Your search keyword '"Patricia M. Kane"' showing total 101 results

1. The cytosolic N-terminal domain of V-ATPase a-subunits is a regulatory hub targeted by multiple signals

Author

Farzana Tuli and Patricia M. Kane

Subjects

organelle, acidification, V-ATPase, regulation, a-subunit, isoform, Biology (General), QH301-705.5

Abstract

Vacuolar H+-ATPases (V-ATPases) acidify several organelles in all eukaryotic cells and export protons across the plasma membrane in a subset of cell types. V-ATPases are multisubunit enzymes consisting of a peripheral subcomplex, V1, that is exposed to the cytosol and an integral membrane subcomplex, Vo, that contains the proton pore. The Vo a-subunit is the largest membrane subunit and consists of two domains. The N-terminal domain of the a-subunit (aNT) interacts with several V1 and Vo subunits and serves to bridge the V1 and Vo subcomplexes, while the C-terminal domain contains eight transmembrane helices, two of which are directly involved in proton transport. Although there can be multiple isoforms of several V-ATPase subunits, the a-subunit is encoded by the largest number of isoforms in most organisms. For example, the human genome encodes four a-subunit isoforms that exhibit a tissue- and organelle-specific distribution. In the yeast S. cerevisiae, the two a-subunit isoforms, Golgi-enriched Stv1 and vacuolar Vph1, are the only V-ATPase subunit isoforms. Current structural information indicates that a-subunit isoforms adopt a similar backbone structure but sequence variations allow for specific interactions during trafficking and in response to cellular signals. V-ATPases are subject to several types of environmental regulation that serve to tune their activity to their cellular location and environmental demands. The position of the aNT domain in the complex makes it an ideal target for modulating V1-Vo interactions and regulating enzyme activity. The yeast a-subunit isoforms have served as a paradigm for dissecting interactions of regulatory inputs with subunit isoforms. Importantly, structures of yeast V-ATPases containing each a-subunit isoform are available. Chimeric a-subunits combining elements of Stv1NT and Vph1NT have provided insights into how regulatory inputs can be integrated to allow V-ATPases to support cell growth under different stress conditions. Although the function and distribution of the four mammalian a-subunit isoforms present additional complexity, it is clear that the aNT domains of these isoforms are also subject to multiple regulatory interactions. Regulatory mechanisms that target mammalian a-subunit isoforms, and specifically the aNT domains, will be described. Altered V-ATPase function is associated with multiple diseases in humans. The possibility of regulating V-ATPase subpopulations via their isoform-specific regulatory interactions are discussed.

Published

2023

2. Adaptive laboratory evolution in S. cerevisiae highlights role of transcription factors in fungal xenobiotic resistance

Author

Sabine Ottilie, Madeline R. Luth, Erich Hellemann, Gregory M. Goldgof, Eddy Vigil, Prianka Kumar, Andrea L. Cheung, Miranda Song, Karla P. Godinez-Macias, Krypton Carolino, Jennifer Yang, Gisel Lopez, Matthew Abraham, Maureen Tarsio, Emmanuelle LeBlanc, Luke Whitesell, Jake Schenken, Felicia Gunawan, Reysha Patel, Joshua Smith, Melissa S. Love, Roy M. Williams, Case W. McNamara, William H. Gerwick, Trey Ideker, Yo Suzuki, Dyann F. Wirth, Amanda K. Lukens, Patricia M. Kane, Leah E. Cowen, Jacob D. Durrant, and Elizabeth A. Winzeler

Subjects

Biology (General), QH301-705.5

Abstract

Ottilie et al. employ an experimental evolution approach to investigate the role of transcription factors in yeast chemical resistance. Most emergent mutations in resistant strains were enriched in transcription factor coding genes, highlighting their importance in drug resistance.

Published

2022

3. Editorial: Intracellular Molecular Processes Affected by pH

Author

Jan M. Antosiewicz and Patricia M. Kane

Subjects

protons and pH inside cells, modelling molecular pH sensing, maintaince of cellular pH, pH dependent intracellular protein localization, mechanisms of pH dependence of viral infection, Biology (General), QH301-705.5

Published

2022

4. RAVE and Rabconnectin-3 Complexes as Signal Dependent Regulators of Organelle Acidification

Author

Michael C. Jaskolka, Samuel R. Winkley, and Patricia M. Kane

Subjects

organelle acidification, Rabconnectin-3, vacuole, endosome and lysosome, V-ATPase, RAVE = regulator of H+-ATPase of vacuoles and endosomes, Biology (General), QH301-705.5

Abstract

The yeast RAVE (Regulator of H+-ATPase of Vacuolar and Endosomal membranes) complex and Rabconnectin-3 complexes of higher eukaryotes regulate acidification of organelles such as lysosomes and endosomes by catalyzing V-ATPase assembly. V-ATPases are highly conserved proton pumps consisting of a peripheral V1 subcomplex that contains the sites of ATP hydrolysis, attached to an integral membrane Vo subcomplex that forms the transmembrane proton pore. Reversible disassembly of the V-ATPase is a conserved regulatory mechanism that occurs in response to multiple signals, serving to tune ATPase activity and compartment acidification to changing extracellular conditions. Signals such as glucose deprivation can induce release of V1 from Vo, which inhibits both ATPase activity and proton transport. Reassembly of V1 with Vo restores ATP-driven proton transport, but requires assistance of the RAVE or Rabconnectin-3 complexes. Glucose deprivation triggers V-ATPase disassembly in yeast and is accompanied by binding of RAVE to V1 subcomplexes. Upon glucose readdition, RAVE catalyzes both recruitment of V1 to the vacuolar membrane and its reassembly with Vo. The RAVE complex can be recruited to the vacuolar membrane by glucose in the absence of V1 subunits, indicating that the interaction between RAVE and the Vo membrane domain is glucose-sensitive. Yeast RAVE complexes also distinguish between organelle-specific isoforms of the Vo a-subunit and thus regulate distinct V-ATPase subpopulations. Rabconnectin-3 complexes in higher eukaryotes appear to be functionally equivalent to yeast RAVE. Originally isolated as a two-subunit complex from rat brain, the Rabconnectin-3 complex has regions of homology with yeast RAVE and was shown to interact with V-ATPase subunits and promote endosomal acidification. Current understanding of the structure and function of RAVE and Rabconnectin-3 complexes, their interactions with the V-ATPase, their role in signal-dependent modulation of organelle acidification, and their impact on downstream pathways will be discussed.

Published

2021

5. Regulation of V-ATPase Activity and Organelle pH by Phosphatidylinositol Phosphate Lipids

Author

Subhrajit Banerjee and Patricia M. Kane

Subjects

phosphatidylinositol phosphate, acidification, organelle, V-ATPase, PIKfyve, lysosome, Biology (General), QH301-705.5

Abstract

Luminal pH and the distinctive distribution of phosphatidylinositol phosphate (PIP) lipids are central identifying features of organelles in all eukaryotic cells that are also critical for organelle function. V-ATPases are conserved proton pumps that populate and acidify multiple organelles of the secretory and the endocytic pathway. Complete loss of V-ATPase activity causes embryonic lethality in higher animals and conditional lethality in yeast, while partial loss of V-ATPase function is associated with multiple disease states. On the other hand, many cancer cells increase their virulence by upregulating V-ATPase expression and activity. The pH of individual organelles is tightly controlled and essential for function, but the mechanisms for compartment-specific pH regulation are not completely understood. There is substantial evidence indicating that the PIP content of membranes influences organelle pH. We present recent evidence that PIPs interact directly with subunit isoforms of the V-ATPase to dictate localization of V-ATPase subpopulations and participate in their regulation. In yeast cells, which have only one set of organelle-specific V-ATPase subunit isoforms, the Golgi-enriched lipid PI(4)P binds to the cytosolic domain of the Golgi-enriched a-subunit isoform Stv1, and loss of PI(4)P binding results in mislocalization of Stv1-containing V-ATPases from the Golgi to the vacuole/lysosome. In contrast, levels of the vacuole/lysosome-enriched signaling lipid PI(3,5)P2 affect assembly and activity of V-ATPases containing the Vph1 a-subunit isoform. Mutations in the Vph1 isoform that disrupt the lipid interaction increase sensitivity to stress. These studies have decoded “zip codes” for PIP lipids in the cytosolic N-terminal domain of the a-subunit isoforms of the yeast V-ATPase, and similar interactions between PIP lipids and the V-ATPase subunit isoforms are emerging in higher eukaryotes. In addition to direct effects on the V-ATPase, PIP lipids are also likely to affect organelle pH indirectly, through interactions with other membrane transporters. We discuss direct and indirect effects of PIP lipids on organelle pH, and the functional consequences of the interplay between PIP lipid content and organelle pH.

Published

2020

6. Human V-ATPase a-subunit isoforms bind specifically to distinct phosphoinositide phospholipids

Author

Connie Mitra and Patricia M. Kane

Abstract

V-ATPases are highly conserved multi-subunit enzymes that maintain the distinct pH of eukaryotic organelles. The integral membrane a-subunit is encoded by tissue and organelle specific isoforms, and its cytosolic N-terminal domain (aNT) modulates organelle specific regulation and targeting of V-ATPases. Organelle membranes have specific phosphatidylinositol phosphate (PIP) lipid enrichment linked to maintenance of organelle pH. In yeast, the aNT domains of the two a-subunit isoforms bind PIP lipids enriched in the organelle membranes where they reside; these interactions affect activity and regulatory properties of the V-ATPases containing each isoform. Humans have four a-subunit isoforms. We hypothesize that the aNT domains of the human isoforms will also bind to specific PIP lipids. The a1 and a2 isoforms of human V-ATPase a-subunits are localized to endolysosomes and Golgi, respectively. Bacterially expressed Hua1NT and Hua2NT bind specifically to endolysosomal PIP lipids PI(3)P and PI(3,5)P2 and Golgi enriched PI(4)P, respectively. Despite the lack of canonical PIP binding sites, potential binding sites in the HuaNT domains were identified by sequence comparisons and existing subunit structures and models. Mutations at a similar location in the distal loops of both HuaNT isoforms compromise binding to their cognate PIP lipids, suggesting that these loops encode PIP specificity of the a-subunit isoforms. These data also suggest a mechanism through which PIP lipid binding could stabilize and activate V-ATPases in distinct organelles.

