Your search keyword '"Glucose Transport Proteins, Facilitative"' showing total 21 results

1. Alternative Splicing and Cleavage of GLUT8

Author

Elias Oxman, Ildiko Kasza, Joshua A. Martin, Katherine A. Senn, Caroline M. Alexander, and Heidi Dvinge

Subjects

GLUT8, Population, Glucose Transport Proteins, Facilitative, Endosomes, 03 medical and health sciences, 0302 clinical medicine, Cell Line, Tumor, Homeostasis, Humans, RNA, Messenger, education, Molecular Biology, Cells, Cultured, 030304 developmental biology, Glucose Transporter Type 1, 0303 health sciences, education.field_of_study, Messenger RNA, biology, Alternative splicing, Glucose transporter, Transporter, Cell Biology, Cell biology, Alternative Splicing, Glucose, 030220 oncology & carcinogenesis, RNA splicing, biology.protein, GLUT1, Lysosomes, Research Article

Abstract

The GLUT (SLC2) family of membrane-associated transporters are described as glucose transporters. However, this family is divided into three classes and, though the regulated transporter activity of class I proteins is becoming better understood, class III protein functions continue to be obscure. We have cataloged the relative expression and splicing of SLC2 mRNA isomers in tumors and normal tissues, with a focus on breast tumors and cell lines. mRNA for the class III protein GLUT8 is the predominant SLC2 species expressed alongside GLUT1 in many tissues, but GLUT8 mRNA exists mostly as an untranslated splice form in tumors. We confirm that GLUT8 is not presented at the cell surface and does not transport glucose directly. However, we reveal a lysosome-dependent reaction that cleaves the GLUT8 protein and releases the carboxy-terminal peptide to a separate vesicle population. Given the localization of GLUT8 at a major metabolic hub (the late endosomal/lysosomal interface) and its regulated cleavage reaction, we evaluated TXNIP-mediated hexosamine homeostasis and speculate that GLUT8 may function as a sensory component of this reaction.

Published

2021

2. Targeted Degradation of Glucose Transporters Protects against Arsenic Toxicity

Author

Jessie Ang, Marta Isasa, John Hanna, Steven P. Gygi, Meera K. Bhanu, Marco Jochem, Helena M. Schnell, Lukas Ende, Yagmur Micoogullari, and Angel Guerra-Moreno

Subjects

Proteomics, Glucose Transport Proteins, Facilitative, chemistry.chemical_element, Down-Regulation, Saccharomyces cerevisiae, Protein degradation, Arsenic, 03 medical and health sciences, 0302 clinical medicine, Ubiquitin, Downregulation and upregulation, Molecular Biology, 030304 developmental biology, 0303 health sciences, Microbial Viability, biology, Arsenic toxicity, Glucose transporter, Ubiquitination, Transporter, Cell Biology, Ubiquitin ligase, Biochemistry, chemistry, Mutation, Proteolysis, biology.protein, 030217 neurology & neurosurgery, Research Article

Abstract

The abundance of cell surface glucose transporters must be precisely regulated to ensure optimal growth under constantly changing environmental conditions. We recently conducted a proteomic analysis of the cellular response to trivalent arsenic, a ubiquitous environmental toxin and carcinogen. A surprising finding was that a subset of glucose transporters was among the most downregulated proteins in the cell upon arsenic exposure. Here we show that this downregulation reflects targeted arsenic-dependent degradation of glucose transporters. Degradation occurs in the vacuole and requires the E2 ubiquitin ligase Ubc4, the E3 ubiquitin ligase Rsp5, and K63-linked ubiquitin chains. We used quantitative proteomic approaches to determine the ubiquitinated proteome after arsenic exposure, which helped us to identify the ubiquitination sites within these glucose transporters. A mutant lacking all seven major glucose transporters was highly resistant to arsenic, and expression of a degradation-resistant transporter restored arsenic sensitivity to this strain, suggesting that this pathway represents a protective cellular response. Previous work suggests that glucose transporters are major mediators of arsenic import, providing a potential rationale for this pathway. These results may have implications for the epidemiologic association between arsenic exposure and diabetes.

Published

2018

3. 2-Deoxyglucose Impairs Saccharomyces cerevisiae Growth by Stimulating Snf1-Regulated and α-Arrestin-Mediated Trafficking of Hexose Transporters 1 and 3

Author

Bob B. Zhang, Allyson F. O'Donnell, Dakshayini G. Chandrashekarappa, Martin C. Schmidt, Rhonda R. McCartney, and Jeremy Thorner

Subjects

Snf3, Saccharomyces cerevisiae Proteins, media_common.quotation_subject, Saccharomyces cerevisiae, Glucose Transport Proteins, Facilitative, Vacuole, Deoxyglucose, Protein Serine-Threonine Kinases, Ubiquitin, Internalization, Molecular Biology, media_common, Arrestin, Endosomal Sorting Complexes Required for Transport, biology, Glucose transporter, Membrane Proteins, Membrane Transport Proteins, Ubiquitin-Protein Ligase Complexes, Glucose analog, Articles, Cell Biology, biology.organism_classification, Endocytosis, Ubiquitin ligase, Cell biology, Protein Transport, Glucose, Biochemistry, biology.protein

Abstract

The glucose analog 2-deoxyglucose (2DG) inhibits the growth of Saccharomyces cerevisiae and human tumor cells, but its modes of action have not been fully elucidated. Yeast cells lacking Snf1 (AMP-activated protein kinase) are hypersensitive to 2DG. Overexpression of either of two low-affinity, high-capacity glucose transporters, Hxt1 and Hxt3, suppresses the 2DG hypersensitivity of snf1Δ cells. The addition of 2DG or the loss of Snf1 reduces HXT1 and HXT3 expression levels and stimulates transporter endocytosis and degradation in the vacuole. 2DG-stimulated trafficking of Hxt1 and Hxt3 requires Rod1/Art4 and Rog3/Art7, two members of the α-arrestin trafficking adaptor family. Mutations in ROD1 and ROG3 that block binding to the ubiquitin ligase Rsp5 eliminate Rod1- and Rog3-mediated trafficking of Hxt1 and Hxt3. Genetic analysis suggests that Snf1 negatively regulates both Rod1 and Rog3, but via different mechanisms. Snf1 activated by 2DG phosphorylates Rod1 but fails to phosphorylate other known targets, such as the transcriptional repressor Mig1. We propose a novel mechanism for 2DG-induced toxicity whereby 2DG stimulates the modification of α-arrestins, which promote glucose transporter internalization and degradation, causing glucose starvation even when cells are in a glucose-rich environment.

