Assembly of the Yeast Vacuolar Proton-Translocating ATPase

The yeast vacuolar proton-translocating ATPase (V-ATPase) is the bestcharacterized member of the V-ATPase family. Biochemical and genetic screensled to the identification of a large number of genes in yeast, designatedVMA, encoding proteins required to assemble a functional V-ATPase. Atotal of thirteen genes encode subunits of the final enzyme complex. Inaddition to subunit-encoding genes, we have identified three genes that codefor proteins that are not part of the final V-ATPase complex yet required forits assembly. We refer to these nonsubunit Vma proteins as assembly factors,since their function is dedicated to assembling the V-ATPase. The assemblyfactors, Vma12p, Vma21p, and Vma22p are localized to the endoplasmicreticulum (ER) and aid the assembly of newly synthesized V-ATPase subunitsthat are translocated into the ER membrane. At least two of these proteins,Vma12p and Vma22p, function together in an assembly complex and interactdirectly with nascent V-ATPase subunits.     

Vma9p (subunit e) is an integral membrane V0 subunit of the yeast V-ATPase

The Saccharomyces cerevisiae vacuolar proton-translocating ATPase (V-ATPase) is composed of 14 subunits distributed between a peripheral V1 subcomplex and an integral membrane V0 subcomplex. Genome-wide screens have led to the identification of the newest yeast V-ATPase subunit, Vma9p. Vma9p (subunit e) is a small hydrophobic protein that is conserved from fungi to animals. We demonstrate that disruption of yeast VMA9 results in the failure of V1 and V0 V-ATPase subunits to assemble onto the vacuole and in decreased levels of the subunit a isoforms Vph1p and Stv1p. We also show that Vma9p is an integral membrane protein, synthesized and inserted into the endoplasmic reticulum (ER), which then localizes to the limiting membrane of the vacuole. All V0 subunits and V-ATPase assembly factors are required for Vma9p to efficiently exit the ER. In the ER, Vma9p and the V0 subunits interact with the V-ATPase assembly factor Vma21p. Interestingly, the association of Vma9p with the V0-Vma21p assembly complex is disrupted with the loss of any single V0 subunit. Similarly, Vma9p is required for V0 subunits Vph1p and Vma6p to associate with the V0-Vma21p complex. In contrast, the proteolipids associate with Vma21p even in the absence of Vma9p. These results demonstrate that Vma9p is an integral membrane subunit of the yeast V-ATPase V0 subcomplex and suggest a model for the arrangement of polypeptides within the V0 subcomplex.     

Structure and Assembly of the Yeast V-ATPase

The yeast V-ATPase belongs to a family of V-type ATPases present in all eucaryotic organisms. In Saccharomyces cerevisiae the V-ATPase is localized to the membrane of the vacuole as well as the Golgi complex and endosomes. The V-ATPase brings about the acidification of these organelles by the transport of protons coupled to the hydrolysis of ATP. In yeast, the V-ATPase is composed of 13 subunits consisting of a catalytic V₁ domain of peripherally associated proteins and a proton-translocating V₀ domain of integral membrane proteins. The regulatory subunit, Vma13p, was the first V-ATPase subunit to have its crystal structure determined. In addition to proteins forming the functional V-ATPase complex, three ER-localized proteins facilitate the assembly of the V₀ subunits following their translation and insertion into the membrane of the ER. Homologues of the Vma21p assembly factor have been identified in many higher eukaryotes supporting a ubiquitous assembly pathway for this important enzyme complex.     

Vma21p is a yeast membrane protein retained in the endoplasmic reticulum by a di-lysine motif and is required for the assembly of the vacuolar H(+)-ATPase complex.