Published

2023

7. Chimeric a-subunit isoforms generate functional yeast V-ATPases with altered regulatory properties in vitro and in vivo

Author

Farzana Tuli and Patricia M. Kane

Subjects

Cell Biology, Molecular Biology

Abstract

V-ATPases are highly regulated proton pumps that are localized and regulated by a-subunit isoforms. Chimeric a-subunits containing parts of different isoforms were designed, their interactions with regulators analyzed, and their function under different stresses determined. One chimeric V-ATPase is as active as the wild-type enzyme but shows distinct regulatory properties in responses to stress.

Published

2023

8. Interactions between the aNT Domains of Human V‐ATPases and Phosphatidylinositol Phosphate Lipids

Author

Connie Mitra and Patricia M. Kane

Subjects

Genetics, Molecular Biology, Biochemistry, Biotechnology

Published

2022

9. Chimeric V‐ATPases with Different Regulatory Properties

Author

Farzana Tuli, Maureen Tarsio, and Patricia M. Kane

Subjects

Genetics, Molecular Biology, Biochemistry, Biotechnology

Published

2022

10. Chimeric a-subunit isoforms generate functional yeast V-ATPases with altered regulatory properties in vitro and in vivo

Author

Farzana Tuli and Patricia M. Kane

Abstract

V-ATPases are highly regulated, multi-subunit proton pumps that acidify organelles. The V-ATPase a-subunit is a two-domain protein containing a C-terminal transmembrane domain that participates in proton transport and a N-terminal cytosolic domain (aNT) that acts as a regulatory hub, integrating environmental inputs to regulate assembly, localization, and V-ATPase activity. Tissue- and organelle-specific a-subunit isoforms exist in most organisms, but how regulatory inputs are decoded by aNT isoforms is unknown. The yeast S. cerevisiae encodes only two organelle-specific a-isoforms, Stv1 in the Golgi and Vph1 in the vacuole. Based on recent structures, we designed chimeric yeast aNTs in which the globular proximal and distal ends are exchanged. The Vph1 proximal-Stv1 distal (VPSD) aNT chimera binds to the glucose-responsive RAVE assembly factor in vitro but exhibits little binding to phosphoinositide lipids that activate V-ATPases. The Stv1 proximal-Vph1 distal (SPVD) aNT lacks RAVE binding but binds more tightly to phosphoinositides than Vph1 or Stv1. When attached to the Vph1 C-terminal domain in vivo, both chimeras complement growth defects of a vph1Δ mutant, but only the SPVD chimera exhibits wild-type V-ATPase activity. Cells containing the SPVD chimera adapt more slowly to a poor carbon source than wild-type cells but grow more rapidly than wild-type after a shift to alkaline pH. This is the first example of a “redesigned” V-ATPase with altered regulatory properties and adaptation to specific stresses.

Published

2022

11. Whole exome sequencing identified ATP6V1C2 as a novel candidate gene for recessive distal renal tubular acidosis

Author

Tilman Jobst-Schwan, Marcella Greco, Patricia M. Kane, Michelle A. Baum, Verena Klämbt, Shrikant Mane, Seema Hashmi, Seth L. Alper, Jutta Gellermann, Richard P. Lifton, Amar J. Majmundar, Florian Buerger, John F. Heneghan, Friedhelm Hildebrandt, Guido F. Laube, Shirlee Shril, Francesco Emma, Farkhanda Hafeez, Hanan M. Fathy, Rezan Topaloglu, Isabel Ottlewski, Martin Pohl, Danko Milosevic, Boris E. Shmukler, and Maureen Tarsio

Subjects

0301 basic medicine, Vacuolar Proton-Translocating ATPases, Candidate gene, Pathology, medicine.medical_specialty, DNA Mutational Analysis, 030232 urology & nephrology, medicine.disease_cause, Renal tubular acidosis, 03 medical and health sciences, 0302 clinical medicine, Renal tubular dysfunction, Distal renal tubular acidosis, Anion Exchange Protein 1, Erythrocyte, Exome Sequencing, medicine, Humans, Chloride-Bicarbonate Antiporters, Child, Exome sequencing, Kidney, Mutation, business.industry, Forkhead Transcription Factors, Acidosis, Renal Tubular, medicine.disease, 030104 developmental biology, medicine.anatomical_structure, FOXI1, Nephrology, business

Abstract

Distal renal tubular acidosis is a rare renal tubular disorder characterized by hyperchloremic metabolic acidosis and impaired urinary acidification. Mutations in three genes (ATP6V0A4, ATP6V1B1 and SLC4A1) constitute a monogenic causation in 58-70% of familial cases of distal renal tubular acidosis. Recently, mutations in FOXI1 have been identified as an additional cause. Therefore, we hypothesized that further monogenic causes of distal renal tubular acidosis remain to be discovered. Panel sequencing and/or whole exome sequencing was performed in a cohort of 17 families with 19 affected individuals with pediatric onset distal renal tubular acidosis. A causative mutation was detected in one of the three "classical" known distal renal tubular acidosis genes in 10 of 17 families. The seven unsolved families were then subjected to candidate whole exome sequencing analysis. Potential disease causing mutations in three genes were detected: ATP6V1C2, which encodes another kidney specific subunit of the V-type proton ATPase (1 family); WDR72 (2 families), previously implicated in V-ATPase trafficking in cells; and SLC4A2 (1 family), a paralog of the known distal renal tubular acidosis gene SLC4A1. Two of these mutations were assessed for deleteriousness through functional studies. Yeast growth assays for ATP6V1C2 revealed loss-of-function for the patient mutation, strongly supporting ATP6V1C2 as a novel distal renal tubular acidosis gene. Thus, we provided a molecular diagnosis in a known distal renal tubular acidosis gene in 10 of 17 families (59%) with this disease, identified mutations in ATP6V1C2 as a novel human candidate gene, and provided further evidence for phenotypic expansion in WDR72 mutations from amelogenesis imperfecta to distal renal tubular acidosis.

Published

2020

12. Interaction between the yeast RAVE complex and Vph1-containing Vo sectors is a central glucose-sensitive interaction required for V-ATPase reassembly

Author

Patricia M. Kane and Michael C. Jaskolka

Subjects

0301 basic medicine, 030102 biochemistry & molecular biology, biology, Chemistry, Endosome, Protein subunit, Saccharomyces cerevisiae, Cell Biology, Vacuole, biology.organism_classification, Biochemistry, Cell biology, Protein–protein interaction, Conserved sequence, 03 medical and health sciences, 030104 developmental biology, Vacuolar acidification, V-ATPase, Molecular Biology

Abstract

The yeast vacuolar H+-ATPase (V-ATPase) of budding yeast (Saccharomyces cerevisiae) is regulated by reversible disassembly. Disassembly inhibits V-ATPase activity under low-glucose conditions by releasing peripheral V1 subcomplexes from membrane-bound Vo subcomplexes. V-ATPase reassembly and reactivation requires intervention of the conserved regulator of H+-ATPase of vacuoles and endosomes (RAVE) complex, which binds to cytosolic V1 subcomplexes and assists reassembly with integral membrane Vo complexes. Consistent with its role, the RAVE complex itself is reversibly recruited to the vacuolar membrane by glucose, but the requirements for its recruitment are not understood. We demonstrate here that RAVE recruitment to the membrane does not require an interaction with V1. Glucose-dependent RAVE localization to the vacuolar membrane required only intact Vo complexes containing the Vph1 subunit, suggesting that the RAVE-Vo interaction is glucose-dependent. We identified a short conserved sequence in the center of the RAVE subunit Rav1 that is essential for the interaction with Vph1 in vivo and in vitro. Mutations in this region resulted in the temperature- and pH-dependent growth phenotype characteristic of ravΔ mutants. However, this region did not account for glucose sensitivity of the Rav1-Vph1 interaction. We quantitated glucose-dependent localization of a GFP-tagged RAVE subunit to the vacuolar membrane in several mutants previously implicated in altering V-ATPase assembly state or glucose-induced assembly. RAVE localization did not correlate with V-ATPase assembly levels reported previously in these mutants, highlighting both the catalytic nature of RAVE's role in V-ATPase assembly and the likelihood of glucose signaling to RAVE independently of V1.

Published

2020

13. A dual action small molecule enhances azoles and overcomes resistance through co-targeting Pdr5 and Vma1

Author

Ning-Ning Liu, Jia Zhou, TONG JIANG, MAUREEN TARSIO, FEIFEI YU, XUEHAN ZHENG, WANJUN QI, LIN LIU, JING-CONG TAN, LUQI WEI, JUN DING, JINGQUAN LI, LINGBING ZENG, BIAO REN, XIAOTIAN HUANG, YIBING PENG, YONG-BING CAO, YANBIN ZHAO, XIN-YU ZHANG, PATRICIA M. KANE, CHANGBIN CHEN, and HUI WANG

Subjects

Azoles, ErbB Receptors, Antifungal Agents, Mycoses, Physiology (medical), Biochemistry (medical), Public Health, Environmental and Occupational Health, Humans, General Medicine, Microbial Sensitivity Tests, Fluconazole

Abstract

Fungal infection threatens human health worldwide due to the limited arsenal of antifungals and the rapid emergence of resistance. Epidermal growth factor receptor (EGFR) is demonstrated to mediate epithelial cell endocytosis of the leading human fungal pathogen, Candida albicans. However, whether EGFR inhibitors act on fungal cells remains unknown. Here, we discovered that the specific EGFR inhibitor osimertinib mesylate (OSI) potentiates azole efficacy against diverse fungal pathogens and overcomes azole resistance. Mechanistic investigation revealed a conserved activity of OSI by promoting intracellular fluconazole accumulation via inhibiting Pdr5 and disrupting V-ATPase function via targeting Vma1 at serine 274, eventually leading to inactivation of the global regulator TOR. Evaluation of the in vivo efficacy and toxicity of OSI demonstrated its potential clinical application in impeding fluconazole resistance. Thus, the identification of OSI as a dual action antifungal with co-targeting activity proposes a potentially effective therapeutic strategy to treat life-threatening fungal infection and overcome antifungal resistance.

