Project description:To evaluate the role of enhanced lysosomes in qNSCs, lysosomal function was inhibited with BafA, a specific inhibitor of the vacuolar-type H(+)-ATPase (V-ATPase).

Project description:Lysosomes are central platforms for not only the degradation of macromolecules but also the integration of multiple signaling pathways. However, whether and how lysosomes mediate the mitochondrial stress response (MSR) remain largely unknown. Here, we demonstrate that lysosomal acidification via the vacuolar H+-ATPase (v-ATPase) is essential for the transcriptional activation of the mitochondrial unfolded protein response (UPRmt). Mitochondrial stress stimulates v-ATPase-mediated lysosomal activation of the mechanistic target of rapamycin complex 1 (mTORC1), which then directly phosphorylates the MSR transcription factor, activating transcription factor 4 (ATF4). Disruption of mTORC1-dependent ATF4 phosphorylation blocks the UPRmt, but not other similar stress responses, such as the UPRER. Finally, ATF4 phosphorylation downstream of the v-ATPase/mTORC1 signaling is indispensable for sustaining mitochondrial redox homeostasis and protecting cells from reactive oxygen species (ROS)-associated cell death upon mitochondrial stress. Thus, v-ATPase/mTORC1-mediated ATF4 phosphorylation via lysosomes links mitochondrial stress to UPRmt activation and mitochondrial function resilience.

Project description:Lysosomes are cytoplasmic organelles central for the degradation of macromolecules to maintain cellular homeostasis and health. However, how lysosomal activity can be boosted to counteract aging and aging-related diseases remains elusive. Here, we reveal that silencing specific vacuolar H+-ATPase subunits (e.g. vha-6), that are essential for intestinal lumen acidification in Caenorhabditis elegans, extends lifespan by ~60%. This longevity phenotype can be explained by an adaptive transcriptional response typified by induction of a set of transcripts involved in lysosomal function and proteolysis, which we termed the lysosomal surveillance response (LySR). LySR activation is characterized by boosted lysosomal activity, enhanced clearance of protein aggregates in worm models of Alzheimer's disease, Huntington’s disease and amyotrophic lateral sclerosis, thereby improving fitness. The GATA transcription factor ELT-2 governs the LySR program and its associated beneficial effects. Activating the LySR pathway may therefore represent an attractive mechanism to reduce proteotoxicity and, as such, potentially extend healthspan.

Project description:Lysosomes are cytoplasmic organelles central for the degradation of macromolecules to maintain cellular homeostasis and health. However, how lysosomal activity can be boosted to counteract aging and aging-related diseases remains elusive. Here, we reveal that silencing specific vacuolar H+-ATPase subunits (e.g. vha-6), that are essential for intestinal lumen acidification in Caenorhabditis elegans, extends lifespan by ~60%. This longevity phenotype can be explained by an adaptive transcriptional response typified by induction of a set of transcripts involved in lysosomal function and proteolysis, which we termed the lysosomal surveillance response (LySR). LySR activation is characterized by boosted lysosomal activity, enhanced clearance of protein aggregates in worm models of Alzheimer's disease, Huntington’s disease and amyotrophic lateral sclerosis, thereby improving fitness. The GATA transcription factor ELT-2 governs the LySR program and its associated beneficial effects. Activating the LySR pathway may therefore represent an attractive mechanism to reduce proteotoxicity and, as such, potentially extend healthspan.

Project description:Lysosomes are cytoplasmic organelles central for the degradation of macromolecules to maintain cellular homeostasis and health. However, how lysosomal activity can be boosted to counteract aging and aging-related diseases remains elusive. Here, we reveal that silencing specific vacuolar H+-ATPase subunits (e.g. vha-6), that are essential for intestinal lumen acidification in Caenorhabditis elegans, extends lifespan by ~60%. This longevity phenotype can be explained by an adaptive transcriptional response typified by induction of a set of transcripts involved in lysosomal function and proteolysis, which we termed the lysosomal surveillance response (LySR). LySR activation is characterized by boosted lysosomal activity, enhanced clearance of protein aggregates in worm models of Alzheimer's disease, Huntington’s disease and amyotrophic lateral sclerosis, thereby improving fitness. The GATA transcription factor ELT-2 governs the LySR program and its associated beneficial effects. Activating the LySR pathway may therefore represent an attractive mechanism to reduce proteotoxicity and, as such, potentially extend healthspan.

