Saccharomyces cerevisiae Lacking Btn1p Modulate Vacuolar ATPase Activity to Regulate pH Imbalance in the Vacuole

Padilla-López, Sergio; Pearce, David A.

doi:10.1074/jbc.m510625200

Cited by 77 publications

(62 citation statements)

References 58 publications

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“…As in previous studies (26,52), we find that the cytosolic pH of cells supplied with glucose is relatively insensitive to extracellular pH, ranging from 6.7 at pH ext 5 to pH 7.1 at pH ext ϭ 7.5, and is even more constant if KCl is present (cytosolic pH 7.0 -7.1). Vacuolar pH appears to be more dependent on extracellular conditions (20,30) but is generally higher in yeast vacuoles than in mammalian lysosomes. We propose that the rise in cytosolic pH upon glucose addition reflects both the availability of metabolically generated ATP and H ϩ and glu-4 G. A. Martínez-Muñ oz and P. Kane, unpublished data.…”

Section: Discussionmentioning

confidence: 99%

“…V-ATPases are also activated by glucose, but they reversibly disassemble in response to glucose deprivation and readdition, resulting in higher levels of assembled pumps and ATPase activity at the vacuole in the presence of glucose (18,19). The activity of both pumps is sensitive to pH, indicating that they may be tuned to respond to changes in cytosolic pH in vivo (20,21). Pma1p, in particular, is activated in response to cytosolic acidification (21), and this mode of regulation is likely to be important for maintenance of cytosolic pH in a narrow range, relatively independent of extracellular pH.…”

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confidence: 99%

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

Martínez-Muñoz¹,

Kane

2008

Journal of Biological Chemistry

238

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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 wildtype 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.The importance of V-ATPases 3 for acidification of the vacuole/lysosomes, Golgi apparatus, and endosomes of eukaryotic cells is well established (1, 2). Multiple cellular processes, including secondary transport of ions and metabolites, maturation of iron transporters, endocytic and biosynthetic protein sorting, and zymogen activation depend on compartment acidification and have been linked to V-ATPase activity (1, 3). In some cells such as macrophages, V-ATPases play specialized roles that clearly include regulation of cytosolic pH (4, 5). However, although V-ATPases pump protons from the cytosol into organelles in all cells, they are not generally believed to play a major role in cytosolic pH regulation.The yeast Saccharomyces cerevisiae has emerged as a major model system for eukaryotic V-ATPases. One reason for this is that yeast mutants lacking all V-ATPase activity (vma mutants) are viable, but loss of V-ATPase activity in eukaryotes other than fungi is lethal (6 -9). Yeast vma mutants do exhibit a set of distinctive phenotypes, however, that includes the inability to grow at pH values lower than 3 or higher than 7 and sensitivity to high extracellular calcium concentrations (2). This Vma Ϫ phenotype suggests a perturbation of pH homeostasis in these cells that is not fully understood. It has been suggested that vma mutants survive at low extracellular p...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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

Martínez-Muñoz¹,

Kane

2008

Journal of Biological Chemistry

238

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“…Despite much effort since its identification in 1995, the function of CLN3 has remained elusive, although it too has been implicated in multiple roles, including lysosome homeostasis (Holopainen et al, 2001;Ramirez-Montealegre and Pearce, 2005;Pohl et al, 2007), autophagy (Cao et al, 2006), cytoskeletal organisation (Luiro et al, 2004;Luiro et al, 2006) and lipid synthesis or modification (Narayan et al, 2006;Hobert and Dawson, 2007). Work in other organisms, especially Saccharomyces cerevisae, also supports a role for CLN3/Btn1p in vacuole pH homeostasis (Pearce and Sherman, 1998;Pearce et al, 1999a;Pearce et al, 1999b;Pearce and Sherman, 1999;Chattopadhyay et al, 2003;Kim et al, 2003;Padilla-Lopez and Pearce, 2006). Significantly, expression of CLN3 restored phenotypes arising from deletion of btn1 in these organisms, indicating that these proteins exert a similar basic function.…”

Section: Introductionmentioning

confidence: 89%

The fission yeast model for the lysosomal storage disorder Batten disease predicts disease severity caused by mutations in CLN3