Published

2021

14. The Human Rogdi Protein Is the Functional Homologue of Yeast Rav2 and Can Promote V‐ATPase Assembly

Author

Patricia M. Kane, Samuel R Winkley, and Michael C. Jaskolka

Subjects

Biochemistry, Chemistry, Genetics, V-ATPase assembly, Molecular Biology, Yeast, Biotechnology

Published

2021

15. Dissecting Regulatory Interactions with Cytosolic N‐terminal Domain of V‐ATPase a‐subunit Isoforms

Author

Patricia M. Kane, Farzana Tuli, and Connie Mitra

Subjects

Gene isoform, Cytosol, Terminal (electronics), Chemistry, Protein subunit, Genetics, V-ATPase, Molecular Biology, Biochemistry, Biotechnology, Domain (software engineering), Cell biology

Published

2021

16. Interaction of the late endo-lysosomal lipid PI(3,5)P2 with the Vph1 isoform of yeast V-ATPase increases its activity and cellular stress tolerance

Author

Maureen Tarsio, Patricia M. Kane, Subhrajit Banerjee, and Kaitlyn Clapp

Subjects

0301 basic medicine, Gene isoform, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Phosphatidylinositol 3,5-bisphosphate, Saccharomyces cerevisiae, Vacuole, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Phosphatidylinositol Phosphates, Osmotic Pressure, Membrane Biology, Lysosome, medicine, Protein Isoforms, V-ATPase, Amino Acid Sequence, Phosphatidylinositol, Molecular Biology, 030102 biochemistry & molecular biology, biology, Chemistry, Cell Biology, biology.organism_classification, Cell biology, Cytosol, 030104 developmental biology, medicine.anatomical_structure, Mutagenesis, Vacuoles, Protein Binding

Abstract

The low-level endo-lysosomal signaling lipid, phosphatidylinositol 3,5-bisphosphate (PI(3,5)P2), is required for full assembly and activity of vacuolar H(+)-ATPases (V-ATPases) containing the vacuolar a-subunit isoform Vph1 in yeast. The cytosolic N-terminal domain of Vph1 is also recruited to membranes in vivo in a PI(3,5)P2-dependent manner, but it is not known if its interaction with PI(3,5)P2 is direct. Here, using biochemical characterization of isolated yeast vacuolar vesicles, we demonstrate that addition of exogenous short-chain PI(3,5)P2 to Vph1-containing vacuolar vesicles activates V-ATPase activity and proton pumping. Modeling of the cytosolic N-terminal domain of Vph1 identified two membrane-oriented sequences that contain clustered basic amino acids. Substitutions in one of these sequences ((231)KTREYKHK) abolished the PI(3,5)P2-dependent activation of V-ATPase without affecting basal V-ATPase activity. We also observed that vph1 mutants lacking PI(3,5)P2 activation have enlarged vacuoles relative to those in WT cells. These mutants exhibit a significant synthetic growth defect when combined with deletion of Hog1, a kinase important for signaling the transcriptional response to osmotic stress. The results suggest that PI(3,5)P2 interacts directly with Vph1, and that this interaction both activates V-ATPase activity and protects cells from stress.

Published

2019

17. Valproate activates the Snf1 kinase in Saccharomyces cerevisiae by decreasing the cytosolic pH

Author

Maureen Tarsio, Michael W. Schmidtke, Pablo Lazcano, Patricia M. Kane, Michael Salsaa, Miriam L. Greenberg, Christian A. Reynolds, Kerestin Aziz, and Maik Hüttemann

Subjects

Fructose 1,6-bisphosphate, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, Protein Serine-Threonine Kinases, Biochemistry, chemistry.chemical_compound, Adenosine Triphosphate, Cytosol, medicine, Glycolysis, Molecular Biology, biology, Valproic Acid, Cell Biology, Hydrogen-Ion Concentration, biology.organism_classification, Cell biology, Enzyme Activation, Proton-Translocating ATPases, chemistry, Mechanism of action, medicine.symptom, Phosphoenolpyruvate carboxykinase, Flux (metabolism), Phosphofructokinase

Abstract

Valproate (VPA) is a widely used mood stabilizer, but its therapeutic mechanism of action is not understood. This knowledge gap hinders the development of more effective drugs with fewer side effects. Using the yeast model to elucidate the effects of VPA on cellular metabolism, we determined that the drug upregulated expression of genes normally repressed during logarithmic growth on glucose medium and increased levels of activated (phosphorylated) Snf1 kinase, the major metabolic regulator of these genes. VPA also decreased the cytosolic pH (pHc) and reduced glycolytic production of 2/3-phosphoglycerate. ATP levels and mitochondrial membrane potential were increased, and glucose-mediated extracellular acidification decreased in the presence of the drug, as indicated by a smaller glucose-induced shift in pH, suggesting that the major P-type proton pump Pma1 was inhibited. Interestingly, decreasing the pHc by omeprazole-mediated inhibition of Pma1 led to Snf1 activation. We propose a model whereby VPA lowers the pHc causing a decrease in glycolytic flux. In response, Pma1 is inhibited and Snf1 is activated, resulting in increased expression of normally repressed metabolic genes. These findings suggest a central role for pHc in regulating the metabolic program of yeast cells.

Published

2021

18. Defining steps in RAVE-catalyzed V-ATPase assembly using purified RAVE and V-ATPase subcomplexes

Author

Maureen Tarsio, Michael C. Jaskolka, Md. Murad Khan, Patricia M. Kane, and Anne M. Smardon

Subjects

0301 basic medicine, assembly, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, SEC, size-exclusion chromatography, Endosome, MBP-C, MBP-tagged subunit C, Protein subunit, Mutant, MBP, maltose-binding protein, Vacuole, Saccharomyces cerevisiae, lysosomal acidification, vacuolar ATPase, yeast, Biochemistry, YEPD, 03 medical and health sciences, Maltose-binding protein, chemistry.chemical_compound, YEPD, yeast extract, peptone, 2% dextrose, V-ATPase, BLI, biolayer interferometry, Molecular Biology, RAVE, TBSE, Tris-buffered saline with EDTA, 030102 biochemistry & molecular biology, biology, vacuole, Chemistry, RAVE, Regulator of the H+-ATPase of Vacuoles and Endosomes, regulation, Cell Biology, Yeast, Cell biology, 030104 developmental biology, proton pump, biology.protein, YEP, yeast extract–peptone medium without glucose, Vph1NT, N-terminal domain of Vo subunit Vph1, V-ATPase, vacuolar H+-ATPase, Research Article

Abstract

The vacuolar H+-ATPase (V-ATPase) is a highly conserved proton pump responsible for the acidification of intracellular organelles in virtually all eukaryotic cells. V-ATPases are regulated by the rapid and reversible disassembly of the peripheral V1 domain from the integral membrane Vo domain, accompanied by release of the V1 C subunit from both domains. Efficient reassembly of V-ATPases requires the Regulator of the H+-ATPase of Vacuoles and Endosomes (RAVE) complex in yeast. Although a number of pairwise interactions between RAVE and V-ATPase subunits have been mapped, the low endogenous levels of the RAVE complex and lethality of constitutive RAV1 overexpression have hindered biochemical characterization of the intact RAVE complex. We describe a novel inducible overexpression system that allows purification of native RAVE and RAVE–V1 complexes. Both purified RAVE and RAVE–V1 contain substoichiometric levels of subunit C. RAVE–V1 binds tightly to expressed subunit C in vitro, but binding of subunit C to RAVE alone is weak. Neither RAVE nor RAVE–V1 interacts with the N-terminal domain of Vo subunit Vph1 in vitro. RAVE–V1 complexes, like isolated V1, have no MgATPase activity, suggesting that RAVE cannot reverse V1 inhibition generated by rotation of subunit H and entrapment of MgADP that occur upon disassembly. However, purified RAVE can accelerate reassembly of V1 carrying a mutant subunit H incapable of inhibition with Vo complexes reconstituted into lipid nanodiscs, consistent with its catalytic activity in vivo. These results provide new insights into the possible order of events in V-ATPase reassembly and the roles of the RAVE complex in each event.

Published

2021

19. Defining the Yeast Resistome through in vitro Evolution and Whole Genome Sequencing

Author

Patricia M. Kane, Jennifer H. Yang, Jacob D. Durrant, Emmanuelle V. LeBlanc, Roy Williams, Trey Ideker, Krypton Carolino, Luke Whitesell, Erich Hellemann, Leah E. Cowen, Jake Schenken, Gisel Lopez, Eddy Vigil, Karla P. Godinez-Macias, Madeline R. Luth, Dyann F. Wirth, Reysha Patel, Elizabeth A. Winzeler, Gregory M. Goldgof, Yo Suzuki, Miranda Song, Joshua R. Smith, Sabine Ottilie, Matthew Abraham, Melissa S. Love, Amanda K. Lukens, William H. Gerwick, Prianka Kumar, Case W. McNamara, Felicia Gunawan, Andrea L. Cheung, and Maureen Tarsio

Subjects

Whole genome sequencing, Genetics, biology, Saccharomyces cerevisiae, Drug resistance, biology.organism_classification, Gene, Transcription factor, Genome, Systematic evolution of ligands by exponential enrichment, Resistome

Abstract

SummaryIn vitro evolution and whole genome analysis were used to comprehensively identify the genetic determinants of chemical resistance in the model microbe, Saccharomyces cerevisiae. Analysis of 355 curated, laboratory-evolved clones, resistant to 80 different compounds, demonstrates differences in the types of mutations that are identified in selected versus neutral evolution and reveals numerous new, compound-target interactions. Through enrichment analysis we further identify a set of 137 genes strongly associated with or conferring drug resistance as indicated by CRISPR-Cas9 engineering. The set of 25 most frequently mutated genes was enriched for transcription factors and for almost 25 percent of the compounds, resistance was mediated by one of 100 independently derived, gain-of-function, single nucleotide variants found in 170-amino-acid domains in two Zn2C6 transcription factors, YRR1 and YRM1 (p < 1x 10 −100). This remarkable enrichment for transcription factors as drug resistance genes may explain why it is challenging to develop effective antifungal killing agents and highlights their important role in evolution.

Published

2021

20. Electrons and Protons | V-ATPases

Author

Patricia M. Kane

Published

2021

21. Some assembly required: Contributions of Tom Stevens' lab to the V-ATPase field

Author

Laurie A. Graham, Patricia M. Kane, and Gregory C. Finnigan

Subjects

0301 basic medicine, Protein subunit, Mutant, Biology, Biochemistry, Article, Fungal Proteins, 03 medical and health sciences, Structural Biology, Protein splicing, Yeasts, Genetics, Animals, Humans, V-ATPase, Molecular Biology, Adenosine Triphosphatases, chemistry.chemical_classification, 030102 biochemistry & molecular biology, Cell Biology, Phenotype, Yeast, Cell biology, Protein Subunits, 030104 developmental biology, Enzyme, chemistry, Mutation, Genetic screen

Abstract

Tom Stevens’ lab has explored the subunit composition and assembly of the yeast V-ATPase for more than 30 years. Early studies helped establish yeast as the predominant model system for study of V-ATPase proton pumps and led to the discovery of protein splicing of the V-ATPase catalytic subunit. The Vma(−) phenotype, characteristic of loss of V-ATPase activity in yeast was key in determining the enzyme’s subunit composition via yeast genetics. V-ATPase subunit composition proved to be highly conserved among eukaryotes. Genetic screens for new vma mutants led to identification of a set of dedicated V-ATPase assembly factors and helped unravel the complex pathways for V-ATPase assembly. In later years, exploration of the evolutionary history of several V-ATPase subunits provided new information about the enzyme’s structure and function. This review highlights V-ATPase work in the Stevens lab between 1987 and 2017.