The yeast vacuolar proton-translocating ATPase (V-ATPase) is a multisubunit complex comprised of peripheral membrane subunits involved in ATP hydrolysis and integral membrane subunits involved in proton pumping. The yeast vma21 mutant was isolated from a screen to identify mutants defective in V-ATPase function. vma21 mutants fail to assemble the V-ATPase complex onto the vacuolar membrane: peripheral subunits accumulate in the cytosol and the 100-kDa integral membrane subunit is rapidly degraded. The product of the VMA21 gene (Vma21p) is an 8.5-kDa integral membrane protein that is not a subunit of the purified V-ATPase complex but instead resides in the endoplasmic reticulum. Vma21p contains a dilysine motif at the carboxy terminus, and mutation of these lysine residues abolishes retention in the endoplasmic reticulum and results in delivery of Vma21p to the vacuole, the default compartment for yeast membrane proteins. Our findings suggest that Vma21p is required for assembly of the integral membrane sector of the V-ATPase in the endoplasmic reticulum and that the unassembled 100-kDa integral membrane subunit present in delta vma21 cells is rapidly degraded by nonvacuolar proteases.     

Voa1p functions in V-ATPase assembly in the yeast endoplasmic reticulum

The yeast Saccharomyces cerevisiae vacuolar ATPase (V-ATPase) is a multisubunit complex divided into two sectors: the V₁ sector catalyzes ATP hydrolysis and the V₀ sector translocates protons, resulting in acidification of its resident organelle. Four protein factors participate in V₀ assembly. We have discovered a fifth V₀ assembly factor, Voa1p (YGR106C); an endoplasmic reticulum (ER)-localized integral membrane glycoprotein. The role of Voa1p in V₀ assembly was revealed in cells expressing an ER retrieval-deficient form of the V-ATPase assembly factor Vma21p (Vma21pQQ). Loss of Voa1p in vma21QQ yeast cells resulted in loss of V-ATPase function; cells were unable to acidify their vacuoles and exhibited growth defects typical of cells lacking V-ATPase. V₀ assembly was severely compromised in voa1 vma21QQ double mutants. Isolation of V₀–Vma21p complexes indicated that Voa1p associates most strongly with Vma21p and the core proteolipid ring of V₀ subunits c, c′, and c″. On assembly of the remaining three V₀ subunits (a, d, and e) into the V₀ complex, Voa1p dissociates from the now fully assembled V₀–Vma21p complex. Our results suggest Voa1p functions with Vma21p early in V₀ assembly in the ER, but then it dissociates before exit of the V₀–Vma21p complex from the ER for transport to the Golgi compartment.     

PKR1 encodes an assembly factor for the yeast V-type ATPase

Deletion of the yeast gene PKR1 (YMR123W) results in an inability to grow on iron-limited medium. Pkr1p is localized to the membrane of the endoplasmic reticulum. Cells lacking Pkr1p show reduced levels of the V-ATPase subunit Vph1p due to increased turnover of the protein in mutant cells. Reduced levels of the V-ATPase lead to defective copper loading of Fet3p, a component of the high affinity iron transport system. Levels of Vph1p in cells lacking Pkr1p are similar to cells unable to assemble a functional V-ATPase due to lack of a V0 subunit or an endoplasmic reticulum (ER) assembly factor. However, unlike yeast mutants lacking a V0 subunit or a V-ATPase assembly factor, low levels of Vph1p present in cells lacking Pkr1p are assembled into a V-ATPase complex, which exits the ER and is present on the vacuolar membrane. The V-ATPase assembled in the absence of Pkr1p is fully functional because the mutant cells are able to weakly acidify their vacuoles. Finally, overexpression of the V-ATPase assembly factor Vma21p suppresses the growth and acidification defects of pkr1Delta cells. Our data indicate that Pkr1p functions together with the other V-ATPase assembly factors in the ER to efficiently assemble the V-ATPase membrane sector.     

