 reverses to promote liver regeneration by stimulating GH release from the pituitary via effects on serum levels of insulin-like growth factor 1. Loss of SOCS2 promotes GH signaling by increasing growth hormone receptor levels and driving phosphorylation of proteins in the GH pathway, establishing a state of hyper-responsiveness to GH. These findings suggest a single protein can play contrasting roles at different times after liver injury and modulation of GH signaling achieves an optimal rate of liver regeneration to balance metabolic and restorative needs. To further understand the mechanism by which SOCS2 increases early liver regeneration, we performed microarray analysis of Socs2-null mice wildtype mice at 24 and 36 hours after hepatectomy. C57BL/6 mice where used as wildtype controls. Socs2-null animals were maintained on a C57BL/6 background. Both wildtype and Socs2-null adult mice were subjected to 2/3 hepatectomy and liver tissue isolated at 24 hours and 36 hours post hepatectomy. Time zero was without hepatectomy in age-matched mice for each genotype. Total RNA isolated from collected liver tissues was pooled for three animals at each time point and two biological replicates (3 pooled liver RNAs each) were labeled for array analysis. This results in a total of 12 microarrays.

Project description:The process of liver regeneration can be divided into a series of stages that include initial inductive or priming events through cellular mitosis. Following two-thirds liver resection, the liver undergoes the “priming” phase, in which cytokines TNF-a and IL-6 activate their respective receptors in hepatocytes. This leads to the activation of several key transcription factors: NF-kB, AP-1, Stat 3, Stat 1, and C/EBP-b and -d . These transcription factors induce the expression of immediate early genes. HGF is also expressed at this time and involved in the transition of quiescent hepatocytes into the G1 phase of the cell cycle. During the G1 phase, delayed early genes are expressed followed by induction of cell cycle–related genes, both of which require new protein synthesis for their production. Increased expression of FoxM1B and TGF-a occurs at the G1/S transition and is correlated with increased expression of cyclinD1 and decreased expression of cdk inhibitors. During the G2/M phase of the cell cycle, FoxM1B directly elevates cyclinB1, cyclinB2, and cdc25B expression. Additionally, FoxM1B is associated with increased cyclinF and p55cdc, which are involved in completion of the cell cycle following partial hepatectomy. In mice, two-thirds partial hepatectomy promotes proliferation of liver cells and rapid growth of the remaining liver tissue, resulting in complete restoration of organ mass in approximately 7 days (Mackey S. et al. Hepatology 2003 Dec;38(6):1349-52). Liver tissue was collected 0h, 24h, 38h, and 48h after partial hepatectomy or sham surgery from both young (5-6 months) and old (25-27 months) CB6F1 mice. All control and partial hepatectomy samples were assayed in triplicate. Relative gene expression levels were determined using Affymetrix moe430_2 oligo arrays.

Project description:The process of liver regeneration can be divided into a series of stages that include initial inductive or priming events through cellular mitosis. Following two-thirds liver resection, the liver undergoes the “priming” phase, in which cytokines TNF-a and IL-6 activate their respective receptors in hepatocytes. This leads to the activation of several key transcription factors: NF-kB, AP-1, Stat 3, Stat 1, and C/EBP-b and -d . These transcription factors induce the expression of immediate early genes. HGF is also expressed at this time and involved in the transition of quiescent hepatocytes into the G1 phase of the cell cycle. During the G1 phase, delayed early genes are expressed followed by induction of cell cycle–related genes, both of which require new protein synthesis for their production. Increased expression of FoxM1B and TGF-a occurs at the G1/S transition and is correlated with increased expression of cyclinD1 and decreased expression of cdk inhibitors. During the G2/M phase of the cell cycle, FoxM1B directly elevates cyclinB1, cyclinB2, and cdc25B expression. Additionally, FoxM1B is associated with increased cyclinF and p55cdc, which are involved in completion of the cell cycle following partial hepatectomy. In mice, two-thirds partial hepatectomy promotes proliferation of liver cells and rapid growth of the remaining liver tissue, resulting in complete restoration of organ mass in approximately 7 days (Mackey S. et al. Hepatology 2003 Dec;38(6):1349-52). Liver tissue was collected 0h, 0.5h, 1h, 2h, and 4h after partial hepatectomy or sham surgery from both young (5-6 months) and old (25-27 months) CB6F1 mice. All control and partial hepatectomy samples were assayed in triplicate. Relative gene expression levels were determined using Affymetrix Murine Genome U74 Version 2 Array.