Published

2018

22. Compensatory Internalization of Pma1 in V-ATPase Mutants in Saccharomyces cerevisiae Requires Calcium- and Glucose-Sensitive Phosphatases

Author

Swetha Devi Velivela and Patricia M. Kane

Subjects

0301 basic medicine, Genetics, 030102 biochemistry & molecular biology, biology, media_common.quotation_subject, Endocytic cycle, Phosphatase, Protein phosphatase 1, Endocytosis, Cell biology, Ubiquitin ligase, 03 medical and health sciences, 030104 developmental biology, Downregulation and upregulation, biology.protein, V-ATPase, Internalization, media_common

Abstract

Loss of V-ATPase activity in organelles triggers compensatory endocytic downregulation of the plasma membrane proton pump Pma1. Here, Velivela and Kane... Loss of V-ATPase activity in organelles, whether through V-ATPase inhibition or V-ATPase (vma) mutations, triggers a compensatory downregulation of the essential plasma membrane proton pump Pma1 in Saccharomyces cerevisiae. We have previously determined that the α-arrestin Rim8 and ubiquitin ligase Rsp5 are essential for Pma1 ubiquination and endocytosis in response to loss of V-ATPase activity. Here, we show that Pma1 endocytosis in V-ATPase mutants does not require Rim101 pathway components upstream and downstream of Rim8, indicating that Rim8 is acting independently in Pma1 internalization. We find that two phosphatases, the calcium-responsive phosphatase calcineurin and the glucose-sensitive phosphatase Glc7 (PP1), and one of the Glc7 regulatory subunits Reg1, exhibit negative synthetic genetic interactions with vma mutants, and demonstrate that both phosphatases are essential for ubiquitination and endocytic downregulation of Pma1 in these mutants. Although both acute and chronic loss of V-ATPase activity trigger the internalization of ∼50% of surface Pma1, a comparable reduction in Pma1 expression in a pma1-007 mutant neither compensates for loss of V-ATPase activity nor stops further Pma1 endocytosis. The results indicate that the cell surface level of Pma1 is not directly sensed and that internalized Pma1 may play a role in compensating for loss of V-ATPase-dependent acidification. Taken together, these results provide new insights into cross talk between two major proton pumps central to cellular pH control.

Published

2018

23. Direct interaction of the Golgi V-ATPase a-subunit isoform with PI(4)P drives localization of Golgi V-ATPases in yeast

Author

Patricia M. Kane and Subhrajit Banerjee

Subjects

0301 basic medicine, Gene isoform, Vacuolar Proton-Translocating ATPases, Cell Physiology, Saccharomyces cerevisiae Proteins, Endosome, Golgi Apparatus, Endosomes, Saccharomyces cerevisiae, Vacuole, Biology, Phosphatidylinositols, 03 medical and health sciences, symbols.namesake, Cytosol, Phosphatidylinositol Phosphates, Organelle, Protein Isoforms, V-ATPase, Golgi localization, Molecular Biology, Articles, Cell Biology, Golgi apparatus, 3. Good health, Cell biology, 030104 developmental biology, Vacuoles, symbols

Abstract

PI(4)P directly interacts with the cytosolic domain of yeast Golgi vacuolar H+-ATPase (V-ATPase) a-isoform, Stv1, and the human Golgi a-subunit isoform. Lys-84 of Stv1 is essential for PI(4)P interaction, and localization of Stv1-containing V-ATPases in vivo requires the PI(4)P interaction. We propose that phosphatidylinositol binding exerts organelle-specific control over V-ATPases., Luminal pH and phosphoinositide content are fundamental features of organelle identity. Vacuolar H+-ATPases (V-ATPases) drive organelle acidification in all eukaryotes, and membrane-bound a-subunit isoforms of the V-ATPase are implicated in organelle-specific targeting and regulation. Earlier work demonstrated that the endolysosomal lipid PI(3,5)P2 activates V-ATPases containing the vacuolar a-subunit isoform in Saccharomyces cerevisiae. Here we demonstrate that PI(4)P, the predominant Golgi phosphatidylinositol (PI) species, directly interacts with the cytosolic amino terminal (NT) domain of the yeast Golgi V-ATPase a-isoform Stv1. Lysine-84 of Stv1NT is essential for interaction with PI(4)P in vitro and in vivo, and interaction with PI(4)P is required for efficient localization of Stv1-containing V-ATPases. The cytosolic NT domain of the human V-ATPase a2 isoform specifically interacts with PI(4)P in vitro, consistent with its Golgi localization and function. We propose that NT domains of Vo a-subunit isoforms interact specifically with PI lipids in their organelles of residence. These interactions can transmit organelle-specific targeting or regulation information to V-ATPases.

Published

2017

24. Interaction between the yeast RAVE complex and Vph1-containing V

Author

Michael C, Jaskolka and Patricia M, Kane

Subjects

Protein Subunits, Vacuolar Proton-Translocating ATPases, Glucose, Saccharomyces cerevisiae Proteins, Multiprotein Complexes, Mutation, Vacuoles, Amino Acid Sequence, Intracellular Membranes, Saccharomyces cerevisiae, Bioenergetics, Protein Binding

Abstract

The yeast vacuolar H(+)-ATPase (V-ATPase) of budding yeast (Saccharomyces cerevisiae) is regulated by reversible disassembly. Disassembly inhibits V-ATPase activity under low-glucose conditions by releasing peripheral V(1) subcomplexes from membrane-bound V(o) subcomplexes. V-ATPase reassembly and reactivation requires intervention of the conserved regulator of H(+)-ATPase of vacuoles and endosomes (RAVE) complex, which binds to cytosolic V(1) subcomplexes and assists reassembly with integral membrane V(o) complexes. Consistent with its role, the RAVE complex itself is reversibly recruited to the vacuolar membrane by glucose, but the requirements for its recruitment are not understood. We demonstrate here that RAVE recruitment to the membrane does not require an interaction with V(1). Glucose-dependent RAVE localization to the vacuolar membrane required only intact V(o) complexes containing the Vph1 subunit, suggesting that the RAVE-V(o) interaction is glucose-dependent. We identified a short conserved sequence in the center of the RAVE subunit Rav1 that is essential for the interaction with Vph1 in vivo and in vitro. Mutations in this region resulted in the temperature- and pH-dependent growth phenotype characteristic of ravΔ mutants. However, this region did not account for glucose sensitivity of the Rav1-Vph1 interaction. We quantitated glucose-dependent localization of a GFP-tagged RAVE subunit to the vacuolar membrane in several mutants previously implicated in altering V-ATPase assembly state or glucose-induced assembly. RAVE localization did not correlate with V-ATPase assembly levels reported previously in these mutants, highlighting both the catalytic nature of RAVE's role in V-ATPase assembly and the likelihood of glucose signaling to RAVE independently of V(1).

Published

2019

25. Some reassembly required: Requirements for RAVE‐mediated reassembly of the yeast V‐ATPase

Author

Michael C. Jaskolka and Patricia M. Kane

Subjects

Chemistry, Genetics, V-ATPase, Molecular Biology, Biochemistry, Yeast, Biotechnology, Cell biology

Published

2019

26. Crystal structure of yeast V 1 ‐ <scp>ATP</scp> ase in the autoinhibited state

Author

Stephan Wilkens, Patricia M. Kane, Rebecca A. Oot, and Edward A. Berry

Subjects

Models, Molecular, 0301 basic medicine, Vacuolar Proton-Translocating ATPases, Conformational change, Protein Conformation, Protein subunit, ATPase, Saccharomyces cerevisiae, Crystallography, X-Ray, Models, Biological, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Protein structure, Catalytic Domain, Organelle, Molecular Biology, General Immunology and Microbiology, biology, General Neuroscience, Articles, biology.organism_classification, Cell biology, Proton pump, Adenosine Diphosphate, Protein Subunits, 030104 developmental biology, biology.protein

Abstract

Vacuolar ATPases (V‐ATPases) are essential proton pumps that acidify the lumen of subcellular organelles in all eukaryotic cells and the extracellular space in some tissues. V‐ATPase activity is regulated by a unique mechanism referred to as reversible disassembly, wherein the soluble catalytic sector, V1, is released from the membrane and its MgATPase activity silenced. The crystal structure of yeast V1 presented here shows that activity silencing involves a large conformational change of subunit H, with its C‐terminal domain rotating ~150° from a position near the membrane in holo V‐ATPase to a position at the bottom of V1 near an open catalytic site. Together with biochemical data, the structure supports a mechanistic model wherein subunit H inhibits ATPase activity by stabilizing an open catalytic site that results in tight binding of inhibitory ADP at another site.

Published

2016

27. Molecular Interactions and Cellular Itinerary of the Yeast RAVE (Regulator of the H+-ATPase of Vacuolar and Endosomal Membranes) Complex

Author

Anne M. Smardon, Maureen Tarsio, Patricia M. Kane, Theodore T. Diakov, and Negin Dehdar Nasab

Subjects

Models, Molecular, Vacuolar Proton-Translocating ATPases, Binding Sites, Saccharomyces cerevisiae Proteins, Endosomal Sorting Complexes Required for Transport, biology, Endosome, Protein subunit, C-terminus, Saccharomyces cerevisiae, Endosomes, Cell Biology, biology.organism_classification, Biochemistry, Protein Structure, Secondary, Protein Structure, Tertiary, Protein–protein interaction, Cell biology, Vacuolar acidification, Two-Hybrid System Techniques, Membrane Biology, Binding site, Molecular Biology

Abstract

The RAVE complex (regulator of the H(+)-ATPase of vacuolar and endosomal membranes) is required for biosynthetic assembly and glucose-stimulated reassembly of the yeast vacuolar H(+)-ATPase (V-ATPase). Yeast RAVE contains three subunits: Rav1, Rav2, and Skp1. Rav1 is the largest subunit, and it binds Rav2 and Skp1 of RAVE; the E, G, and C subunits of the V-ATPase peripheral V1 sector; and Vph1 of the membrane Vo sector. We identified Rav1 regions required for interaction with its binding partners through deletion analysis, co-immunoprecipitation, two-hybrid assay, and pulldown assays with expressed proteins. We find that Skp1 binding requires sequences near the C terminus of Rav1, V1 subunits E and C bind to a conserved region in the C-terminal half of Rav1, and the cytosolic domain of Vph1 binds near the junction of the Rav1 N- and C-terminal halves. In contrast, Rav2 binds to the N-terminal domain of Rav1, which can be modeled as a double β-propeller. Only the V1 C subunit binds to both Rav1 and Rav2. Using GFP-tagged RAVE subunits in vivo, we demonstrate glucose-dependent association of RAVE with the vacuolar membrane, consistent with its role in glucose-dependent V-ATPase assembly. It is known that V1 subunit C localizes to the V1-Vo interface in assembled V-ATPase complexes and is important in regulated disassembly of V-ATPases. We propose that RAVE cycles between cytosol and vacuolar membrane in a glucose-dependent manner, positioning V1 and V0 subcomplexes and orienting the V1 C subunit to promote assembly.