A genome-wide enhancer screen implicates sphingolipid composition in vacuolar ATPase function in Saccharomyces cerevisiae

The function of the vacuolar H(+)-ATPase (V-ATPase) enzyme complex is to acidify organelles; this process is critical for a variety of cellular processes and has implications in human disease. There are five accessory proteins that assist in assembly of the membrane portion of the complex, the V(0) domain. To identify additional elements that affect V-ATPase assembly, trafficking, or enzyme activity, we performed a genome-wide enhancer screen in the budding yeast Saccharomyces cerevisiae with two mutant assembly factor alleles, VMA21 with a dysfunctional ER retrieval motif (vma21QQ) and vma21QQ in combination with voa1Δ, a nonessential assembly factor. These alleles serve as sensitized genetic backgrounds that have reduced V-ATPase enzyme activity. Genes were identified from a variety of cellular pathways including a large number of trafficking-related components; we characterized two redundant gene pairs, HPH1/HPH2 and ORM1/ORM2. Both sets demonstrated synthetic growth defects in combination with the vma21QQ allele. A loss of either the HPH or ORM gene pairs alone did not result in a decrease in vacuolar acidification or defects in V-ATPase assembly. While the Hph proteins are not required for V-ATPase function, Orm1p and Orm2p are required for full V-ATPase enzyme function. Consistent with the documented role of the Orm proteins in sphingolipid regulation, we have found that inhibition of sphingolipid synthesis alleviates Orm-related growth defects.     

The yeast vacuolar proton-translocating ATPase contains a subunit homologous to the Manduca sexta and bovine e subunits that is essential for function

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.     

Defined sites of interaction between subunits E (Vma4p), C (Vma5p), and G (Vma10p) within the stator structure of the vacuolar H+-ATPase

Vacuolar H(+)-ATPases (V-ATPases) are multi-subunit membrane proteins that couple ATP hydrolysis to the extrusion of protons from the cytoplasm. Although they share a common macromolecular architecture and rotational mechanism with the F(1)F(0)-ATPases, the organization of many of the specialized V-ATPase subunits within this rotary molecular motor remains uncertain. In this study, we have identified sequence segments involved in linking putative stator subunits in the Saccharomyces V-ATPase. Precipitation assays revealed that subunits Vma5p (subunit C) and Vma10p (subunit G), expressed as glutathione-S-transferase fusion proteins in E. coli, are both able to interact strongly with Vma4p (subunit E) expressed in a cell-free system. GST-Vma10p also associated with Vma2p and Vma1p, the core subunits of the ATP-hydrolyzing domain, and was able to self-associate to form a dimer. Mutations within the first 19-residue region of Vma4p, which disrupted interaction with Vma5p in vitro, also prevented the Vma4p polypeptide from restoring V-ATPase function in a complementation assay in vivo. These mutations did not prevent assembly of Vma5p (subunit C) and Vma2p (subunit B) into an inactive complex at the vacuolar membrane, indicating that Vma5p must make multiple interactions involving other V-ATPase subunits. A second, highly conserved region of Vma4p between residues 19 and 38 is involved in binding Vma10p. This region is highly enriched in charged residues, suggesting a role for electrostatic effects in Vma4p-Vma10p interaction. These protein interaction studies show that the N-terminal region of Vma4p is a key factor not only in the stator structure of the V-ATPase rotary molecular motor, but also in mediating interactions with putative regulatory subunits.     

Role of Vma21p in assembly and transport of the yeast vacuolar ATPase

The Saccharomyces cerevisiae vacuolar H+-ATPase (V-ATPase) is a multisubunit complex composed of a peripheral membrane sector (V1) responsible for ATP hydrolysis and an integral membrane sector (V0) required for proton translocation. Biogenesis of V0 requires an endoplasmic reticulum (ER)-localized accessory factor, Vma21p. We found that in vma21Delta cells, the major proteolipid subunit of V0 failed to interact with the 100-kDa V0 subunit, Vph1p, indicating that Vma21p is necessary for V0 assembly. Immunoprecipitation of Vma21p from wild-type membranes resulted in coimmunoprecipitation of all five V0 subunits. Analysis of vmaDelta strains showed that binding of V0 subunits to Vma21p was mediated by the proteolipid subunit Vma11p. Although Vma21p/proteolipid interactions were independent of Vph1p, Vma21p/Vph1p association was dependent on all other V0 subunits, indicating that assembly of V0 occurs in a defined sequence, with Vph1p recruitment into a Vma21p/proteolipid/Vma6p complex representing the final step. An in vitro assay for ER export was used to demonstrate preferential packaging of the fully assembled Vma21p/proteolipid/Vma6p/Vph1p complex into COPII-coated transport vesicles. Pulse-chase experiments showed that the interaction between Vma21p and V0 was transient and that Vma21p/V0 dissociation was concomitant with V0/V1 assembly. Blocking ER export in vivo stabilized the interaction between Vma21p and V0 and abrogated assembly of V0/V1. Although a Vma21p mutant lacking an ER-retrieval signal remained associated with V0 in the vacuole, this interaction did not affect the assembly of vacuolar V0/V1 complexes. We conclude that Vma21p is not involved in regulating the interaction between V0 and V1 sectors, but that it has a crucial role in coordinating the assembly of V0 subunits and in escorting the assembled V0 complex into ER-derived transport vesicles.     