Published

2015

4. The Laforin-Malin Complex Negatively Regulates Glycogen Synthesis by Modulating Cellular Glucose Uptake via Glucose Transporters

Author

Subramaniam Ganesh, Sweta Singh, and Pankaj Kumar Singh

Subjects

Glucose uptake, Glucose Transport Proteins, Facilitative, AMP-Activated Protein Kinases, Biology, Lafora disease, Glycogen debranching enzyme, Mice, chemistry.chemical_compound, Adenosine Triphosphate, Chlorocebus aethiops, medicine, Animals, Humans, Protein kinase A, Glycogen synthase, Molecular Biology, Inclusion Bodies, Glycogen, Glucose transporter, Biological Transport, Articles, Cell Biology, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Glucose, Lafora Disease, chemistry, Biochemistry, COS Cells, biology.protein, Carrier Proteins, Laforin

Abstract

Lafora disease (LD), an inherited and fatal neurodegenerative disorder, is characterized by increased cellular glycogen content and the formation of abnormally branched glycogen inclusions, called Lafora bodies, in the affected tissues, including neurons. Therefore, laforin phosphatase and malin ubiquitin E3 ligase, the two proteins that are defective in LD, are thought to regulate glycogen synthesis through an unknown mechanism, the defects in which are likely to underlie some of the symptoms of LD. We show here that laforin's subcellular localization is dependent on the cellular glycogen content and that the stability of laforin is determined by the cellular ATP level, the activity of 5′-AMP-activated protein kinase, and the affinity of malin toward laforin. By using cell and animal models, we further show that the laforin-malin complex regulates cellular glucose uptake by modulating the subcellular localization of glucose transporters; loss of malin or laforin resulted in an increased abundance of glucose transporters in the plasma membrane and therefore excessive glucose uptake. Loss of laforin or malin, however, did not affect glycogen catabolism. Thus, the excessive cellular glucose level appears to be the primary trigger for the abnormally higher levels of cellular glycogen seen in LD.

Published

2012

5. Embryonic Fibroblasts from Mice Lacking Tgif Were Defective in Cell Cycling

Author

Pamela A. Hoodless and Lynn Mar

Subjects

Glucose Transport Proteins, Facilitative, Retinoic acid, Embryonic Development, Tretinoin, Biology, Retinoid X receptor, Functional Laterality, Mice, chemistry.chemical_compound, Transforming Growth Factor beta, Coactivator, Animals, Molecular Biology, Transcription factor, Cell Proliferation, Homeodomain Proteins, Cell Cycle, Gene Expression Regulation, Developmental, Articles, Cell Biology, Transforming growth factor beta, Fibroblasts, Embryo, Mammalian, Molecular biology, Retinoic acid receptor, Phenotype, chemistry, Gene Targeting, Histone deacetylase complex, biology.protein, PAX6

Abstract

Holoprosencephaly (HPE) is the most common birth defect affecting prosencephalic development, resulting in the loss of forebrain midline structures (35). More than 12 chromosomal regions have been mapped in sporadic and familial HPE cases. One region, mapping at 18p11.3 in humans, contains the gene TGIF. Deletions and mutations of TGIF have been associated with HPE (1, 5, 12, 16, 41). Intriguingly, HPE demonstrates considerable variability and incomplete penetrance; the penetrance for TGIF mutations or deletions is only 10% (1, 38). TGIF is a three-amino-acid loop extension (TALE) homeobox-containing transcription factor. Members of the TALE family, which includes PBC and MEIS class proteins, form heteromeric complexes with each other to regulate transcription of developmentally important genes, such as the Hox and Pax6 genes (31). Members of this family can also function as cofactors to provide specificity and cooperativity for Hox genes. Although TGIF has not been shown to bind PBC proteins (11, 23), TGIF can mutually compete and inhibit downstream target genes with MEIS (58). TGIF was first implicated as an antagonist in the retinoic acid (RA) pathway because it competed for DNA binding with the RXRα retinoic acid receptor (6). In addition, TGIF has been shown to repress downstream transcriptional activity of RXR (4). Subsequently, TGIF was also shown to be a transcriptional corepressor, interacting with Smad2 to regulate transforming growth factor beta (TGF-β)-responsive gene transcription (55). TGF-β-dependent transcriptional repression by TGIF is mediated through multiple domains, by direct competition with the coactivator p300/CBP for Smad2 interaction and through recruitment of the histone deacetylase complex, the carboxyl terminal binding protein (CtBP) complex, and the Sin3 complex, all of which modify chromatin configuration (33, 54, 56). Finally, TGIF protein stability can also be regulated by the Ras/mitogen-activated protein kinase (MAPK) pathway (28). Interestingly, both the retinoic acid and the TGF-β/Nodal pathways have been implicated in the development of HPE. Mutations in FOXH1, a transcription factor in the TGF-β pathway, have been identified in HPE patients (34). Similarly, mice deficient for genes in the TGF-β pathway, such as the compound mutant Smad2+/− Nodal+/−, developed HPE (39). In addition, prenatal exposure to retinoic acid causes susceptibility to HPE in humans and model organisms (34, 44). To investigate the function of Tgif during mouse development, we generated Tgif-null mice. The loss of Tgif resulted in a spectrum of abnormal phenotypes, including laterality defects, all of which occurred at low penetrance. In addition, fibroblasts derived from mutant embryos displayed a cell cycle progression defect. We demonstrated that expression of wild-type human TGIF proteins rescued the proliferative defect in mouse embryonic fibroblasts (MEFs) while expression of proteins containing a subset of mutations within the homeodomain identified in HPE patients did not. Unexpectedly, the absence of Tgif did not alter the normal antiproliferative response to stimulation of the TGF-β, retinoic acid, or Ras/MAPK pathways.

