Genes for directing vacuolar morphogenesis in Saccharomyces cerevisiae. II. VAM7, a gene for regulating morphogenic assembly of the vacuoles.

VAM7 gene function has shown to be required for proper morphogenesis of the vacuole in yeast. The DNA fragments that complemented the defective vacuolar morphology of the vam7-1 mutation were isolated from a yeast genomic library. An overlapping 2.5-kilobase BglII-HindIII region was found to be sufficient for complementation of the vam7-1 phenotype. This fragment was integrated at the chromosomal VAM7 locus, indicating that it contained an authentic VAM7 gene. On nucleotide sequencing of the VAM7 gene, an open reading frame of 948 base pairs, coding for a hydrophilic polypeptide of 316 amino acid residues, was identified. The deduced amino acid sequence of the carboxyl-terminal region of the VAM7 gene product has heptad repeats and shows potential ability to form a coiled-coil structure. Disruption of VAM7 was not lethal; cells with a disrupted VAM7 gene did not, however, have a prominent large vacuoles but rather numerous small compartments that accumulated the histochemical marker molecule of the vacuolar compartment. They contained mature forms of the vacuolar marker proteins carboxypeptidase Y and vacuolar glycoprotein vgp72. A mutant with both vam7 and vam5 null mutations was constructed and shown to have neither vacuolar structures stained with ade-related fluorochrome nor mature forms of vacuolar marker proteins. These findings suggested that the VAM7 gene product functions in the process of morphogenic assembly of the vacuolar compartment but is not involved in the protein sorting and delivery to the vacuole.     

Vacuolar/pre-vacuolar compartment Qa-SNAREs VAM3/SYP22 and PEP12/SYP21 have interchangeable functions in Arabidopsis

SNAREs (soluble N-ethylmaleimide sensitive factor attachment protein receptors) mediate specific membrane fusion between transport vesicles or organelles and target membranes. VAM3/SYP22 and PEP12/SYP21 are Qa-SNAREs that act in the vacuolar transport pathway of Arabidopsis thaliana, and are localized predominantly on the vacuolar membrane and the pre-vacuolar compartment (PVC), respectively. Previous studies have shown that loss-of-function mutants of VAM3/SYP22 or PEP12/SYP21 showed male gametophytic lethality, suggesting that VAM3/SYP22 and PEP12/SYP21 possess different, non-redundant functions. We have re-evaluated the effects of mutations in these genes using T-DNA insertion mutants in the Columbia accession. We found that a mutation in VAM3/SYP22 (vam3-1) caused pleiotropic abnormalities, including semi-dwarfism and wavy leaves. In contrast, a loss-of-function mutant of PEP12/SYP21 (pep12) showed no apparent abnormal phenotype. We also found that the double vam3-1 pep12 mutant had severely reduced fertilization competence, although male and female gametophytes (vam3-1(-) pep12(-) ) maintained the ability to fertilize. Moreover, promoter swapping analysis revealed that expression of a GFP-PEP12/SYP21 fusion under the control of the VAM3/SYP22 promoter suppressed all phenotypes of the vam3-1 mutant. These results indicate that the functions of VAM3/SYP22 and PEP12/SYP21 were redundant and interchangeable.     

Mutational analysis of Vam4/Ypt7p function in the vacuolar biogenesis and morphogenesis in the yeast,Saccharomyces cerevisiae

Summary The vacuole is one of the most prominent compartments in yeast cells. The wild-type yeast cells have a large vacuolar compartment which occupies approximately a quarter of the cell volume, while thevam4 mutant cells exhibit highly fragmented vacuolar morphology. We isolated theVAM4 gene and found that theVAM4 is identical to theYPT7 which encodes a member of small GTP-binding protein superfamily. We introduced mutations to theVAM4/YPT7 which alter nucleotide binding characteristics of the gene product specifically, and their activities for the vacuolar morphogenesis were examined by transforming the mutant genes into yeast cells. The Thr22Asn mutation, which was expected to fix the protein in the GDP-bound state, resulted in loss of function in the vacuolar morphogenesis. Subcellular fractionation analysis indicated that the mutant molecule did not associate with intracellular membranes efficiently. In contrast, Vam4/Ypt7p with the Gln68Leu mutation, which was expected to be the GTP-bound form, complemented the fragmented vacuolar morphology of vam4 mutant cells. Vam4/Ypt7p with the Gln68Leu mutation also complemented the defects in the biogenesis of vacuolar alkaline phosphatase whose maturation requires the proper function of Vam4/Ypt7p. Overexpression of the mutant proteins in wild-type cells did not develop dominant-negative effects on the vacuolar assembly. These results indicated that the GTP-bound form of Vam4/Ypt7p promotes the biogenesis and morphogenesis of the yeast vacuolar compartment.Abbreviations ALP alkaline phosphatase - CDE centromeric - DNA element - CPY carboxypeptidase Y - GST glutathione S-transferase     

