Project description:Cells convert complex metabolic information into stress-adapted autophagy responses. Canonically, multilayered protein kinase networks converge on the conserved Atg1/ULK kinase complex (AKC) to induce non-selective and selective forms of autophagy in response to metabolic changes. Here, we show that, upon phosphate starvation, the metabolite sensor Pho81 interacts with the adaptor subunit Atg11 at the AKC via an Atg11/FIP200 interaction motif to modulate pexophagy by virtue of its conserved phospho-metabolite sensing SPX domain. Notably, core AKC components Atg13 and Atg17 are dispensable for phosphate starvation-induced autophagy revealing significant compositional and functional plasticity of the AKC. Our data indicate that, instead of functioning as a selective autophagy receptor, Pho81 compensates for partially inactive Atg13 by promoting Atg11-phosphorylation by Atg1 critical for pexophagy during phosphate starvation. Our work shows Atg11/FIP200 adaptor subunits not only bind selective autophagy receptors but also modulator subunits that convey metabolic information directly to the AKC for autophagy regulation.

Project description:We performed phosphorylation site mapping on of budding yeast Atg13 applying a quantitative mass spectrometry-based proteomics approach based on stable isotope labeling with amino acids in cell culture (SILAC). We determined changes in the Atg13 phosphorylation pattern in response of inhibition of kinase Atg1 and starvation conditions (using rapamycin), respectively. To do so, Atg13 was tandem purified via a histidine-biotin (HB) tag from cells growing at the respective experimental condition. Different stimulus-dependent PTM profiles of Atg13 have been identified.

Project description:Autophagy is a conserved intracellular degradation pathway exerting various cytoprotective and homeostatic functions by utilizing de novo double membrane vesicle (autophagosome) formation to target a wide range of cytoplasmic material for vacuolar/lysosomal degradation. The Atg1 kinase is one of its key regulators coordinating a complex signaling program to orchestrate autophagosome formation. Combining in vitro reconstitution and cell based approaches, we demonstrate that Atg1 is activated by lipidated Atg8 (Atg8-PE) stimulating substrate phosphorylation along the growing autophagosomal membrane. Atg1 dependent phosphorylation of Atg13 triggers Atg1 complex dissociation resulting in rapid turnover of Atg1 complex subunits at the pre-autophagosomal structure. Moreover, Atg1 recruitment by Atg8-PE self-regulates Atg8-PE levels in the growing autophagosomal membrane by phosphorylating and inhibiting the Atg8 specific E2 and E3. Taken together, our work uncovers the molecular basis for positive and negative feedback imposed by Atg1, and opposing phosphorylation and dephosphorylation events governing the spatiotemporal regulation of autophagy.

Project description:Autophagy is a conserved process that recycles cellular contents to promote survival. Although nitrogen starvation is the canonical inducer of autophagy, recent studies have revealed several other nutrients important to this process. In this study, we used a quantitative, high-throughput assay to identify potassium starvation as a new and potent inducer of autophagy. We found that potassium-dependent autophagy requires the core pathway kinases Atg1, Atg5, Vps34, as well as other components of Phosphatidylinositol 3-kinase Complex I. Transmission electron microscopy revealed abundant autophagosome formation in response to both stimuli. RNA sequencing indicated distinct transcriptional responses – nitrogen affects transport of ions such as copper while potassium targets the organization of other cellular components. Thus, nitrogen and potassium share the ability to influence metabolic supply and demand but do so in different ways. Both inputs promote catabolism through bulk autophagy, but inhibit cellular anabolism through distinct mechanisms.

Project description:As a core Autophagy-related (Atg) protein during yeast autophagy, Atg1 interacts with numerous other proteins, and its kinase activity facilitates to phosphorylate various substrates. How Atg1-interacting partners and substrates synergistically orchestrate autophagy remains to be further dissected. In this study, we conducted a transcriptomic, proteomic and phosphoproteomic profiling of Atg1-dependent molecular landscapes during nitrogen starvation-triggered autophagy.

Project description:RNA-seq raw data of WT, Atg1-KO and Atg1-KD yeast during nitrogen starvation induced autophagy

Project description:To explore the mechanisms of autophagy in the regulation of vascular tumour cells, we generated three autophagy-related genes, Fip200, Atg5 and Atg7, knockout vascular tumor cells in 562 cell line by CRISPR-Cas9-based sgRNAs. Three independent replicates of mRNA samples were prepared from each KO cells and subjected to RNA-sequencing in comparison to three samples from control 562 cells. We examined changes in gene expression by transcriptional profiling of Fip200 KO, Atg5 KO, and Atg7 KO cells, compared to control 562 cells respectively.

Project description:Brassinosteroids (BRs) regulate plant growth, development and stress responses by activating the core transcription factor BRI1-EMS-SUPPRESSOR1 (BES1). The E3 Ubiquitin ligase(s) that modify BES1 for autophagy-mediated degradation remain to be fully defined. In this study, we identified an F-box family E3 ubiquitin ligase termed BES1-ASSOCIATED F-BOX1 (BAF1). BAF1 interacts with and ubiquitinates BES1. Accordingly, BES1 stability and protein levels were reduced in BAF1 overexpression plants but increased in a baf1 loss-of-function mutant and in BAF1-DF (BAF1 with F-box deleted, dominant-negative form) overexpression lines. Selective autophagy of BES1, but not bulk autophagy, was significantly compromised in the baf1 mutant under sucrose starvation. BES1 degradation mediated by BAF1 could be blocked through autophagy but not proteasome inhibitors, suggesting that BAF1 mediates BES1 degradation largely through autophagy. baf1 and BAF1-DF overexpression plants had increased BR-regulated growth but were sensitive to long-term sucrose starvation, while BAF1 overexpression plants had decreased BR-regulated growth but were highly tolerant of sucrose starvation. Our results not only established BAF1 as a novel E3 ubiquitin ligase that targets BES1 for degradation through selective autophagy pathway, but also revealed a mechanism for plants to reduce growth during sucrose starvation by targeting this central growth regulator.

Project description:The molecular chaperone Hsp90 is involved in the stability and activity of its client proteins which largely comprise of kinases. Phosphorylation of Hsp90 by these kinase clients provides a reciprocal regulatory mechanism between these proteins, however the mechanism of regulating the cellular pathway remains elusive. Here, we show that the serine/threonine kinase Atg1(yeast)/ULK1(mammalian) phosphorylates a conserved serine in the amino-domain of Hsp90 and reduces its ATPase activity hence lowers chaperone function. Broadly this modification negatively impacts the chaperoning of the kinase clients including Atg1/ULK1, yet enhances the activity of the non-kinase clients such as the heat shock factor and the steroid hormone receptors. Interestingly, ATG1/ULK1 mediated phosphorylation of the Hsp90 is essential for initiation of autophagy since yeast expressing a non-phosphorylatable Hsp90 were unable to undergo autophagy and the phosphomimetic Hsp90 mutants were underwent autophagy even in the absence of stimulus. Our findings provide a new paradigm where kinase client mediated phosphorylation of Hsp90 not only regulates the chaperone function but it is essential to initiate and regulate the relevant signaling pathway.

Project description:Our preliminary data showed that FIP200 is essential for dsRNA-induced interferon production. To corroborate the role of FIP200 in RIG-I signaling pathway, we are going to examine the cytosolic dsRNA-induced gene expression in mouse RAW24.7 macrophages and FIP200 knockout RAW cells.