Atg14: A Key Player in Orchestrating Autophagy

Phosphorylation of phosphatidylinositol (PtdIns) by a PtdIns 3-kinase is an essential process in autophagy. Atg14, a specific subunit of one of the PtdIns 3-kinase complexes, targets the complex to the probable site of autophagosome formation, thereby, sorting the complex to function specifically in autophagy. The N-terminal half of Atg14, containing coiled-coil domains, is required to form the PtdIns 3-kinase complex and target it to the proper site. The C-terminal half of yeast Atg14 is suggested to be involved in the formation of a normal-sized autophagosome. The C-terminal half of mammalian Atg14 contains the Barkor/Atg14(L) autophagosome-targeting sequence (BATS) domain that preferentially binds to the highly curved membranes containing PtdIns(3)P and is proposed to target the PtdIns 3-kinase complex efficiently to the isolation membrane. Thus, the N- and C-terminal halves of Atg14 are likely to have an essential core function and a regulatory role, respectively

PtdIns 3-Kinase Orchestrates Autophagosome Formation in Yeast

Eukaryotic cells can massively transport their own cytoplasmic contents into a lytic compartment, the vacuole/lysosome, for recycling through a conserved system called autophagy. The key process in autophagy is the sequestration of cytoplasmic contents within a double-membrane structure, the autophagosome. Autophagosome formation requires the elaborate cooperation of Atg (autophagy-related) proteins and lipid molecules. Phosphorylation of phosphatidylinositol (PtdIns) by a PtdIns 3-kinase, Vps34, is a key step in coordinating Atg proteins and lipid molecules. Vps34 forms two distinct protein complexes, only one of which is involved in generating autophagic membranes. Upon induction of autophagy, PtdIns(3)P, the enzymatic product of PtdIns 3-kinase, is massively transported into the lumen of the vacuole via autophagy. PtdIns(3)P is enriched on the inner membrane of the autophagosome. PtdIns(3)P recruits the Atg18−Atg2 complex and presumably other Atg proteins to autophagic membranes, thereby coordinating lipid molecules and Atg proteins

DOCK2 is involved in the host genetics and biology of severe COVID-19

「コロナ制圧タスクフォース」COVID-19疾患感受性遺伝子DOCK2の重症化機序を解明 --アジア最大のバイオレポジトリーでCOVID-19の治療標的を発見--. 京都大学プレスリリース. 2022-08-10.Identifying the host genetic factors underlying severe COVID-19 is an emerging challenge. Here we conducted a genome-wide association study (GWAS) involving 2, 393 cases of COVID-19 in a cohort of Japanese individuals collected during the initial waves of the pandemic, with 3, 289 unaffected controls. We identified a variant on chromosome 5 at 5q35 (rs60200309-A), close to the dedicator of cytokinesis 2 gene (DOCK2), which was associated with severe COVID-19 in patients less than 65 years of age. This risk allele was prevalent in East Asian individuals but rare in Europeans, highlighting the value of genome-wide association studies in non-European populations. RNA-sequencing analysis of 473 bulk peripheral blood samples identified decreased expression of DOCK2 associated with the risk allele in these younger patients. DOCK2 expression was suppressed in patients with severe cases of COVID-19. Single-cell RNA-sequencing analysis (n = 61 individuals) identified cell-type-specific downregulation of DOCK2 and a COVID-19-specific decreasing effect of the risk allele on DOCK2 expression in non-classical monocytes. Immunohistochemistry of lung specimens from patients with severe COVID-19 pneumonia showed suppressed DOCK2 expression. Moreover, inhibition of DOCK2 function with CPYPP increased the severity of pneumonia in a Syrian hamster model of SARS-CoV-2 infection, characterized by weight loss, lung oedema, enhanced viral loads, impaired macrophage recruitment and dysregulated type I interferon responses. We conclude that DOCK2 has an important role in the host immune response to SARS-CoV-2 infection and the development of severe COVID-19, and could be further explored as a potential biomarker and/or therapeutic target

Dynamics and function of PtdIns(3)P in autophagy.