A Multispecificity Syntaxin Homologue, Vam3p, Essential for Autophagic and Biosynthetic Protein Transport to the Vacuole

Protein transport in eukaryotic cells requires the selective docking and fusion of transport intermediates with the appropriate target membrane. t-SNARE molecules that are associated with distinct intracellular compartments may serve as receptors for transport vesicle docking and membrane fusion through interactions with specific v-SNARE molecules on vesicle membranes, providing the inherent specificity of these reactions. VAM3 encodes a 283–amino acid protein that shares homology with the syntaxin family of t-SNARE molecules. Polyclonal antiserum raised against Vam3p recognized a 35-kD protein that was associated with vacuolar membranes by subcellular fractionation. Null mutants of vam3 exhibited defects in the maturation of multiple vacuolar proteins and contained numerous aberrant membrane-enclosed compartments. To study the primary function of Vam3p, a temperature-sensitive allele of vam3 was generated (vam3^tsf). Upon shifting the vam3^tsf mutant cells to nonpermissive temperature, an immediate block in protein transport through two distinct biosynthetic routes to the vacuole was observed: transport via both the carboxypeptidase Y pathway and the alkaline phosphatase pathway was inhibited. In addition, vam3^tsf cells also exhibited defects in autophagy. Both the delivery of aminopeptidase I and the docking/ fusion of autophagosomes with the vacuole were defective at high temperature. Upon temperature shift, vam3^tsf cells accumulated novel membrane compartments, including multivesicular bodies, which may represent blocked transport intermediates. Genetic interactions between VAM3 and a SEC1 family member, VPS33, suggest the two proteins may act together to direct the docking and/or fusion of multiple transport intermediates with the vacuole. Thus, Vam3p appears to function as a multispecificity receptor in heterotypic membrane docking and fusion reactions with the vacuole. Surprisingly, we also found that overexpression of the endosomal t-SNARE, Pep12p, suppressed vam3Δ mutant phenotypes and, likewise, overexpression of Vam3p suppressed the pep12Δ mutant phenotypes. This result indicated that SNAREs alone do not define the specificity of vesicle docking reactions.     

Vam7p, a SNAP-25-Like Molecule, and Vam3p, a Syntaxin Homolog, Function Together in Yeast Vacuolar Protein Trafficking

A genetic screen to isolate gene products required for vacuolar morphogenesis in the yeast Saccharomyces cerevisiae identified VAM7, a gene which encodes a protein containing a predicted coiled-coil domain homologous to the coiled-coil domain of the neuronal t-SNARE, SNAP-25 (Y. Wada and Y. Anraku, J. Biol. Chem. 267:18671–18675, 1992; T. Weimbs, S. H. Low, S. J. Chapin, K. E. Mostov, P. Bucher, and K. Hofmann, Proc. Natl. Acad. Sci. USA 94:3046–3051, 1997). Analysis of a temperature-sensitive-for-function (tsf) allele of VAM7 (vam7^tsf) demonstrated that the VAM7 gene product directly functions in vacuolar protein transport. vam7^tsf mutant cells incubated at the nonpermissive temperature displayed rapid defects in the delivery of multiple proteins that traffic to the vacuole via distinct biosynthetic pathways. Examination of vam7^tsf cells at the nonpermissive temperature by electron microscopy revealed the accumulation of aberrant membranous compartments that may represent unfused transport intermediates. A fraction of Vam7p was localized to vacuolar membranes. Furthermore, VAM7 displayed genetic interactions with the vacuolar syntaxin homolog, VAM3. Consistent with the genetic results, Vam7p physically associated in a complex containing Vam3p, and this interaction was enhanced by inactivation of the yeast NSF (N-ethyl maleimide-sensitive factor) homolog, Sec18p. In addition to the coiled-coil domain, Vam7p also contains a putative NADPH oxidase p40^phox (PX) domain. Changes in two conserved amino acids within this domain resulted in synthetic phenotypes when combined with the vam3^tsf mutation, suggesting that the PX domain is required for Vam7p function. This study provides evidence for the functional and physical interaction between Vam7p and Vam3p at the vacuolar membrane, where they function as part of a t-SNARE complex required for the docking and/or fusion of multiple transport intermediates destined for the vacuole.     

