Overexpressed maltose transporters in laboratory and lager yeasts: Localization and competition with endogenous transporters

Plain and fluorescently tagged versions of Agt1, Mtt1 and Malx1 maltose transporters were overexpressed in two laboratory yeasts and one lager yeast. The plain and tagged versions of each transporter supported similar transport activities, indicating that they are similarly trafficked and have similar catalytic activities. When they were expressed under the control of the strong constitutive PGK1 promoter only minor proportions of the fluorescent transporters were associated with the plasma membrane, the rest being found in intracellular structures. Transport activity of each tagged transporter in each host was roughly proportional to the plasma membrane‐associated fluorescence. All three transporters were subject to glucose‐triggered inactivation when the medium glucose concentration was abruptly raised. Results also suggest competition between endogenous and overexpressed transporters for access to the plasma membrane.     

The Gas family of proteins of Saccharomyces cerevisiae: characterization and evolutionary analysis

The GAS multigene family of Saccharomyces cerevisiae is constituted by five genes (GAS1-GAS5), but GAS1 was the only one to have been characterized to date. Gas1 is a glycosylphosphatidylinositol-anchored protein predominantly localized in the plasma membrane and is also a representative of family GH72 of glycosidase/transglycosidases, a wide group of yeast and fungal enzymes involved in cell wall assembly. Gas1-Gas5 proteins share a common N-terminal domain but exhibit different C-terminal extensions, in which a domain named Cys-Box is located. This domain is similar to the carbohydrate binding module 43 and is present only in Gas1p and Gas2p. Here we report the expression in P. pastoris of soluble forms of Gas proteins. Gas1, 2, 4 and 5 proteins were secreted with a yield of about 30-40 mg/l of medium, whereas the yield for Gas3p was about three times lower. Gas proteins proved to be N-glycosylated. Purified Gas proteins were tested for enzymatic activity. Gas2, Gas4 and Gas5p showed a beta-(1,3)-glucanosyltransferase activity similar to Gas1p. A phylogenetic tree of the N-terminal regions of family GH72 members was constructed. Two subfamilies of N-terminal regions were distinguished: one subfamily, GH72(+), contains proteins that possess a Cys-box in the C-terminal region, whereas family GH72(-) comprises proteins that lack a Cys-box. On the basis of this net distinction, we speculate that the type of C-tail region imposed constraints to the evolution of the N-terminal portion.     

Isolation and characterization of the plasma membrane biotin transporter from Schizosaccharomyces pombe

The fission yeast Schizosaccharomyces pombe is auxotrophic for biotin (vitamin H) and growth depends on biotin uptake over the plasma membrane. Here a biotin transport mutant of Saccharomyces cerevisiae is used to identify the vht1(+) gene encoding the Schizosaccharomyces pombe plasma membrane transport protein for biotin. SpVht1p belongs to the family of allantoate transporters and has only little sequence homology to the S. cerevisiae biotin transporter. Although having dissimilar primary structures, the biotin transporters in Sz. pombe and S. cerevisiae share similar biochemical properties and regulation. Like in S. cerevisiae, biotin uptake in Sz. pombe is a high-affinity process, is optimal at acidic pH values and inhibited by protonophores, indicating that SpVht1p acts as a proton-biotin symporter. Desthiobiotin, the metabolic precursor of biotin, is also imported by SpVht1p. Deletion of vht1(+) abolishes growth on low external concentrations of the vitamin, showing that vht1(+) encodes the only protein that mediates biotin uptake in Sz. pombe. Expression of vht1(+) is maximal at low external biotin concentrations, indicating that Sz. pombe can adjust the rate of biotin uptake to meet the requirement for the vitamin.     