Phosphorylation of phosphatidylinositol (PtdIns) by PtdIns 3-kinase is essential for autophagy. However, the distribution and function of the enzymatic product, PtdIns 3-phosphate (PtdIns(3)P), has been unknown. We monitored PtdIns(3)P distribution during autophagy by live imaging, biochemistry, and electron microscopy, and found that PtdIns(3)P is massively delivered into the vacuole via autophagy. PtdIns(3)P is highly enriched as a membrane component of the elongating isolation membranes and autophagosome membranes rather than as an enclosed cargo, implying direct involvement of PtdIns(3)P in autophagosome formation. This observation also provides important basic information on the nature of the autophagosome membrane, which is still poorly understood. Notably, PtdIns(3)P is highly enriched on the inner (concave) surfaces of the isolation membrane and autophagosome compared to the outer surfaces. PtdIns(3)P is also enriched on ambiguous structures juxtaposed to the elongating tips of isolation membranes. We also investigated the function of PtdIns(3)P in autophagy, and show that PtdIns(3)P recruits the Atg18-Atg2 complex to autophagic membranes through an Atg18-PtdIns(3)P interaction. Interestingly, PtdIns(3)P is required only for the association of the Atg18-Atg2 complex to autophagic membranes but not for any subsequent functional activity of the Atg18-Atg2 complex, suggesting that PtdIns(3)P does not act allosterically on Atg18. Based on these results we discuss the function of PtdIns(3)P in autophagy

The Rim101 pathway contributes to ER stress adaptation through sensing the state of plasma membrane

Yeast cells sense alterations in the plasma membrane (PM) lipid asymmetry and external alkalization by the sensor protein Rim21, which functions in the Rim101 pathway. Rim101 signaling is initiated at the PM by the recruitment of the Rim101 signaling complex. The PM physically associates with the cortical endoplasmic reticulum (ER) to form ER-PM contact sites, where several signaling events, lipid exchange, and ion transport take place. In the present study, we investigated the spatial relationship between ER-PM contact sites and the sites of Rim101 signaling. Rim101 signaling mostly proceeds outside ER-PM contact sites in the PM and did not require intact ER-PM contact for its activation. Rather, the Rim101 pathway was constitutively activated by ER-PM contact site disruption, which is known to cause ER stress. ER stress induced by tunicamycin treatment activated the Rim101 pathway. Furthermore, the sensitivity of cells to tunicamycin without ER-PM contact was considerably elevated by the deletion of RIM21. These results suggest that the Rim101 pathway is important for the adaptation to ER stress by compensating for alterations in PM lipid asymmetry induced by ER stress

Signaling Events of the Rim101 Pathway Occur at the Plasma Membrane in a Ubiquitination-Dependent Manner

In yeast, external alkalization and alteration in plasma membrane lipid asymmetry are sensed by the Rim101 pathway. It is currently under debate whether the signal elicited by external alkalization is transduced to downstream molecules at the plasma membrane or via endocytosis of the Rim21 sensor protein at the late endosome. We found that the downstream molecules, including arrestin-related protein Rim8, calpain-like protein Rim13, and scaffold protein Rim20, accumulated at the plasma membrane upon external alkalization and that the accumulation was dependent on Rim21. Snf7, an endosomal sorting complex required for transport (ESCRT) III subunit also essential for the Rim101 pathway, localized to the plasma membrane, in addition to the late endosome, under alkaline conditions. Snf7 at the plasma membrane but not at the late endosome was shown to be involved in Rim101 signaling. In addition, the Rim101 pathway was normally activated, even when endocytosis was severely impaired. Considering this information as a whole, we propose that Rim101 signaling proceeds at the plasma membrane. We also found that activity of the Rsp5 ubiquitin ligase was required for recruiting the downstream molecules to the plasma membrane, suggesting that ubiquitination mediates Rim101 signaling at the plasma membrane

Effects on vesicular transport pathways at the late endosome in cells with limited very long-chain fatty acids

Very long-chain fatty acids (VLCFAs), fatty acids with chain length of > 20, possess a wide range of biological functions. However, their roles at the molecular level remain largely unknown. In the presented study, we screened for multicopy suppressors that rescued temperature-sensitive growth of VLCFA-limited yeast cells, and identified the VPS21 gene, encoding a Rab GTPase, as such a suppressor. When the vps21Δ mutation was introduced into a deletion mutant of the SUR4 gene, which encodes a VLCFA elongase, a synthetic growth defect was observed. Endosome-mediated vesicular trafficking pathways, including endocytosis and the CPY pathway, were severely impaired in sur4Δ vps21Δ double mutants, while the AP-3 pathway that bypasses the endosome was unaffected. In addition, the sur4Δ mutant also exhibited a synthetic growth defect when combined with the deletion of VPS3, which encodes a subunit of the CORVET (class C core vacuole/endosome tethering) complex that tethers transport vesicles to the late endosome/multivesicular body (MVB). These results suggest that requirement of VLCFAs is especially high in the endosomal pathways, of all the intracellular trafficking pathways