Published

2015

28. Perturbation of the Vacuolar ATPase

Author

Patricia M. Kane, Maureen Tarsio, Yan Chen, J. Michael McCaffery, Yihui Shi, Rania M. Deranieh, and Miriam L. Greenberg

Subjects

biology, ATP synthase, Phosphatidylinositol Phosphates, Vacuolar Proton-Translocating ATPases, Cell Biology, Vacuole, Biochemistry, chemistry.chemical_compound, chemistry, Proton transport, biology.protein, Inositol, Phosphatidylinositol, Inositol-3-phosphate synthase, Molecular Biology

Abstract

Depletion of inositol has profound effects on cell function and has been implicated in the therapeutic effects of drugs used to treat epilepsy and bipolar disorder. We have previously shown that the anticonvulsant drug valproate (VPA) depletes inositol by inhibiting myo-inositol-3-phosphate synthase, the enzyme that catalyzes the first and rate-limiting step of inositol biosynthesis. To elucidate the cellular consequences of inositol depletion, we screened the yeast deletion collection for VPA-sensitive mutants and identified mutants in vacuolar sorting and the vacuolar ATPase (V-ATPase). Inositol depletion caused by starvation of ino1Δ cells perturbed the vacuolar structure and decreased V-ATPase activity and proton pumping in isolated vacuolar vesicles. VPA compromised the dynamics of phosphatidylinositol 3,5-bisphosphate (PI3,5P2) and greatly reduced V-ATPase proton transport in inositol-deprived wild-type cells. Osmotic stress, known to increase PI3,5P2 levels, did not restore PI3,5P2 homeostasis nor did it induce vacuolar fragmentation in VPA-treated cells, suggesting that perturbation of the V-ATPase is a consequence of altered PI3,5P2 homeostasis under inositol-limiting conditions. This study is the first to demonstrate that inositol depletion caused by starvation of an inositol synthesis mutant or by the inositol-depleting drug VPA leads to perturbation of the V-ATPase.

Published

2015

29. Deciphering the isoform code contained in V o a‐subunit isoforms of the V‐ATPase

Author

Michael C. Jaskolka, Farzana Tuli, Maureen Tarsio, Connie Mitra, Subhrajit Banerjee, and Patricia M. Kane

Subjects

Gene isoform, Code (set theory), Biochemistry, Chemistry, Protein subunit, Genetics, V-ATPase, Molecular Biology, Biotechnology

Published

2020

30. Progress Toward Understanding the Molecular Details and Consequences of IgE-Receptor Crosslinking

Author

David Holowka, Deborah Robertson, Barbara Baird, Patricia M. Kane, Byron Goldstein, Jon D. Erickson, and Anant K. Menon

Subjects

biology, Chemistry, Immunology, biology.protein, Receptor, Immunoglobulin E

Published

2018

31. Compensatory Internalization of Pma1 in V-ATPase Mutants in

Author

Swetha Devi, Velivela and Patricia M, Kane

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, vacuole, arrestin, Intracellular Signaling Peptides and Proteins, Cell Cycle Proteins, Saccharomyces cerevisiae, Investigations, ubiquitination, Models, Biological, Phosphoric Monoester Hydrolases, synthetic lethality, phosphatase, Repressor Proteins, Protein Transport, Proton-Translocating ATPases, acidification, Glucose, Cellular Genetics, proton pump, Protein Phosphatase 1, Mutation, endocytosis, Calcium, calcineurin

Abstract

Loss of V-ATPase activity in organelles triggers compensatory endocytic downregulation of the plasma membrane proton pump Pma1. Here, Velivela and Kane..., Loss of V-ATPase activity in organelles, whether through V-ATPase inhibition or V-ATPase (vma) mutations, triggers a compensatory downregulation of the essential plasma membrane proton pump Pma1 in Saccharomyces cerevisiae. We have previously determined that the α-arrestin Rim8 and ubiquitin ligase Rsp5 are essential for Pma1 ubiquination and endocytosis in response to loss of V-ATPase activity. Here, we show that Pma1 endocytosis in V-ATPase mutants does not require Rim101 pathway components upstream and downstream of Rim8, indicating that Rim8 is acting independently in Pma1 internalization. We find that two phosphatases, the calcium-responsive phosphatase calcineurin and the glucose-sensitive phosphatase Glc7 (PP1), and one of the Glc7 regulatory subunits Reg1, exhibit negative synthetic genetic interactions with vma mutants, and demonstrate that both phosphatases are essential for ubiquitination and endocytic downregulation of Pma1 in these mutants. Although both acute and chronic loss of V-ATPase activity trigger the internalization of ∼50% of surface Pma1, a comparable reduction in Pma1 expression in a pma1-007 mutant neither compensates for loss of V-ATPase activity nor stops further Pma1 endocytosis. The results indicate that the cell surface level of Pma1 is not directly sensed and that internalized Pma1 may play a role in compensating for loss of V-ATPase-dependent acidification. Taken together, these results provide new insights into cross talk between two major proton pumps central to cellular pH control.

Published

2017

32. The signaling lipid PI(3,5)P2stabilizes V1–Vosector interactions and activates the V-ATPase

Author

Tao Xu, Patricia M. Kane, Lois S. Weisman, Sergio Couoh-Cardel, Wandi Zhu, Sheena C. Li, Theodore T. Diakov, and Maureen Tarsio

Subjects

0303 health sciences, Phosphatidylinositol 3,5-bisphosphate, Phosphatidylinositol Phosphates, Saccharomyces cerevisiae, Cell Biology, Biology, biology.organism_classification, 3. Good health, Cell biology, 03 medical and health sciences, Cytosol, chemistry.chemical_compound, 0302 clinical medicine, chemistry, Membrane protein, Pi, V-ATPase, Signal transduction, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Vacuolar proton-translocating ATPases (V-ATPases) are highly conserved, ATP-driven proton pumps regulated by reversible dissociation of its cytosolic, peripheral V1domain from the integral membrane Vodomain. Multiple stresses induce changes in V1-Voassembly, but the signaling mechanisms behind these changes are not understood. Here we show that certain stress-responsive changes in V-ATPase activity and assembly require the signaling lipid phosphatidylinositol 3,5-bisphosphate (PI(3,5)P2). V-ATPase activation through V1-Voassembly in response to salt stress is strongly dependent on PI(3,5)P2synthesis. Purified Vocomplexes preferentially bind to PI(3,5)P2on lipid arrays, suggesting direct binding between the lipid and the membrane sector of the V-ATPase. Increasing PI(3,5)P2levels in vivo recruits the N-terminal domain of Vo-sector subunit Vph1p from cytosol to membranes, independent of other subunits. This Vph1p domain is critical for V1-Vointeraction, suggesting that interaction of Vph1p with PI(3,5)P2-containing membranes stabilizes V1-Voassembly and thus increases V-ATPase activity. These results help explain the previously described vacuolar acidification defect in yeast fab1∆ and vac14∆ mutants and suggest that human disease phenotypes associated with PI(3,5)P2loss may arise from compromised V-ATPase stability and regulation.

Published

2014

33. The RAVE complex is an isoform-specific V-ATPase assembly factor in yeast

Author

Theodore T. Diakov, Anne M. Smardon, Negin Dehdar Nasab, Patricia M. Kane, Robert W. West, Maureen Tarsio, and Heba I. Diab

Subjects

Cell Physiology, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Endosome, ATPase, Saccharomyces cerevisiae, Mutant, Golgi Apparatus, Endosomes, medicine.disease_cause, 03 medical and health sciences, symbols.namesake, medicine, Molecular Biology, 030304 developmental biology, Adaptor Proteins, Signal Transducing, 0303 health sciences, Mutation, biology, 030302 biochemistry & molecular biology, Cell Biology, Articles, Golgi apparatus, biology.organism_classification, Cell biology, Vacuolar acidification, Biochemistry, Vacuoles, symbols, biology.protein

Abstract

Vacuolar H+-ATPases (V-ATPases) acidify multiple organelles, and subunit isoforms help impart organelle-specific regulation of acidification. The regulator of ATPase of vacuoles and endosomes (RAVE) complex regulates organelle acidification by promoting V-ATPase assembly. This work demonstrates that RAVE is the first identified isoform-specific V-ATPase assembly factor required for control of vacuolar acidification., The regulator of ATPase of vacuoles and endosomes (RAVE) complex is implicated in vacuolar H+-translocating ATPase (V-ATPase) assembly and activity. In yeast, rav1∆ mutants exhibit a Vma− growth phenotype characteristic of loss of V-ATPase activity only at high temperature. Synthetic genetic analysis identified mutations that exhibit a full, temperature-independent Vma− growth defect when combined with the rav1∆ mutation. These include class E vps mutations, which compromise endosomal sorting. The synthetic Vma− growth defect could not be attributed to loss of vacuolar acidification in the double mutants, as there was no vacuolar acidification in the rav1∆ mutant. The yeast V-ATPase a subunit is present as two isoforms, Stv1p in Golgi and endosomes and Vph1p in vacuoles. Rav1p interacts directly with the N-terminal domain of Vph1p. STV1 overexpression suppressed the growth defects of both rav1∆ and rav1∆vph1∆, and allowed RAVE-independent assembly of active Stv1p-containing V-ATPases in vacuoles. Mutations causing synthetic genetic defects in combination with rav1∆ perturbed the normal localization of Stv1–green fluorescent protein. We propose that RAVE is necessary for assembly of Vph1-containing V-ATPase complexes but not Stv1-containing complexes. Synthetic Vma− phenotypes arise from defects in Vph1p-containing complexes caused by rav1∆, combined with defects in Stv1p-containing V-ATPases caused by the second mutation. Thus RAVE is the first isoform-specific V-ATPase assembly factor.