Published

2006

6. GLUT8 Is Dispensable for Embryonic Development but Influences Hippocampal Neurogenesis and Heart Function

Author

Thierry Pedrazzini, Friedrich Beermann, Bernard Thorens, Mathieu Membrez, Jacques-Antoine Haefliger, Edith Hummler, and Rebecca Savioz

Subjects

medicine.medical_specialty, GLUT8, Genotype, Organogenesis, Xenopus, Glucose Transport Proteins, Facilitative, Embryonic Development, Connexin, Hippocampal formation, Hippocampus, Connexins, Sodium Channels, Mice, Internal medicine, medicine, Animals, Homeostasis, Glucose homeostasis, RNA, Messenger, Molecular Biology, Cell Proliferation, Mice, Knockout, biology, Heart development, Myocardium, Body Weight, Neurogenesis, Glucose transporter, Heart, Organ Size, Articles, Cell Biology, Glucose, Endocrinology, Gene Targeting, biology.protein

Abstract

GLUT8 is a glucose transporter isoform expressed at high levels in testis; at intermediate levels in the brain, including the hippocampus; and at lower levels in the heart and several other tissues. GLUT8 is located in an intracellular compartment and does not appear to translocate to the cell surface, except in blastocysts, where insulin has been reported to induce its surface expression. Here, we generated mice with inactivation of the glut8 gene. We showed that expression of GLUT8 was not required for normal embryonic development and that glut8-/- mice had normal postnatal development, glucose homeostasis, and response to mild stress. Adult glut8-/- mice showed increased proliferation of hippocampal cells but no defect in memory acquisition and retention. Absence of GLUT8 from the heart did not alter heart size and morphology but led to an increase in P-wave duration, which was not associated with abnormal Nav1.5 Na+ channel or connexin expression. Thus, absence of GLUT8 expression in the mouse caused complex but mild physiological alterations.

Published

2006

7. Evidence for High-Capacity Bidirectional Glucose Transport across the Endoplasmic Reticulum Membrane by Genetically Encoded Fluorescence Resonance Energy Transfer Nanosensors

Author

David W. Ehrhardt, Marcus Fehr, Hitomi Takanaga, and Wolf B. Frommer

Subjects

Cytochalasin B, Glucose Transport Proteins, Facilitative, Biosensing Techniques, Biology, Endoplasmic Reticulum, Cell membrane, chemistry.chemical_compound, Cytosol, Fluorescence Resonance Energy Transfer, medicine, Humans, Nanotechnology, Molecular Biology, Endoplasmic reticulum, Cell Membrane, Glucose transporter, Biological Transport, Intracellular Membranes, Cell Biology, Membrane transport, Cell biology, Glucose, medicine.anatomical_structure, Gluconeogenesis, chemistry, Galactose, Hepatocytes, Signal Transduction

Abstract

Glucose release from hepatocytes is important for maintenance of blood glucose levels. Glucose-6-phosphate phosphatase, catalyzing the final metabolic step of gluconeogenesis, faces the endoplasmic reticulum (ER) lumen. Thus, glucose produced in the ER has to be either exported from the ER into the cytosol before release into circulation or exported directly by a vesicular pathway. To measure ER transport of glucose, fluorescence resonance energy transfer-based nanosensors were targeted to the cytosol or the ER lumen of HepG2 cells. During perfusion with 5 mM glucose, cytosolic levels were maintained at approximately 80% of the external supply, indicating that plasma membrane transport exceeded the rate of glucose phosphorylation. Glucose levels and kinetics inside the ER were indistinguishable from cytosolic levels, suggesting rapid bidirectional glucose transport across the ER membrane. A dynamic model incorporating rapid bidirectional ER transport yields a very good fit with the observed kinetics. Plasma membrane and ER membrane glucose transport differed regarding sensitivity to cytochalasin B and showed different relative kinetics for galactose uptake and release, suggesting catalysis by distinct activities at the two membranes. The presence of a high-capacity glucose transport system on the ER membrane is consistent with the hypothesis that glucose export from hepatocytes occurs via the cytosol by a yet-to-be-identified set of proteins.

Published

2005

8. Differential Requirement of SAGA Subunits for Mot1p and Taf1p Recruitment in Gene Activation

Author

H. T. Marc Timmers, Hetty A.A.M. van Teeffelen, and Chris J. C. van Oevelen

Subjects

Transcriptional Activation, Saccharomyces cerevisiae Proteins, Monosaccharide Transport Proteins, Transcription, Genetic, Glucose Transport Proteins, Facilitative, Gene Expression, RNA polymerase II, Saccharomyces cerevisiae, Gene Expression Regulation, Fungal, Promoter Regions, Genetic, Molecular Biology, Transcription factor, Histone Acetyltransferases, Adenosine Triphosphatases, TATA-Binding Protein Associated Factors, Genetics, biology, DNA Helicases, Membrane Proteins, Promoter, Cell Biology, DNA-Binding Proteins, Protein Subunits, TAF1, Glucose, Transcription Factor TFIID, biology.protein, Transcription factor II D, TATA-binding protein, Protein Kinases, Protein Binding, Transcription Factors

Abstract

Transcription activation in yeast (Saccharomyces cerevisiae) involves ordered recruitment of transcription factor complexes, such as TFIID, SAGA, and Mot1p. Previously, we showed that both Mot1p and Taf1p are recruited to the HXT2 and HXT4 genes, which encode hexose transporter proteins. Here, we show that SAGA also binds to the HXT2 and HXT4 promoters and plays a pivotal role in the recruitment of Mot1p and Taf1p. The deletion of either SPT3 or SPT8 reduces Mot1p binding to HXT2 and HXT4. Surprisingly, the deletion of GCN5 reduces Taf1p binding to both promoters. When GCN5 is deleted in spt3Delta or spt8Delta strains, neither Mot1p nor Taf1p binds, and this results in a diminished recruitment of TATA binding protein and polymerase II to the HXT4 but not the HXT2 promoter. This is reflected by the SAGA-dependent expression of HXT4. In contrast, SAGA-independent induction of HXT2 suggests a functional redundancy with other factors. A functional interplay of different SAGA subunits with Mot1p and Taf1p was supported by phenotypic analysis of MOT1 SAGA or TAF1/SAGA double mutant strains, which revealed novel genetic interactions between MOT1 and SPT8 and between TAF1 and GCN5. In conclusion, our data demonstrate functional links between SAGA, Mot1p, and TFIID in HXT gene regulation.