Sphingolipid synthesis is involved in autophagy in Saccharomyces cerevisiae

In eukaryotes, autophagy is a conserved protein degradation system that degrades cytoplasmic components by encompassing them with double-membrane structures, called autophagosomes, and delivering them to the lytic compartments of vacuoles/lysosomes. Certain Atg proteins are known to be involved in autophagy, yet the identity and function of lipid molecules involved remain largely unknown. We investigated the involvement of sphingolipids in autophagy using Saccharomyces cerevisiae. Inhibiting synthesis of the simplest complex sphingolipid, inositol phosphorylceramide (IPC), resulted in reduced autophagic activities. Similar results were obtained using myriocin, an inhibitor of the first step in sphingolipid synthesis. Our results indicate that sphingolipids, especially IPC, are required for autophagy. Inhibition of sphingolipid synthesis had no effect on formation of Atg12-Atg5 or Atg8-phosphatidylethanolamine conjugates, on maturation of vacuolar proteases, or on formation of the pre-autophagosomal structure (PAS). These results suggest that sphingolipids are not involved in the cellular signaling that leads to formation of the PAS, but may be involved in the process of autophagosome formation

Unperverted synthesis of complex sphingolipids is essential for cell survival under nitrogen starvation

Changes in membrane dynamics are known to occur in cells faced with starvation. However, the functions of the major lipid components of biological membranes, sphingolipids, during the starvation response remain unclear. In this study, we found that yeast cells lacking genes encoding mannosylinositol phosphorylceramide (MIPC) synthases (csg1 csh1) underwent rapid cell death upon nitrogen starvation, but not upon carbon starvation or carbon and nitrogen starvation. Addition of NaN3 prevented the nitrogen starvation-induced cell death of the csg1 csh1 cells, indicating that energy production is required for this rapid cell death. IPC) species containing phytosphingosine. Removing Ca2+ by treating the cells with a calcium chelator or by changing the medium to a Ca2+-free medium before nitrogen starvation rescued the cells from death. Approximately half of the cells died shortly after collapse of the vacuole, whereas in the other half, morphological changes in the cytoplasm preceded vacuole disruption. Because the vacuole is the major Ca2+ storage organelle, we suggest that the vacuole is involved in the cell death either directly or indirectly. We report here that normal synthesis of complex sphingolipids is important for cell survival in nitrogen-starved medium

Membrane Protein Rim21 Plays a Central Role in Sensing Ambient pH in Saccharomyces cerevisiae

External alkalization activates the Rim101 pathway in Saccharomyces cerevisiae. In this pathway, three integral membrane proteins Rim21, Dfg16, and Rim9 are considered to be the components of the pH-sensor machinery. However, how these proteins are involved in pH sensing is totally unknown. In this work, we investigated the localization, physical interaction, and interrelationship of Rim21, Dfg16, and Rim9. These proteins were found to form a complex and to localize to the plasma membrane in a patchy and mutually-dependent manner. Their cellular level was also mutually dependent. In particular, the Rim21 level was significantly decreased in dfg16Δ and rim9Δ cells. Upon external alkalization, the proteins were internalized and degraded. We also demonstrate that the transient degradation of Rim21 completely suppressed the Rim101 pathway but the degradation of neither Dfg16 nor Rim9 did. This finding strongly suggests that Rim21 is the pH-sensor protein and that Dfg16 and Rim9 play auxiliary functions through maintaining the Rim21 level and assisting its plasma membrane localization. Even without external alkalization, the Rim101 pathway was activated in a Rim21-dependent manner by either protonophore treatment or depletion of phosphatidylserine in the inner leaflet of the plasma membrane, both of which caused plasma membrane depolarization like the external alkalization. Therefore, the plasma membrane depolarization seems to be one of the key signals for the pH-sensor molecule Rim21