Pth1/Vam3p is the syntaxin homolog at the vacuolar membrane of Saccharomyces cerevisiae required for the delivery of vacuolar hydrolases.

The PEP12 homolog Pth1p (Pep twelve homolog 1) is predicted to be similar in size to Pep12p, the endosomal syntaxin homolog that mediates docking of Golgi-derived transport vesicles and, like other members of the syntaxin family, is predicted to be a cytoplasmically oriented, integral membrane protein with a C-terminal transmembrane domain. Kinetic analyses indicate that deltapth1/vam3 mutants fail to process the soluble vacuolar hydrolase precursors and that PrA, PrB and most of CpY accumulate within the cell in their Golgi-modified P2 precursor forms. This is in contrast to a pep12 mutant in which P2CpY is secreted from the cell. Furthermore, pep12 is epistatic to pth1/vam3 with respect to the CpY secretion phenotype. Alkaline phosphatase, a vacuolar membrane hydrolase, accumulates in its precursor form in the deltapth1/vam3 mutant. Maturation of pro-aminopeptidase I, a hydrolase precursor delivered directly to the vacuole from the cytoplasm, is also blocked in the deltapth1/vam3 mutant. Subcellular fractionation localizes Pth1/Vam3p to vacuolar membranes. Based on these data, we propose that Pth1/Vam3p is the vacuolar syntaxin/t-SNARE homolog that participates in docking of transport vesicles at the vacuolar membrane and that the function of Pth1/Vam3p impinges on at least three routes of protein delivery to the yeast vacuole.     

The yeast vps class E mutants: the beginning of the molecular genetic analysis of multivesicular body biogenesis

In 1992, Raymond et al. published a compilation of the 41 yeast vacuolar protein sorting (vps) mutant groups and described a large class of mutants (class E vps mutants) that accumulated an exaggerated prevacuolar endosome-like compartment. Further analysis revealed that this "class E compartment" contained soluble vacuolar hydrolases, vacuolar membrane proteins, and Golgi membrane proteins unable to recycle back to the Golgi complex, yet these class E vps mutants had what seemed to be normal vacuoles. The 13 class E VPS genes were later shown to encode the proteins that make up the complexes required for formation of intralumenal vesicles in late endosomal compartments called multivesicular bodies, and for the sorting of ubiquitinated cargo proteins into these internal vesicles for eventual delivery to the vacuole or lysosome.     

Vps41p function in the alkaline phosphatase pathway requires homo-oligomerization and interaction with AP-3 through two distinct domains

Transport of proteins through the ALP (alkaline phosphatase) pathway to the vacuole requires the function of the AP-3 adaptor complex and Vps41p. However, unlike other adaptor protein-dependent pathways, the ALP pathway has not been shown to require additional accessory proteins or coat proteins, such as membrane recruitment factors or clathrin. Two independent genetic approaches have been used to identify new mutants that affect transport through the ALP pathway. These screens yielded new mutants in both VPS41 and the four AP-3 subunit genes. Two new VPS41 alleles exhibited phenotypes distinct from null mutants of VPS41, which are defective in vacuolar morphology and protein transport through both the ALP and CPY sorting pathways. The new alleles displayed severe ALP sorting defects, normal vacuolar morphology, and defects in ALP vesicle formation at the Golgi complex. Sequencing analysis of these VPS41 alleles revealed mutations encoding amino acid changes in two distinct domains of Vps41p: a conserved N-terminal domain and a C-terminal clathrin heavy-chain repeat (CHCR) domain. We demonstrate that the N-terminus of Vps41p is required for binding to AP-3, whereas the C-terminal CHCR domain directs homo-oligomerization of Vps41p. These data indicate that a homo-oligomeric form of Vps41p is required for the formation of ALP containing vesicles at the Golgi complex via interactions with AP-3.     

