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:The general consensus is that the vacuolar-type H+-translocating ATPase (V-ATPase) is critical for macroautophagy/autophagy. However, there is a fundamental conundrum because follicular lymphoma-associated mutations in the V-ATPase result in lysosomal/vacuolar deacidification but elevated autophagy activity under nutrient-replete conditions and the underlying mechanisms remain mysterious. Here, working in yeast, we show that V-ATPase dysfunction activates a selective autophagy flux termed the "V-ATPase-autophagy axis". By combining transcriptomic and proteomic profiling, along with genome-wide suppressor screening approaches, we found that the V-ATPase-autophagy axis is regulated through a unique mechanism distinct from classical nitrogen starvation-induced autophagy. Tryptophan metabolism negatively regulates the V-ATPase-autophagy axis via two parallel effectors. On the one hand, it activates ribosome biogenesis, thus repressing the translation of the transcription factor Gcn4/ATF4. On the other hand, tryptophan fuels NAD+ de novo biosynthesis to inhibit autophagy. These results provide a clear explanation for the mutational activation of autophagy seen in follicular lymphoma patients.

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:Valosin‐containing protein (VCP)/p97/Cdc48 is an essential AAA+ ATPase associated with many ubiquitin-dependent cellular pathways that plays a central role in protein quality control in all eukaryotes. Its functional diversity relies on its ability to cooperate with a large number of protein cofactors that provide pathway selectivity and fine-tune substrate processing. Here, we identified the main partners of the recently characterized Leishmania infantum VCP homolog (LiVCP) and we provide the first insights into the biology of the LiVCP network in Trypanosomatidae. Among the LiVCP core partners detected by immunoprecipitation (IP) and LC-MS/MS mass spectra acquisition, we determined p47, FAF1, UFD1 and PUB1 as the major cofactors of the Leishmania VCP. Furthermore, we provide in silico analyses demonstrating the conserved regions of these cofactors that potentially interact with LiVCP. We employed ‘‘network proteomics’’ using IP and LC-MS/MS studies for each cofactor to confirm their close partnership with LiVCP and to identify the cofactor-specific interacting partners as well as the partners that are shared among multiple cofactors and LiVCP complexes, such as the important heterotrimer VCP-NPL4-UFD1 complex in Leishmania. Our results suggest a glycosome/peroxisome association of LiFAF1. Gene Ontology analysis of each proteome coupled with digitonin fractionation and immunofluorescence studies indicated nuclear association for Lip47, cytoplasmic and vacuolar association for LiUFD1, glycosome association for LiFAF1, and endoplasmic reticulum interaction for LiPUB1 protein. All together, these data provide the first VCP protein network in Trypanosomatidae. Further functional and structural analysis of the essential LiVCP quality control protein network may lead to the development of new anti-parasitic drugs.

Project description:To adapt mitochondrial function to the ever-changing intra- and extra-cellular environment, multiple mitochondrial stress response (MSR) pathways, including the mitochondrial unfolded protein response (UPRmt), have evolved. However, how the mitochondrial stress signal is sensed and relayed to UPRmt transcription factors, such as ATFS-1 in Caenorhabditis elegans, remains largely unknown. Here, we show that a panel of vacuolar H+-ATPase (v-ATPase) subunits and the target of rapamycin complex 1 (TORC1) activity are essential for the cytosolic relay of mitochondrial stress to ATFS-1, and for the induction of the UPRmt. Mechanistically, mitochondrial stress stimulates v-ATPase/Rheb-dependent TORC1 activation, subsequently promoting ATFS-1 translation. Increased translation of ATFS-1 upon mitochondrial stress furthermore relies on a set of ribosomal components, but is independent of GCN-2/PEK-1 signaling. Finally, the v-ATPase and ribosomal subunits are required for mitochondrial surveillance and mitochondrial stress-induced longevity. These results reveal a v-ATPase-TORC1-ATFS-1 signaling pathway that links mitochondrial stress to the UPRmt through intimate crosstalks between multiple organelles.

Project description:TFEB-vacuolar ATPase signaling regulates lysosomal activity and immune response in tauopathy

