Fab1p Is Essential for PtdIns(3)P 5-Kinase Activity and the Maintenance of Vacuolar Size and Membrane Homeostasis

The Saccharomyces cerevisiae FAB1 gene encodes a 257-kD protein that contains a cysteine-rich RING-FYVE domain at its NH₂-terminus and a kinase domain at its COOH terminus. Based on its sequence, Fab1p was initially proposed to function as a phosphatidylinositol 4-phosphate (PtdIns(4)P) 5-kinase (Yamamoto et al., 1995). Additional sequence analysis of the Fab1p kinase domain, reveals that Fab1p defines a subfamily of putative PtdInsP kinases that is distinct from the kinases that synthesize PtdIns(4,5)P₂. Consistent with this, we find that unlike wild-type cells, fab1Δ, fab1^tsf, and fab1 kinase domain point mutants lack detectable levels of PtdIns(3,5)P₂, a phosphoinositide recently identified both in yeast and mammalian cells. PtdIns(4,5)P₂ synthesis, on the other hand, is only moderately affected even in fab1Δ mutants. The presence of PtdIns(3)P in fab1 mutants, combined with previous data, indicate that PtdIns(3,5)P₂ synthesis is a two step process, requiring the production of PtdIns(3)P by the Vps34p PtdIns 3-kinase and the subsequent Fab1p- dependent phosphorylation of PtdIns(3)P yielding PtdIns(3,5)P₂. Although Vps34p-mediated synthesis of PtdIns(3)P is required for the proper sorting of hydrolases from the Golgi to the vacuole, the production of PtdIns(3,5)P₂ by Fab1p does not directly affect Golgi to vacuole trafficking, suggesting that PtdIns(3,5)P₂ has a distinct function. The major phenotypes resulting from Fab1p kinase inactivation include temperature-sensitive growth, vacuolar acidification defects, and dramatic increases in vacuolar size. Based on our studies, we hypothesize that whereas Vps34p is essential for anterograde trafficking of membrane and protein cargoes to the vacuole, Fab1p may play an important compensatory role in the recycling/turnover of membranes deposited at the vacuole. Interestingly, deletion of VAC7 also results in an enlarged vacuole morphology and has no detectable PtdIns(3,5)P₂, suggesting that Vac7p functions as an upstream regulator, perhaps in a complex with Fab1p. We propose that Fab1p and Vac7p are components of a signal transduction pathway which functions to regulate the efflux or turnover of vacuolar membranes through the regulated production of PtdIns(3,5)P₂.     

Deletion of Vacuolar Proton-translocating ATPase Voa Isoforms Clarifies the Role of Vacuolar pH as a Determinant of Virulence-associated Traits in Candida albicans

Vacuolar proton-translocating ATPase (V-ATPase) is a central regulator of cellular pH homeostasis, and inactivation of all V-ATPase function has been shown to prevent infectivity in Candida albicans. V-ATPase subunit a of the V_o domain (V_oa) is present as two fungal isoforms: Stv1p (Golgi) and Vph1p (vacuole). To delineate the individual contribution of Stv1p and Vph1p to C. albicans physiology, we created stv1Δ/Δ and vph1Δ/Δ mutants and compared them to the corresponding reintegrant strains (stv1Δ/ΔR and vph1Δ/ΔR). V-ATPase activity, vacuolar physiology, and in vitro virulence-related phenotypes were unaffected in the stv1Δ/Δ mutant. The vph1Δ/Δ mutant exhibited defective V₁V_o assembly and a 90% reduction in concanamycin A-sensitive ATPase activity and proton transport in purified vacuolar membranes, suggesting that the Vph1p isoform is essential for vacuolar V-ATPase activity in C. albicans. The vph1Δ/Δ cells also had abnormal endocytosis and vacuolar morphology and an alkalinized vacuolar lumen (pH_vph1Δ_/Δ = 6.8 versus pH_vph1Δ_/Δ_R = 5.8) in both yeast cells and hyphae. Secreted protease and lipase activities were significantly reduced, and M199-induced filamentation was impaired in the vph1Δ/Δ mutant. However, the vph1Δ/Δ cells remained competent for filamentation induced by Spider media and YPD, 10% FCS, and biofilm formation and macrophage killing were unaffected in vitro. These studies suggest that different virulence mechanisms differentially rely on acidified vacuoles and that the loss of both vacuolar (Vph1p) and non-vacuolar (Stv1p) V-ATPase activity is necessary to affect in vitro virulence-related phenotypes. As a determinant of C. albicans pathogenesis, vacuolar pH alone may prove less critical than originally assumed.     

