Association of yeast transporters with detergent-resistant membranes correlates with their cell-surface location

Detergent-resistant membrane (DRM) fractions enriched in ergosterol and sphingolipids can be isolated from yeast cells and have been proposed to represent the biochemical equivalents of lipid rafts. Most yeast plasma membrane proteins studied for their detergent solubility have been found in DRMs, except for the Hxt1 and Gap1 permeases. We here compared Gap1 detergent solubility in wild-type and various mutant cells under conditions promoting cell surface accumulation or ubiquitin-dependent down-regulation of the permease. We show that Gap1 present at the plasma membrane is associated with DRMs. This association occurs at the Golgi level. In the absence of sphingolipid neosynthesis, Gap1 fails to accumulate at the plasma membrane and is missorted to the vacuolar lumen. Furthermore, the presence of Gap1 at the plasma membrane correlates perfectly with its association with DRMs, whatever the activity or ubiquitination state of the permease and regardless of whether it has reached the cell surface via normal secretion, after recycling, or upon missorting to the vacuole before rerouting to the plasma membrane. Finally, we show that Hxt1 present at the cell surface is also associated with DRMs. We discuss a model where yeast plasma membrane proteins are systematically associated with sphingolipid/ergosterol-enriched microdomains when located at the cell surface.     

Galactose transporters discriminate steric anomers at the cell surface in yeast

Aldose-1-epimerase or mutarotase (EC 5.1.3.3) catalyzes interconversion of α/β-anomers of aldoses, such as glucose and galactose, and is distributed in a wide variety of organisms from bacteria to humans. Nevertheless, the physiological role of this enzyme has been elusive in most cases, because the α-form of aldoses in the solid state spontaneously converts to the β-form in an aqueous solution until an equilibrium of α : β=36.5 : 63.5 is reached. A gene named GAL10 encodes this enzyme in yeast. Here, we show that the GAL10 -encoded mutarotase is necessary for utilization of galactose in the milk yeast Kluyveromyces lactis , and that this condition is presumably created by the presence of the β-specific galactose transporter, which excludes the α-anomer from the α/β-mixture in the medium at the cell surface. Thus, we found that a mutarotase-deficient mutant of K. lactis failed to grow on medium, in which galactose was the sole carbon source, but, surprisingly, that the growth failure is suppressed by concomitant expression of the Saccharomyces cerevisiae -derived galactose transporter Gal2p, but not by that of the K. lactis galactose transporter Hgt1p. We also suggest the existence of another mutarotase in K. lactis , whose physiological role remains unknown, however.     

A genomic view of yeast membrane transporters.

The yeast membrane transporters play crucial roles in functions as diverse as nutrient uptake, drug resistance, salt tolerance, control of cell volume, efflux of undesirable metabolites and sensing of extracellular nutrients. A significant fraction of the many transporters inventoried after sequencing of the yeast genome has been characterised by classical experimental approaches. Post-genomic analysis has allowed a more extensive characterisation of transporter categories less tractable by genetics, for instance of transporters of intracellular membranes or transporters encoded by multigene families and displaying overlapping substrate specificities. A complete view of the role of membrane transporters in the metabolism of yeast may not be far off.     

miRDB: a microRNA target prediction and functional annotation database with a wiki interface

MicroRNAs (miRNAs) are short noncoding RNAs that are involved in the regulation of thousands of gene targets. Recent studies indicate that miRNAs are likely to be master regulators of many important biological processes. Due to their functional importance, miRNAs are under intense study at present, and many studies have been published in recent years on miRNA functional characterization. The rapid accumulation of miRNA knowledge makes it challenging to properly organize and present miRNA function data. Although several miRNA functional databases have been developed recently, this remains a major bioinformatics challenge to miRNA research community. Here, we describe a new online database system, miRDB, on miRNA target prediction and functional annotation. Flexible web search interface was developed for the retrieval of target prediction results, which were generated with a new bioinformatics algorithm we developed recently. Unlike most other miRNA databases, miRNA functional annotations in miRDB are presented with a primary focus on mature miRNAs, which are the functional carriers of miRNA-mediated gene expression regulation. In addition, a wiki editing interface was established to allow anyone with Internet access to make contributions on miRNA functional annotation. This is a new attempt to develop an interactive community-annotated miRNA functional catalog. All data stored in miRDB are freely accessible at http://mirdb.org.     

