Vacuolar fragmentation promotes fluxes of microautophagy and micronucleophagy but not of macroautophagy.

Vacuoles and lysosomes are organelles involved in the degradation of cytoplasmic proteins and organelles. Vacuolar morphology is dynamically regulated by fission and fusion in budding yeast. Vacuolar fusion is elicited in nutrient-depleted conditions and mediated by inactivation of target of rapamycin complex 1 (TORC1) protein kinase. However, it is unknown whether and how vacuolar morphology affects macroautophagy and microautophagy, which are induced by nutrient starvation and TORC1 inactivation. Here, we developed a system to control vacuolar fission in budding yeast. Vacuolar fragmentation promoted microautophagy but not macroautophagy. Vacuolar fragmentation caused multiple nucleus-vacuole junctions. Multiple vacuoles caused by vacuolar fragmentation also improved micronucleophagy (microautophagic degradation of a portion of the nucleus). However, vacuolar morphology did not impact nucleolar remodeling, condensation of the rDNA (rRNA gene) region, or separation of ribosomal DNA from nucleolar proteins, which is evoked by TORC1 inactivation. Thus, this study provides insights into the impacts of vacuolar/lysosomal morphology on macroautophagy and microautophagy.

Interphase chromosome condensation in nutrient-starved conditions requires Cdc14 and Hmo1, but not condensin, in yeast.

When asynchronously growing cells suffer from nutrient depletion and inactivation of target of rapamycin complex 1 (TORC1) protein kinase, the rDNA (rRNA gene) region is condensed in budding yeast Saccharomyces cerevisiae, which is executed by condensin and Cdc14 protein phosphatase. However, it is unknown whether these mitotic factors can condense the rDNA region in nutrient-starved interphase cells. Here, we show that condensin is not involved in TORC1 inactivation-induced rDNA condensation in G1 cells. Instead, the high-mobility group protein Hmo1 drove this process. The histone deacetylase Rpd3 and Cdc14, which repress rRNA transcription, were both required for the interphase rDNA condensation. Furthermore, interphase rDNA condensation necessitated CLIP and cohibin that tether rDNA to inner nuclear membranes. Finally, we showed that Hmo1, CLIP, Rpd3, and Cdc14 were required for survival in nutrient-starved G1 cells. Thus, this study disclosed novel features of interphase chromosome condensation.

TORC1 inactivation promotes APC/C-dependent mitotic slippage in yeast and human cells.

Unsatisfied kinetochore-microtubule attachment activates the spindle assembly checkpoint to inhibit the metaphase-anaphase transition. However, some cells eventually override mitotic arrest by mitotic slippage. Here, we show that inactivation of TORC1 kinase elicits mitotic slippage in budding yeast and human cells. Yeast mitotic slippage was accompanied with aberrant aspects, such as degradation of the nucleolar protein Net1, release of phosphatase Cdc14, and anaphase-promoting complex/cyclosome (APC/C)-Cdh1-dependent degradation of securin and cyclin B in metaphase. This mitotic slippage caused chromosome instability. In human cells, mammalian TORC1 (mTORC1) inactivation also invoked mitotic slippage, indicating that TORC1 inactivation-induced mitotic slippage is conserved from yeast to mammalian cells. However, the invoked mitotic slippage in human cells was not dependent on APC/C-Cdh1. This study revealed an unexpected involvement of TORC1 in mitosis and provides information on undesirable side effects of the use of TORC1 inhibitors as immunosuppressants and anti-tumor drugs.

The PI3 Kinase Complex II-PI3P-Vps27 Axis on Vacuolar Membranes is Critical for Microautophagy Induction and Nutrient Stress Adaptation.

Phosphatidylinositol 3-phosphate (PI3P), a scaffold of membrane-associated proteins required for diverse cellular events, is produced by Vps34-containing phosphatidylinositol 3-kinase (PI3K). PI3K complex I (PI3KCI)-generated PI3P is required for macroautophagy, whereas PI3K complex II (PI3KCII)-generated PI3P is required for endosomal sorting complex required for transport (ESCRT)-mediated multi-vesicular body (MVB) formation in late endosomes. ESCRT also promotes vacuolar membrane remodeling in microautophagy after nutrient starvation and inactivation of target of rapamycin complex 1 (TORC1) protein kinase in budding yeast. Whereas PI3KCI and macroautophagy are critical for the nutrient starvation response, the physiological roles of PI3KCII and microautophagy during starvation are largely unknown. Here, we showed that PI3KCII-produced PI3P on vacuolar membranes is required for microautophagy induction and survival in nutrient-stressed conditions. PI3KCII is required for Vps27 (an ESCRT-0 component) recruitment and ESCRT-0 complex formation on vacuolar surfaces after TORC1 inactivation. Forced recruitment of Vps27 onto vacuolar membranes rescued the defect in microautophagy induction in PI3KCII-deficient cells, indicating that a critical role of PI3P on microautophagy induction is Vps27 recruitment onto vacuolar surfaces. Finally, vacuolar membrane-associated Vps27 was able to recover survival during nutrient starvation in cells lacking PI3KCII or Vps27. This study revealed that the PI3KCII-PI3P-Vps27 axis on vacuolar membranes is critical for ESCRT-mediated microautophagy induction and nutrient stress adaptation.