Haines

Codlin

Mole

2009

Disease Models &Amp; Mechanisms

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SUMMARYThe function of the CLN3 protein, which is mutated in patients with the neurodegenerative lysosomal storage disorder Batten disease, has remained elusive since it was identified 13 years ago. Here, we exploited the Schizosaccharomyces pombe model to gain new insights into CLN3 function. We modelled all missense mutations of CLN3 in the orthologous protein Btn1p, as well as a series of targeted mutations, and assessed trafficking and the ability of the mutant proteins to rescue four distinct phenotypes of btn1⌬ cells. Mutating the C-terminal cysteine residues of Btn1p caused it to be internalised into the vacuole, providing further evidence that this protein functions from pre-vacuole compartments. Mutations in the lumenal regions of the multi-spanning membrane protein, especially in the third lumenal domain which contains a predicted amphipathic helix, had the most significant impact on Btn1p function, indicating that these domains of CLN3 are functionally important. Only one mutant protein was able to rescue the cell curving phenotype (p.Glu295Lys), and since this mutation is associated with a very protracted disease progression, this phenotype could be used to predict the disease severity of novel mutations in CLN3. The ability to predict disease phenotypes in S. pombe confirms this yeast as an invaluable tool to understanding Batten disease. RESEARCH ARTICLEmodelled some disease-causing mutations of CLN3 in Btn1p and found that they altered the trafficking and/or function of Btn1p (Gachet et al., 2005; Codlin et al., 2008b). In this study, we modelled the full complement of disease-causing mutations in order to build up a complete picture of the impact of mutations on protein function. To exploit the S. pombe model effectively, we required distinct phenotypes associated with the deletion of btn1 that could be assayed easily. In the absence of btn1, S. pombe cells have larger vacuoles, which are also less acidic, than those in wild-type cells. Cells with the btn1 deletion are also delayed in the final stages of cytokinesis, and more cells are in the process of septation compared with wild-type cells (Codlin et al., 2008b). The cytokinesis delay is more severe at 37°C, when growth of btn1⌬ cells is temperaturesensitive. Following 18 hours of growth at 37°C, btn1⌬ cells are swollen or lysed owing to total loss of bipolar growth. Prior to this, after 7 hours of growth at 37°C, btn1⌬ cells fail to initiate bipolar growth and remain monopolar for growth (Codlin et al., 2008a; Codlin et al., 2008b). Additionally, we report here that after 4 hours of growth at the non-permissive temperature, btn1⌬ cells lose their rod-shaped morphology and become bent or curved. Therefore, we chose the following four readily-assayable marker phenotypes of btn1⌬ cells: (1) increased vacuole size, (2) septation index during normal growth conditions, (3) cell curving and (4) monopolar growth at 37°C. Importantly, ectopic expression of Btn1p or CLN3 can rescue all of these phenotypes in btn1⌬ cells. In these phenotypic assays, w...

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“…Our activity assay and the use of inhibitors was based on (Serrano 1978;Clelland and Saleuddin 2000;Lunde and Kubo 2000;Padilla-Lopez and Pearce 2006), with modifications, as follows. The assay mixture contained the activity buffer (50 mM MES/TRIS, 5 mM MgCl 2 , pH 7.0), 5 mM sodium azide (to inhibit mitochondrial ATPase), 0.2 mM ammonium molybdate (to inhibit acid phosphatases), 100 μM sodium orthovanadate (to inhibit plasma membrane proton-ATPase).…”

Section: Atpase Activity Assaymentioning

confidence: 99%

“…Since the substrate of the reaction is MgATP and MgCl 2 is in excess to Na 2 ATP, the substrate concentration was close to 2 mM (at least in the beginning of the reaction). Several inhibitors that are known to inhibit other ATPases (Serrano 1978;Clelland and Saleuddin 2000;Lunde and Kubo 2000;Padilla-Lopez and Pearce 2006) were tested. These 'other' inhibitors removed only about 20% of the total ATPase activity, even at relatively high inhibitor concentration.…”

Section: Atpase Activity Assaymentioning

confidence: 99%

Estimating the rotation rate in the vacuolar proton-ATPase in native yeast vacuolar membranes

et al. 2012

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The rate of rotation of the rotor of the yeast vacuolar proton-ATPase (V-ATPase), relative to the stator or the steady parts of enzyme, is estimated in native vacuolar membrane vesicles of Saccharomyces cerevisiae under standardised conditions. Membrane vesicles are spontaneously formed after exposing purified yeast vacuoles to osmotic shock. The fraction of the total ATPase activity originating from V-ATPase is determined using the potent and specific inhibitor of the enzyme, concanamycin A. Inorganic phosphate liberated from ATP in the vacuolar membrane vesicle system, during 10 min of ATPase activity at 20 °C, is assayed spectrophotometrically for different concanamycin A concentrations. A fit to the quadratic binding equation, assuming a single concanamycin A binding site on a monomeric V-ATPase (our data is incompatible with models assuming more binding sites) to the inhibitor titration curve determines the concentration of the enzyme. Combining it with the known rotation:ATP stoichiometry of V-ATPase and the assayed concentration of inorganic phosphate liberated by V-ATPase leads to an average rate of ~9.53 Hz of the 360 degrees rotation, which, according to the time-dependence of the activity, extrapolates to ~14.14 Hz for the beginning of the reaction. These are low limit estimates. To our knowledge this is the first report of the rotation rate in a V-ATPase that is not subjected to genetic or chemical modification and it is not fixed on a solid support, instead it is functioning in its native membrane environment.Special Issue: Structure, function, folding and assembly of membrane proteins -Insight from Biophysics.

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Saccharomyces cerevisiae Lacking Btn1p Modulate Vacuolar ATPase Activity to Regulate pH Imbalance in the Vacuole

Cited by 77 publications

References 58 publications

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

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

The fission yeast model for the lysosomal storage disorder Batten disease predicts disease severity caused by mutations in CLN3

Estimating the rotation rate in the vacuolar proton-ATPase in native yeast vacuolar membranes

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