Published

2005

9. Regulation and Recognition of SCFGrr1 Targets in the Glucose and Amino Acid Signaling Pathways

Author

Nathalie Spielewoy, Tatyana I. Kalashnikova, Karin Flick, Curt Wittenberg, and John R. Walker

Subjects

Proteasome Endopeptidase Complex, Saccharomyces cerevisiae Proteins, Monosaccharide Transport Proteins, Ubiquitin-Protein Ligases, Saccharomyces cerevisiae, Glucose Transport Proteins, Facilitative, Biology, F-box protein, Ubiquitin, Cyclin-dependent kinase, Cyclins, Gene Expression Regulation, Fungal, Casein Kinase I, Amino Acids, Cell Growth and Development, Molecular Biology, Adaptor Proteins, Signal Transducing, SKP Cullin F-Box Protein Ligases, F-Box Proteins, Membrane Proteins, Cell Biology, biology.organism_classification, Protein Structure, Tertiary, Cell biology, Glucose, Proteasome, Biochemistry, Mutation, biology.protein, Phosphorylation, Casein kinases, Protein Binding, Signal Transduction

Abstract

SCFGrr1, one of several members of the SCF family of E3 ubiquitin ligases in budding Saccharomyces cerevisiae, is required for both regulation of the cell cycle and nutritionally controlled transcription. In addition to its role in degradation of Gic2 and the CDK targets Cln1 and Cln2, Grr1 is also required for induction of glucose- and amino acid-regulated genes. Induction of HXT genes by glucose requires the Grr1-dependent degradation of Mth1. We show that Mth1 is ubiquitinated in vivo and degraded via the proteasome. Furthermore, phosphorylated Mth1, targeted by the casein kinases Yck1/2, binds to Grr1. That binding depends upon the Grr1 leucine-rich repeat (LRR) domain but not upon the F-box or basic residues within the LRR that are required for recognition of Cln2 and Gic2. Those observations extend to a large number of Grr1-dependent genes, some targets of the amino acid-regulated SPS signaling system, which are properly regulated in the absence of those basic LRR residues. Finally, we show that regulation of the SPS targets requires the Yck1/2 casein kinases. We propose that casein kinase I plays a similar role in both nutritional signaling pathways by phosphorylating pathway components and targeting them for ubiquitination by SCFGrr1.

Published

2004

10. Psy2 targets the PP4 family phosphatase Pph3 to dephosphorylate Mth1 and repress glucose transporter gene expression

Author

Curt Wittenberg, Aaron Aslanian, Marisela Guaderrama, Tony Hunter, John R. Yates, Hui Ma, and Bong-Kwan Han

Subjects

Snf3, Saccharomyces cerevisiae Proteins, Phosphatase, Immunoblotting, Glucose Transport Proteins, Facilitative, Saccharomyces cerevisiae, Biology, Gene Expression Regulation, Fungal, Two-Hybrid System Techniques, Phosphoprotein Phosphatases, Protein phosphorylation, Phosphorylation, Protein kinase A, Molecular Biology, Adaptor Proteins, Signal Transducing, Kinase, Reverse Transcriptase Polymerase Chain Reaction, Glucose transporter, Nuclear Proteins, Cell Biology, Protein phosphatase 2, Articles, Cyclic AMP-Dependent Protein Kinases, DNA-Binding Proteins, Enzyme Activation, Glucose, Biochemistry, Mutation, Protein Binding, Transcription Factors

Abstract

The reversible nature of protein phosphorylation dictates that any protein kinase activity must be counteracted by protein phosphatase activity. How phosphatases target specific phosphoprotein substrates and reverse the action of kinases, however, is poorly understood in a biological context. We address this question by elucidating a novel function of the conserved PP4 family phosphatase Pph3-Psy2, the yeast counterpart of the mammalian PP4c-R3 complex, in the glucose-signaling pathway. Our studies show that Pph3-Psy2 specifically targets the glucose signal transducer protein Mth1 via direct binding of the EVH1 domain of the Psy2 regulatory subunit to the polyproline motif of Mth1. This activity is required for the timely dephosphorylation of the downstream transcriptional repressor Rgt1 upon glucose withdrawal, a critical event in the repression of HXT genes, which encode glucose transporters. Pph3-Psy2 dephosphorylates Mth1, an Rgt1 associated corepressor, but does not dephosphorylate Rgt1 at sites associated with inactivation, in vitro. We show that Pph3-Psy2 phosphatase antagonizes Mth1 phosphorylation by protein kinase A (PKA), the major protein kinase activated in response to glucose, in vitro and regulates Mth1 function via putative PKA phosphorylation sites in vivo. We conclude that the Pph3-Psy2 phosphatase modulates Mth1 activity to facilitate precise regulation of HXT gene expression by glucose.