Degradation of unassembled Vph1p reveals novel aspects of the yeast ER quality control system

The endoplasmic reticulum quality control (ERQC) system retains and degrades soluble and membrane proteins that misfold or fail to assemble. Vph1p is the 100 kDa membrane subunit of the yeast Saccharomyces cerevisiae V-ATPase, which together with other subunits, assembles into the V-ATPase in the ER, requiring the ER resident protein Vma22p. In vma22Delta cells, Vph1p remains an integral membrane protein with wild-type topology in the ER membrane before undergoing a rapid and concerted degradation requiring neither vacuolar proteases nor transport to the Golgi. Failure to assemble targets Vph1p for degradation in a process involving ubiquitylation, the proteasome and cytosolic but not ER lumenal chaperones. Vph1p appears to possess the traits of a 'classical' ERQC substrate, yet novel characteristics are involved in its degradation: (i) UBC genes other than UBC6 and UBC7 are involved and (ii) components of the ERQC system identified to date (Der1p, Hrd1p/Der3p and Hrd3p) are not required. These data suggest that other ERQC components must exist to effect the degradation of Vph1p, perhaps comprising an alternative pathway.     

Hph1 and Hph2 are novel components of the Sec63/Sec62 posttranslational translocation complex that aid in vacuolar proton ATPase biogenesis

Hph1 and Hph2 are homologous integral endoplasmic reticulum (ER) membrane proteins required for Saccharomyces cerevisiae survival under environmental stress conditions. To investigate the molecular functions of Hph1 and Hph2, we carried out a split-ubiquitin-membrane-based yeast two-hybrid screen and identified their interactions with Sec71, a subunit of the Sec63/Sec62 complex, which mediates posttranslational translocation of proteins into the ER. Hph1 and Hph2 likely function in posttranslational translocation, as they interact with other Sec63/Sec62 complex subunits, i.e., Sec72, Sec62, and Sec63. hph1Δ hph2Δ cells display reduced vacuole acidification; increased instability of Vph1, a subunit of vacuolar proton ATPase (V-ATPase); and growth defects similar to those of mutants lacking V-ATPase activity. sec71Δ cells exhibit similar phenotypes, indicating that Hph1/Hph2 and the Sec63/Sec62 complex function during V-ATPase biogenesis. Hph1/Hph2 and the Sec63/Sec62 complex may act together in this process, as vacuolar acidification and Vph1 stability are compromised to the same extent in hph1Δ hph2Δ and hph1Δ hph2Δ sec71Δ cells. In contrast, loss of Pkr1, an ER protein that promotes posttranslocation assembly of Vph1 with V-ATPase subunits, further exacerbates hph1Δ hph2Δ phenotypes, suggesting that Hph1 and Hph2 function independently of Pkr1-mediated V-ATPase assembly. We propose that Hph1 and Hph2 aid Sec63/Sec62-mediated translocation of specific proteins, including factors that promote efficient biogenesis of V-ATPase, to support yeast cell survival during environmental stress.     

Subunits of the Saccharomyces cerevisiae signal recognition particle required for its functional expression.