Development of series of gateway binary vectors, pGWBs, for realizing efficient construction of fusion genes for plant transformation

We developed a new series of binary vectors useful for Gateway cloning to facilitate transgenic experiments in plant biotechnology. The new system, Gateway Binary Vectors (pGWBs) realized efficient cloning, constitutive expression using the cauliflower mosaic virus (CaMV) 35S promoter and the construction of fusion genes by simple clonase reaction with an entry clone. The reporters employable in this system are beta-glucuronidase (GUS), synthetic green fluorescent protein with S65T mutation (sGFP), luciferase (LUC), enhanced yellow fluorescent protein (EYFP), and enhanced cyan fluorescent protein (ECFP). The tags available are 6xHis, FLAG, 3xHA, 4xMyc, 10xMyc, GST, T7-epitope, and tandem affinity purification (TAP). In total, 13 kinds of reporter or tag were arranged and were almost applicable to both N- and C-fusions. The pGWBs could be used for many purposes, such as promoter::reporter analysis, observation of subcellular localization by the expression of proteins fused to a reporter or tag, and analysis of protein-protein interaction by copurification and immunodetection experiments. The pGWBs were constructed with modified pBI101 containing a CaMV35S promoter-driven hygromycin phosphotransferase (HPT) gene as the second selection marker. We also constructed pGWBs with the marker HPT driven by the nopaline synthase promoter. By using the pGWB system, the expression of tagged proteins, and the localization of GFP-fused proteins were easily analyzed. Moreover, tissue-specific and inducible gene expression using a promoter was also monitored with pGWBs. It is expected that, the pGWB system will serve as a powerful tool for plasmid construction in plant research.     

Human NKCC2 cation–Cl– co‐transporter complements lack of Vhc1 transporter in yeast vacuolar membranes

Cation–chloride co‐transporters serve to transport Cl^– and alkali metal cations. Whereas a large family of these exists in higher eukaryotes, yeasts only possess one cation–chloride co‐transporter, Vhc1, localized to the vacuolar membrane. In this study, the human cation–chloride co‐transporter NKCC2 complemented the phenotype of VHC1 deletion in Saccharomyces cerevisiae and its activity controlled the growth of salt‐sensitive yeast cells in the presence of high KCl, NaCl and LiCl. A S. cerevisiae mutant lacking plasma‐membrane alkali–metal cation exporters Nha1 and Ena1‐5 and the vacuolar cation–chloride co‐transporter Vhc1 is highly sensitive to increased concentrations of alkali–metal cations, and it proved to be a suitable model for characterizing the substrate specificity and transport activity of human wild‐type and mutated cation–chloride co‐transporters. Copyright © 2013 John Wiley & Sons, Ltd.     

Human placental amino acid transporter genes: expression and function

Recent findings on amino acid transporter genes are reviewed with particular focus on matching previously described transport systems to individual genes. Functional studies using cloned and expressed transporters are considered as the critical tool allowing identification of the functional properties of individual genes. Specifically, these experiments allow identification of the transported substrate amino acids and of the transport mechanism. We focus on the very recent discovery and properties of the heterodimeric family of amino acid transport proteins where two subunits encoded in different genes are required. For these transporters, co-expression of both subunits is mandatory for functional studies. The field of placental amino acid transport is further complicated by complexities arising from both gestational age-specific and species-specific gene expression. The function of the transporter also depends on its cellular localization in the trophoblast. In addition, for transporters that are coupled to ion gradients, both membrane potential and ion pumping will contribute to the rate of amino acid delivery to the fetus. Regulation of function is important not only for fetal nutrition but also for specific additional aspects of placental biology.     

Binding of Cdc48p to a ubiquitin-related UBX domain from novel yeast proteins involved in intracellular proteolysis and sporulation

The Cdc48/p97 AAA-ATPase functions in membrane fusion and ubiquitin-dependent protein degradation. Here, we show that, in yeast, Cdc48p interacts with three novel proteins, Cuil-3p, which contain a conserved ubiquitin-related (UBX) domain. Cui2p and Cui3p are closely related, interact with each other, and are localized at the perinuclear membrane. Cdc48p binds directly the UBX domain of Cui3p in vitro. Multiple deletions of the CUI1, CUI2 and CUI3 genes confer deficiency in sporulation and degradation of model ubiquitin-protein fusions. The Cuil-3 proteins were also found to interact with Ufd3p, a WD repeat protein known to associate with Cdc48p. Together, these results indicate that the Cuil-3 proteins form complexes that are components of the ubiquitin-proteasome system.     