Essential Role for Vacuolar Acidification in Candida albicans Virulence

Fungal infections are on the rise, with mortality above 30% in patients with septic Candida infections. Mutants lacking V-ATPase activity are avirulent and fail to acidify endomembrane compartments, exhibiting pleiotropic defects in secretory, endosomal, and vacuolar pathways. However, the individual contribution of organellar acidification to virulence and its associated traits is not known. To dissect their separate roles in Candida albicans pathogenicity we generated knock-out strains for the V₀ subunit a genes VPH1 and STV1, which target the vacuole and secretory pathway, respectively. While the two subunits were redundant in many vma phenotypes, such as alkaline pH sensitivity, calcium homeostasis, respiratory defects, and cell wall integrity, we observed a unique contribution of VPH1. Specifically, vph1Δ was defective in acidification of the vacuole and its dependent functions, such as metal ion sequestration as evidenced by hypersensitivity to Zn²⁺ toxicity, whereas stv1Δ resembled wild type. In growth conditions that elicit morphogenic switching, vph1Δ was defective in forming hyphae whereas stv1Δ was normal or only modestly impaired. Host cell interactions were evaluated in vitro using the Caco-2 model of intestinal epithelial cells, and murine macrophages. Like wild type, stv1Δ was able to inflict cellular damage in Caco-2 and macrophage cells, as assayed by LDH release, and escape by filamentation. In contrast, vph1Δ resembled a vma7Δ mutant, with significant attenuation in host cell damage. Finally, we show that VPH1 is required for fungal virulence in a murine model of systemic infection. Our results suggest that vacuolar acidification has an essential function in the ability of C. albicans to form hyphae and establish infection.     

Vac14 controls PtdIns(3,5)P(2) synthesis and Fab1-dependent protein trafficking to the multivesicular body

BACKGROUND: The PtdIns3P 5-kinase Fab1 makes PtdIns(3,5)P(2), a phosphoinositide essential for retrograde trafficking between the vacuole/lysosome and the late endosome and also for trafficking of some proteins into the vacuole via multivesicular bodies (MVB). No regulators of Fab1 were identified until recently. RESULTS: Visual screening of the Eurofan II panel of S. cerevisiae deletion mutants identified YLR386w as a novel regulator of vacuolar function. Others recently identified this ORF as encoding the vacuolar inheritance gene VAC14. Like fab1 mutants, yeast lacking Vac14 have enlarged vacuoles that do not acidify correctly. FAB1 overexpression corrects these defects. vac14Delta cells make very little PtdIns(3,5)P(2), and hyperosmotic shock does not stimulate PtdIns(3,5)P(2) synthesis in the normal manner, implicating Vac14 in Fab1 regulation. We also show that, like fab1Delta mutants, vac14Delta cells fail to sort GFP-Phm5 to the MVB and thence to the vacuole: irreversible ubiquitination of GFP-Phm5 overcomes this defect. In the BY4742 genetic background, loss of Vac14 causes much more penetrant effects on phosphoinositide metabolism and vacuolar trafficking than does loss of Vac7, another regulator of Fab1. Vac14 contains motifs suggestive of a role in protein trafficking and interacts with several proteins involved in clathrin-mediated membrane sorting and phosphoinositide metabolism. CONCLUSIONS: Vac14 and Vac7 are both upstream activators of Fab1-catalysed PtdIns(3,5)P(2) synthesis, with Vac14 the dominant contributor to the hierarchy of control. Vac14 is essential for the regulated synthesis of PtdIns(3,5)P(2), for control of trafficking of some proteins to the vacuole lumen via the MVB, and for maintenance of vacuole size and acidity.     

Phosphatidylinositol 3,5‐Bisphosphate‐Rich Membrane Domains in Endosomes and Lysosomes

Phosphatidylinositol 3,5‐bisphosphate (PtdIns(3,5)P₂) has critical functions in endosomes and lysosomes. We developed a method to define nanoscale distribution of PtdIns(3,5)P₂ using freeze‐fracture electron microscopy. GST‐ATG18‐4×FLAG was used to label PtdIns(3,5)P₂ and its binding to phosphatidylinositol 3‐phosphate (PtdIns(3)P) was blocked by an excess of the p40^phox PX domain. In yeast exposed to hyperosmotic stress, PtdIns(3,5)P₂ was concentrated in intramembrane particle (IMP)‐deficient domains in the vacuolar membrane, which made close contact with adjacent membranes. The IMP‐deficient domain was also enriched with PtdIns(3)P, but was deficient in Vph1p, a liquid‐disordered domain marker. In yeast lacking either PtdIns(3,5)P₂ or its effector, Atg18p, the IMP‐deficient, PtdIns(3)P‐rich membranes were folded tightly to make abnormal tubular structures, thus showing where the vacuolar fragmentation process is arrested when PtdIns(3,5)P₂ metabolism is defective. In HeLa cells, PtdIns(3,5)P₂ was significantly enriched in the vesicular domain of RAB5‐ and RAB7‐positive endosome/lysosomes of the tubulo‐vesicular morphology. This biased distribution of PtdIns(3,5)P₂ was also observed using fluorescence microscopy, which further showed enrichment of a retromer component, VPS35, in the tubular domain. This is the first report to show segregation of PtdIns(3,5)P₂‐rich and ‐deficient domains in endosome/lysosomes, which should be important for endosome/lysosome functionality.      