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.     

Synthetic genetic interactions with temperature-sensitive clathrin in Saccharomyces cerevisiae. Roles for synaptojanin-like Inp53p and dynamin-related Vps1p in clathrin-dependent protein sorting at the trans-Golgi network

Clathrin is involved in selective protein transport at the Golgi apparatus and the plasma membrane. To further understand the molecular mechanisms underlying clathrin-mediated protein transport pathways, we initiated a genetic screen for mutations that display synthetic growth defects when combined with a temperature-sensitive allele of the clathrin heavy chain gene (chc1-521) in Saccharomyces cerevisiae. Mutations, when present in cells with wild-type clathrin, were analyzed for effects on mating pheromone alpha-factor precursor maturation and sorting of the vacuolar protein carboxypeptidase Y as measures of protein sorting at the yeast trans-Golgi network (TGN) compartment. By these criteria, two classes of mutants were obtained, those with and those without defects in protein sorting at the TGN. One mutant with unaltered protein sorting at the TGN contains a mutation in PTC1, a type 2c serine/threonine phosphatase with widespread influences. The collection of mutants displaying TGN sorting defects includes members with mutations in previously identified vacuolar protein sorting genes (VPS), including the dynamin family member VPS1. Striking genetic interactions were observed by combining temperature-sensitive alleles of CHC1 and VPS1, supporting the model that Vps1p is involved in clathrin-mediated vesicle formation at the TGN. Also in the spectrum of mutants with TGN sorting defects are isolates with mutations in the following: RIC1, encoding a product originally proposed to participate in ribosome biogenesis; LUV1, encoding a product potentially involved in vacuole and microtubule organization; and INP53, encoding a synaptojanin-like inositol polyphosphate 5-phosphatase. Disruption of INP53, but not the related INP51 and INP52 genes, resulted in alpha-factor maturation defects and exacerbated alpha-factor maturation defects when combined with chc1-521. Our findings implicate a wide variety of proteins in clathrin-dependent processes and provide evidence for the selective involvement of Inp53p in clathrin-mediated protein sorting at the TGN.     

Protein sorting in yeast: mutants defective in vacuole biogenesis mislocalize vacuolar proteins into the late secretory pathway

We have devised a genetic selection for mutant yeast cells that fail to properly deliver the vacuolar glycoprotein CPY to the lysosome-like vacuole. This has allowed us to identify mutations in eight VPL complementation groups that result in aberrant secretion of up to approximately 90% of the immunoreactive CPY. Other soluble vacuolar proteins are also affected by each vpl mutation, demonstrating that a sorting system for multiple vacuolar proteins exists in yeast. Mislocalized CPY apparently traverses late stages of the secretory pathway, since a vesicle-accumulating sec1 mutation prevents secretion of this protein. Despite the presence of abnormal membrane-enclosed organelles in some of the vpl mutants, maturation and secretion of invertase are not substantially perturbed. Thus vpl mutations define a new class of genes that encode products required for sorting of newly synthesized vacuolar proteins from secretory proteins during their transit through the yeast secretory pathway.     

Organelle assembly in yeast: characterization of yeast mutants defective in vacuolar biogenesis and protein sorting