Published

2013

11. Two Different Repressors Collaborate To Restrict Expression of the Yeast Glucose Transporter Genes HXT2 and HXT4 to Low Levels of Glucose

Author

Mark Johnston and Sabire Özcan

Subjects

Snf3, Saccharomyces cerevisiae Proteins, Genotype, Monosaccharide Transport Proteins, Recombinant Fusion Proteins, Genes, Fungal, Molecular Sequence Data, Saccharomyces cerevisiae, Glucose Transport Proteins, Facilitative, Repressor, Regulatory Sequences, Nucleic Acid, Fungal Proteins, Transcription (biology), Gene Expression Regulation, Fungal, Gene expression, Transcriptional regulation, Cloning, Molecular, Promoter Regions, Genetic, Molecular Biology, DNA Primers, Sequence Deletion, Binding Sites, Base Sequence, biology, Glucose transporter, Membrane Proteins, Zinc Fingers, Promoter, Cell Biology, beta-Galactosidase, biology.organism_classification, DNA-Binding Proteins, Repressor Proteins, Glucose, Oligodeoxyribonucleotides, Biochemistry, Mutagenesis, Research Article

Abstract

Transcription of the yeast HXT2 and HXT4 genes, which encode glucose transporters, is induced only by low levels of glucose. This low-glucose-induced expression is mediated by two independent repression mechanisms: in the absence of glucose, transcription of both genes is prevented by Rgt1p, a C6 zinc cluster protein; at high levels of glucose, expression of HXT2 and HXT4 is repressed by Mig1p. Only at low glucose concentrations are both repressors inactive, leading to a 10- to 20-fold induction of gene expression. Mig1p and Rgt1p act directly on HXT2 and HXT4 by binding to their promoters. This transcriptional regulation is physiologically very important to the yeast cell because it causes these glucose transporters to be expressed only in low-glucose media, in which they are required for growth.

Published

1996

12. Std1 and Mth1 proteins interact with the glucose sensors to control glucose-regulated gene expression in Saccharomyces cerevisiae

Author

Simon C. Watkins, Harry Solimeo, Ciprian Almonte, Tommy S. Tillman, Stefan Wölfl, Rhonda R. McCartney, Xudong Zhang, and Martin C. Schmidt

Subjects

Snf3, Saccharomyces cerevisiae Proteins, Glycoside Hydrolases, Monosaccharide Transport Proteins, Recombinant Fusion Proteins, Mutant, Saccharomyces cerevisiae, Green Fluorescent Proteins, Glucose Transport Proteins, Facilitative, Mutagenesis (molecular biology technique), Gene Expression, Gene Expression Regulation, Enzymologic, Fungal Proteins, Gene Expression Regulation, Fungal, Gene expression, Cloning, Molecular, Molecular Biology, Adaptor Proteins, Signal Transducing, Regulation of gene expression, biology, beta-Fructofuranosidase, Glucose transporter, Intracellular Signaling Peptides and Proteins, Membrane Proteins, Cell Biology, biology.organism_classification, Luminescent Proteins, Glucose, Membrane protein, Biochemistry, Mutagenesis

Abstract

The Std1 protein modulates the expression of glucose-regulated genes, but its exact molecular role in this process is unclear. A two-hybrid screen for Std1-interacting proteins identified the hydrophilic C-terminal domains of the glucose sensors, Snf3 and Rgt2. The homologue of Std1, Mth1, behaves differently from Std1 in this assay by interacting with Snf3 but not Rgt2. Genetic interactions between STD1, MTH1, SNF3, and RGT2 suggest that the glucose signaling is mediated, at least in part, through interactions of the products of these four genes. Mutations in MTH1 can suppress the raffinose growth defect of a snf3 mutant as well as the glucose fermentation defect present in cells lacking both glucose sensors (snf3 rgt2). Genetic suppression by mutations in MTH1 is likely to be due to the increased and unregulated expression of hexose transporter genes. In media lacking glucose or with low levels of glucose, the hexose transporter genes are subject to repression by a mechanism that requires the Std1 and Mth1 proteins. An additional mechanism for glucose sensing must exist since a strain lacking all four genes (snf3 rgt2 std1 mth1) is still able to regulate SUC2 gene expression in response to changes in glucose concentration. Finally, studies with green fluorescent protein fusions indicate that Std1 is localized to the cell periphery and the cell nucleus, supporting the idea that it may transduce signals from the plasma membrane to the nucleus.

Published

1999

13. Trinucleotide insertions, deletions, and point mutations in glucose transporters confer K+ uptake in Saccharomyces cerevisiae

Author

Hong Liang, Christopher H. Ko, Todd Herman, and Richard F. Gaber

Subjects

Saccharomyces cerevisiae Proteins, Monosaccharide Transport Proteins, Glucose uptake, Mutant, Saccharomyces cerevisiae, Glucose Transport Proteins, Facilitative, Biology, Protein Structure, Secondary, Fungal Proteins, chemistry.chemical_compound, Trinucleotide Repeats, Cell and Organelle Structure and Assembly, Point Mutation, Genes, Suppressor, Molecular Biology, Gene, Alleles, Sequence Deletion, Point mutation, Glucose transporter, Membrane Proteins, Transporter, Cell Biology, biology.organism_classification, Molecular biology, chemistry, Biochemistry, Galactose, Potassium

Abstract

Deletion of TRK1 and TRK2 abolishes high-affinity K+ uptake in Saccharomyces cerevisiae, resulting in the inability to grow on typical synthetic growth medium unless it is supplemented with very high concentrations of potassium. Selection for spontaneous suppressors that restored growth of trk1delta trk2delta cells on K+-limiting medium led to the isolation of cells with unusual gain-of-function mutations in the glucose transporter genes HXT1 and HXT3 and the glucose/galactose transporter gene GAL2. 86Rb uptake assays demonstrated that the suppressor mutations conferred increased uptake of the ion. In addition to K+, the mutant hexose transporters also conferred permeation of other cations, including Na+. Because the selection strategy required such gain of function, mutations that disrupted transporter maturation or localization to the plasma membrane were avoided. Thus, the importance of specific sites in glucose transport could be independently assessed by testing for the ability of the mutant transporter to restore glucose-dependent growth to cells containing null alleles of all of the known functional glucose transporter genes. Twelve sites, most of which are conserved among eukaryotic hexose transporters, were revealed to be essential for glucose transport. Four of these have previously been shown to be essential for glucose transport by animal or plant transporters. Eight represented sites not previously known to be crucial for glucose uptake. Each suppressor mutant harbored a single mutation that altered an amino acid(s) within or immediately adjacent to a putative transmembrane domain of the transporter. Seven of 38 independent suppressor mutations consisted of in-frame insertions or deletions. The nature of the insertions and deletions revealed a striking DNA template dependency: each insertion generated a trinucleotide repeat, and each deletion involved the removal of a repeated nucleotide sequence.