Project description:RNA N6-methyladenosine (m6A) modification emerges as a pivotal mechanism underpinning numerous intracellular processes. METTL14 dimerizes with METTL3 as a m6A writer to install m6A on mRNA. Subsequently, m6A readers bind to m6A-marked RNAs to influence their metabolism/fate. However, there is a knowledge gap in m6A writers and readers governing liver metabolism. Glucose-6-phosphatase catalytic subunit (G6pc) is the gatekeeper of glycogenolysis and gluconeogenesis, determining hepatic glucose production (HGP); however, posttranscriptional regulation of G6pc is poorly understood. Here, we identify METTL14 as a posttranscriptional regulator of G6pc synthesis. Deletion of Mettl14 decreased, whereas overexpression of METTL14 increased, G6pc mRNA m6A methylation in hepatocytes. We mapped five m6A sites, and mutating the 5 sites (G6pcΔ5A) blocked METTL14-induced m6A methylation of G6pcΔ5A mRNA. METTL14 increased G6pc but not G6pcΔ5A mRNA stability and translation. YTHDF1 and YTHDF3 acted as m6A readers for G6pc mRNA to increase G6pc synthesis. Deletion of Mettl14 decreased gluconeogenesis in primary hepatocytes, liver slices, and mice. Liver METTL14, METTL3, and m6A-methylated G6pc mRNA were upregulated in mice with diet-induced obesity. Deletion of hepatic Mettl14 decreased HGP and mitigated diet-induced metabolic disorders. Collectively, these results unveil a previously-unrecognized METTL14/G6pc mRNA m6A/G6pc biosynthesis/HGP axis guiding glucose metabolism in health and disease.

Project description:m6A regulates virtually every step in RNA metabolism. However, its toles in limb development remains largely unknown. To understand the roles, we created a limb bud-specific conditional knockout (cKO) mice and control heterozygous (cHet) mice of the Mettl14 gene, which encodes an essential subunit in the m6A methyltransferase complex METTL3/METTL14. We harvested limb buds from the mice on E12.5 and applied the proteins to quantitative mass spectrometry to understand how the depletion of Mettl14 affected the proteomes.

Project description:Background and aims: Lethal liver failure is an important clinical issue. To overcome liver failure, we focused on liver regeneration mechanisms by activation of HSCs and KCs. It is known that the HSC-secreted Mac-2 binding protein glycan isomer (M2BPGi) has a function to activate Kupffer cells (KCs) in fibrotic liver. However, the importance and functional mechanism of liver regeneration by HSCs/M2BPGi/KCs axis in remnant liver after hepatectomy are still unknown. The aim of this study is to clarify whether the HSCs-derived M2BPGi can activate KCs in damaged-liver by not only fibrosis but also after hepatectomy and to elucidate the new molecular mechanism of liver regeneration by HSCs and KCs. Methods: We examined the effect of M2BPGi on human hepatocytes and KCs, and explored secretory factors from M2BPGi-activated KCs by proteomics approach. Further, the effect of Glucose-regulated protein 78 (GRP78) as one of the M2BPGi-related secreted proteins on liver regeneration was examined in in vitro analysis and mouse hepatectomy model. Results: Although M2BPGi had no hepatocyte promoting effect, M2BPGi promoted the production of GRP78 in KCs. The KCs-drived GRP78 promoted hepatocyte proliferation. GRP78 administration facilitated liver regeneration in 70% hepatectomy mice and increased the survival rate in lethal 90% hepatectomy mice with liver failure. Conclusion: The M2BPGi activated-KCs extract the GRP78 which facilitates liver regeneration via activation of the proliferation potency of hepatocytes. Moreover, GRP78 administration could improve the survival in the lethal mice model. Our data suggested that the new hepatotrophic factor GRP78 may be a promising therapeutic tool for lethal liver failure in the clinic.