Project description:Kinesins are motor proteins found in all eukaryotic lineages that move along microtubules to mediate Kinesins are motor proteins found in all eukaryotic lineages that move along microtubules to mediate cellular processes such as mitosis and intracellular transport. In trypanosomatids, the kinesin superfamily has undergone a prominent expansion, resulting in one of the most diverse kinesin repertoires that includes the two kinetoplastid-restricted families X1 and X2. Here, we characterize in Trypanosoma brucei TbKifX2A, an orphaned X2 kinesin. TbKifX2A tightly interacts with TbPH1, a kinesin-like protein with a likely inactive motor domain, a rarely reported occurrence. Both TbKifX2A and TbPH1 localize to the microtubule quartet (MtQ), a characteristic but poorly understood cytoskeletal structure that wraps around the flagellar pocket as it extends to the cell body anterior. The proximal proteome of TbPH1 revealed two other interacting proteins, the flagellar pocket protein FP45 and intriguingly another X2 kinesin, TbKifX2C. Simultaneous ablation of TbKifX2A/TbPH1 results in the depletion of FP45 and TbKifX2C and also an expansion of the flagellar pocket, among other morphological defects. TbKifX2A is the first motor protein to be localized to the MtQ. The observation that TbKifX2C also associates with the MtQ suggests that the X2 kinesin family may have co-evolved with the MtQ, both kinetoplastid-specific traits.cellular processes such as mitosis and intracellular transport. In trypanosomatids, the kinesin superfamily has undergone a prominent expansion, resulting in one of the most diverse kinesin repertoires that includes the two kinetoplastid-restricted families X1 and X2. Here, we characterize in Trypanosoma brucei TbKifX2A, an orphaned X2 kinesin. TbKifX2A tightly interacts with TbPH1, a kinesin-like protein with a likely inactive motor domain, a rarely reported occurrence. Both TbKifX2A and TbPH1 localize to the microtubule quartet (MtQ), a characteristic but poorly understood cytoskeletal structure that wraps around the flagellar pocket as it extends to the cell body anterior. The proximal proteome of TbPH1 revealed two other interacting proteins, the flagellar pocket protein FP45 and intriguingly another X2 kinesin, TbKifX2C. Simultaneous ablation of TbKifX2A/TbPH1 results in the depletion of FP45 and TbKifX2C and also an expansion of the flagellar pocket, among other morphological defects. TbKifX2A is the first motor protein to be localized to the MtQ. The observation that TbKifX2C also associates with the MtQ suggests that the X2 kinesin family may have co-evolved with the MtQ, both kinetoplastid-specific traits.

Project description:Yeast vacuoles, equivalent to lysosomes in other eukaryotes, are important acidic degradative organelles as well as storage compartments and signaling hubs. To perform these functions, they rely on important protein complexes, including the V-ATPase, responsible for organelle acidification. In this study, we used cross-linking mass spectrometry to characterize the protein complexes of isolated vacuoles. We were able to detect many known protein-protein interactions, including known protein complexes, as well as undescribed ones. Among these, we identified the uncharacterized TLDc domain-containing protein Rtc5 as a novel interactor of the V-ATPase. We show that Rtc5 localizes to the vacuole membrane depending on N-myristoylation and on its interactions with the V-ATPase. We further analyzed the influence of this protein, and the second yeast TLDc domain-containing protein, Oxr1, on V-ATPase function. We find that both Rtc5 and Oxr1 promote the disassembly of the vacuolar V-ATPase in vivo, counteracting the role of the assembly chaperone, the RAVE complex. Finally, Oxr1 is necessary for the retention in the late Golgi complex of an organelle-specific subunit of the V-ATPase. Collectively, our results shed light on the in vivo roles of yeast TLDc domain-containing proteins in relation to the V-ATPase, highlighting the multifaceted regulation of this crucial protein complex.

Project description:In spite of their universal function, the composition of kinetochores differs greatly across eukaryotes. Trypanosomes and other organisms Kinetoplastida diverged very early during eukaryotic radiation from the line that includes animals and fungi, and build kinetochores with very little detectable homology to models. However, the full extent of the trypanosome kinetochore is unclear. Here, we have used quantitative proteomics from multiple start points to define the interaction network of the kinetoplastid kinetochore-interacting proteins (KKIPs). These data identify new components of the kinetochore and define a stable 9-protein complex distal to KKIP1 that forms the majority of the kinetoplastid outer kinetochore.

Project description:Amino acid homeostasis is critical for many cellular processes. It is well established that amino acids are compartmentalized using pH gradients generated between organelles and the cytoplasm; however, the dynamics of this partitioning has not been explored. We have developed a highly sensitive pH reporter, and we find that the major amino acid storage compartment in Saccharomyces cerevisiae, the lysosome-like vacuole, alkalinizes prior to cell division and re-acidifies as cells divide. The vacuolar pH dynamics require the uptake of extracellular amino acids and activity of TORC1, the v-ATPase and the cycling of the vacuolar specific lipid, PI3,5P2 which is regulated by the cyclin-dependent kinase, CDK5/Pho85. Vacuolar pH regulation enables amino acid sequestration and mobilization from the organelle, which is important for mitochondrial function, ribosome homeostasis and cell size control. Collectively, our data provide a new paradigm for the use of dynamic pH-dependent amino acid compartmentalization during cell growth/division.