Published

1998

14. Rgt1p of Saccharomyces cerevisiae, a key regulator of glucose-induced genes, is both an activator and a repressor of transcription

Author

T Leong, Mark Johnston, and Sabire Özcan

Subjects

Snf3, Saccharomyces cerevisiae Proteins, Genotype, Monosaccharide Transport Proteins, Transcription, Genetic, Saccharomyces cerevisiae, Molecular Sequence Data, Restriction Mapping, Glucose Transport Proteins, Facilitative, Repressor, Fungal Proteins, Bacterial Proteins, Transcription (biology), Promoter Regions, Genetic, Molecular Biology, Gene, Transcription factor, biology, Activator (genetics), Serine Endopeptidases, Glucose transporter, Cell Biology, biology.organism_classification, Recombinant Proteins, DNA-Binding Proteins, Repressor Proteins, Kinetics, Glucose, Biochemistry, Trans-Activators, Transcription Factors, Research Article

Abstract

The RGT1 gene of Saccharomyces cerevisiae plays a central role in the glucose-induced expression of hexose transporter (HXT) genes. Genetic evidence suggests that it encodes a repressor of the HXT genes whose function is inhibited by glucose. Here, we report the isolation of RGT1 and demonstrate that it encodes a bifunctional transcription factor. Rgt1p displays three different transcriptional modes in response to glucose: (i) in the absence of glucose, it functions as a transcriptional repressor; (ii) high concentrations of glucose cause it to function as a transcriptional activator; and (iii) in cells growing on low levels of glucose, Rgt1p has a neutral role, neither repressing nor activating transcription. Glucose alters Rgt1p function through a pathway that includes two glucose sensors, Snf3p and Rgt2p, and Grr1p. The glucose transporter Snf3p, which appears to be a low-glucose sensor, is required for inhibition of Rgt1p repressor function by low levels of glucose. Rgt2p, a glucose transporter that functions as a high-glucose sensor, is required for conversion of Rgt1p into an activator by high levels of glucose. Grr1p, a component of the glucose signaling pathway, is required both for inactivation of Rgt1p repressor function by low levels of glucose and for conversion of Rgt1p into an activator at high levels of glucose. Thus, signals generated by two different glucose sensors act through Grr1p to determine Rgt1p function.

Published

1996

15. Differential requirement of SAGA subunits for Mot1p and Taf1p recruitment in gene activation.

Author

van Oevelen CJ, van Teeffelen HA, and Timmers HT

Subjects

Adenosine Triphosphatases, DNA Helicases genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Glucose metabolism, Glucose Transport Proteins, Facilitative, Histone Acetyltransferases, Membrane Proteins genetics, Membrane Proteins metabolism, Monosaccharide Transport Proteins genetics, Monosaccharide Transport Proteins metabolism, Promoter Regions, Genetic, Protein Binding, Protein Kinases genetics, Protein Kinases metabolism, Protein Subunits genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, TATA-Binding Protein Associated Factors genetics, Transcription Factor TFIID genetics, Transcription Factors genetics, Transcription, Genetic, Transcriptional Activation, DNA Helicases metabolism, Gene Expression Regulation, Fungal, Protein Subunits metabolism, Saccharomyces cerevisiae Proteins metabolism, TATA-Binding Protein Associated Factors metabolism, Transcription Factor TFIID metabolism, Transcription Factors metabolism

Abstract

Transcription activation in yeast (Saccharomyces cerevisiae) involves ordered recruitment of transcription factor complexes, such as TFIID, SAGA, and Mot1p. Previously, we showed that both Mot1p and Taf1p are recruited to the HXT2 and HXT4 genes, which encode hexose transporter proteins. Here, we show that SAGA also binds to the HXT2 and HXT4 promoters and plays a pivotal role in the recruitment of Mot1p and Taf1p. The deletion of either SPT3 or SPT8 reduces Mot1p binding to HXT2 and HXT4. Surprisingly, the deletion of GCN5 reduces Taf1p binding to both promoters. When GCN5 is deleted in spt3Delta or spt8Delta strains, neither Mot1p nor Taf1p binds, and this results in a diminished recruitment of TATA binding protein and polymerase II to the HXT4 but not the HXT2 promoter. This is reflected by the SAGA-dependent expression of HXT4. In contrast, SAGA-independent induction of HXT2 suggests a functional redundancy with other factors. A functional interplay of different SAGA subunits with Mot1p and Taf1p was supported by phenotypic analysis of MOT1 SAGA or TAF1/SAGA double mutant strains, which revealed novel genetic interactions between MOT1 and SPT8 and between TAF1 and GCN5. In conclusion, our data demonstrate functional links between SAGA, Mot1p, and TFIID in HXT gene regulation.

Published

2005

16. Regulation and recognition of SCFGrr1 targets in the glucose and amino acid signaling pathways.

Author

Spielewoy N, Flick K, Kalashnikova TI, Walker JR, and Wittenberg C

Subjects

Adaptor Proteins, Signal Transducing, Casein Kinase I metabolism, Cyclins metabolism, F-Box Proteins metabolism, Glucose Transport Proteins, Facilitative, Membrane Proteins metabolism, Monosaccharide Transport Proteins genetics, Monosaccharide Transport Proteins metabolism, Mutation, Proteasome Endopeptidase Complex metabolism, Protein Binding, Protein Structure, Tertiary, SKP Cullin F-Box Protein Ligases metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins genetics, Ubiquitin metabolism, Ubiquitin-Protein Ligases genetics, Amino Acids metabolism, Gene Expression Regulation, Fungal, Glucose metabolism, Saccharomyces cerevisiae Proteins metabolism, Signal Transduction physiology, Ubiquitin-Protein Ligases metabolism