Yeast vacuole protein targeting (vpt) mutants exhibit defects in the sorting and processing of multiple vacuolar hydrolases. To evaluate the impact these vpt mutations have on the biogenesis and functioning of the lysosome-like vacuole, we have used light and electron microscopic techniques to analyze the vacuolar morphology in the mutants. These observations have permitted us to assign the vpt mutants to three distinct classes. The class A vpt mutants (26 complementation groups) contain 1-3 large vacuoles that are morphologically indistinguishable from those in the parental strain, suggesting that only a subset of the proteins destined for delivery to this compartment is mislocalized. One class A mutant (vpt13) is very sensitive to low pH and exhibits a defect in vacuole acidification. Consistent with a potential role for vacuolar pH in protein sorting, we found that bafilomycin A1, a specific inhibitor of the vacuolar ATPase, as well as the weak base ammonium acetate and the proton ionophore carbonyl cyanide m-chlorophenylhydrazone, collapse the pH gradient across the vacuolar membrane and cause the missorting and secretion of two vacuolar hydrolases in wild-type cells. Mutants in the three class B vpt complementation groups exhibit a fragmented vacuole morphology. In these mutants, no large normal vacuoles are observed. Instead, many (20-40) smaller vacuole-like organelles accumulate. The class C vpt mutants, which constitute four complementation groups, exhibit extreme defects in vacuole biogenesis. The mutants lack any organelle resembling a normal vacuole but accumulate other organelles including vesicles, multilamellar membrane structures, and Golgi-related structures. Heterozygous class C zygotes reassemble normal vacuoles rapidly, indicating that some of the accumulated aberrant structures may be intermediates in vacuole formation. These class C mutants also exhibit sensitivity to osmotic stress, suggesting an osmoregulatory role for the vacuole. The vpt mutants should provide insights into the normal physiological role of the vacuole, as well as allowing identification of components required for vacuole protein sorting and/or vacuole assembly.     

VPS21 encodes a rab5-like GTP binding protein that is required for the sorting of yeast vacuolar proteins.

Many of the vacuolar protein sorting (vps) mutants of Saccharomyces cerevisiae exhibit severe defects in the sorting of vacuolar proteins but still retain near-normal vacuole morphology. The gene affected in one such mutant, vps21, has been cloned and found to encode a member of the ras-like GTP binding protein family. Sequence comparisons with other known GTP binding proteins indicate that Vps21p is unique but shares striking similarity with mammalian rab5 proteins (> 50% identity and > 70% similarity). Regions with highest similarity are clustered within the putative GTP binding motifs and the proposed effector domains of the Vps21/rab5 proteins. Point mutations constructed within these conserved regions inactivate Vps21p function; the mutant cells missort and secrete the soluble vacuolar hydrolase carboxypeptidase Y (CPY). Cells carrying a complete deletion of the VPS21 coding sequence (i) are viable but exhibit a growth defect at 38 degrees C, (ii) missort multiple vacuolar proteins, (iii) accumulate 40-50 nm vesicles and (iv) contain a large vacuole. VPS21 encodes a 22 kDa protein that binds GTP and fractionates with subcellular membranes. Mutant analysis indicates that the association with a membrane(s) is dependent on geranylgeranylation of the C-terminal cysteine residue(s) of Vps21p. We propose that Vps21p functions in the targeting and/or fusion of transport vesicles that mediate the delivery of proteins to the vacuole.     

A yeast protein related to a mammalian Ras-binding protein, Vps9p, is required for localization of vacuolar proteins.

In the yeast Saccharomyces cerevisiae, mutations in vacuolar protein sorting (VPS) genes result in secretion of proteins normally localized to the vacuole. Characterization of the VPS pathway has provided considerable insight into mechanisms of protein sorting and vesicle-mediated intracellular transport. We have cloned VPS9 by complementation of the vacuolar protein sorting defect of vps9 cells, characterized its gene product, and investigated its role in vacuolar protein sorting. Cells with a vps9 disruption exhibit severe vacuolar protein sorting defects and a temperature-sensitive growth defect at 38 degrees C. Electron microscopic examination of delta vps9 cells revealed the appearance of novel reticular membrane structures as well as an accumulation of 40- to 50-nm-diameter vesicles, suggesting that Vps9p may be required for the consumption of transport vesicles containing vacuolar protein precursors. A temperature-conditional allele of vps9 was constructed and used to investigate the function of Vps9p. Immediately upon shifting of temperature-conditional vps9 cells to the nonpermissive temperature, newly synthesized carboxypeptidase Y was secreted, indicating that Vps9p function is directly required in the VPS pathway. Antibodies raised against Vps9p immunoprecipitate a rare 52-kDa protein that fractionates with cytosolic proteins following cell lysis and centrifugation. Analysis of the VPS9 DNA sequence predicts that Vps9p is related to human proteins that bind Ras and negatively regulate Ras-mediated signaling. We term the related regions of Vps9p and these Ras-binding proteins a GTPase binding homology domain and suggest that it defines a family of proteins that bind monomeric GTPases. Vps9p may bind and serve as an effector of a rab GTPase, like Vps2lp, required for vacuolar protein sorting.     