Construction of phosphatidylethanolamine-less strain of Saccharomyces cerevisiae. Effect on amino acid transport

A triple yeast mutant was constructed which lacks BST1, the gene for sphingosine lyase, besides the phosphatidylserine decarboxylases PSD1 and PSD2. In this yeast mutant, which can only be grown in the presence of exogenous ethanolamine, phosphatidylethanolamine can be depleted to very low levels. Under those conditions, respiration as well as glucose and 3-O-methylglucose uptake proceed unaffected. Plasma membrane ATPase is as active in these cells as that of control cells grown in the presence of ethanolamine. Drastically decreased, however, are H+/amino acid symporters. The activities of arginine (Can1p), proline (Put4p) and general amino acid permease (Gap1p) are decreased more than 20-fold. Amino acid transport in yeast is dependent on coupling to the proton motive force. It can be envisaged that phosphatidylethanolamine might play a role in this process or in the early steps of the secretion pathway common for all amino acid permeases or, eventually, it could affect the transport proteins directly at the plasma membrane Transformation of the triple mutant with a CEN plasmid harbouring BST1 wild-type gene totally reversed its phenotype to that observed in the double mutant.     

Differential expression of ABC transporters and their regulatory genes during lactation and dry period in bovine mammary tissue

ATP-binding cassette (ABC) transporters play a pivotal role in human physiology, and mutations in these genes often result in severe hereditary diseases. ABC transporters are expressed in the bovine mammary gland but their physiological role in this organ remains elusive. Based on findings in the context of human disorders we speculated that candidate ABC transporters are implicated in lipid and cholesterol transport in the mammary gland. Therefore we investigated the expression pattern of selected genes that are associated with sterol transport in lactating and nonlactating mammary glands of dairy cows. mRNA levels from mammary gland biopsies taken during lactation and in the first and second week of the dry period were analysed using quantitative PCR. Five ABC transporter genes, namely ABCA1, ABCA7, ABCG1, ABCG2 and ABCG5, their regulating genes LXRalpha, PPARgamma, SREBP1 and the milk proteins lactoferrin and alpha-lactalbumin were assessed. A significantly enhanced expression in the dry period was observed for ABCA1 while a significant decrease of expression in this period was detected for ABCA7, ABCG2, SREBP1 and alpha-lactalbumin. ABCG1, ABCG5, LXRalpha, PPARgamma and lactoferrin expression was not altered between lactation and dry period. These results indicate that candidate ABC transporters involved in lipid and cholesterol transport show differential mRNA expression between lactation and the dry period. This may be due to physiological changes in the mammary gland such as immigration of macrophages or the accumulation of fat due to the loss of liquid in the involuting mammary gland. The current mRNA expression analysis of transporters in the mammary gland is the prerequisite for elucidating novel molecular mechanisms underlying cholesterol and lipid transfer into milk.     

Allelic variants of hexose transporter Hxt3p and hexokinases Hxk1p/Hxk2p in strains of Saccharomyces cerevisiae and interspecies hybrids

The transport of sugars across the plasma membrane is a critical step in the utilization of glucose and fructose by Saccharomyces cerevisiae during must fermentations. Variations in the molecular structure of hexose transporters and kinases may affect the ability of wine yeast strains to finish sugar fermentation, even under stressful wine conditions. In this context, we sequenced and compared genes encoding the hexose transporter Hxt3p and the kinases Hxk1p/Hxk2p of Saccharomyces strains and interspecies hybrids with different industrial usages and regional backgrounds. The Hxt3p primary structure varied in a small set of amino acids, which characterized robust yeast strains used for the production of sparkling wine or to restart stuck fermentations. In addition, interspecies hybrid strains, previously isolated at the end of spontaneous fermentations, revealed a common amino acid signature. The location and potential influence of the amino acids exchanges is discussed by means of a first modelled Hxt3p structure. In comparison, hexokinase genes were more conserved in different Saccharomyces strains and hybrids. Thus, molecular variants of the hexose carrier Hxt3p, but not of kinases, correlate with different fermentation performances of yeast. Copyright © 2015 John Wiley & Sons, Ltd.     

