scholarly journals The Membrane Protein Alkaline Phosphatase Is Delivered to the Vacuole by a Route That Is Distinct from the VPS-dependent Pathway

1997 ◽  
Vol 138 (3) ◽  
pp. 531-545 ◽  
Author(s):  
Robert C. Piper ◽  
Nia J. Bryant ◽  
Tom H. Stevens
Keyword(s):  
Alkaline Phosphatase ◽  
Membrane Protein ◽  
Membrane Trafficking ◽  
Transmembrane Domain ◽  
Alternative Pathway ◽  
Loss Of Function ◽  
Yeast Saccharomyces Cerevisiae ◽  
Atpase Subunit ◽  
Transport Vesicles ◽  
Dependent Pathway

Membrane trafficking intermediates involved in the transport of proteins between the TGN and the lysosome-like vacuole in the yeast Saccharomyces cerevisiae can be accumulated in various vps mutants. Loss of function of Vps45p, an Sec1p-like protein required for the fusion of Golgi-derived transport vesicles with the prevacuolar/endosomal compartment (PVC), results in an accumulation of post-Golgi transport vesicles. Similarly, loss of VPS27 function results in an accumulation of the PVC since this gene is required for traffic out of this compartment. The vacuolar ATPase subunit Vph1p transits to the vacuole in the Golgi-derived transport vesicles, as defined by mutations in VPS45, and through the PVC, as defined by mutations in VPS27. In this study we demonstrate that, whereas VPS45 and VPS27 are required for the vacuolar delivery of several membrane proteins, the vacuolar membrane protein alkaline phosphatase (ALP) reaches its final destination without the function of these two genes. Using a series of ALP derivatives, we find that the information to specify the entry of ALP into this alternative pathway to the vacuole is contained within its cytosolic tail, in the 13 residues adjacent to the transmembrane domain, and loss of this sorting determinant results in a protein that follows the VPS-dependent pathway to the vacuole. Using a combination of immunofluorescence localization and pulse/chase immunoprecipitation analysis, we demonstrate that, in addition to ALP, the vacuolar syntaxin Vam3p also follows this VPS45/27-independent pathway to the vacuole. In addition, the function of Vam3p is required for membrane traffic along the VPS-independent pathway.

Pth1/Vam3p Is the Syntaxin Homolog at the Vacuolar Membrane of Saccharomyces cerevisae Required for the Delivery of Vacuolar Hydrolases

Genetics ◽  
1998 ◽  
Vol 148 (1) ◽  
pp. 85-98 ◽  
Author(s):  
Amit Srivastava ◽  
Elizabeth W Jones
Keyword(s):  
Alkaline Phosphatase ◽  
Membrane Protein ◽  
Protein Delivery ◽  
Transmembrane Domain ◽  
Integral Membrane Protein ◽  
Subcellular Fractionation ◽  
Vacuolar Membrane ◽  
Yeast Vacuole ◽  
Transport Vesicles ◽  
Vacuolar Membranes

AbstractThe 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 Δpth1/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 Δpth1/vam3 mutant. Maturation of pro-aminopeptidase I, a hydrolase precursor delivered directly to the vacuole from the cytoplasm, is also blocked in the Δpth1/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.

scholarly journals Erv26p Directs Pro-Alkaline Phosphatase into Endoplasmic Reticulum–derived Coat Protein Complex II Transport Vesicles

2006 ◽  
Vol 17 (11) ◽  
pp. 4780-4789 ◽  
Author(s):  
Catherine A. Bue ◽  
Christine M. Bentivoglio ◽  
Charles Barlowe
Keyword(s):  
Alkaline Phosphatase ◽  
Endoplasmic Reticulum ◽  
Coat Protein ◽  
Membrane Protein ◽  
Protein Complex ◽  
Integral Membrane Protein ◽  
Secretory Proteins ◽  
Complex Ii ◽  
Transport Vesicles ◽  
Copii Vesicles

Secretory proteins are exported from the endoplasmic reticulum (ER) in transport vesicles formed by the coat protein complex II (COPII). We detected Erv26p as an integral membrane protein that was efficiently packaged into COPII vesicles and cycled between the ER and Golgi compartments. The erv26Δ mutant displayed a selective secretory defect in which the pro-form of vacuolar alkaline phosphatase (pro-ALP) accumulated in the ER, whereas other secretory proteins were transported at wild-type rates. In vitro budding experiments demonstrated that Erv26p was directly required for packaging of pro-ALP into COPII vesicles. Moreover, Erv26p was detected in a specific complex with pro-ALP when immunoprecipitated from detergent-solublized ER membranes. Based on these observations, we propose that Erv26p serves as a transmembrane adaptor to link specific secretory cargo to the COPII coat. Because ALP is a type II integral membrane protein in yeast, these findings imply that an additional class of secretory cargo relies on adaptor proteins for efficient export from the ER.