The signal recognition particle (SRP) is an evolutionarily conserved ribonucleoprotein (RNP) complex that functions in protein targeting to the endoplasmic reticulum (ER) membrane. Only two protein subunits of the SRP, Srp54p and Sec65p, and the RNA subunit, scR1, were previously known in the yeast Saccharomyces cerevisiae. Purification of yeast SRP by immunoaffinity chromatography revealed five additional proteins. Amino acid sequencing and cloning of the genes encoding four of these proteins demonstrated that the yeast SRP contains homologs (termed Srp14p, Srp68p and Srp72p) of the SRP14, SRP68 and SRP72 subunits found in mammalian SRP. The yeast SRP also contains a 21 kDa protein (termed Srp21p) that is not homologous to any protein in mammalian SRP. An additional 7 kDa protein may correspond to the mammalian SRP9. Disruption of any one of the four genes encoding the newly identified SRP proteins results in slow cell growth and inefficient protein translocation across the ER membrane. These phenotypes are indistinguishable from those resulting from the disruption of genes encoding SRP components identified previously. These data indicate that a lack of any of the analyzed SRP components results in loss of SRP function. ScR1 RNA and SRP proteins are at reduced levels in cells lacking any one of the newly identified proteins. In contrast, SRP components are present at near wild type levels and SRP subparticles are present in cells lacking either Srp54p or Sec65p. Thus Srp14p, Srp21p, Srp68p and Srp72p, but not Sec65p or Srp54p, are required for stable expression of the yeast SRP.     

A 100 kDa polypeptide associates with the V0 membrane sector but not with the active oat vacuolar H(+)-ATPase, suggesting a role in assembly

The vacuolar H(+)-ATPase (V-ATPase) is responsible for acidifying endomembrane compartments in eukaryotic cells. Although a 100 kDa subunit is common to many V-ATPases, it is not detected in a purified and active pump from oat (Ward J.M. and Sze H. (1992) Plant Physiol. 99, 925-931). A 100 kDa subunit of the yeast V-ATPase is encoded by VPH1. Immunostaining revealed a Vph1p-related polypeptide in oat membranes, thus the role of this polypeptide was investigated. Membrane proteins were detergent-solubilized and size-fractionated, and V-ATPase subunits were identified by immunostaining. A 100 kDa polypeptide was not associated with the fully assembled ATPase; however, it was part of an approximately 250 kDa V0 complex including subunits of 36 and 16 kDa. Immunostaining with an affinity-purified antibody against the oat 100 kDa protein confirmed that the polypeptide was part of a 250 kDa complex and that it had not degraded in the approximately 670 kDa holoenzyme. Co-immunoprecipitation with a monoclonal antibody against A subunit indicated that peripheral subunits exist as assembled V1 subcomplexes in the cytosol. The free V1 subcomplex became attached to the detergent-solubilized V0 sector after mixing, as subunits of both sectors were co-precipitated by an antibody against subunit A. The absence of this polypeptide from the active enzyme suggests that, unlike the yeast Vph1p, the 100 kDa polypeptide in oat is not required for activity. Its association with the free Vo subcomplex would support a role of this protein in V-ATPase assembly and perhaps in sorting.     

The presence of the alternatively spliced A2 cassette in the vacuolar H+-ATPase subunit A prevents assembly of the V1 catalytic domain.