Arabidopsis FAB1/PIKfyve Proteins Are Essential for Development of Viable Pollen

Phosphatidylinositol 3,5-bisphosphate [PtdIns(3,5)P₂] is a phospholipid that has a role in controlling membrane trafficking events in yeast and animal cells. The function of this lipid in plants is unknown, although its synthesis has been shown to be up-regulated upon osmotic stress in plant cells. PtdIns(3,5)P₂ is synthesized by the PIKfyve/Fab1 family of proteins, with two orthologs, FAB1A and FAB1B, being present in Arabidopsis (Arabidopsis thaliana). In this study, we attempt to address the role of this lipid by analyzing the phenotypes of plants mutated in FAB1A and FAB1B. It was not possible to generate plants homozygous for mutations in both genes, although single mutants were isolated. Both homozygous single mutant plant lines exhibited a leaf curl phenotype that was more marked in FAB1B mutants. Genetic transmission analysis revealed that failure to generate double mutant lines was entirely due to inviability of pollen carrying mutant alleles of both FAB1A and FAB1B. This pollen displayed severe defects in vacuolar reorganization following the first mitotic division of development. The presence of abnormally large vacuoles in pollen at the tricellular stage resulted in the collapse of the majority of grains carrying both mutant alleles. This demonstrates a crucial role for PtdIns(3,5)P₂ in modulating the dynamics of vacuolar rearrangement essential for successful pollen development. Taken together, our results are consistent with PtdIns(3,5)P₂ production being central to cellular responses to changes in osmotic conditions.Phosphoinositides make up a minor fraction of total membrane lipids in all eukaryotic organisms. Their production is spatially restricted to the cytoplasmic leaflet of specific organellar membranes and temporally regulated by phosphatidylinositol (PtdIns) kinases and phosphatases. Three of the five hydoxyl groups of PtdIns can be phosphorylated, either singly or combinatorially, to produce seven different phosphoinositides. These different phosphoinositides can recruit and/or activate proteins with specific phosphoinositide-binding domains and have been implicated in the regulation of many important cellular functions, including membrane trafficking, cell growth, and cytoskeleton remodeling (Di Paolo and De Camilli, 2006).In animal cells, phosphorylation at the 3 position of PtdIns and its phosphorylated derivatives can be carried out by three different classes of PtdIns 3-kinase (classes I–III; Cantley, 2002). Plants and yeast only have class III PtdIns 3-kinases that are orthologs of the Saccharomyces cerevisiae protein Vps34p (Mueller-Roeber and Pical, 2002). Vps34p orthologs are thought to use PtdIns as their sole lipid substrate and produce PtdIns 3-phosphate (PtdIns3P). PtdIns3P is involved in endosomal/lysosomal protein sorting in eukaryotic cells in addition to cellular signaling events (Backer, 2008).In plants, PtdIns3P is essential for normal growth and development. Arabidopsis (Arabidopsis thaliana) plants carrying a VPS34 antisense construct have severe developmental defects (Welters et al., 1994). Furthermore, using pharmacological inhibitors of PtdIns3P production and analysis of transgenic plants defective in downstream signaling from PtdIns3P, it has been shown that this lipid has a role to play in many diverse physiological processes, such as root hair growth (Lee et al., 2008a). The phenotypes observed in studies of PtdIns3P function in plants are consistent with a role in endosomal and vacuolar trafficking in plants (Kim et al., 2001; Lee et al., 2008a), as in other eukaryotes. Recently, an attempt to generate vps34 homozygous mutant plant lines was unsuccessful due to failure of the mutant vps34 allele to transmit through the male germ line (Lee et al., 2008b).Importantly, PtdIns3P is the precursor to another phosphoinositide, PtdIns 3,5-bisphosphate [PtdIns(3,5)P₂], which also has vital roles in endosomal trafficking in eukaryotes (Dove et al., 2009). Thus, it is possible that some of the effects in plants attributed to PtdIns3P in previous studies may actually be due to an inability of cells to produce PtdIns(3,5)P₂. PtdIns(3,5)P₂ is produced by the PtdIns3P 5-kinases PIKfyve and Fab1p in animal and yeast cells, respectively. PIKfyve/Fab1p proteins have an N-terminal FYVE domain necessary for binding to PtdIns3P-containing membranes, a central Cpn60_TCP1 (for HSP chaperonin T complex 1) homology domain, and a C-terminal kinase domain. In Arabidopsis, there are a number of genes encoding putative Fab1p homologs, but only two of them, FAB1A (At4g33240) and FAB1B (At3g14270), encode proteins having FYVE domains at their N termini (Mueller-Roeber and Pical, 2002). It is likely that these proteins are PtdIns3P 5-kinases in Arabidopsis. Despite the importance of PtdIns(3,5)P₂ in yeast and animals, very little is known about its function in plants. However, it has been shown that hyperosmotic stress can induce the rapid synthesis of PtdIns(3,5)P₂ in cell suspension cultures from a number of plant species (Meijer and Munnik, 2003) and in pollen tubes from tobacco (Nicotiana tabacum; Zonia and Munnik, 2004). This production is consistent with a requirement for PtdIns(3,5)P₂ in vacuolar membrane reorganization, as water moves from the vacuole to the cytosol upon cells being placed under hyperosmotic stress. In animal cells, defective PtdIns(3,5)P₂ production leads to cytoplasmic vacuolation of endosome-derived membranes (Ikonomov et al., 2001; Jefferies et al., 2008). It seems that there is a general requirement in all eukaryotes for PtdIns(3,5)P₂ production in endomembrane remodeling. This remodeling could be mediated by proteins that bind to PtdIns(3,5)P₂. A number of candidates have been identified, including yeast Svp1p (Dove et al., 2004), its mammalian homolog WIP149 (Jeffries et al., 2004), CHMP3 (Whitley et al., 2003), and Ent3p (Friant et al., 2003).In this study, we aimed to further investigate the role of PtdIns(3,5)P₂ in plant physiology and the function of PIKfyve/Fab1p orthologs in Arabidopsis by generating mutant plant lines homozygous for T-DNA insertions in both FAB1A and FAB1B. We failed to generate double homozygous fab1a/fab1b knockout plants but observed subtle phenotypes in both fab1a and fab1b single homozygous plants. The data show that pollen with a fab1a/fab1b genotype has an abnormal vacuolar phenotype and does not contribute to the next generation. Our data are consistent with the hypothesis that the male gametophytic defect observed in vps34 mutant pollen (Lee et al., 2008b) is due to an inability of this pollen to generate PtdIns(3,5)P₂ and is not a direct result of the lack of PtdIns3P.     