scholarly journals Atg19 Mediates a Dual Interaction Cargo Sorting Mechanism in Selective Autophagy

2007 ◽  
Vol 18 (3) ◽  
pp. 919-929 ◽  
Author(s):  
Chiung-Ying Chang ◽  
Wei-Pang Huang
Keyword(s):  
Membrane Trafficking ◽  
Eukaryotic Cells ◽  
Vesicle Formation ◽  
Double Knockout ◽  
Yeast Saccharomyces Cerevisiae ◽  
Selective Autophagy ◽  
Atg Proteins ◽  
Transport Vesicles ◽  
Efficient Delivery ◽  
Transport Defect

Autophagy is a catabolic membrane-trafficking mechanism conserved in all eukaryotic cells. In addition to the nonselective transport of bulk cytosol, autophagy is responsible for efficient delivery of the vacuolar enzyme Ape1 precursor (prApe1) in the budding yeast Saccharomyces cerevisiae, suggesting the presence of a prApe1 sorting machinery. Sequential interactions between Atg19-Atg11 and Atg19-Atg8 pairs are thought responsible for targeting prApe1 to the vesicle formation site, the preautophagosomal structure (PAS), and loading it into transport vesicles, respectively. However, the different patterns of prApe1 transport defect seen in the atg11Δ and atg19Δ strains seem to be incompatible with this model. Here we report that prApe1 could not be targeted to the PAS and failed to be delivered into the vacuole in atg8Δ atg11Δ double knockout cells regardless of the nutrient conditions. We postulate that Atg19 mediates a dual interaction prApe1-sorting mechanism through independent, instead of sequential, interactions with Atg11 and Atg8. In addition, to efficiently deliver prApe1 to the vacuole, a proper interaction between Atg11 and Atg9 is indispensable. We speculate that Atg11 may elicit a cargo-loading signal and induce Atg9 shuttling to a specific PAS site, where Atg9 relays the signal and recruits other Atg proteins to induce vesicle formation.

scholarly journals Endosomal trafficking of yeast membrane proteins

2018 ◽  
Vol 46 (6) ◽  
pp. 1551-1558 ◽  
Author(s):  
Kamilla M. E. Laidlaw ◽  
Chris MacDonald
Keyword(s):  
Membrane Proteins ◽  
Membrane Protein ◽  
Membrane Trafficking ◽  
Surface Membrane ◽  
Multivesicular Body ◽  
Endosomal Trafficking ◽  
Yeast Saccharomyces Cerevisiae ◽  
Endosomal Membrane ◽  
Recent Developments ◽  
Intracellular Compartments

Various membrane trafficking pathways transport molecules through the endosomal system of eukaryotic cells, where trafficking decisions control the localisation and activity of a diverse repertoire of membrane protein cargoes. The budding yeast Saccharomyces cerevisiae has been used to discover and define many mechanisms that regulate conserved features of endosomal trafficking. Internalised surface membrane proteins first localise to endosomes before sorting to other compartments. Ubiquitination of endosomal membrane proteins is a signal for their degradation. Ubiquitinated cargoes are recognised by the endosomal sorting complex required for transport (ESCRT) apparatus, which mediate sorting through the multivesicular body pathway to the lysosome for degradation. Proteins that are not destined for degradation can be recycled to other intracellular compartments, such as the Golgi and the plasma membrane. In this review, we discuss recent developments elucidating the mechanisms that drive membrane protein degradation and recycling pathways in yeast.

scholarly journals Vamp-7 Mediates Vesicular Transport from Endosomes to Lysosomes

1999 ◽  
Vol 146 (4) ◽  
pp. 765-776 ◽  
Author(s):  
Raj J. Advani ◽  
Bin Yang ◽  
Rytis Prekeris ◽  
Kelly C. Lee ◽  
Judith Klumperman ◽  
...  
Keyword(s):  
Membrane Protein ◽  
Membrane Trafficking ◽  
Polyclonal Antibodies ◽  
Vesicular Transport ◽  
Brefeldin A ◽  
Immunohistochemical Analysis ◽  
Endocytic Pathway ◽  
Permeabilized Cells ◽  
Transport Vesicles ◽  
Late Endosomes