Saccharomyces genome database: underlying principles and organisation

A scientific database can be a powerful tool for biologists in an era where large-scale genomic analysis, combined with smaller-scale scientific results, provides new insights into the roles of genes and their products in the cell. However, the collection and assimilation of data is, in itself, not enough to make a database useful. The data must be incorporated into the database and presented to the user in an intuitive and biologically significant manner. Most importantly, this presentation must be driven by the user's point of view; that is, from a biological perspective. The success of a scientific database can therefore be measured by the response of its users - statistically, by usage numbers and, in a less quantifiable way, by its relationship with the community it serves and its ability to serve as a model for similar projects. Since its inception ten years ago, the Saccharomyces Genome Database (SGD) has seen a dramatic increase in its usage, has developed and maintained a positive working relationship with the yeast research community, and has served as a template for at least one other database. The success of SGD, as measured by these criteria, is due in large part to philosophies that have guided its mission and organisation since it was established in 1993. This paper aims to detail these philosophies and how they shape the organisation and presentation of the database.     

Nitrate transporters and peptide transporters

In higher plants, two types of nitrate transporters, NRT1 and NRT2, have been identified. In Arabidopsis, there are 53 NRT1 genes and 7 NRT2 genes. NRT2 are high-affinity nitrate transporters, while most members of the NRT1 family are low-affinity nitrate transporters. The exception is CHL1 (AtNRT1.1), which is a dual-affinity nitrate transporter, its mode of action being switched by phosphorylation and dephosphorylation of threonine 101. Two of the NRT1 genes, CHL1 and AtNRT1.2, and two of the NRT2 genes, AtNRT2.1 and AtNRT2.2, are known to be involved in nitrate uptake. In addition, AtNRT1.4 is required for petiole nitrate storage. On the other hand, some members of the NRT1 family are dipeptide transporters, called PTRs, which transport a broad spectrum of di/tripeptides. In barley, HvPTR1, expressed in the plasma membrane of scutellar epithelial cells, is involved in mobilizing peptides, produced by hydrolysis of endosperm storage protein, to the developing embryo. In higher plants, there is another family of peptide transporters, called oligopeptide transporters (OPTs), which transport tetra/pentapeptides. In addition, some OPTs transport GSH, GSSH, GSH conjugates, phytochelatins, and metals.     

TSdb: A database of transporter substrates linking metabolic pathways and transporter systems on a genome scale via their shared substrates

TSdb (http://tsdb.cbi.pku.edu.cn) is the first manually curated central repository that stores formatted information on the substrates of transporters. In total, 37608 transporters with 15075 substrates from 884 organisms were curated from UniProt functional annotation. A unique feature of TSdb is that all the substrates are mapped to identifiers from the KEGG Ligand compound database. Thus, TSdb links current metabolic pathway schema with compound transporter systems via the shared compounds in the pathways. Furthermore, all the transporter substrates in TSdb are classified according to their biochemical properties, biological roles and subcellular localizations. In addition to the functional annotation of transporters, extensive compound annotation that includes inhibitor information from the KEGG Ligand and BRENDA databases has been integrated, making TSdb a useful source for the discovery of potential inhibitory mechanisms linking transporter substrates and metabolic enzymes. User-friendly web interfaces are designed for easy access, query and download of the data. Text and BLAST searches against all transporters in the database are provided. We will regularly update the substrate data with evidence from new publications.     

Differential expression of intestinal membrane transporters in cholera patients

Vibrio cholerae causes the cholera disease through secretion of cholera toxin (CT), resulting in severe diarrhoea by modulation of membrane transporters in the intestinal epithelium. Genes encoding membrane-spanning transporters identified as being differentially expressed during cholera disease in a microarray screening were studied by real-time PCR, immunohistochemistry and in a CaCo-2 cell model. Two amino acid transporters, SLC7A11 and SLC6A14, were upregulated in acute cholera patients compared to convalescence. Five other transporters were downregulated; aquaporin 10, SLC6A4, TRPM6, SLC23A1 and SLC30A4, which have specificity for water, serotonin (5-HT), magnesium, vitamin C and zinc, respectively. The majority of these changes appear to be attempts of the host to counteract the secretory response. Our results also support the concept that epithelial cells are involved in 5-HT signalling during acute cholera.     