Cdc14 phosphatase downmodulates ESCRT-0 complex formation on vacuolar membranes and microautophagy after TORC1 inactivation.

Remodeling of vacuolar membranes mediated by endosomal sorting complex required for transport (ESCRT) is critical for microautophagy induction in budding yeast. Nutrient depletion and inactivation of target of rapamycin complex 1 (TORC1) protein kinase elicit recruitment of the ESCRT-0 complex (Vps27-Hse1) onto vacuolar membranes and ESCRT-mediated microautophagy induction. Mitotic protein phosphatase Cdc14 antagonizes TORC1-mediated phosphorylation in macroautophagy induction after nutrient starvation and TORC1 inactivation. Here, we report that Cdc14 downregulates microautophagy induction after TORC1 inactivation. Cdc14 dysfunction stimulated the vacuolar membrane recruitment of Hse1, but not Vps27, after TORC1 inactivation, promoting ESCRT-0 complex formation. Conversely, overexpression of CDC14 compromises Hse1 recruitment on vacuolar membranes and microautophagy induction after TORC1 inactivation. Thus, Cdc14 phosphatase regulates the fluxes of two types of autophagy in the opposite directions, namely, it elicits macroautophagy and attenuates microautophagy.

Sorting nexin Mdm1/SNX14 regulates nucleolar dynamics at the NVJ after TORC1 inactivation.

The degradation of nucleolar proteins - nucleophagy - is elicited by nutrient starvation or the inactivation of target of rapamycin complex 1 (TORC1) protein kinase in budding yeast. Prior to nucleophagy, nucleolar proteins migrate to the nucleus-vacuole junction (NVJ), where micronucleophagy occurs, whereas rDNA (rRNA gene) repeat regions are condensed and escape towards NVJ-distal sites. This suggests that the NVJ controls nucleolar dynamics from outside of the nucleus after TORC1 inactivation, but its molecular mechanism is unclear. Here, we show that sorting nexin (SNX) Mdm1, an inter-organelle tethering protein at the NVJ, mediates TORC1 inactivation-induced nucleolar dynamics. Furthermore, Mdm1 was required for proper nucleophagic degradation of nucleolar proteins after TORC1 inactivation, where it was dispensable for the induction of nucleophagic flux itself. This indicated that nucleophagy and nucleolar dynamics are independently regulated by TORC1 inactivation. Finally, Mdm1 was critical for survival during nutrient starvation conditions. Mutations of SNX14, a human Mdm1 homolog, cause neurodevelopmental disorders. This study provides a novel insight into relationship between sorting nexin-mediated microautophagy and neurodevelopmental disorders.

The vacuole controls nucleolar dynamics and micronucleophagy via the NVJ.

Chromosomes have their own territories and dynamically translocate in response to internal and external cues. However, whether and how territories and the relocation of chromosomes are controlled by other intracellular organelles remains unknown. Upon nutrient starvation and target of rapamycin complex 1 (TORC1) inactivation, micronucleophagy, which preferentially degrades nucleolar proteins, occurs at the nucleus-vacuole junction (NVJ) in budding yeast. Ribosomal DNA (rDNA) is condensed and relocated against the NVJ, whereas nucleolar proteins move towards the NVJ for micronucleophagic degradation, causing dissociation of nucleolar proteins from rDNA. These findings imply that the NVJ is the critical platform in the directional movements of rDNA and nucleolar proteins. Here, we show that cells lacking the NVJ (NVJΔ cells) largely lost rDNA condensation and rDNA-nucleolar protein separation after TORC1 inactivation. The macronucleophagy receptor Atg39, an outer nuclear membrane protein, accumulated at the NVJ and was degraded by micronucleophagy. These suggested that macronucleophagy is also dependent on the presence of the NVJ. However, micronucleophagy, but not macronucleophagy, was abolished in NVJΔ cells. This study clearly demonstrated that vacuoles controls intranuclear events, nucleolar dynamics, from outside of the nucleus via the NVJ under the control of TORC1.