Vacuolar ATPases (V-ATPases) are multisubunit enzymes that couple the hydrolysis of ATP to the transport of H+ across membranes, and thus acidify several intracellular compartments and some extracellular spaces. Despite the high degree of genetic and pharmacological homogeneity of V-ATPases, cells differentially modulate the lumenal pH of organelles and, in some cells, V-ATPases are selectively targetted to the plasma membrane. Although the mechanisms underlying such differences are not known, the subunit isoform composition of V-ATPases could contribute to altered assembly, targeting or activity. We previously identified an alternatively spliced variant of the chicken A subunit in which a 30 amino acid cassette (A1) containing the Walker consensus sequence for ATP binding is replaced by a 24 amino acid cassette (A2) that lacks this feature. We have examined the ability of chimeric yeast/chicken A subunits containing either the A1 or the A2 cassette to restore the V-ATPase activity of yeast that lack the A subunit. The A1-containing chimeric subunit, but not the chimera that contains the A2 cassette, partially restores the ability of the mutated yeast to grow at neutral pH. Both chimeric proteins are expressed, although at lower levels than the similarly transfected yeast A subunit. The A2-containing subunit fails to associate with the vacuolar membrane or support the assembly of V-ATPase complexes. Thus, the substitution of the A1 sequence by A2 not only removes the Walker nucleotide binding sequence but also compromises the ability of the A subunit to assemble with other V-ATPase subunits.     

Degradation of the gluconeogenic enzyme fructose-1, 6-bisphosphatase is dependent on the vacuolar ATPase

The key gluconeogenic enzyme fructose-1,6-bisphosphatase (FBPase) is induced during glucose starvation. After the addition of glucose, inactivated FBPase is selectively targeted to Vid (vacuolar import and degradation) vesicles and then to the vacuole for degradation. To identify proteins involved in this pathway, we screened various libraries for mutants that failed to degrade FBPase. Via these approaches, subunits of the vacuolar- H+ -ATPase (V-ATPase) have been identified repeatedly. The V-ATPase has established roles in endocytosis, sorting of carboxypeptidase Y and homotypic vacuole fusion. Here, we show that mutants lacking Stv1p, Vph1p, and other subunits of the V-ATPase are defective for FBPase degradation. FBPase was detected in Vid vesicles. However, most FBPase was resistant to proteinase K digestion in the Deltavph1 or vma mutants, whereas the majority of FBPase was sensitive to proteinase K digestion in the Deltastv1 mutant. Therefore, STV1 and VPH1 have distinct functions in FBPase degradation. In cells lacking V0 genes, Vma2p and Vma5p were still detected on Vid vesicles and vacuoles, suggesting that the distribution of V1 proteins is independent of V0 genes. The V0 and V1 domains are assembled following a glucose shift and the assembly is not regulated by protein kinase A and RAV genes. Assembly of the V0 complex is necessary for FBPase trafficking, since mutants that block the assembly and transport of V0 out of the ER were defective in FBPase degradation.     

Effects of human a3 and a4 mutations that result in osteopetrosis and distal renal tubular acidosis on yeast V-ATPase expression and activity

V-ATPases are multimeric proton pumps. The 100-kDa "a" subunit is encoded by four isoforms (a1-a4) in mammals and two (Vph1p and Stv1p) in yeast. a3 is enriched in osteoclasts and is essential for bone resorption, whereas a4 is expressed in the distal nephron and acidifies urine. Mutations in human a3 and a4 result in osteopetrosis and distal renal tubular acidosis, respectively. Human a3 (G405R and R444L) and a4 (P524L and G820R) mutations were recreated in the yeast ortholog Vph1p, a3 (G424R and R462L), and a4 (W520L and G812R). Mutations in a3 resulted in wild type vacuolar acidification and growth on media containing 4 mM ZnCl2, 200 mM CaCl2, or buffered to pH 7.5 with V-ATPase hydrolytic and pumping activity decreased by 30-35%. Immunoblots confirmed wild type levels for V-ATPase a, A, and B subunits on vacuolar membranes. a4 G812R resulted in defective growth on selective media with V-ATPase hydrolytic and pumping activity decreased by 83-85% yet with wild type levels of a, A, and B subunits on vacuolar membranes. The a4 W520L mutation had defective growth on selective media with no detectable V-ATPase activity and reduced expression of a, A, and B subunits. The a4 W520L mutation phenotypes were dominant negative, as overexpression of wild type yeast a isoforms, Vph1p, or Stv1p, did not restore growth. However, deletion of endoplasmic reticulum assembly factors (Vma12p, Vma21p, and Vma22p) partially restored a and B expression. That a4 W520L affects both Vo and V1 subunits is a unique phenotype for any V-ATPase subunit mutation and supports the concerted pathway for V-ATPase assembly in vivo.     