Assembly of a Fab1 phosphoinositide kinase signaling complex requires the Fig4 phosphoinositide phosphatase

Phosphatidylinositol-3,5-bisphosphate [PtdIns(3,5)P₂] regulates several vacuolar functions, including acidification, morphology, and membrane traffic. The lipid kinase Fab1 converts phosphatidylinositol-3-phosphate [PtdIns(3)P] to PtdIns(3,5)P₂. PtdIns(3,5)P₂ levels are controlled by the adaptor-like protein Vac14 and the Fig4 PtdIns(3,5)P₂-specific 5-phosphatase. Interestingly, Vac14 and Fig4 serve a dual function: they are both implicated in the synthesis and turnover of PtdIns(3,5)P₂ by an unknown mechanism. We now show that Fab1, through its chaperonin-like domain, binds to Vac14 and Fig4 and forms a vacuole-associated signaling complex. The Fab1 complex is tethered to the vacuole via an interaction between the FYVE domain in Fab1 and PtdIns(3)P on the vacuole. Moreover, Vac14 and Fig4 bind to each other directly and are mutually dependent for interaction with the Fab1 kinase. Our observations identify a protein complex that incorporates the antagonizing Fab1 lipid kinase and Fig4 lipid phosphatase into a common functional unit. We propose a model explaining the dual roles of Vac14 and Fig4 in the synthesis and turnover of PtdIns(3,5)P₂.     

Arabidopsis FAB1A/B is possibly involved in the recycling of auxin transporters

Fab1/PIKfyve produces Phosphatidylinositol-3,5-bisphosphate (PtdIns (3,5) P₂) from Phosphatidylinositol-3-phosphate (PtdIns 3-P), and is involved not only in vacuole/lysosome homeostasis, but also in transporting various proteins to the vacuole or recycling proteins on the plasma membrane (PM) through the use of endosomes in a variety of eukaryotic cells. We previously demonstrated that Arabidopsis FAB1A/B functions as PtdIns-3,5-kinase in both Arabidopsis and fission yeast and plays a key role in vacuolar acidification and endocytosis. Although the conditional FAB1A/B knockdown mutant revealed an auxin-resistant phenotype to a membrane-impermeable auxin, 2,4-dichlorophenoxyacetic acid (2,4-D), the mutant did not exhibit this phenotype to a membrane-permeable artificial auxin, naphthalene 1-acetic acid (NAA). The difference in the sensitivities to 2,4-D and NAA is similar to those of the auxin-resistant mutants such as aux1. Taken together, these results suggest that impairment of the function of Arabidopsis FAB1A/B might cause a defect in the membrane recycling capabilities of the auxin transporters and inhibit proper auxin transport into the cells in Arabidopsis.Key words: auxin signaling, auxin transporter, recycling of plasma membrane proteinsPhosphatidylinositol-3,5-bisphosphate (PtdIns (3,5) P₂) exists on the external membrane of multi-vesicular bodies (MVBs) at very low levels in eukaryotic cells,^1,2 and plays key roles in endomembrane homeostasis including endocytosis, vacuole/lysosome formation and vacuolar acidification.^1,3 PtdIns (3,5) P₂ deficiency causes an enlarged vacuolar structure in yeast and mammalian cells.^4,5 FAB1 forms a protein complex with its regulatory molecules, and synthesizes PtdIns (3,5) P₂ from PtdIns 3P.^6–9 In Arabidopsis, there are four Fab1/PIKfyve orthologs (FAB1A, FAB1B, FAB1C and FAB1D) in the genome, and the double homozygous mutant of FAB1A and FAB1B exhibited the male gametophyte lethal phenotype.¹⁰ Previously, we reported that conditional loss-of-function and gain-of-function mutants of FAB1A/B impair endomembrane homeostasis and reveal various developmental phenotypes.¹¹ Interestingly, lateral root formation by exogenous auxin, which is known as a typical auxin-responsive phenotype, was largely impaired when FAB1A/B expression was conditionally downregulated or upregulated. From these results, we speculated that the defect in the endocytosis process in fab1a/b mutants might inhibit the precise recycling process of auxin transporters on the PM, thereby inhibiting proper auxin transport into the plant cells.¹¹ In this report, we tested this hypothesis to assess the sensitivity on auxin-dependent lateral root formation to a membrane permeable auxin, NAA, in the fab1a/b knockdown mutant.     