Practical aspects of overexpressing bacterial secondary membrane transporters for structural studies

Membrane transporter proteins play critical physiological roles in the cell and constitute 5-10% of prokaryotic and eukaryotic genomes. High-resolution structural information is essential for understanding the functional mechanism of these proteins. A prerequisite for structural study is to overexpress such proteins in large quantities. In the last few years, over 20 bacterial membrane transporters were overexpressed at a level of 1 mg/l of culture or higher, most often in Escherichia coli. In this review, we analyzed those factors that affect the quantity and quality of the protein produced, and summarized recent progress in overexpression of membrane transporters from bacterial inner membrane. Rapid progress in genome sequencing provides opportunities for expressing several homologues and orthologues of the target protein simultaneously, while the availability of various expression vectors allows flexible experimental design. Careful optimization of cell culture conditions can drastically improve the expression level and homogeneity of the target protein. New sample preparation techniques for mass spectrometry of membrane proteins have enabled one to identity the rigid protein core, which can be subsequently overexpressed. Size-exclusion chromatography on HPLC has proven to be an efficient method in screening detergent, pH an other conditions required for maintaining the stability and monodispersity of the protein. Such high-quality preparations of membrane transporter proteins will probably lead to successful crystallization and structure determination of these proteins in the next few years.     

The control of mitochondrial respiration in yeast: A possible role of the outer mitochondrial membrane

Mitochondrial respiration in yeast (S. cerevisiae) is regulated by the level of glucose in the medium. Glucose is known to inhibit respiration by repressing key enzymes in the respiratory chain. We present evidence that the early events in this inhibition include the closure of VDAC channels, the primary pathway for metabolite flow across the outer membrane. Aluminum hydroxide is known to inhibit the closure of VDAC. Addition of aluminum acetylacetonate to yeast cells, which should elevate the aluminum hydroxide concentrations in the cytoplasm, caused the inhibition of cell respiration by glucose to be delayed for up to 100 min. No significant effect of aluminum was observed in cells grown on glycerol. Yeast cells lacking the VDAC gene were also unresponsive to the addition of aluminum salt in the presence of glucose. Therefore, the closure of VDAC channels may be an early step in the inhibition of the respiration of yeast by glucose.     

Evolution of gene families: the multidrug resistance transporter genes in five related yeast species

The available genomic sequences of five closely related hemiascomycetous yeast species (Kluyveromyces lactis, Kluyveromyces waltii, Candida glabrata, Ashbya (Eremothecium) gossypii with Saccharomyces cerevisiae as a reference) were analysed to identify multidrug resistance (MDR) transport proteins belonging to the ATP-binding cassette (ABC) and major facilitator superfamilies (MFS), respectively. The phylogenetic trees clearly demonstrate that a similar set of gene (sub)families already existed in the common ancestor of all five fungal species studied. However, striking differences exist between the two superfamilies with respect to the evolution of the various subfamilies. Within the ABC superfamily all six half-size transporters with six transmembrane-spanning domains (TMs) and most full-size transporters with 12 TMs have one and only one gene per genome. An exception is the PDR family, in which gene duplications and deletions have occurred independently in individual genomes. Among the MFS transporters, the DHA2 family (TC 2.A.1.3) is more variable between species than the DHA1 family (TC 2.A.1.2). Conserved gene order relationships allow to trace the evolution of most (sub)families, for which the Kluyveromyces lactis genome can serve as an optimal scaffold. Cross-species sequence alignment of orthologous upstream gene sequences led to the identification of conserved sequence motifs ("phylogenetic footprints"). Almost half of them match known sequence motifs for the MDR regulators described in S. cerevisiae. The biological significance of those and of the novel predicted motifs awaits to be confirmed experimentally.     