Cdc14 protein phosphatase and topoisomerase II mediate rDNA dynamics and nucleophagic degradation of nucleolar proteins after TORC1 inactivation.

Nutrient starvation and inactivation of target of rapamycin complex 1 (TORC1) protein kinase elicits nucleophagy degrading nucleolar proteins in budding yeast. After TORC1 inactivation, nucleolar proteins are relocated to sites proximal to the nucleus-vacuole junction (NVJ), where micronucleophagy occurs, whereas ribosomal DNA (rDNA encoding rRNA) escapes from the NVJ. Condensin-mediated rDNA condensation promotes the repositioning and nucleophagic degradation of nucleolar proteins. However, the molecular mechanism of TORC1 inactivation-induced chromosome condensation is still unknown. Here, we show that Cdc14 protein phosphatase and topoisomerase II (Topo II), which are engaged in rDNA condensation in mitosis, facilitate rDNA condensation after TORC1 inactivation. rDNA condensation after rapamycin treatment was compromised in cdc14-1 and top2-4 mutants. In addition, the repositioning of rDNA and nucleolar proteins and nucleophagic degradation of nucleolar proteins were impeded in these mutants. Furthermore, Cdc14 and Topo II were required for the survival of quiescent cells in prolonged nutrient-starved conditions. This study reveals that these factors are critical for starvation responses.

ESCRT machinery plays a role in microautophagy in yeast.

BACKGROUND: Microautophagy, which degrades cargos by direct lysosomal/vacuolar engulfment of cytoplasmic cargos, is promoted after nutrient starvation and the inactivation of target of rapamycin complex 1 (TORC1) protein kinase. In budding yeast, microautophagy has been commonly assessed using processing assays with green fluorescent protein (GFP)-tagged vacuolar membrane proteins, such as Vph1 and Pho8. The endosomal sorting complex required for transport (ESCRT) system is proposed to be required for microautophagy, because degradation of vacuolar membrane protein Vph1 was compromised in ESCRT-defective mutants. However, ESCRT is also critical for the vacuolar sorting of most vacuolar proteins, and hence reexamination of the involvement of ESCRT in microautophagic processes is required. RESULTS: Here, we show that the Vph1-GFP processing assay is unsuitable for estimating the involvement of ESCRT in microautophagy, because Vph1-GFP accumulated highly in the prevacuolar class E compartment in ESCRT mutants. In contrast, GFP-Pho8 and Sna4-GFP destined for vacuolar membranes via an alternative adaptor protein-3 (AP-3) pathway, were properly localized on vacuolar membranes in ESCRT-deficient cells. Nevertheless, microautophagic degradation of GFP-Pho8 and Sna4-GFP after TORC1 inactivation was hindered in ESCRT mutants, indicating that ESCRT is indeed required for microautophagy after nutrient starvation and TORC1 inactivation. CONCLUSIONS: These findings provide evidence for the direct role of ESCRT in microautophagy induction.

TORC1 regulates G1/S transition and cell proliferation via the E2F homologs MBF and SBF in yeast.

The yeast E2F functional homologs MBF (Mbp1/Swi6) and SBF (Swi4/Swi6) complexes are critical transcription factors for G1/S transition. The target of rapamycin complex 1 (TORC1) kinase promotes G1/S transition via upregulation of the G1 cyclin Cln3 that activates MBF and SBF in favorable nutrient conditions. Here, we show evidence that TORC1 directly regulates G1/S transition via MBF and SBF. Various proteins involved in G1/S transition, including Mbp1 and Swi4, but not Swi6, were largely lost after rapamycin treatment. TORC1 inactivation facilitated degradation of Mbp1 and Swi4. Mbp1 degradation was dependent on Skp1-Cullin1-F-box (SCF)-Grr1 and proteasomes. We identified a PEST-like degron in Mbp1. Mutant cells with an unstable Mbp1 protein were hypersensitive to rapamycin and more accumulated G1 cells in the absence and presence of rapamycin. This study revealed that TORC1 directly controls MBF/SBF-mediated G1/S transition in response to nutrient availability.

PP2A promotes ESCRT-0 complex formation on vacuolar membranes and microautophagy induction after TORC1 inactivation.

Deformation of vacuolar membranes mediated by endosomal sorting complex required for transport (ESCRT) is necessary for microautophagy. Target of rapamycin complex 1 (TORC1) protein kinase negatively regulates ESCRT-0 (Vps27-Hse1) recruitment onto vacuolar membranes and microautophagy induction. However, whether and how protein phosphatase regulates these events is unknown. Here, we show that the TORC1-downstream protein phosphatase PP2A-Cdc55 is important for these events after TORC1 inactivation in budding yeast. Loss of PP2A-Cdc55 compromised vacuolar localization of Hse1, but not Vps27. This study revealed that the orchestrated action of PP2A induces microautophagy upon TORC1 inactivation.