Functional genomics of monensin sensitivity in yeast: implications for post-Golgi traffic and vacuolar H<Superscript>+</Superscript>-ATPase function

We have screened a complete collection of yeast knockout mutants for sensitivity to monensin, an ionophore that interferes with intracellular transport. A total of 63 sensitive strains were found. Most of the strains were deleted for genes involved in post-Golgi traffic, with an emphasis on vacuolar biogenesis. A high correlation was thus seen with VPS and VAM genes, but there were also significant differences between the three sets of genes. A weaker correlation was seen with sensitivity to NaCl, in particular rate of growth effects. Interestingly, all 14 genes encoding subunits of the vacuolar H(+)-ATPase (V-ATPase) were absent in our screen, even though they appeared in the VPS or VAM screens. All monensin-sensitive mutants that could be tested interact synthetically with a deletion of the A subunit of the V-ATPase, Vma1. Synthetic lethality was limited to mutations affecting endocytosis or retrograde transport to Golgi. In addition, vma1 was epistatic over the monensin sensitivity of vacuolar transport mutants, but not endocytosis mutants. Deletions of the two isoforms of the V-ATPase a subunit, Vph1 and Stv1 had opposite effects on the monensin sensitivity of a ypt7 mutant. These findings are consistent with a model where monensin inhibits growth by interfering with the maintenance of an acidic pH in the late secretory pathway. The synthetic lethality of vma1 with mutations affecting retrograde transport to the Golgi further suggests that it is in the late Golgi that a low pH must be maintained.     

Ultrastructure of two secretory mutants of Saccharomyces cerevisiae as revealed by freeze-fracture technique

Permissive and restrictive phenotypes of two secretory mutants of Saccharomyces cerevisiae, sec 1 and sec 18, were studied by freeze-fracture technique. The sec 1 mutant, in addition to accumulating secretory vesicles, was characterized by a disappearance of the plasma membrane invaginations and by an aggregation of intra-membrane particles in vacuolar membranes. A prolonged incubation of the cells at 37 degrees C led to pathological fusion of some vesicles with the plasma membrane. After the cells were transferred back to the permissive temperature the invaginations reappeared rapidly while the accumulated vesicles disappeared only after budding had been resumed. The sec 18 mutant, apart from having distended endoplasmic reticulum membranes, also lost the plasma membrane invaginations at 37 degrees C and regained them at 24 degrees C. The described ultrastructural changes are typical for the restrictive phenotypes and represent further manifestations of the pleiotropic effect of the respective sec mutations.     

Topogenesis of peroxisomal proteins does not require a functional cytoplasm-to-vacuole transport

Folded and even oligomeric proteins can be imported from the cytosol into vacuoles and into peroxisomes. Pro-aminopeptidase I (prAPI) oligomerizes into a dodecamer and is imported into the vacuole via the cytoplasm-to-vacuole transport (cvt) pathway. How peroxisomes accommodate folded proteins is completely unknown. Peroxisome biogenesis and cvt do not only share the import of folded protein complexes but also show mechanistic parallels such as the employment of ubiquitin conjugation systems. In search for a genetic overlap, selected cvt and autophagocytosis (atg) mutants were tested for defects in peroxisome biogenesis. Most of the mutants did not exhibit a mislocalization of peroxisomal matrix proteins to the cytosol which would be typical of a defect in the peroxisome biogenesis. However, two mutants, deltaatg14 and deltacvt4/vam6, displayed a general growth defect and deltacvt8/vps41 showed cytosolic mislocalization not only of peroxisomal but also of mitochondrial proteins, indicating a more general defect in organelle biogenesis. Our data do not provide evidence for a genetic overlap of the import pathway for peroxisomal proteins and the cvt pathway.     

The product of HUM1, a novel yeast gene, is required for vacuolar Ca2+/H+ exchange and is related to mammalian Na+/Ca2+ exchangers.