Published

2014

34. Energy powerhouses of cells come into focus

Author

Patricia M. Kane

Subjects

0301 basic medicine, Multidisciplinary, biology, Chemistry, ATPase, Mitochondrion, Adenosine, Proton pump, Chloroplast, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, Biochemistry, ATP hydrolysis, medicine, biology.protein, Electrochemical gradient, Adenosine triphosphate, 030217 neurology & neurosurgery, medicine.drug

Abstract

In every kingdom of life, rotary adenosine triphosphate (ATP) synthases and adenosine triphosphatases (ATPases) play key roles in cellular energy generation and release processes. In mitochondria, chloroplasts, and bacteria, F-type (F1Fo) ATP synthases synthesize ATP using energy from a proton gradient. They are also able to perform the reverse process, generating proton gradients by ATP hydrolysis. The related V-type (V1Vo) ATPases have similar structures and serve as proton pumps. Two articles in this issue report structures of membrane-embedded ATP synthases from yeast mitochondria [Srivastava et al. , page 619, ( 1 )] and spinach chloroplasts [Hahn et al. , page 620, ( 2 )]. Together with other recent structures, these articles define core design principles of rotary ATP synthases and ATPases but also highlight organism-specific differences.

Published

2018

35. Loss of Vacuolar H+-ATPase (V-ATPase) Activity in Yeast Generates an Iron Deprivation Signal That Is Moderated by Induction of the Peroxiredoxin TSA2

Author

Heba I. Diab and Patricia M. Kane

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Transcription, Genetic, Iron, Saccharomyces cerevisiae, Mutant, Biochemistry, Gene Expression Regulation, Fungal, Transcriptional regulation, Homeostasis, V-ATPase, Molecular Biology, Transcription factor, biology, Promoter, Peroxiredoxins, Cell Biology, Hydrogen-Ion Concentration, biology.organism_classification, Oxidative Stress, Regulon, Peroxidases, Peroxiredoxin, Gene Deletion, Signal Transduction, Transcription Factors

Abstract

Vacuolar H(+)-ATPases (V-ATPases) acidify intracellular organelles and help to regulate overall cellular pH. Yeast vma mutants lack V-ATPase activity and allow exploration of connections between cellular pH, iron, and redox homeostasis common to all eukaryotes. A previous microarray study in a vma mutant demonstrated up-regulation of multiple iron uptake genes under control of Aft1p (the iron regulon) and only one antioxidant gene, the peroxiredoxin TSA2 (Milgrom, E., Diab, H., Middleton, F., and Kane, P. M. (2007) Loss of vacuolar proton-translocating ATPase activity in yeast results in chronic oxidative stress. J. Biol. Chem. 282, 7125-7136). Fluorescent biosensors placing GFP under transcriptional control of either an Aft1-dependent promoter (P(FIT2)-GFP) or the TSA2 promoter (P(TSA2)-GFP) were constructed to monitor transcriptional signaling. Both biosensors were up-regulated in the vma2Δ mutant, and acute V-ATPase inhibition with concanamycin A induced coordinate up-regulation from both promoters. PTSA2-GFP induction was Yap1p-dependent, indicating an oxidative stress signal. Total cell iron measurements indicate that the vma2Δ mutant is iron-replete, despite up-regulation of the iron regulon. Acetic acid up-regulated P(FIT2)-GFP expression in wild-type cells, suggesting that loss of pH control contributes to an iron deficiency signal in the mutant. Iron supplementation significantly decreased P(FIT2)-GFP expression and, surprisingly, restored P(TSA2)-GFP to wild-type levels. A tsa2Δ mutation induced both nuclear localization of Aft1p and P(FIT2)-GFP expression. The data suggest a novel function for Tsa2p as a negative regulator of Aft1p-driven transcription, which is induced in V-ATPase mutants to limit transcription of the iron regulon. This represents a new mechanism bridging the antioxidant and iron-regulatory pathways that is intimately linked to pH homeostasis.

Published

2013

36. Proton Transport and pH Control in Fungi

Author

Patricia M. Kane

Subjects

Models, Molecular, 0301 basic medicine, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, 030106 microbiology, Gene Expression, Saccharomyces cerevisiae, Article, 03 medical and health sciences, Species Specificity, Proton transport, Organelle, Extracellular, V-ATPase, Ion Transport, Chemistry, Cell Membrane, Transporter, Hydrogen-Ion Concentration, Proton pump, Proton-Translocating ATPases, Cytosol, Vacuoles, Biophysics, Protons, Homeostasis, Signal Transduction

Abstract

Despite diverse and changing extracellular environments, fungi maintain a relatively constant cytosolic pH and numerous organelles of distinct lumenal pH. Key players in fungal pH control are V-ATPases and the P-type proton pump Pma1. These two proton pumps act in concert with a large array of other transporters and are highly regulated. The activities of Pma1 and the V-ATPaseare coordinated under some conditions, suggesting that pH in the cytosol and organelles is not controlled independently. Genomic studies, particularly in the highly tractable S. cerevisiae, are beginning to provide a systems-level view of pH control, including transcriptional responses to acid or alkaline ambient pH and definition of the full set of regulators required to maintain pH homeostasis. Genetically encoded pH sensors have provided new insights into localized mechanisms of pH control, as well as highlighting the dynamic nature of pH responses to the extracellular environment. Recent studies indicate that cellular pH plays a genuine signaling role that connects nutrient availability and growth rate through a number of mechanisms. Many of the pH control mechanisms found in S. cerevisiae are shared with other fungi, with adaptations for their individual physiological contexts. Fungi deploy certain proton transport and pH control mechanisms not shared with other eukaryotes; these regulators of cellular pH are potential antifungal targets. This re view describes current and emerging knowledge proton transport and pH control mechanisms in S. cerevisiae and briefly discusses how these mechanisms vary among fungi.

Published

2016

37. Regulation of Vacuolar H + -ATPase Activity by the Cdc42 Effector Ste20 in Saccharomyces cerevisiae

Author

Thomas Höfken, Meng Lin, Patricia M. Kane, and Sheena C. Li

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, MAP Kinase Signaling System, Saccharomyces cerevisiae, Hyphae, Vacuole, Protein Serine-Threonine Kinases, Biology, Microbiology, Enzyme activator, Kinase activity, cdc42 GTP-Binding Protein, Protein kinase A, Molecular Biology, Effector, fungi, Articles, General Medicine, Protein-Serine-Threonine Kinases, MAP Kinase Kinase Kinases, biology.organism_classification, Cell biology, Enzyme Activation, Cdc42 GTP-Binding Protein, Biochemistry, Vacuoles, Gene Deletion, Protein Binding

Abstract

In the budding yeast Saccharomyces cerevisiae , the Cdc42 effector Ste20 plays a crucial role in the regulation of filamentous growth, a response to nutrient limitation. Using the split-ubiquitin technique, we found that Ste20 forms a complex with Vma13, an important regulatory subunit of vacuolar H + -ATPase (V-ATPase). This protein-protein interaction was confirmed by a pulldown assay and coimmunoprecipitation. We also demonstrate that Ste20 associates with vacuolar membranes and that Ste20 stimulates V-ATPase activity in isolated vacuolar membranes. This activation requires Ste20 kinase activity and does not depend on increased assembly of the V 1 and V 0 sectors of the V-ATPase, which is a major regulatory mechanism. Furthermore, loss of V-ATPase activity leads to a strong increase in invasive growth, possibly because these cells fail to store and mobilize nutrients efficiently in the vacuole in the absence of the vacuolar proton gradient. In contrast to the wild type, which grows in rather small, isolated colonies on solid medium during filamentation, hyperinvasive vma mutants form much bigger aggregates in which a large number of cells are tightly clustered together. Genetic data suggest that Ste20 and the protein kinase A catalytic subunit Tpk2 are both activated in the vma13 Δ strain. We propose that during filamentous growth, Ste20 stimulates V-ATPase activity. This would sustain nutrient mobilization from vacuolar stores, which is beneficial for filamentous growth.

Published

2012

38. Vacuolar H + -ATPase Works in Parallel with the HOG Pathway To Adapt Saccharomyces cerevisiae Cells to Osmotic Stress

Author

Sheena C. Li, Jason M. Rizzo, Theodore T. Diakov, and Patricia M. Kane

Subjects

Glycerol, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Transcription, Genetic, Osmotic shock, Protein subunit, Saccharomyces cerevisiae, Cellular detoxification, Vacuole, Microbiology, Genes, Reporter, Osmotic Pressure, Gene Expression Regulation, Fungal, Phosphorylation, Protein kinase A, Molecular Biology, biology, Osmolar Concentration, Salt Tolerance, Articles, General Medicine, biology.organism_classification, Adaptation, Physiological, Biochemistry, Mutation, Mitogen-Activated Protein Kinases, Signal Transduction

Abstract

Hyperosmotic stress activates an array of cellular detoxification mechanisms, including the high-osmolarity glycerol (HOG) pathway. We report here that vacuolar H + -ATPase (V-ATPase) activity helps provide osmotic tolerance in Saccharomyces cerevisiae . V-ATPase subunit genes exhibit complex haploinsufficiency interactions with HOG pathway components. vma mutants lacking V-ATPase function are sensitive to high concentrations of salt and exhibit Hog1p activation even at low salt concentrations, as demonstrated by phosphorylation of Hog1p, a shift in Hog1-green fluorescent protein localization, transcriptional activation of a subset of HOG pathway effectors, and transcriptional inhibition of parallel mitogen-activated protein kinase pathway targets. vma2Δ hog1Δ and vma3Δ pbs2Δ double mutants have a synthetic growth phenotype, poor salt tolerance, and an aberrant, hyper-elongated morphology on solid media, accompanied by activation of a filamentous response element-LacZ construct, indicating cross talk into the filamentous growth pathway. Vacuoles isolated from wild-type cells briefly exposed to salt show higher levels of V-ATPase activity, and Na + /H + exchange in isolated vacuolar vesicles suggests a biochemical basis for the genetic interactions observed. V-ATPase activity is upregulated during salt stress by increasing assembly of the catalytic V 1 sector with the membrane-bound V o sector. Together, these data suggest that the V-ATPase acts in parallel with the HOG pathway in order to mediate salt detoxification.