Osh6 links yeast vacuolar functions to lifespan extension and TOR

Comment on: Gebre S, et al. Cell Cycle 2012; 11:2176-88.Almost all organisms age–the aging process is both genetically determined and can be modified by the environment. Lifespan extension by dietary restriction (DR) is observed in evolutionarily distant species from yeast to mammals. Not only are the phenomena of aging and DR conserved, but at least some mechanisms and genes are evolutionarily conserved, which may pave the way to manipulate human aging.¹ For example, TOR (target of rapamycin) mediates aging and, when suppressed, triggers anti-aging processes in many species. Moreover, identifying genes that modulate the potential for cell division is of great interest, given that changes in the number of times that cells divide have been associated with longevity manipulations in mammals (including DR).²Sterols are hydrophobic molecules present in all cellular organisms. For instance, cholesterol is an essential structural component of cellular membranes of mammals and several of its derivates have additional hormonal and signaling functions. Oxysterols are oxygenated derivates of cholesterol. Oxysterol-binding protein (OSBP)-related protein (ORP) family members are present in numerous copies from yeast to man, suggesting that this protein family has fundamental functions in eukaryotes. OSBP and ORPs regulate lipid metabolism, vesicle transport and various signaling pathways³ and may specifically mediate lipid exchange at membrane contact sites.The lifespan-extending effect of DR has often been shown to be mediated by specific genes and to be accompanied by discrete changes in gene expression as well as metabolic reprogramming. Both lipid metabolism and cellular recycling activities have been demonstrated to be essential for lifespan extension in numerous species. For example, DR suppresses sterol synthesis from yeast to mammals,⁴ while it induces some form of autophagy, a mighty housekeeping mechanism utilizing lysosomes within its power to recycle various kinds of molecules and cellular structures. Vacuoles, the yeast equivalent of mammalian lysosomes, are highly dynamic organelles that fuse and divide in response to environmental or intrinsic cues. Mutants with defects in vacuolar fusion (such as ypt7Δ, nyv1Δ, vac8Δ, or erg6Δ) are either short-lived or do not appear to respond to DR.⁵While mammals have 12 OSBPs, the yeast genome encodes seven oxysterol-binding protein sequence homologs (OSH). Deletion of any OSH gene alone does not impact on vacuolar morphology, yet deletion of all results in highly fragmented vacuoles, a sign of defective vacuole fusion. Gebre et al. now show that overexpression of OSH family member OSH6 in yeast can complement the vacuole fusion defect of nyv1Δ but not erg6Δ or vac8Δ. Thus, Osh6 mediates vacuolar fusion, which depends on ergosterol (Erg6), and the protein anchor Vac8. In contrast, overexpression of another OSH-family member, OSH5, exacerbated fragmentation and decreased lifespan in wild-type cells. It is interesting to note that OSH5 expression progressively increases with age, and Osh6 overexpression blocked this age-dependent change in OSH5 levels. Also, elevated Osh6 maintains the enrichment of Vac8 in microdomains of vacuolar membranes with advancing age, which is required for vacuole fusion. Intriguingly, exactly at the age when the longevity protein Sir2 declines, Osh6 protein levels also decline.⁶Furthermore, Gebre et al. showed that P_ERG6-OSH6 (ERG6 promoter driving OSH6 overexpression) dramatically extends the lifespan of wild-type and nyv1Δ mutants. tor1Δ mutants are also long-lived, though not so long as P_ERG6-OSH6. Surprisingly, P_ERG6-OSH6 tor1Δ double mutant had a very short lifespan. P_ERG6-OSH6 mutants were more sensitive to TOR inhibitors, indicating that TOR is less active in this strain.⁶ OSH6 overexpression downregulates total cellular sterol levels, just like DR. Osh6 binds PI3P and PI(3,5)P2 which are vacuole-specific lipids.⁷ As such, Osh6 might promote vacuole fusion by regulating the transports and/or distribution of sterols to the vacuolar membranes. But where are the sterols coming from? Numerous overexpression mutants with effects in vacuolar morphology are involved in endocytosis.⁸ Similarly, Osh6’s coiled-coil domain interacts with Vps4, which is located in endosomes. TOR complex 1 (TORC1) also sits on endosomes as well as on vacuoles and actively catalyzes vacuolar scission.⁹ Osh6 may therefore (1) transport sterols from late endosomes to the vacuolar membrane (Fig. 1), which increases the homototypic fusion ability of vacuoles, and (2) averaging the lipids between late endosome and vacuoles promotes also late-endosome-to-vacuole fusion.Open in a separate windowFigure 1. Putative mechanism of the lifespan extension conferred by Osh6 overexpression. TORC1 promotes vacuolar scission and therefore fragments vacuoles. In contrast, Osh6 enhances vacuolar fusion and might be doing this by transporting sterols from the endosomes to the vacuolar membrane. Improved vacuolar morphology then promotes autophagy. Thus, Osh6 appears to counteract TORC1 activity.Overall, Gebre and colleagues link the vacuole to lifespan extension, perhaps via TOR, and reveal that vacuole fusion is both necessary and sufficient for lifespan extension.     