Project description:The aging of hematopoietic stem cells (HSCs) significantly alters their characteristics. Mitochondria, essential for cellular metabolism, play a crucial role, and their dysfunction is a hallmark of aging-induced changes. The impact of mitochondrial mass on aged HSCs remains incompletely understood. Here, we demonstrate that HSCs with high mitochondrial mass during aging are not merely cells that have accumulated damaged mitochondria and become exhausted. Instead, these HSCs retain a high regenerative capacity and remain in the aging bone marrow. Furthermore, we identified GPR183 as a novel marker characterizing aged HSCs through single-cell analysis. HSCs marked by GPR183 were also enriched in aged HSCs with high mitochondrial mass, possessing a high capacity of self-renewal. These insights deepen our understanding of HSC aging and provide new perspectives on the assessment of aged HSCs, underscoring the importance of mitochondrial dynamics in the aging.

Project description:The aging of hematopoietic stem cells (HSCs) significantly alters their characteristics. Mitochondria, essential for cellular metabolism, play a crucial role, and their dysfunction is a hallmark of aging-induced changes. The impact of mitochondrial mass on aged HSCs remains incompletely understood. Here, we demonstrate that HSCs with high mitochondrial mass during aging are not merely cells that have accumulated damaged mitochondria and become exhausted. Instead, these HSCs retain a high regenerative capacity and remain in the aging bone marrow. Furthermore, we identified GPR183 as a novel marker characterizing aged HSCs through single-cell analysis. HSCs marked by GPR183 were also enriched in aged HSCs with high mitochondrial mass, possessing a high capacity of self-renewal. These insights deepen our understanding of HSC aging and provide new perspectives on the assessment of aged HSCs, underscoring the importance of mitochondrial dynamics in the aging.

Project description:NKG7 is a lysosomal membrane protein whose expression is restricted to cytotoxic lymphocytes. Although the importance of NKG7 in anti-tumor immunity has been shown, little is known about the molecular function and regulation of NKG7. To elucidate NKG7 molecular function, we performed NKG7-proximity labeling using TurboID system in 293T cells, followed by mass-spectrometry. We identified vacuolar H+ ATPase (v-ATPase; lysosomal proton pump) subunit ATP6AP2 as a potential NKG7-interacting protein, and validated the interaction via exogenous coimmunoprecipitation. We further showed that NKG7 inhibits v-ATPase activity, thereby impacting lysosomal homeostasis and mTORC1 regulation at lysosomes.

Project description:Lysosomal membrane permeabilization (LMP) or lysosomal membrane damage is commonly associated with aging and age-related diseases. In searching for cellular mechanisms in response to LMP, we used a proteomic approach to identify proteins enriched on damaged lysosomes. This unbiased approach identified a new phosphoinositide signaling pathway triggered by LMP to mediate rapid lysosomal repair. Specifically, LMP induces fast lysosomal recruitment of PI4K2A which generates high levels of the lipid messenger phosphatidylinositol-4-phosphate (PtdIns4P) on damaged lysosomes. Lysosomal PtdIns4P in turn recruits multiple oxysterol-binding protein (OSBP)-related protein (ORP) family members, including ORP9, ORP10, and ORP11, to orchestrate extensive membrane contact sites (MCSs) between damaged lysosomes and the endoplasmic reticulum (ER). The ORPs subsequently catalyze robust ER-to-lysosomal transport of phosphatidylserine (PS), which is critical for rapid lysosomal repair. The lipid transporter ATG2 is also recruited to damaged lysosomes, activated by PS, and is essential for rapid lysosomal repair. Our findings identify a phosphoinositide-dependent membrane tethering and lipid transport (PITT) pathway essential for the maintenance of lysosomal membrane integrity, with important implications for a wide range of diseases characterized by impaired lysosomal function.

Project description:Quiescence is a fundamental property that maintains hematopoietic stem cells (HSCs)’ potency throughout life. Quiescent HSCs are thought to rely on glycolysis for their energy but the overall metabolic properties of HSCs remain incompletely understood. Using combined approaches including single cell RNA-Seq we show that mitochondrial membrane potential (MMP) distinguishes the quiescent from cycling-primed HSCs. We found that primed but not quiescent HSCs relied readily on glycolysis. Notably, in vivo inhibition of glycolysis robustly enhanced the competitive repopulation ability of primed HSCs. We further show that HSC quiescence is maintained by an abundance of large lysosomes. Repression of lysosomal activation led to further enlargement of lysosomes, while repressing mTOR activation and glucose uptake. This also induced increased lysosomal sequestration of mitochondria and enhanced the competitive repopulation ability of primed HSCs by over 90-fold in vivo. These findings show that restraining lysosomal activity is key in preserving HSC quiescence and potency, and may be therapeutically relevant.