Calcineurin, or PP2B, plays a critical role in mediating Ca2+-dependent signaling in many cell types. In yeast cells, this highly conserved protein phosphatase regulates aspects of ion homeostasis and cell wall synthesis. We show that calcineurin mutants are sensitive to high concentrations of Mn2+ and identify two genes, CCC1 and HUM1, that, at high dosages, increase the Mn2+ tolerance of calcineurin mutants. CCC1 was previously identified by complementation of a Ca2+-sensitive (csg1) mutant. HUM1 (for "high copy number undoes manganese") is a novel gene whose predicted protein product shows similarity to mammalian Na+/Ca2+ exchangers. hum1 mutations confer Mn2+ sensitivity in some genetic backgrounds and exacerbate the Mn2+ sensitivity of calcineurin mutants. Furthermore, disruption of HUM1 in a calcineurin mutant strain results in a Ca2+-sensitive phenotype. We investigated the effect of disrupting HUM1 in other strains with defects in Ca2+ homeostasis. The Ca2+ sensitivity of pmc1 mutants, which lack a P-type ATPase presumed to transport Ca2+ into the vacuole, is exacerbated in a hum1 mutant strain background. Also, the Ca2+ content of hum1 pmc1 cells is less than that of pmc1 cells. In contrast, the Ca2+ sensitivity of vph1 mutants, which are specifically defective in vacuolar acidification, is not significantly altered by disruption of Hum1p function. These genetic interactions suggest that Hum1p may participate in vacuolar Ca2+/H+ exchange. Therefore, we prepared vacuolar membrane vesicles from wild-type and hum1 cells and compared their Ca2+ transport properties. Vacuolar membrane vesicles from hum1 mutants lack all Ca2+/H+ antiport activity, demonstrating that Hum1p catalyzes the exchange of Ca2+ for H+ across the yeast vacuolar membrane.     

lin-35/Rb cooperates with the SWI/SNF complex to control Caenorhabditis elegans larval development

Null mutations in lin-35, the Caenorhabditis elegans ortholog of the mammalian Rb protein, cause no obvious morphological defects. Using a genetic approach to identify genes that may function redundantly with lin-35, we have isolated a mutation in the C. elegans psa-1 gene. lin-35; psa-1 double mutants display severe developmental defects leading to early larval arrest and adult sterility. The psa-1 gene has previously been shown to encode a C. elegans homolog of yeast SWI3, a critical component of the SWI/SNF complex, and has been shown to regulate asymmetric cell divisions during C. elegans development. We observed strong genetic interactions between psa-1 and lin-35 as well as a subset of the class B synMuv genes that include lin-37 and lin-9. Loss-of-function mutations in lin-35, lin-37, and lin-9 strongly enhanced the defects of asymmetric T cell division associated with a psa-1 mutation. Our results suggest that LIN-35/Rb and a certain class B synMuv proteins collaborate with the SWI/SNF protein complex to regulate the T cell division as well as other events essential for larval growth.     

Compartment acidification is required for efficient sorting of proteins to the vacuole in Saccharomyces cerevisiae.

The vacuole of the yeast Saccharomyces cerevisiae contains a proton-translocating ATPase that acidifies the vacuolar lumen and generates a pH gradient across the vacuole membrane. We have investigated the role of compartment acidification of the vacuolar system in the sorting of vacuolar proteins. Strains with chromosomal disruptions of the genes encoding the A, B, or c subunit of the vacuolar ATPase are unable to acidify their vacuoles. These vat mutant strains accumulate and secrete precursor forms of the soluble vacuolar hydrolases carboxypeptidase Y and proteinase A. The kinetics of secretion suggests that missorting occurs in the Golgi complex or in post-Golgi vesicles. The presence of mature forms of the vacuolar proteins within the cell indicates that vat mutations do not cause defects in zymogen processing. Precursor forms of the membrane-associated vacuolar hydrolase alkaline phosphatase are also accumulated in vat mutant cells but to a lesser extent, suggesting that sorting of vacuolar membrane proteins is less sensitive to changes in the lumenal pH. A similar type of missorting defect can be induced in wild-type cells at pH 7.5. These results indicate that acidification of the vacuolar system is important for efficient sorting of proteins to the vacuole.