Identification of inhibitors of vacuolar proton-translocating ATPase pumps in yeast by high-throughput screening flow cytometry

Fluorescence intensity of the pH-sensitive carboxyfluorescein derivative 2,7-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) was monitored by high-throughput flow cytometry in living yeast cells. We measured fluorescence intensity of BCECF trapped in yeast vacuoles, acidic compartments equivalent to lysosomes where vacuolar proton-translocating ATPases (V-ATPases) are abundant. Because V-ATPases maintain a low pH in the vacuolar lumen, V-ATPase inhibition by concanamycin A alkalinized the vacuole and increased BCECF fluorescence. Likewise, V-ATPase-deficient mutant cells had greater fluorescence intensity than wild-type cells. Thus, we detected an increase of fluorescence intensity after short- and long-term inhibition of V-ATPase function. We used yeast cells loaded with BCECF to screen a small chemical library of structurally diverse compounds to identify V-ATPase inhibitors. One compound, disulfiram, enhanced BCECF fluorescence intensity (although to a degree beyond that anticipated for pH changes alone in the mutant cells). Once confirmed by dose-response assays (EC₅₀ = 26 μM), we verified V-ATPase inhibition by disulfiram in secondary assays that measured ATP hydrolysis in vacuolar membranes. The inhibitory action of disulfiram against V-ATPase pumps revealed a novel effect previously unknown for this compound. Because V-ATPases are highly conserved, new inhibitors identified could be used as research and therapeutic tools in cancer, viral infections, and other diseases where V-ATPases are involved.     

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

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.     

Atg18 regulates organelle morphology and Fab1 kinase activity independent of its membrane recruitment by phosphatidylinositol 3,5-bisphosphate

The lipid kinase Fab1 governs yeast vacuole homeostasis by generating PtdIns(3,5)P(2) on the vacuolar membrane. Recruitment of effector proteins by the phospholipid ensures precise regulation of vacuole morphology and function. Cells lacking the effector Atg18p have enlarged vacuoles and high PtdIns(3,5)P(2) levels. Although Atg18 colocalizes with Fab1p, it likely does not directly interact with Fab1p, as deletion of either kinase activator-VAC7 or VAC14-is epistatic to atg18Delta: atg18Deltavac7Delta cells have no detectable PtdIns(3,5)P(2). Moreover, a 2xAtg18 (tandem fusion) construct localizes to the vacuole membrane in the absence of PtdIns(3,5)P(2), but requires Vac7p for recruitment. Like the endosomal PtdIns(3)P effector EEA1, Atg18 membrane binding may require a protein component. When the lipid requirement is bypassed by fusing Atg18 to ALP, a vacuolar transmembrane protein, vac14Delta vacuoles regain normal morphology. Rescue is independent of PtdIns(3,5)P(2), as mutation of the phospholipid-binding site in Atg18 does not prevent vacuole fission and properly regulates Fab1p activity. Finally, the vacuole-specific type-V myosin adapter Vac17p interacts with Atg18p, perhaps mediating cytoskeletal attachment during retrograde transport. Atg18p is likely a PtdIns(3,5)P(2)"sensor," acting as an effector to remodel membranes as well as regulating its synthesis via feedback that might involve Vac7p.     

Rapid Structural Changes and Acidification of Guard Cell Vacuoles during Stomatal Closure Require Phosphatidylinositol 3,5-Bisphosphate

Rapid stomatal closure is essential for water conservation in plants and is thus critical for survival under water deficiency. To close stomata rapidly, guard cells reduce their volume by converting a large central vacuole into a highly convoluted structure. However, the molecular mechanisms underlying this change are poorly understood. In this study, we used pH-indicator dyes to demonstrate that vacuolar convolution is accompanied by acidification of the vacuole in fava bean (Vicia faba) guard cells during abscisic acid (ABA)–induced stomatal closure. Vacuolar acidification is necessary for the rapid stomatal closure induced by ABA, since a double mutant of the vacuolar H⁺-ATPase vha-a2 vha-a3 and vacuolar H⁺-PPase mutant vhp1 showed delayed stomatal closure. Furthermore, we provide evidence for the critical role of phosphatidylinositol 3,5-bisphosphate [PtdIns(3,5)P₂] in changes in pH and morphology of the vacuole. Single and double Arabidopsis thaliana null mutants of phosphatidylinositol 3-phosphate 5-kinases (PI3P5Ks) exhibited slow stomatal closure upon ABA treatment compared with the wild type. Moreover, an inhibitor of PI3P5K reduced vacuolar acidification and convolution and delayed stomatal closure in response to ABA. Taken together, these results suggest that rapid ABA-induced stomatal closure requires PtdIns(3,5)P₂, which is essential for vacuolar acidification and convolution.     

Yeast Phosphofructokinase-1 Subunit Pfk2p Is Necessary for pH Homeostasis and Glucose-dependent Vacuolar ATPase Reassembly

V-ATPases are conserved ATP-driven proton pumps that acidify organelles. Yeast V-ATPase assembly and activity are glucose-dependent. Glucose depletion causes V-ATPase disassembly and its inactivation. Glucose readdition triggers reassembly and resumes proton transport and organelle acidification. We investigated the roles of the yeast phosphofructokinase-1 subunits Pfk1p and Pfk2p for V-ATPase function. The pfk1Δ and pfk2Δ mutants grew on glucose and assembled wild-type levels of V-ATPase pumps at the membrane. Both phosphofructokinase-1 subunits co-immunoprecipitated with V-ATPase in wild-type cells; upon deletion of one subunit, the other subunit retained binding to V-ATPase. The pfk2Δ cells exhibited a partial vma growth phenotype. In vitro ATP hydrolysis and proton transport were reduced by 35% in pfk2Δ membrane fractions; they were normal in pfk1Δ. In vivo, the pfk1Δ and pfk2Δ vacuoles were alkalinized and the cytosol acidified, suggestive of impaired V-ATPase proton transport. Overall the pH alterations were more dramatic in pfk2Δ than pfk1Δ at steady state and after readdition of glucose to glucose-deprived cells. Glucose-dependent reassembly was 50% reduced in pfk2Δ, and the vacuolar lumen was not acidified after reassembly. RAVE-assisted glucose-dependent reassembly and/or glucose signals were disturbed in pfk2Δ. Binding of disassembled V-ATPase (V₁ domain) to its assembly factor RAVE (subunit Rav1p) was 5-fold enhanced, indicating that Pfk2p is necessary for V-ATPase regulation by glucose. Because Pfk1p and Pfk2p are necessary for V-ATPase proton transport at the vacuole in vivo, a role for glycolysis at regulating V-ATPase proton transport is discussed.     