Abstract

SCFGrr1, one of several members of the SCF family of E3 ubiquitin ligases in budding Saccharomyces cerevisiae, is required for both regulation of the cell cycle and nutritionally controlled transcription. In addition to its role in degradation of Gic2 and the CDK targets Cln1 and Cln2, Grr1 is also required for induction of glucose- and amino acid-regulated genes. Induction of HXT genes by glucose requires the Grr1-dependent degradation of Mth1. We show that Mth1 is ubiquitinated in vivo and degraded via the proteasome. Furthermore, phosphorylated Mth1, targeted by the casein kinases Yck1/2, binds to Grr1. That binding depends upon the Grr1 leucine-rich repeat (LRR) domain but not upon the F-box or basic residues within the LRR that are required for recognition of Cln2 and Gic2. Those observations extend to a large number of Grr1-dependent genes, some targets of the amino acid-regulated SPS signaling system, which are properly regulated in the absence of those basic LRR residues. Finally, we show that regulation of the SPS targets requires the Yck1/2 casein kinases. We propose that casein kinase I plays a similar role in both nutritional signaling pathways by phosphorylating pathway components and targeting them for ubiquitination by SCFGrr1.

Published

2004

17. Activation of the RAS/cyclic AMP pathway suppresses a TOR deficiency in yeast.

Author

Schmelzle T, Beck T, Martin DE, and Hall MN

Subjects

Antifungal Agents pharmacology, Autophagy drug effects, Cell Cycle Proteins, DNA-Binding Proteins metabolism, Glucose Transport Proteins, Facilitative, Glycogen metabolism, Monosaccharide Transport Proteins drug effects, Phosphatidylinositol 3-Kinases deficiency, Phosphotransferases (Alcohol Group Acceptor) deficiency, Ribosomes drug effects, Saccharomyces cerevisiae metabolism, Sirolimus pharmacology, Transcription Factors metabolism, Transcription, Genetic, ras Proteins drug effects, Cyclic AMP metabolism, Fungal Proteins, Phosphatidylinositol 3-Kinases metabolism, Phosphotransferases (Alcohol Group Acceptor) metabolism, Saccharomyces cerevisiae Proteins metabolism, ras Proteins metabolism

Abstract

The TOR (target of rapamycin) and RAS/cyclic AMP (cAMP) signaling pathways are the two major pathways controlling cell growth in response to nutrients in yeast. In this study we examine the functional interaction between TOR and the RAS/cAMP pathway. First, activation of the RAS/cAMP signaling pathway confers pronounced resistance to rapamycin. Second, constitutive activation of the RAS/cAMP pathway prevents several rapamycin-induced responses, such as the nuclear translocation of the transcription factor MSN2 and induction of stress genes, the accumulation of glycogen, the induction of autophagy, the down-regulation of ribosome biogenesis (ribosomal protein gene transcription and RNA polymerase I and III activity), and the down-regulation of the glucose transporter HXT1. Third, many of these TOR-mediated responses are independent of the previously described TOR effectors TAP42 and the type 2A-related protein phosphatase SIT4. Conversely, TOR-controlled TAP42/SIT4-dependent events are not affected by the RAS/cAMP pathway. Finally, and importantly, TOR controls the subcellular localization of both the protein kinase A catalytic subunit TPK1 and the RAS/cAMP signaling-related kinase YAK1. Our findings suggest that TOR signals through the RAS/cAMP pathway, independently of TAP42/SIT4. Therefore, the RAS/cAMP pathway may be a novel TOR effector branch.

Published

2004

18. Std1 and Mth1 proteins interact with the glucose sensors to control glucose-regulated gene expression in Saccharomyces cerevisiae.

Author

Schmidt MC, McCartney RR, Zhang X, Tillman TS, Solimeo H, Wölfl S, Almonte C, and Watkins SC

Subjects

Adaptor Proteins, Signal Transducing, Cloning, Molecular, Fungal Proteins genetics, Gene Expression Regulation, Enzymologic, Glucose Transport Proteins, Facilitative, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Green Fluorescent Proteins, Intracellular Signaling Peptides and Proteins, Luminescent Proteins metabolism, Membrane Proteins genetics, Monosaccharide Transport Proteins genetics, Mutagenesis, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae metabolism, beta-Fructofuranosidase, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Glucose metabolism, Membrane Proteins metabolism, Monosaccharide Transport Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins

Abstract

The Std1 protein modulates the expression of glucose-regulated genes, but its exact molecular role in this process is unclear. A two-hybrid screen for Std1-interacting proteins identified the hydrophilic C-terminal domains of the glucose sensors, Snf3 and Rgt2. The homologue of Std1, Mth1, behaves differently from Std1 in this assay by interacting with Snf3 but not Rgt2. Genetic interactions between STD1, MTH1, SNF3, and RGT2 suggest that the glucose signaling is mediated, at least in part, through interactions of the products of these four genes. Mutations in MTH1 can suppress the raffinose growth defect of a snf3 mutant as well as the glucose fermentation defect present in cells lacking both glucose sensors (snf3 rgt2). Genetic suppression by mutations in MTH1 is likely to be due to the increased and unregulated expression of hexose transporter genes. In media lacking glucose or with low levels of glucose, the hexose transporter genes are subject to repression by a mechanism that requires the Std1 and Mth1 proteins. An additional mechanism for glucose sensing must exist since a strain lacking all four genes (snf3 rgt2 std1 mth1) is still able to regulate SUC2 gene expression in response to changes in glucose concentration. Finally, studies with green fluorescent protein fusions indicate that Std1 is localized to the cell periphery and the cell nucleus, supporting the idea that it may transduce signals from the plasma membrane to the nucleus.

Published

1999

19. Trinucleotide insertions, deletions, and point mutations in glucose transporters confer K+ uptake in Saccharomyces cerevisiae.