TORC1 ensures membrane trafficking of Tat2 tryptophan permease via a novel transcriptional activator Vhr2 in budding yeast.

The target of rapamycin complex 1 (TORC1) protein kinase is activated by nutrients and controls nutrient uptake via the membrane trafficking of various nutrient permeases. However, its molecular mechanisms remain elusive. Cholesterol (ergosterol in yeast) in conjunction with sphingolipids forms tight-packing microdomains, "lipid rafts", which are critical for intracellular protein sorting. Here we show that a novel target of rapamycin (TOR)-interacting transcriptional activator Vhr2 is required for full expression of some ERG genes for ergosterol biogenesis and for proper sorting of the tryptophan permease Tat2 in budding yeast. Loss of Vhr2 caused sterol biogenesis disturbance and Tat2 missorting. TORC1 activity maintained VHR2 transcript and protein levels, and total sterol levels. Vhr2 was not involved in regulation of the TORC1-downstream protein kinase Npr1, which regulates Tat2 sorting. This study suggests that TORC1 regulates nutrient uptake via sterol biogenesis.

TORC1 regulates ESCRT-0 complex formation on the vacuolar membrane and microautophagy induction in yeast.

Microautophagy is promoted after nutrient starvation and inactivation of target of rapamycin complex 1 (TORC1) kinase. Invagination of vacuolar membranes by endosomal sorting complex required for transport (ESCRT) is required for microautophagy. Vps27, a subunit of ESCRT-0, is recruited onto vacuolar membranes via dephosphorylation after TORC1 inactivation. Here, we showed that Hse1, another ESCRT-0 subunit, is also recruited onto vacuolar membranes after TORC1 inactivation, promoting formation of ESCRT-0 complex on vacuolar membranes. Hse1 recruitment was dependent on Vps27, whereas Vps27 recruitment was independent of Hse1. Not only Vps27 but also Hse1 was required for ESCRT-III recruitment onto vacuolar membranes and microautophagy induction after TORC1 inactivation. This study revealed that ESCRT-0 (Vps27-Hse1) complex formation on vacuolar membranes is important for microautophagy inactivation after TORC1 inactivation.

rDNA Condensation Promotes rDNA Separation from Nucleolar Proteins Degraded for Nucleophagy after TORC1 Inactivation.

Nutrient starvation and inactivation of target of rapamycin complex 1 (TORC1) protein kinase induce nucleophagy preferentially degrading only nucleolar components in budding yeast. Nucleolar proteins are relocated to sites proximal to the nucleus-vacuole junction (NVJ), where micronucleophagy occurs, whereas rDNA, which is embedded in the nucleolus under normal conditions, moves to NVJ-distal regions, causing rDNA dissociation from nucleolar proteins after TORC1 inactivation. This repositioning is mediated via chromosome linkage INM protein (CLIP)-cohibin complexes that tether rDNA to the inner nuclear membrane. Here, we show that TORC1 inactivation-induced rDNA condensation promotes the repositioning of rDNA and nucleolar proteins. Defects in condensin, Rpd3-Sin3 histone deacetylase (HDAC), and high-mobility group protein 1 (Hmo1), which are involved in TORC1 inactivation-induced rDNA condensation, compromised the repositioning and nucleophagic degradation of nucleolar proteins, although rDNA still escaped from nucleophagic degradation in these mutants. We propose a model in which rDNA condensation after TORC1 inactivation generates a motive force for the repositioning of rDNA and nucleolar proteins.

Def1 mediates the degradation of excess nucleolar protein Nop1 in budding yeast.

Nucleolar proteins such as Nop1/fibrillarin are degraded by nucleophagy in nutrient-starved conditions. However, whether and how excess nucleolar proteins are removed in normal conditions is unknown. Here we show that overexpressed nucleolar protein Nop1 is toxic and degraded in nutrient-rich conditions in budding yeast. The degradation was dependent on proteasomes. The CUE domain-containing protein Def1 mediated the degradation via the CUE domain and alleviated toxicity of Nop1 overexpression. Def1 was recruited to overexpressed Nop1 in the nucleolus. Ubiquitin mutants compromised this recruitment. This study revealed that Def1 is a novel factor for ubiquitin-dependent degradation of excess nucleolar proteins.