Published

2012

39. Consequences of Loss of Vph1 Protein-containing Vacuolar ATPases (V-ATPases) for Overall Cellular pH Homeostasis

Author

Maureen Tarsio, Anne M. Smardon, Huimei Zheng, Gloria A. Martínez-Muñoz, and Patricia M. Kane

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Endosome, Golgi Apparatus, Saccharomyces cerevisiae, Vacuole, Biology, Biochemistry, symbols.namesake, Cytosol, Chloride Channels, Catalytic Domain, Organelle, Molecular Biology, Cell Biology, Golgi apparatus, Proton pump, Cell biology, Isoenzymes, Glucose, Vacuolar acidification, Sweetening Agents, Mutation, Vacuoles, symbols

Abstract

In yeast cells, subunit a of the vacuolar proton pump (V-ATPase) is encoded by two organelle-specific isoforms, VPH1 and STV1. V-ATPases containing Vph1 and Stv1 localize predominantly to the vacuole and the Golgi apparatus/endosomes, respectively. Ratiometric measurements of vacuolar pH confirm that loss of STV1 has little effect on vacuolar pH. Loss of VPH1 results in vacuolar alkalinization that is even more rapid and pronounced than in vma mutants, which lack all V-ATPase activity. Cytosolic pH responses to glucose addition in the vph1Δ mutant are similar to those in vma mutants. The extended cytosolic acidification in these mutants arises from reduced activity of the plasma membrane proton pump, Pma1p. Pma1p is mislocalized in vma mutants but remains at the plasma membrane in both vph1Δ and stv1Δ mutants, suggesting multiple mechanisms for limiting Pma1 activity when organelle acidification is compromised. pH measurements in early prevacuolar compartments via a pHluorin fusion to the Golgi protein Gef1 demonstrate that pH responses of these compartments parallel cytosolic pH changes. Surprisingly, these compartments remain acidic even in the absence of V-ATPase function, possibly as a result of cytosolic acidification. These results emphasize that loss of a single subunit isoform may have effects far beyond the organelle where it resides.

Published

2011

40. Cardiolipin Mediates Cross-Talk between Mitochondria and the Vacuole

Author

Shuliang Chen, Maureen Tarsio, Patricia M. Kane, and Miriam L. Greenberg

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Sodium-Hydrogen Exchangers, Cardiolipins, Saccharomyces cerevisiae, Vacuole, Mitochondrion, Biology, chemistry.chemical_compound, Cardiolipin, Homeostasis, Humans, Inner mitochondrial membrane, Cation Transport Proteins, Cell Shape, Molecular Biology, ATP synthase, Intracellular Signaling Peptides and Proteins, Temperature, Articles, Cell Biology, Mitochondria, Cell biology, Vacuolar acidification, Ion homeostasis, chemistry, Vacuoles, biology.protein, Signal Transduction

Abstract

Cardiolipin (CL) is an anionic phospholipid with a dimeric structure predominantly localized in the mitochondrial inner membrane, where it is closely associated with mitochondrial function, biogenesis, and genome stability ( Daum, 1985 ; Janitor and Subik, 1993 ; Jiang et al., 2000 ; Schlame et al., 2000 ; Zhong et al., 2004 ). Previous studies have shown that yeast mutant cells lacking CL due to a disruption in CRD1, the structural gene encoding CL synthase, exhibit defective colony formation at elevated temperature even on glucose medium ( Jiang et al., 1999 ; Zhong et al., 2004 ), suggesting a role for CL in cellular processes apart from mitochondrial bioenergetics. In the current study, we present evidence that the crd1Δ mutant exhibits severe vacuolar defects, including swollen vacuole morphology and loss of vacuolar acidification, at 37°C. Moreover, vacuoles from crd1Δ show decreased vacuolar H+-ATPase activity and proton pumping, which may contribute to loss of vacuolar acidification. Deletion mutants in RTG2 and NHX1, which mediate vacuolar pH and ion homeostasis, rescue the defective colony formation phenotype of crd1Δ, strongly suggesting that the temperature sensitivity of crd1Δ is a consequence of the vacuolar defects. Our results demonstrate the existence of a novel mitochondria-vacuole signaling pathway mediated by CL synthesis.

Published

2008

41. Vacuolar and Plasma Membrane Proton Pumps Collaborate to Achieve Cytosolic pH Homeostasis in Yeast

Author

Gloria A. Martínez-Muñoz and Patricia M. Kane

Subjects

Vacuolar Proton-Translocating ATPases, ATPase, Vacuole, Saccharomyces cerevisiae, Biochemistry, Cell membrane, Cytosol, medicine, Homeostasis, Enzyme Inhibitors, Molecular Biology, biology, Cell Membrane, Cell Biology, Hydrogen-Ion Concentration, Proton pump, Cell biology, Membrane Transport, Structure, Function, and Biogenesis, Protein Transport, medicine.anatomical_structure, Vacuolar acidification, Mutation, Vacuoles, biology.protein, Additions and Corrections, Macrolides, Protons

Abstract

Vacuolar proton-translocating ATPases (V-ATPases) play a central role in organelle acidification in all eukaryotic cells. To address the role of the yeast V-ATPase in vacuolar and cytosolic pH homeostasis, ratiometric pH-sensitive fluorophores specific for the vacuole or cytosol were introduced into wild-type cells and vma mutants, which lack V-ATPase subunits. Transiently glucose-deprived wild-type cells respond to glucose addition with vacuolar acidification and cytosolic alkalinization, and subsequent addition of K+ ion increases the pH of both the vacuole and cytosol. In contrast, glucose addition results in an increase in vacuolar pH in both vma mutants and wild-type cells treated with the V-ATPase inhibitor concanamycin A. Cytosolic pH homeostasis is also significantly perturbed in the vma mutants. Even at extracellular pH 5, conditions optimal for their growth, cytosolic pH was much lower, and response to glucose was smaller in the mutants. In plasma membrane fractions from the vma mutants, activity of the plasma membrane proton pump, Pma1p, was 65–75% lower than in fractions from wild-type cells. Immunofluorescence microscopy confirmed decreased levels of plasma membrane Pma1p and increased Pma1p at the vacuole and other compartments in the mutants. Pma1p was not mislocalized in concanamycin-treated cells, but a significant reduction in cytosolic pH under all conditions was still observed. We propose that short-term, V-ATPase activity is essential for both vacuolar acidification in response to glucose metabolism and for efficient cytosolic pH homeostasis, and long-term, V-ATPases are important for stable localization of Pma1p at the plasma membrane.

Published

2008

42. Perturbation of the Vacuolar ATPase: A NOVEL CONSEQUENCE OF INOSITOL DEPLETION

Author

Rania M, Deranieh, Yihui, Shi, Maureen, Tarsio, Yan, Chen, J Michael, McCaffery, Patricia M, Kane, and Miriam L, Greenberg

Subjects

Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Valproic Acid, Saccharomyces cerevisiae, Lipids, Protein Transport, Phosphatidylinositol Phosphates, Drug Resistance, Fungal, Osmotic Pressure, Vacuoles, Homeostasis, Anticonvulsants, Myo-Inositol-1-Phosphate Synthase, Intramolecular Lyases, Gene Deletion, Inositol

Abstract

Depletion of inositol has profound effects on cell function and has been implicated in the therapeutic effects of drugs used to treat epilepsy and bipolar disorder. We have previously shown that the anticonvulsant drug valproate (VPA) depletes inositol by inhibiting myo-inositol-3-phosphate synthase, the enzyme that catalyzes the first and rate-limiting step of inositol biosynthesis. To elucidate the cellular consequences of inositol depletion, we screened the yeast deletion collection for VPA-sensitive mutants and identified mutants in vacuolar sorting and the vacuolar ATPase (V-ATPase). Inositol depletion caused by starvation of ino1Δ cells perturbed the vacuolar structure and decreased V-ATPase activity and proton pumping in isolated vacuolar vesicles. VPA compromised the dynamics of phosphatidylinositol 3,5-bisphosphate (PI3,5P2) and greatly reduced V-ATPase proton transport in inositol-deprived wild-type cells. Osmotic stress, known to increase PI3,5P2 levels, did not restore PI3,5P2 homeostasis nor did it induce vacuolar fragmentation in VPA-treated cells, suggesting that perturbation of the V-ATPase is a consequence of altered PI3,5P2 homeostasis under inositol-limiting conditions. This study is the first to demonstrate that inositol depletion caused by starvation of an inositol synthesis mutant or by the inositol-depleting drug VPA leads to perturbation of the V-ATPase.

Published

2015

43. Inositol Depletion Perturbs the Vacuolar‐ATPase: A Novel Mechanism of Action of Valproate

Author

Rania M. Deranieh, Patricia M. Kane, Miriam L. Greenberg, Yihui Shi, and Mauraeen Tarsio

Subjects

chemistry.chemical_compound, Mechanism of action, Chemistry, Genetics, medicine, Inositol, medicine.symptom, Vacuolar ATPase, Molecular Biology, Biochemistry, Biotechnology, Cell biology

Published

2015

44. The E and G Subunits of the Yeast V-ATPase Interact Tightly and Are Both Present at More Than One Copy per V1 Complex

Author

Jianzhong Liu, Maureen Tarsio, Anne M. Smardon, Patricia M. Kane, Colleen M.H. Charsky, and Masashi Ohira

Subjects

Vacuolar Proton-Translocating ATPases, Specificity factor, Protein subunit, Gi alpha subunit, Saccharomyces cerevisiae, Biology, Biochemistry, Copurification, Fungal Proteins, Epitopes, Structure-Activity Relationship, Cytosol, Two-Hybrid System Techniques, Eukaryotic Small Ribosomal Subunit, Molecular Biology, G alpha subunit, Neurospora crassa, Eukaryotic Large Ribosomal Subunit, Cell Biology, Protein Structure, Tertiary, G beta-gamma complex, Mutation, Gene Deletion, Plasmids, Protein Binding

Abstract

The E and G subunits of the yeast V-ATPase are believed to be part of the peripheral or stator stalk(s) responsible for physically and functionally linking the peripheral V1 sector, responsible for ATP hydrolysis, to the membrane V0 sector, containing the proton pore. The E and G subunits interact tightly and specifically, both on a far Western blot of yeast vacuolar proteins and in the yeast two-hybrid assay. Amino acids 13-79 of the E subunit are critical for the E-G two-hybrid interaction. Different tagged versions of the G subunit were expressed in a diploid cell, and affinity purification of cytosolic V1 sectors via a FLAG-tagged G subunit resulted in copurification of a Myc-tagged G subunit, implying more than one G subunit was present in each V1 complex. Similarly, hemagglutinin-tagged E subunit was able to affinity-purify V1 sectors containing an untagged version of the E subunit from heterozygous diploid cells, suggesting that more than one E subunit is present. Overexpression of the subunit G results in a destabilization of subunit E similar to that seen in the complete absence of subunit G (Tomashek, J. J., Graham, L. A., Hutchins, M. U., Stevens, T. H., and Klionsky, D. J. (1997) J. Biol. Chem. 272, 26787-26793). These results are consistent with recent models showing at least two peripheral stalks connecting the V1 and V0 sectors of the V-ATPase and would allow both stalks to be based on an EG dimer.