Author

Liang H, Ko CH, Herman T, and Gaber RF

Subjects

Alleles, Fungal Proteins metabolism, Glucose Transport Proteins, Facilitative, Membrane Proteins genetics, Membrane Proteins metabolism, Monosaccharide Transport Proteins metabolism, Point Mutation, Protein Structure, Secondary, Saccharomyces cerevisiae, Sequence Deletion, Trinucleotide Repeats, Fungal Proteins genetics, Genes, Suppressor, Monosaccharide Transport Proteins genetics, Potassium pharmacokinetics, Saccharomyces cerevisiae Proteins

Abstract

Deletion of TRK1 and TRK2 abolishes high-affinity K+ uptake in Saccharomyces cerevisiae, resulting in the inability to grow on typical synthetic growth medium unless it is supplemented with very high concentrations of potassium. Selection for spontaneous suppressors that restored growth of trk1delta trk2delta cells on K+-limiting medium led to the isolation of cells with unusual gain-of-function mutations in the glucose transporter genes HXT1 and HXT3 and the glucose/galactose transporter gene GAL2. 86Rb uptake assays demonstrated that the suppressor mutations conferred increased uptake of the ion. In addition to K+, the mutant hexose transporters also conferred permeation of other cations, including Na+. Because the selection strategy required such gain of function, mutations that disrupted transporter maturation or localization to the plasma membrane were avoided. Thus, the importance of specific sites in glucose transport could be independently assessed by testing for the ability of the mutant transporter to restore glucose-dependent growth to cells containing null alleles of all of the known functional glucose transporter genes. Twelve sites, most of which are conserved among eukaryotic hexose transporters, were revealed to be essential for glucose transport. Four of these have previously been shown to be essential for glucose transport by animal or plant transporters. Eight represented sites not previously known to be crucial for glucose uptake. Each suppressor mutant harbored a single mutation that altered an amino acid(s) within or immediately adjacent to a putative transmembrane domain of the transporter. Seven of 38 independent suppressor mutations consisted of in-frame insertions or deletions. The nature of the insertions and deletions revealed a striking DNA template dependency: each insertion generated a trinucleotide repeat, and each deletion involved the removal of a repeated nucleotide sequence.

Published

1998

20. Rgt1p of Saccharomyces cerevisiae, a key regulator of glucose-induced genes, is both an activator and a repressor of transcription.

Author

Ozcan S, Leong T, and Johnston M

Subjects

Bacterial Proteins biosynthesis, DNA-Binding Proteins, Fungal Proteins biosynthesis, Genotype, Glucose metabolism, Glucose pharmacology, Glucose Transport Proteins, Facilitative, Kinetics, Molecular Sequence Data, Monosaccharide Transport Proteins biosynthesis, Monosaccharide Transport Proteins genetics, Promoter Regions, Genetic, Recombinant Proteins biosynthesis, Recombinant Proteins metabolism, Repressor Proteins biosynthesis, Restriction Mapping, Saccharomyces cerevisiae genetics, Serine Endopeptidases biosynthesis, Trans-Activators biosynthesis, Transcription Factors, Repressor Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins, Trans-Activators metabolism, Transcription, Genetic drug effects

Abstract

The RGT1 gene of Saccharomyces cerevisiae plays a central role in the glucose-induced expression of hexose transporter (HXT) genes. Genetic evidence suggests that it encodes a repressor of the HXT genes whose function is inhibited by glucose. Here, we report the isolation of RGT1 and demonstrate that it encodes a bifunctional transcription factor. Rgt1p displays three different transcriptional modes in response to glucose: (i) in the absence of glucose, it functions as a transcriptional repressor; (ii) high concentrations of glucose cause it to function as a transcriptional activator; and (iii) in cells growing on low levels of glucose, Rgt1p has a neutral role, neither repressing nor activating transcription. Glucose alters Rgt1p function through a pathway that includes two glucose sensors, Snf3p and Rgt2p, and Grr1p. The glucose transporter Snf3p, which appears to be a low-glucose sensor, is required for inhibition of Rgt1p repressor function by low levels of glucose. Rgt2p, a glucose transporter that functions as a high-glucose sensor, is required for conversion of Rgt1p into an activator by high levels of glucose. Grr1p, a component of the glucose signaling pathway, is required both for inactivation of Rgt1p repressor function by low levels of glucose and for conversion of Rgt1p into an activator at high levels of glucose. Thus, signals generated by two different glucose sensors act through Grr1p to determine Rgt1p function.

Published

1996

21. Two different repressors collaborate to restrict expression of the yeast glucose transporter genes HXT2 and HXT4 to low levels of glucose.

Author

Ozcan S and Johnston M

Subjects

Base Sequence, Binding Sites, Cloning, Molecular, DNA Primers, DNA-Binding Proteins isolation & purification, DNA-Binding Proteins metabolism, Fungal Proteins biosynthesis, Genes, Fungal drug effects, Genotype, Glucose Transport Proteins, Facilitative, Molecular Sequence Data, Mutagenesis, Oligodeoxyribonucleotides, Promoter Regions, Genetic, Recombinant Fusion Proteins biosynthesis, Regulatory Sequences, Nucleic Acid, Repressor Proteins isolation & purification, Repressor Proteins metabolism, Sequence Deletion, Zinc Fingers, beta-Galactosidase biosynthesis, Gene Expression Regulation, Fungal drug effects, Glucose pharmacology, Membrane Proteins biosynthesis, Monosaccharide Transport Proteins biosynthesis, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins

Abstract

Transcription of the yeast HXT2 and HXT4 genes, which encode glucose transporters, is induced only by low levels of glucose. This low-glucose-induced expression is mediated by two independent repression mechanisms: in the absence of glucose, transcription of both genes is prevented by Rgt1p, a C6 zinc cluster protein; at high levels of glucose, expression of HXT2 and HXT4 is repressed by Mig1p. Only at low glucose concentrations are both repressors inactive, leading to a 10- to 20-fold induction of gene expression. Mig1p and Rgt1p act directly on HXT2 and HXT4 by binding to their promoters. This transcriptional regulation is physiologically very important to the yeast cell because it causes these glucose transporters to be expressed only in low-glucose media, in which they are required for growth.

Published

1996