A genomic screen for yeast vacuolar membrane ATPase mutants

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, approximately 4700 yeast deletion mutants were screened for growth defects at pH 7.5 in 60 mm CaCl(2). 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 cwh36Delta 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, vps34Delta, vps15Delta, vps45Delta, and vps16Delta, caused both Vma- growth phenotypes and lower V-ATPase activity in isolated vacuoles, as did the shp1Delta 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.     

Skp1p regulates Soi3p/Rav1p association with endosomal membranes but is not required for vacuolar ATPase assembly

Skp1p is an essential component of SCF-type E3 ubiquitin ligase complexes and associates with these through binding to F-box proteins. Skp1p also binds F-box proteins in a number of non-SCF complexes. The Skp1p-associated yeast protein Soi3p/Rav1p (hereafter referred to as Rav1p) is a component of the RAVE complex required for regulated assembly of vacuolar ATPase (V-ATPase). Rav1p is also involved in transport of TGN proteins and endocytic cargo between early and late endosomes. To evaluate the role of Skp1p in the RAVE complex, we made use of the fact that overexpression of Rav1p is toxic because it sequesters Skp1p from essential interactions. We isolated a separation of function allele of SKP1, skp1(Asn108Tyr), that completely abrogated the Rav1p interaction but allowed Skp1p to perform other essential cellular functions. Cells containing the skp1(Asn108Tyr) allele as the sole source of Skp1p exhibited normal V-ATPase assembly and activity. However, in the skp1(Asn108Tyr) mutant strain, the membrane-associated pool of Rav1-green fluorescent protein was increased, suggesting that Skp1p is important for the release of Rav1p from endosomal membranes where it functions in V-ATPase assembly. Thus, although part of the RAVE complex, Skp1p does not appear to be involved in V-ATPase assembly but instead in the cycling of the complex off membranes. This work also provides a generalizable approach to defining the roles of interactions of Skp1p with individual F-box proteins through the isolation of special alleles of SKP1.     

CCDC115 Deficiency Causes a Disorder of Golgi Homeostasis with Abnormal Protein Glycosylation

Disorders of Golgi homeostasis form an emerging group of genetic defects. The highly heterogeneous clinical spectrum is not explained by our current understanding of the underlying cell-biological processes in the Golgi. Therefore, uncovering genetic defects and annotating gene function are challenging. Exome sequencing in a family with three siblings affected by abnormal Golgi glycosylation revealed a homozygous missense mutation, c.92T>C (p.Leu31Ser), in coiled-coil domain containing 115 (CCDC115), the function of which is unknown. The same mutation was identified in three unrelated families, and in one family it was compound heterozygous in combination with a heterozygous deletion of CCDC115. An additional homozygous missense mutation, c.31G>T (p.Asp11Tyr), was found in a family with two affected siblings. All individuals displayed a storage-disease-like phenotype involving hepatosplenomegaly, which regressed with age, highly elevated bone-derived alkaline phosphatase, elevated aminotransferases, and elevated cholesterol, in combination with abnormal copper metabolism and neurological symptoms. Two individuals died of liver failure, and one individual was successfully treated by liver transplantation. Abnormal N- and mucin type O-glycosylation was found on serum proteins, and reduced metabolic labeling of sialic acids was found in fibroblasts, which was restored after complementation with wild-type CCDC115. PSI-BLAST homology detection revealed reciprocal homology with Vma22p, the yeast V-ATPase assembly factor located in the endoplasmic reticulum (ER). Human CCDC115 mainly localized to the ERGIC and to COPI vesicles, but not to the ER. These data, in combination with the phenotypic spectrum, which is distinct from that associated with defects in V-ATPase core subunits, suggest a more general role for CCDC115 in Golgi trafficking. Our study reveals CCDC115 deficiency as a disorder of Golgi homeostasis that can be readily identified via screening for abnormal glycosylation in plasma.