Regulation of Fab1 phosphatidylinositol 3-phosphate 5-kinase pathway by Vac7 protein and Fig4, a polyphosphoinositide phosphatase family member

The Saccharomyces cerevisiae FAB1 gene encodes the sole phosphatidylinositol 3-phosphate [PtdIns(3)P] 5-kinase responsible for synthesis of the polyphosphoinositide PtdIns(3,5)P(2). VAC7 encodes a 128-kDa transmembrane protein that localizes to vacuolar membranes. Both vac7 and fab1 null mutants have dramatically enlarged vacuoles and cannot grow at elevated temperatures. Additionally, vac7Delta mutants have nearly undetectable levels of PtdIns(3,5)P(2), suggesting that Vac7 functions to regulate Fab1 kinase activity. To test this hypothesis, we isolated a fab1 mutant allele that bypasses the requirement for Vac7 in PtdIns(3,5)P(2) production. Expression of this fab1 allele in vac7Delta mutant cells suppresses the temperature sensitivity, vacuolar morphology, and PtdIns(3,5)P(2) defects normally exhibited by vac7Delta mutants. We also identified a mutant allele of FIG4, whose gene product contains a Sac1 polyphosphoinositide phosphatase domain, which suppresses vac7Delta mutant phenotypes. Deletion of FIG4 in vac7Delta mutant cells suppresses the temperature sensitivity and vacuolar morphology defects, and dramatically restores PtdIns(3,5)P(2) levels. These results suggest that generation of PtdIns(3,5)P(2) by the Fab1 lipid kinase is regulated by Vac7, whereas turnover of PtdIns(3,5)P(2) is mediated in part by the Sac1 polyphosphoinositide phosphatase family member Fig4.     

Loss-of-function and gain-of-function mutations in FAB1A/B impair endomembrane homeostasis, conferring pleiotropic developmental abnormalities in Arabidopsis

In eukaryotic cells, PtdIns 3,5-kinase, Fab1/PIKfyve produces PtdIns (3,5) P(2) from PtdIns 3-P, and functions in vacuole/lysosome homeostasis. Herein, we show that expression of Arabidopsis (Arabidopsis thaliana) FAB1A/B in fission yeast (Schizosaccharomyces pombe) fab1 knockout cells fully complements the vacuole morphology phenotype. Subcellular localizations of FAB1A and FAB1B fused with green fluorescent protein revealed that FAB1A/B-green fluorescent proteins localize to the endosomes in root epidermal cells of Arabidopsis. Furthermore, reduction in the expression levels of FAB1A/B by RNA interference impairs vacuolar acidification and endocytosis. These results indicate that Arabidopsis FAB1A/B functions as PtdIns 3,5-kinase in plants and in fission yeast. Conditional knockdown mutant shows various phenotypes including root growth inhibition, hyposensitivity to exogenous auxin, and disturbance of root gravitropism. These phenotypes are observed also in the overproducing mutants of FAB1A and FAB1B. The overproducing mutants reveal additional morphological phenotypes including dwarfism, male-gametophyte sterility, and abnormal floral organs. Taken together, this evidence indicates that imbalanced expression of FAB1A/B impairs endomembrane homeostasis including endocytosis, vacuole formation, and vacuolar acidification, which causes pleiotropic developmental phenotypes mostly related to the auxin signaling in Arabidopsis.     

Osmotic stress-induced increase of phosphatidylinositol 3,5-bisphosphate requires Vac14p, an activator of the lipid kinase Fab1p

Phosphatidylinositol 3,5-bisphosphate (PtdIns[3,5]P(2)) was first identified as a non-abundant phospholipid whose levels increase in response to osmotic stress. In yeast, Fab1p catalyzes formation of PtdIns(3,5)P(2) via phosphorylation of PtdIns(3)P. We have identified Vac14p, a novel vacuolar protein that regulates PtdIns(3,5)P(2) synthesis by modulating Fab1p activity in both the absence and presence of osmotic stress. We find that PtdIns(3)P levels are also elevated in response to osmotic stress, yet, only the elevation of PtdIns(3,5)P(2) levels are regulated by Vac14p. Under basal conditions the levels of PtdIns(3,5)P(2) are 18-28-fold lower than the levels of PtdIns(3)P, PtdIns(4)P, and PtdIns(4,5)P(2). After a 10 min exposure to hyperosmotic stress the levels of PtdIns(3,5)P(2) rise 20-fold, bringing it to a cellular concentration that is similar to the other phosphoinositides. This suggests that PtdIns(3,5)P(2) plays a major role in osmotic stress, perhaps via regulation of vacuolar volume. In fact, during hyperosmotic stress the vacuole morphology of wild-type cells changes dramatically, to smaller, more highly fragmented vacuoles, whereas mutants unable to synthesize PtdIns(3,5)P(2) continue to maintain a single large vacuole. These findings demonstrate that Vac14p regulates the levels of PtdIns(3,5)P(2) and provide insight into why PtdIns(3,5)P(2) levels rise in response to osmotic stress.     