A more complete picture of the molecules that are critical for the organization of membrane compartments is beginning to emerge through the characterization of proteins in the vesicle-associated membrane protein (also called synaptobrevin) family of membrane trafficking proteins. To better understand the mechanisms of membrane trafficking within the endocytic pathway, we generated a series of monoclonal and polyclonal antibodies against the cytoplasmic domain of vesicle-associated membrane protein 7 (VAMP-7). The antibodies recognize a 25-kD membrane-associated protein in multiple tissues and cell lines. Immunohistochemical analysis reveals colocalization with a marker of late endosomes and lysosomes, lysosome-associated membrane protein 1 (LAMP-1), but not with other membrane markers, including p115 and transferrin receptor. Treatment with nocodozole or brefeldin A does not disrupt the colocalization of VAMP-7 and LAMP-1. Immunoelectron microscopy analysis shows that VAMP-7 is most concentrated in the trans-Golgi network region of the cell as well as late endosomes and transport vesicles that do not contain the mannose-6 phosphate receptor. In streptolysin- O–permeabilized cells, antibodies against VAMP-7 inhibit the breakdown of epidermal growth factor but not the recycling of transferrin. These data are consistent with a role for VAMP-7 in the vesicular transport of proteins from the early endosome to the lysosome.

scholarly journals Crossover Interference in Saccharomyces cerevisiae Requires a TID1/RDH54- and DMC1-Dependent Pathway

Genetics ◽  
2003 ◽  
Vol 163 (4) ◽  
pp. 1273-1286 ◽  
Author(s):  
Miki Shinohara ◽  
Kazuko Sakai ◽  
Akira Shinohara ◽  
Douglas K Bishop
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Meiotic Recombination ◽  
Strand Break ◽  
Tetrad Analysis ◽  
Yeast Saccharomyces Cerevisiae ◽  
Crossover Interference ◽  
Meiotic Progression ◽  
Invasion Stage ◽  
Strand Invasion ◽  
Dependent Pathway

Abstract Two RecA-like recombinases, Rad51 and Dmc1, function together during double-strand break (DSB)-mediated meiotic recombination to promote homologous strand invasion in the budding yeast Saccharomyces cerevisiae. Two partially redundant proteins, Rad54 and Tid1/Rdh54, act as recombinase accessory factors. Here, tetrad analysis shows that mutants lacking Tid1 form four-viable-spore tetrads with levels of interhomolog crossover (CO) and noncrossover recombination similar to, or slightly greater than, those in wild type. Importantly, tid1 mutants show a marked defect in crossover interference, a mechanism that distributes crossover events nonrandomly along chromosomes during meiosis. Previous work showed that dmc1Δ mutants are strongly defective in strand invasion and meiotic progression and that these defects can be partially suppressed by increasing the copy number of RAD54. Tetrad analysis is used to show that meiotic recombination in RAD54-suppressed dmc1Δ cells is similar to that in tid1; the frequency of COs and gene conversions is near normal, but crossover interference is defective. These results support the proposal that crossover interference acts at the strand invasion stage of recombination.

scholarly journals mRNA Surveillance Complex PELOTA-HBS1 Regulates Phosphoinositide-Dependent Protein Kinase1 and Plant Growth

2021 ◽  
Author(s):  
Wei Kong ◽  
Shutang Tan ◽  
Qing Zhao ◽  
De-Li Lin ◽  
Zhi-Hong Xu ◽  
...  
Keyword(s):  
Quality Control ◽  
Messenger Rna ◽  
Loss Of Function ◽  
Yeast Saccharomyces Cerevisiae ◽  
Developmental Defects ◽  
Mrna Surveillance ◽  
Dna Insertion ◽  
Dependent Protein ◽  
Heterodimeric Complex ◽  
Severe Growth

Abstract The quality control system for messenger RNA (mRNA) is fundamental for cellular activities in eukaryotes. To elucidate the molecular mechanism of 3’-Phosphoinositide-Dependent Protein Kinase1 (PDK1), a master regulator that is essential throughout eukaryotic growth and development, we employed a forward genetic approach to screen for suppressors of the loss-of-function T-DNA insertion double mutant pdk1.1 pdk1.2 in Arabidopsis thaliana. Notably, the severe growth attenuation of pdk1.1 pdk1.2 was rescued by sop21 (suppressor of pdk1.1 pdk1.2), which harbours a loss-of-function mutation in PELOTA1 (PEL1). PEL1 is a homologue of mammalian PELOTA and yeast (Saccharomyces cerevisiae) DOM34p, which each form a heterodimeric complex with the GTPase HBS1 (HSP70 SUBFAMILY B SUPPRESSOR1, also called SUPERKILLER PROTEIN7, SKI7), a protein that is responsible for ribosomal rescue and thereby assures the quality and fidelity of mRNA molecules during translation. Genetic analysis further revealed that a dysfunctional PEL1-HBS1 complex failed to degrade the T-DNA-disrupted PDK1 transcripts, which were truncated but functional, and thus rescued the growth and developmental defects of pdk1.1 pdk1.2. Our studies demonstrated the functionality of a homologous PELOTA-HBS1 complex and identified its essential regulatory role in plants, providing insights into the mechanism of mRNA quality control.

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