Project description:Synthesis and degradation of cellular constituents must be balanced to maintain cellular homeostasis, especially during adaptation to environmental stress. The role of autophagy in the degradation of proteins and organelles is well-characterized. However, autophagy-mediated RNA degradation in response to stress and the potential preference of specific RNAs to undergo autophagy-mediated degradation have not been examined. In this study, we demonstrate selective mRNA degradation by rapamycin-induced autophagy in yeast. Profiling of mRNAs from the vacuole reveals that subsets of mRNAs, such as those encoding amino acid biosynthesis and ribosomal proteins, are preferentially delivered to the vacuole by autophagy for degradation. We also reveal that autophagy-mediated mRNA degradation is tightly coupled with translation by ribosomes. Genome-wide ribosome profiling suggested a high correspondence between ribosome association and targeting to the vacuole. We propose that autophagy-mediated mRNA degradation is a unique and previously-unappreciated function of autophagy that affords post-transcriptional gene regulation.

Project description:Control of mRNA levels is a fundamental aspect in the regulation of gene expression and is achieved through a balance between mRNA synthesis and decay. E-twenty-six-related gene (Erg) proteins are canonical transcription factors whose described functions are confined to the control of mRNA synthesis. Here, we report that ERG also regulates gene expression by affecting mRNA stability and identify the molecular mechanisms underlying this function. ERG is recruited to mRNAs via its interaction with the RNA-binding protein RBPMS and promotes mRNA decay by binding to CNOT2, a component of the CCR4 deadenylation complex. Transcriptome-wide mRNA stability analysis revealed that ERG controls the degradation of a subset of mRNAs highly connected to Aurora signaling, and whose decay during S-phase is necessary for mitotic progression. Our data indicate that control of gene expression by mammalian transcription factors may follow a more complex scheme than previously anticipated, integrating mRNA synthesis and degradation.

Project description:Autophagy is a catabolic membrane trafficking process involved in degradation of cellular constituents through lysosomes, which maintains cell and tissue homeostasis. While much attention has been focused on autophagic turnover of cytoplasmic materials, little is known regarding the role of autophagy in degrading nuclear components. Here we report that autophagy machinery mediates degradation of nuclear lamina in mammalian cells, a process we term laminophagy. The autophagy protein LC3 is present in the nucleus and directly interacts with the nuclear lamina protein Lamin B1, and associates with lamin-associated domains (LADs) on chromatin. This interaction does not downregulate Lamin B1 during starvation, but mediates nuclear lamina degradation upon tumorigenic insults, such as by oncogenic Ras. Laminophagy is achieved by nucleus-to-cytosol transport that delivers Lamin B1 to lysosome for degradation. Inhibiting autophagy or LC3-Lamin B1 interaction prevents oncogenic Ras-induced Lamin B1 loss and delays oncogene-induced cell cycle arrest. Our study unveils a role of autophagy in degrading nuclear materials, and suggests laminophagy as a guarding mechanism protecting cells from tumorigenesis.

Project description:Maternal mRNA degradation is a critical event of maternal-to-zygotic transition (MZT) that determines the developmental potential of early embryos. Nuclear Poly(A)-binding proteins (PABPNs) are extensively involved in mRNA post-transcriptional regulations, but their functions in mammalian MZT has not been investigated. In this study, we identified a novel maternal-effect factor PABPN1-like (PABPN1L), rather than its ubiquitously expressed homolog PABPN1, as an RNA-binding adapter of the mammalian MZT licensing factor BTG4 which mediates maternal mRNAs clearance. Female Pabpn1l null mice produced morphologically normal oocytes but were infertile owing to early developmental arrest of the resultant embryos at the 1-to-2-cell stages without undergoing ZGA. Deletion of Pabpn1l impairs the deadenylation and degradation of a subset of BTG4-targeted maternal mRNAs during MZT. In addition to recruiting BTG4 to the mRNA 3ʹ-poly(A) tails, PABPN1L is also required for BTG4 protein accumulation in maturing oocytes by protecting BTG4 from SCF-βTrCP1 E3 ubiquitin ligase-mediated polyubiquitination and degradation. This study highlights a noncanonical cytoplasmic function of nuclear poly(A)-binding proteins mRNA turnover as well as its physiological importance during MZT.

Project description:In this study, we demonstrated that OTX2 was transcriptionally and post-transcriptionally regulated by O-GlcNAcylation. We describe the modes of degradation of this essential homeobox protein involving both the proteasome and macroautophagy. While the proteasome remains the canonical degradation pathway, we demonstrated that OTX2 forms oligomers and/or aggregates that are resistant to proteasomal degradation and require macroautophagy. Furthermore, elevated cellular concentration of OTX2 promoted aggregation, OTX2 could either interact with the chaperonin CCT5 or be O-GlcNAcylated at the key residues (S1135/S136/T137) to prevent its oligomerization, suggesting a protective role of O-GlcNAcylation in OTX2 turnover.