Genome-wide Analysis of AP-3–dependent Protein Transport in Yeast

The evolutionarily conserved adaptor protein-3 (AP-3) complex mediates cargo-selective transport to lysosomes and lysosome-related organelles. To identify proteins that function in AP-3–mediated transport, we performed a genome-wide screen in Saccharomyces cerevisiae for defects in the vacuolar maturation of alkaline phosphatase (ALP), a cargo of the AP-3 pathway. Forty-nine gene deletion strains were identified that accumulated precursor ALP, many with established defects in vacuolar protein transport. Maturation of a vacuolar membrane protein delivered via a separate, clathrin-dependent pathway, was affected in all strains except those with deletions of YCK3, encoding a vacuolar type I casein kinase; SVP26, encoding an endoplasmic reticulum (ER) export receptor for ALP; and AP-3 subunit genes. Subcellular fractionation and fluorescence microscopy revealed ALP transport defects in yck3Δ cells. Characterization of svp26Δ cells revealed a role for Svp26p in ER export of only a subset of type II membrane proteins. Finally, ALP maturation kinetics in vac8Δ and vac17Δ cells suggests that vacuole inheritance is important for rapid generation of proteolytically active vacuolar compartments in daughter cells. We propose that the cargo-selective nature of the AP-3 pathway in yeast is achieved by AP-3 and Yck3p functioning in concert with machinery shared by other vacuolar transport pathways.     

Genes Required for Vacuolar Acidity in Saccharomyces Cerevisiae

Mutations that cause loss of acidity in the vacuole (lysosome) of Saccharomyces cerevisiae were identified by screening colonies labeled with the fluorescent, pH-sensitive, vacuolar labeling agent, 6-carboxyfluorescein. Thirty nine vacuolar pH (Vph-) mutants were identified. Four of these contained mutant alleles of the previously described PEP3, PEP5, PEP6 and PEP7 genes. The remaining mutants defined eight complementation groups of vph mutations. No alleles of the VAT2 or TFP1 genes (known to encode subunits of the vacuolar H(+)-ATPase) were identified in the Vph- screen. Strains bearing mutations in any of six of the VPH genes failed to grow on medium buffered at neutral pH; otherwise, none of the vph mutations caused notable growth inhibition on standard yeast media. Expression of the vacuolar protease, carboxypeptidase Y, was defective in strains bearing vph4 mutations but was apparently normal in strains bearing any of the other vph mutations. Defects in vacuolar morphology at the light microscope level were evident in all Vph- mutants. Strains that contained representative mutant alleles of the 17 previously described PEP genes were assayed for vacuolar pH; mutations in seven of the PEP genes (including PEP3, PEP5, PEP6 and PEP7) caused loss of vacuolar acidity.     

Complementation analysis in PtdInsP kinase-deficient yeast mutants demonstrates that Schizosaccharomyces pombe and murine Fab1p homologues are phosphatidylinositol 3-phosphate 5-kinases

Phosphatidylinositol 3,5-bisphosphate (PtdIns(3,5)P(2)) is widespread in eukaryotic cells. In Saccharomyces cerevisiae, PtdIns(3,5)P(2) synthesis is catalyzed by the PtdIns3P 5-kinase Fab1p, and loss of this activity results in vacuolar morphological defects, indicating that PtdIns(3,5)P(2) is essential for vacuole homeostasis. We have therefore suggested that all Fab1p homologues may be PtdIns3P 5-kinases involved in membrane trafficking. It is unclear which phosphatidylinositol phosphate kinases (PIPkins) are responsible for PtdIns(3,5)P(2) synthesis in higher eukaryotes. To clarify how PtdIns(3,5)P(2) is synthesized in mammalian and other cells, we determined whether yeast and mammalian Fab1p homologues or mammalian Type I PIPkins (PtdIns4P 5-kinases) make PtdIns(3,5)P(2) in vivo. The recently cloned murine (p235) and Schizosaccharomyces pombe FAB1 homologues both restored basal PtdIns(3,5)P(2) synthesis in Deltafab1 cells and made PtdIns(3,5)P(2) in vitro. Only p235 corrected the growth and vacuolar defects of fab1 S. cerevisiae. A mammalian Type I PIPkin supported no PtdIns(3,5)P(2) synthesis. Thus, FAB1 and its homologues constitute a distinct class of Type III PIPkins dedicated to PtdIns(3,5)P(2) synthesis. The differential abilities of p235 and of SpFab1p to complement the phenotypic defects of Deltafab1 cells suggests that interaction(s) with other protein factors may be important for spatial and/or temporal regulation of PtdIns(3,5)P(2) synthesis. These results also suggest that p235 may regulate a step in membrane trafficking in mammalian cells that is analogous to its function in yeast.