The hexose transporters at the plasma membrane and the tonoplast of higher plants

The uptake of hexoses in higher plant cells is thought to be catalyzed by an H⁺/hexose contrasporter in the plasma membrane. Transport studies with isolated plant vacuoles indicate that, at the tonoplast, a second hexose transporter is located with properties different from the plasma membrane transporter. Recently membrane vesicles of high purity and defined orientation have been used for a more rigorous individual characterization of these two carriers. Concomitantly, a cDNA for the inducible H⁺/hexose cotransporter of the green alga Chlorella has been sequenced and shown to exhibit homology to a group of hexose transporters (for facilitated diffusion) of other eukaryotic and prokaryotic organisms. With a probe derived from the Chlorella sequence, the first plant gene for an H⁺/hexose contransporter ( Arabidopsis thaliana ) has been isolated, opening the route to molecular studies of structure, function and evolution of the hexose transporters of higher plants. The present review discusses recent work on the kinetic characterization and identification of the higher plant plasma membrane and tonoplast hexose transporters as well as their respective cellular functions. Furthermore, perspectives for future research on the plant hexose transporters are outlined.     

Transdab wiki: the interactive transglutaminase substrate database on web 2.0 surface

TRANSDAB wiki is a database of transglutaminase substrate proteins. This wiki is designed to provide quality content of all the details (including synonyms, structures, references) about transglutaminase substrate proteins and interaction partners. Currently TRANSDAB contains 243 articles about substrate proteins for 6 transglutaminase types in a user-friendly, editable format. Our aim was to collect structural information about substrate proteins and this information is provided in form of images, videos and links. The scientific community is invited to edit the database and besides providing up-to-date information, this wiki should serve as a platform for valuable discussions.     

酿酒酵母戊糖转运蛋白及C6/C5共代谢菌株的研究进展

充分利用木质纤维素中的糖分是提高以此类生物质为原料生产二代燃料乙醇经济盈利性的基本要求,也是实现其他生物基化学品规模化生产的基础。传统的乙醇生产微生物酿酒酵母Saccharomyces cerevisiae具有独特的生产性能及内在优势,是备受关注的底盘细胞,但其不能有效地利用戊糖。利用代谢工程、合成生物学策略,对二代燃料乙醇生产专用酿酒酵母的精准构制持续研究了30余年,已明显改善了其对木糖/葡萄糖的乙醇共发酵能力。近年来关注点集中在早期忽略的限速步骤即糖转运环节的研究上,以期实现不同糖分各行其道、高效专一性转运蛋白各行其责的二代燃料乙醇生产特种酿酒酵母所需的糖转运理想状态。文中主要综述了酿酒酵母戊糖转运蛋白的研究进展,及酿酒酵母的木糖和L-阿拉伯糖代谢工程的研究现状。     

The SPX domain of the yeast low‐affinity phosphate transporter Pho90 regulates transport activity

Yeast has two phosphate‐uptake systems that complement each other: the high‐affinity transporters (Pho84 and Pho89) are active under phosphate starvation, whereas Pho87 and Pho90 are low‐affinity transporters that function when phosphate is abundant. Here, we report new regulatory functions of the amino‐terminal SPX domain of Pho87 and Pho90. By studying truncated versions of Pho87 and Pho90, we show that the SPX domain limits the phosphate‐uptake velocity, suppresses phosphate efflux and affects the regulation of the phosphate signal transduction pathway. Furthermore, split‐ubiquitin assays and co‐immunoprecipitation suggest that the SPX domain of both Pho90 and Pho87 interacts physically with the regulatory protein Spl2. This work suggests that the SPX domain inhibits low‐affinity phosphate transport through a physical interaction with Spl2.     

Cytochemical staining of a yeast polyphosphate fraction,localized outside the plasma membrane

Summary Primary aldehyde fixation in the presence of Ca²⁺ and Mg²⁺ followed by alkaline Pb²⁺ staining leads to electron microscopical visualization of lead precipitates in the yeastKluyveromyces marxianus. These lead precipitates are found in vacuoles, cytoplasm, and on the outside of the plasma membrane in the periplasmic and inner cell wall regions.X-ray microanalysis shows that the precipitates contain high amounts of Pb and P. The amount of precipitated material appeared to correlate with the cellular polyphosphate content. When Ca²⁺ and Mg²⁺ are omitted from the primary fixative no peripheral Pb/P deposits are observed. In a subsequent washing step a small amount of long chain polyphosphate is liberated. It is concluded that this method leads to visualization of cellular polyphosphate, including a fraction localized outside the plasma membrane ofKluyveromyces marxianus.     