TORC1, Tel1/Mec1, and Mpk1 regulate autophagy induction after DNA damage in budding yeast.

Target of rapamycin complex 1 (TORC1) protein kinase responds to various stresses including genotoxic stress. However, its molecular mechanism is poorly understood. Here, we show that DNA damage induces nonselective and selective autophagy in budding yeast. DNA damage caused the attenuation of TORC1 activity, dephosphorylation of Atg13, and autophagy induction. The TORC1-upstream Rag GTPase Gtr1 was not required for TORC1 inactivation and autophagy induction after DNA damage. Furthermore, DNA damage responsive protein kinases Mec1/ATM and Tel1/ATR, and stress-responsive mitogen-activated protein kinase Mpk1/Slt2 were required for the full induction of autophagy. Autophagic proteolysis was required for DNA damage tolerance in TORC1 inactive conditions. This study revealed that multiple protein kinases regulate DNA damage-induced autophagy.

TORC1 regulates autophagy induction in response to proteotoxic stress in yeast and human cells.

Misfolded and aggregated proteins are eliminated to maintain protein homeostasis. Autophagy contributes to the removal of protein aggregates. However, if and how proteotoxic stress induces autophagy is poorly understood. Here we show that proteotoxic stress after treatment with azetidine-2-carboxylic acid (AZC), a toxic proline analog, induces autophagy in budding yeast. AZC treatment attenuated target of rapamycin complex 1 (TORC1) activity, resulting in the dephosphorylation of Atg13, a key factor of autophagy. By contrast, AZC treatment did not affect target of rapamycin complex 2 (TORC2). Proteotoxic stress also induced TORC1 inactivation and autophagy in fission yeast and human cells. This study suggested that TORC1 is a conserved key factor to cope with proteotoxic stress in eukaryotic cells.

TORC1 regulates the DNA damage checkpoint via checkpoint protein levels.

Target of rapamycin complex 1 (TORC1) protein kinase, a master controller of cell growth, is thought to be involved in genome integrity. However, the molecular mechanisms associated with this are unclear. Here, we show that TORC1 inactivation causes decreases in the levels of a wide range of proteins involved in the DNA damage checkpoint (DDC) signaling including Tel1, Mre11, Rad9, Mrc1, and Chk1 in budding yeast. Furthermore, TORC1 inactivation compromised DDC activation, DNA repair, and cell survival after DNA damage. TORC1 inactivation promoted proteasomal degradation of Rad9 and Mre11 in a manner dependent on Skp1-Cullin-F-box protein (SCF). Finally, CDK promoted the degradation of Rad9. This study revealed that TORC1 is essential for genome integrity via the maintenance of DDC signaling.

Cdh1 degradation is mediated by APC/C-Cdh1 and SCF-Cdc4 in budding yeast.

Cdh1, a substrate-recognition subunit of anaphase-promoting complex/cyclosome (APC/C), is a tumor suppressor, and it is downregulated in various tumor cells in humans. APC/C-Cdh1 is activated from late M phase to G1 phase by antagonizing Cdk1-mediated inhibitory phosphorylation. However, how Cdh1 protein levels are properly regulated is ill-defined. Here we show that Cdh1 is degraded via APC/C-Cdh1 and Skp1-Cullin1-F-box (SCF)-Cdc4 in the budding yeast Saccharomyces cerevisiae. Cdh1 degradation was promoted by forced localization of Cdh1 into the nucleus, where APC/C and SCF are present. Cdk1 promoted APC/C-Cdh1-mediated Cdh1 degradation, whereas polo kinase Cdc5 elicited SCF-Cdc4-mediated degradation. Thus, Cdh1 degradation is controlled via multiple pathways.

CDK phosphorylation regulates Mcm3 degradation in budding yeast.

Accurate regulation of activity and level of the MCM complex is critical for precise DNA replication and genome transmission. Cyclin-dependent kinase (CDK) negatively regulates nuclear localization of the MCM complex via phosphorylation of the Mcm3 subunit. More recently, we found that Mcm3 is degraded via the Skp1-Cullin-F-box (SCF)-proteasome axis in budding yeast. However, how Mcm3 degradation is regulated is largely unknown. Here, we show that CDK represses Mcm3 degradation. Phosphorylated Mcm3 was excluded from the nucleus, where SCF is predominantly located, although CDK-mediated phosphorylation itself generated a phosphodegron of Mcm3, stimulating the degradation of Mcm3 resident in the nucleus. Thus, CDK negatively regulated nuclear MCM levels by exclusion from the nucleus and degradation in the nucleus via Mcm3 phosphorylation. We will discuss the physiological importance of Mcm3 degradation.