Published

2006

45. Close-Up and Genomic Views of the Yeast Vacuolar H+-ATPase

Author

Patricia M. Kane

Subjects

Vacuolar Proton-Translocating ATPases, Physiology, Protein subunit, ATPase, Cell Biology, Vacuole, Biology, Yeast, Cell biology, Fungal Proteins, Protein Subunits, Biochemistry, ATP hydrolysis, Vacuolar H+-ATPase, Mutation, biology.protein, Bioorganic chemistry, Genome, Fungal, Ploidy

Abstract

The yeast V-ATPase has emerged as an excellent model for other eukaryotic V-ATPases. In this review, recent biochemical and genomic studies of the yeast V-ATPase are described, with a focus on: 1) the role of V(1) subunit H in coupling ATP hydrolysis and proton pumping and 2) identification of the full set of yeast haploid deletion mutants that exhibit the pH and calcium-sensitive growth characteristic of loss of V-ATPase activity. The combination of "close-up" biochemical views of V-ATPase structure and mechanism and "geomic" views of its functional reach promises to provide new insights into the physiological of V-ATPases.

Published

2005

46. A Genomic Screen for Yeast Vacuolar Membrane ATPase Mutants

Author

Anne M. Smardon, Mercedes I. Alba, Patricia M. Kane, Maria Sambade, and Robert W. West

Subjects

Vacuolar Proton-Translocating ATPases, Protein subunit, Mutant, Saccharomyces cerevisiae, Vacuole, Investigations, Biology, medicine.disease_cause, Protein targeting, Genetics, medicine, Adenosine Triphosphatases, Vacuolar protein sorting, Mutation, Calcineurin, Hydrogen-Ion Concentration, Alkaline Phosphatase, biology.organism_classification, Vacuolar acidification, Microscopy, Fluorescence, Biochemistry, Quinacrine, Vacuoles, Genome, Fungal, Gene Deletion

Abstract

V-ATPases acidify multiple organelles, and yeast mutants lacking V-ATPase activity exhibit a distinctive set of growth defects. To better understand the requirements for organelle acidification and the basis of these growth phenotypes, ∼4700 yeast deletion mutants were screened for growth defects at pH 7.5 in 60 mm CaCl2. In addition to 13 of 16 mutants lacking known V-ATPase subunits or assembly factors, 50 additional mutants were identified. Sixteen of these also grew poorly in nonfermentable carbon sources, like the known V-ATPase mutants, and were analyzed further. The cwh36Δ mutant exhibited the strongest phenotype; this mutation proved to disrupt a previously uncharacterized V-ATPase subunit. A small subset of the mutations implicated in vacuolar protein sorting, vps34Δ, vps15Δ, vps45Δ, and vps16Δ, caused both Vma− growth phenotypes and lower V-ATPase activity in isolated vacuoles, as did the shp1Δ mutation, implicated in both protein sorting and regulation of the Glc7p protein phosphatase. These proteins may regulate V-ATPase targeting and/or activity. Eight mutants showed a Vma− growth phenotype but no apparent defect in vacuolar acidification. Like V-ATPase-deficient mutants, most of these mutants rely on calcineurin for growth, particularly at high pH. A requirement for constitutive calcineurin activation may be the predominant physiological basis of the Vma− growth phenotype.

Published

2005

47. The Yeast Vacuolar Proton-translocating ATPase Contains a Subunit Homologous to the Manduca sexta and Bovine e Subunits That Is Essential for Function

Author

Patricia M. Kane and Maria Sambade

Subjects

Glycerol, Vacuolar Proton-Translocating ATPases, Saccharomyces cerevisiae Proteins, Chromaffin Cells, Protein subunit, ATPase, Molecular Sequence Data, Mutant, Vacuole, Biology, medicine.disease_cause, Biochemistry, Epitopes, Open Reading Frames, Saccharomyces, Manduca, Centrifugation, Density Gradient, medicine, Animals, Amino Acid Sequence, Molecular Biology, Mutation, Sequence Homology, Amino Acid, Intracellular Membranes, Cell Biology, Hydrogen-Ion Concentration, biology.organism_classification, Yeast, Protein Structure, Tertiary, Open reading frame, Phenotype, Manduca sexta, Vacuoles, biology.protein, Cattle, Genome, Fungal, Protons, Plasmids

Abstract

The yeast cwh36Delta mutant was identified in a screen for yeast mutants exhibiting a Vma(-) phenotype suggestive of loss of vacuolar proton-translocating ATPase (V-ATPase) activity. The mutation disrupts two genes, CWH36 and a recently identified open reading frame on the opposite strand, YCL005W-A. We demonstrate that disruption of YCL005W-A is entirely responsible for the Vma(-) growth phenotype of the cwh36Delta mutant. YCL005W-A encodes a homolog of proteins associated with the Manduca sexta and bovine chromaffin granule V-ATPase. The functional significance of these proteins for V-ATPase activity had not been tested, but we show that the protein encoded by YCL005W-A, which we call Vma9p, is essential for V-ATPase activity in yeast. Vma9p is localized to the vacuole but fails to reach the vacuole in a mutant lacking one of the integral membrane subunits of the V-ATPase. Vma9p is associated with the yeast V-ATPase complex in vacuolar membranes, as demonstrated by co-immunoprecipitation with known V-ATPase subunits and glycerol gradient fractionation of solubilized vacuolar membranes. Based on this evidence, we propose that Vma9p is a genuine subunit of the yeast V-ATPase and that e subunits may be a functionally essential part of all eukaryotic V-ATPases.

Published

2004

48. Yeast V1-ATPase

Author

Stephan Wilkens, Zhenyu Zhang, Colleen M.H. Charsky, and Patricia M. Kane

Subjects

biology, Chemistry, Protein subunit, Vesicle, Resolution (electron density), Saccharomyces cerevisiae, Cell Biology, biology.organism_classification, Mass spectrometry, Biochemistry, Yeast, law.invention, Crystallography, Affinity chromatography, law, Electron microscope, Molecular Biology

Abstract

V1-ATPase from the yeast Saccharomyces cerevisiae was purified via a FLAG affinity tag introduced into the N terminus of the G subunit. The preparation migrated as a single band in native gel electrophoresis and contained subunits ABCDEFGH (with subunit C present at substoichiometric amounts) as determined by matrix-assisted laser desorption ionization time-of-flight mass spectrometry. The initial specific Ca-ATPase activity was ∼6 μmol/min/mg. The structure of the yeast V1-ATPase was studied by electron microscopy of negatively stained and frozen hydrated samples. A 25-A resolution three-dimensional model of the complex was calculated from two-dimensional projections by the angular reconstitution technique. The model shows six elongated densities arranged in pseudo-3-fold symmetry around a large central cavity. At the top of the molecule, various protrusions can be seen. At the bottom of the complex, two large masses are visible that are connected to the main body of the molecule. Comparison of the yeast V1 structure with the structure of the intact V1V0-ATPase from bovine brain clathrin-coated vesicles (Wilkens, S., Vasilyeva, E., and Forgac, M. (1999) J. Biol. Chem. 274, 31804–31810) indicates that the structure of the isolated V1 from yeast is very similar to the structure of the V1 domain in the intact V-ATPase complex.

Published

2003

49. [Untitled]

Author

Patricia M. Kane and Karlett J. Parra

Subjects

biology, Physiology, ATPase, Cell Biology, Vacuole, biology.organism_classification, Yeast, Cell biology, Membrane, Biochemistry, Manduca sexta, biology.protein, Gene silencing, V-ATPase, Bioorganic chemistry

Abstract

The yeast vacuolar proton-translocating ATPase (V-ATPase) is an excellent model for V-ATPases in all eukaryotic cells. Activity of the yeast V-ATPase is reversibly down-regulated by disassembly of the peripheral (V1) sector, which contains the ATP-binding sites, from the membrane (V0) sector, which contains the proton pore. A similar regulatory mechanism has been found in Manduca sexta and is believed to operate in other eukaryotes. We are interested in the mechanism of reversible disassembly and its implications for V-ATPase structure. In this review, we focus on (1) characterization of the yeast V-ATPase stalk subunits, which form the interface between V1 and V0, (2) potential mechanisms of silencing ATP hydrolytic activity in disassembled V1 sectors, and (3) the structure and function of RAVE, a recently discovered complex that regulates V-ATPase assembly.

Published

2003

50. The RAVE Complex Is Essential for Stable Assembly of the Yeast V-ATPase

Author

Maureen Tarsio, Patricia M. Kane, and Anne M. Smardon

Subjects

Vacuolar Proton-Translocating ATPases, Genotype, ATPase, Protein subunit, Mutant, Cell Cycle Proteins, Biology, medicine.disease_cause, Models, Biological, Biochemistry, Fungal Proteins, Proton transport, medicine, V-ATPase, S-Phase Kinase-Associated Proteins, Molecular Biology, Mutation, Cell Membrane, Cell Biology, Precipitin Tests, Cytosol, Glucose, biology.protein, Signal transduction, Protein Binding, Signal Transduction

Abstract

Vacuolar proton-translocating ATPases are composed of a peripheral complex, V(1), attached to an integral membrane complex, V(o). Association of the two complexes is essential for ATP-driven proton transport and is regulated post-translationally in response to glucose concentration. A new complex, RAVE, was recently isolated and implicated in glucose-dependent reassembly of V-ATPase complexes that had disassembled in response to glucose deprivation (Seol, J. H., Shevchenko, A., and Deshaies, R. J. (2001) Nat. Cell Biol. 3, 384-391). Here, we provide evidence supporting a role for RAVE in reassembly of the V-ATPase but also demonstrate an essential role in V-ATPase assembly under other conditions. The RAVE complex associates reversibly with V(1) complexes released from the membrane by glucose deprivation but binds constitutively to cytosolic V(1) sectors in a mutant lacking V(o) sectors. V-ATPase complexes from cells lacking RAVE subunits show serious structural and functional defects even in glucose-grown cells or in combination with a mutation that blocks disassembly of the V-ATPase. RAVE small middle dotV(1) interactions are specifically disrupted in cells lacking V(1) subunits E or G, suggesting a direct involvement for these subunits in interaction of the two complexes. Skp1p, a RAVE subunit involved in many different signal transduction pathways, binds stably to other RAVE subunits under conditions that alter RAVE small middle dotV(1) binding; thus, Skp1p recruitment to the RAVE complex does not appear to provide a signal for V-ATPase assembly.

Published

2002