Plant and yeast NHX antiporters: roles in membrane trafficking

The plant NHX gene family encodes Na + /H + antiporters which are crucial for salt tolerance, potassium homeostasis and cellular pH regulation. Understanding the role of NHX antiporters in membrane trafficking is becoming an increasingly interesting subject of study. Membrane trafficking is a central cellular process during which proteins, lipids and polysaccharides are continuously exchanged among membrane compartments. Yeast ScNhx1p, a prevacuole/ vacuolar Na + /H + antiporter, plays an important role in regulating pH to control trafficking out of the endosome. Evidence begins to accumulate that plant NHX antiporters might function in regulating membrane trafficking in plants.     

Glutathione transporters

Background

Glutathione (GSH) is synthesized in the cytoplasm but there is a requirement for glutathione not only in the cytoplasm, but in the other organelles and the extracellular milieu. GSH is also imported into the cytoplasm. The transports of glutathione across these different membranes in different systems have been biochemically demonstrated. However the molecular identity of the transporters has been established only in a few cases.

Scope of review

An attempt has been made to present the current state of knowledge of glutathione transporters from different organisms as well as different organelles. These include the most well characterized transporters, the yeast high-affinity, high-specificity glutathione transporters involved in import into the cytoplasm, and the mammalian MRP proteins involved in low affinity glutathione efflux from the cytoplasm. Other glutathione transporters that have been described either with direct or indirect evidences are also discussed.

Major conclusions

The molecular identity of a few glutathione transporters has been unambiguously established but there is a need to identify the transporters of other systems and organelles. There is a lack of direct evidence establishing transport by suggested transporters in many cases. Studies with the high affinity transporters have led to important structure-function insights.

General significance

An understanding of glutathione transporters is critical to our understanding of redox homeostasis in living cells. By presenting our current state of understanding and the gaps in our knowledge the review hopes to stimulate research in these fields. This article is part of a Special Issue entitled Cellular functions of glutathione.     

Prospore membrane formation: how budding yeast gets shaped in meiosis

During meiosis in Saccharomyces cerevisiae four daughter cells, called spores, are generated within the boundaries of the mother cell. This cell differentiation process requires de novo synthesis of prospore membranes (PSMs), which are the precursors of the spore plasma membranes. Assembly of these membranes is initiated at the spindle pole bodies (SPBs) during meiosis II. At this stage of the cell cycle, 4 SPBs are present. Two different meiosis-specific structures are known to be required for PSM formation. At the SPBs, specialized attachments, called the meiotic plaques, provide the required functionality necessary for the recruitment and assembly of the membranes. During subsequent membrane elongation, a second structure becomes important. This proteinaceous assembly forms a coat, called the leading edge protein coat (LEP coat), which covers the boundaries of the membranes. Assembly of the coat occurs at sites next to the SPBs, whereas its disassembly is concomitant to the closure of the membranes. This mini review discusses our current understanding of how the meiotic plaque and the LEP coat might function during biogenesis of the prospore membrane.     

VegTrack: A structured vegetation restoration activity database

Summary  Information about on-ground vegetation restoration activities (e.g. fencing and revegetation) is critical if natural resource management (NRM) groups are to monitor progress towards restoration targets, assess the efficacy of their interventions and adaptively learn from different actions. However, in Australia, there are few practical guidelines for recording data, making it difficult to consistently compare actions between sites and through time. Records of primary information are particularly important given the ongoing national investment in vegetation restoration activities. With the aid of six-case study areas in different landscapes, robust guidelines and tools were developed and incorporated into VegTrack , a methodology, which allows groups to develop their own vegetation restoration activity database. VegTrack differentiates spatial data from attribute data storing each in different databases (a GIS and a relational database management system respectively). We describe the process which enables NRM groups to develop their own database, and provide a Microsoft Access 2003 version of VegTrack to allow NRM groups to commence activity recording. To demonstrate the utility of the VegTrack method in different situations and to encourage consistency across study areas, we describe the application of the guidelines for several scenarios including riparian revegetation, corridors disrupted by roads and infill plantings.