Project description:Autophagy is a lysosomal degradation pathway critical for maintaining cellular homeostasis and viability, and is predominantly regarded as a rapid and dynamic cytoplasmic process. To improve our understanding of the transcriptional and epigenetic events associated with autophagy, we performed genome-wide transcriptomic and epigenomic profiling after nutrient deprivation in human wildtype and autophagy-deficient cells. We observed that nutrient deprivation leads to the transcriptional induction of numerous autophagy-associated genes. These transcriptional changes are reflected at the epigenetic level (H3K4me3, H3K27ac, and H3K56ac) and are independent of autophagic flux.

Project description:Autophagy is a lysosomal degradation pathway critical for maintaining cellular homeostasis and viability, and is predominantly regarded as a rapid and dynamic cytoplasmic process. To improve our understanding of the transcriptional and epigenetic events associated with autophagy, we performed genome-wide transcriptomic and epigenomic profiling after nutrient deprivation in human wildtype and autophagy-deficient cells. We observed that nutrient deprivation leads to the transcriptional induction of numerous autophagy-associated genes. These transcriptional changes are reflected at the epigenetic level (H3K4me3, H3K27ac, and H3K56ac) and are independent of autophagic flux.

Project description:The hexosamine biosynthetic pathway (HBP) is a pathway that requires glucose using approximately 3% ~ 5% of total glucose coming into cells. HBP synthesizes UDP-GlcNAc using not only glucose but also various metabolic products such as those amino acid, fatty acid and nucleotide. O-GlcNAcylation by Ogt is considered the act as a nutrient sensor because the amount of UDP-GlcNAc is influenced by various metabolites. Therefore, when the balance of O-glcnacylation is broken, it induces diseases such as cancer or neurological diseases or affects the differentiation of cells.  Bone homeostasis is regulated by osteoblasts that produce bone and osteoclasts that resorb bone. Disruption of this balance leads to diseases such as osteoporosis. Previous studies reported that osteoblast differentiation was inhibited by excessive O-GlcNAcylation. Increased o-glcnacylation of runx2 induced bone homeostasis imbalance by reducing the transcriptional activity of runx2 and mRNA expression of the target gene of runx2 involved in osteoblast differentiation. However, how O-GlcNAcylation regulates differentiation of osteoclast remains unclear. So, the goals of our study are to describe expression changes in genes expression associated with O-GlcNAcylation during RNAKL-mediated osteoclast differentiation.

Project description:Autophagy is a highly conserved lysosomal degrative pathway important for maintaining cellular homeostasis. Much of our current knowledge of autophagy is focused on the initiation steps with the later steps, particularly lysosomal fusion leading to autolysosome formation and the subsequent role of lysosomal enzymes in degradation and recycling become evident. Autophagy can function in both cell survival and cell death, however the mechanisms that distinguish adaptive/survival autophagy from autophagy-dependent cell death remains to be established. Here we use a proteomic analysis of larval midguts during degradation identifying a group of proteins with peptidase activity, suggesting a role in autophagy-dependent cell death. We show that Cathepsin L deficient Drosophila larval midgut cells, accumulate autophagic vesicles due to a block in autophagic flux, yet midgut degradation in not compromised. The accumulation of large aberrant autolysosomes in the absence of Cathepsin function appears to be the consequence of decreased degradative capacity as they contain undigested cytoplasmic material rather and not due to a defect in autophagosome-lysosome fusion. Finally, we find that other Cathepsins are also required for proper autolysosomal degradation in Drosophila larval midgut cells and that this is conserved in mammalian cells. Our findings suggest that Cathepsins play an important degrative role in the autolysosome to maintain autophagy flux, by balancing autophagosome production and turnover (to prevent autophagic stress).

Project description:The PI3K-PKB/c-akt-FOXO signalling network provides a major intracellular hub for regulation of cell proliferation, survival and stress resistance1. Here we report a novel function for FOXO transcription factors in regulating autophagy through modulation of intracellular glutamine levels. To identify novel transcriptional targets of this module we performed an unbiased microarray analysis after conditional activation of the key components PI3K, PKB, FOXO3 and FOXO4. Utilising this global pathway approach we identified glutamine synthetase (GS) as being transcriptionally regulated by PI3K-PKB-FOXO signalling. FOXO-mediated increase in GS expression specifically induced glutamine production independently of cell type, and this was evolutionary conserved. FOXO activation resulted in mTOR inhibition by preventing the translocation of mTOR to lysosomal membranes, which was dependent on GS activity. Increased GS activity resulted in increased autophagosome turnover as measured by LC3 lipidation, p62 degradation, and confocal imaging of LC3, p62, WIPI-1, ULK2 and Atg12. Inhibition of FOXO3-mediated autophagy resulted in increased apoptosis, suggesting that the induction of autophagy by FOXO3-mediated upregulation of GS is important for cellular survival. These findings reveal a novel signalling network that can directly modulate autophagy through regulation of glutamine metabolism. conditional activation of pkb and pi3k were followed in a timeseries. Each timepoint consists of 4 independent replicates, labeled with either cy3 or cy5 and put on array against time0.