Amino acid residues involved in ligand preference of the Snf3 transporter‐like sensor in Saccharomyces cerevisiae

Snf3 is a plasma membrane protein in Saccharomyces cerevisiae able to sense the presence of glucose. Although the Snf3 protein does not transport sugars, it shares sequence similarity with various glucose transporters from other organisms. We investigated the sugar specificity/preferences of Snf3. The ability of cells to sense sugars in vivo was monitored by following the degradation of the Mth1 protein, an early event in the signal pathway. Our study reveals that Snf3, in addition to glucose, also senses fructose and mannose, as well as the glucose analogues 2‐deoxyglucose, 3‐O‐methylglucoside and 6‐deoxyglucose. The signalling proficiency of a non‐phosphorylatable analogue strongly supports the notion that sensing through Snf3 does not require sugar phosphorylation. Sequence comparisons of Snf3 to glucose transporters indicated amino acid residues possibly involved in sensing of sugars other than glucose. By site‐specific mutagenesis of the structural gene, roles of specific residues in Snf3 could be established. Change of isoleucine‐374 to valine in transmembrane segment 7 of Snf3 partially abolished sensing of fructose and mannose, while mutagenesis causing a change of phenylalanine‐462 to tyrosine in transmembrane segment 10 of Snf3 abolished sensing of fructose. Neither of these amino acid changes affected the ability of Snf3 to sense glucose, nor did they permit Snf3 to sense galactose. These data indicate a similarity between a ligand binding site of the sensor Snf3 and binding sites used for facilitated hexose transport in the GLUT proteins. Copyright © 2009 John Wiley & Sons, Ltd.     

Screening for novel essential genes of Saccharomyces cerevisiae involved in protein secretion

We describe here a screening procedure devised for searching new genes involved in protein secretion in Saccharomyces cerevisiae. The screening procedure takes advantage of yeast strains constructed within the EUROFAN project, in which the promoters of the novel essential genes were replaced by the doxycycline-regulated tetO(7)-CYC1 promoter. This promoter is active in normal growth medium but results in downregulation of the gene in the presence of doxycycline. The yeast cells were grown in the presence or absence of doxycycline, and both the growth and secretion of the heat shock protein, Hsp150p, into the culture medium were determined. In seven strains there was a specific effect on protein secretion. In a strain in which the RPN5 gene was downregulated, the level of secreted Hsp150p was increased compared to the control culture. When RER2 was downregulated, cells secreted Hsp150p that was not of the mature size. In five strains, secretion was more severely reduced than cell growth. One of these downregulated genes, YGL098w, was recently reported to encode an ER-located t-SNARE, USE1. Four of the genes detected, NOG2, NOP15, RRP40 and SDA1, encode proteins involved in ribosome assembly, suggesting a possible new signalling pathway between ribosome biogenesis and production of secreted proteins. The results obtained here indicate that the present screen could be successfully used in larger scale to identify novel secretion-related genes.     

Translational regulator RpL10p/Grc5p interacts physically and functionally with Sed1p,a dynamic component of the yeast cell surface

Biogenesis of an active ribosome complement and a dynamic cell surface complement are two major determinants of cellular growth. In yeast, the 60S ribosomal subunit protein RpL10p/Grc5p functions during successive stages in ribosome biogenesis, specifically rRNA processing, nucle(ol)ar preribosomal subunit assembly, nucleo-cytoplasmic transport and cytoplasmic maturation of ribosomes. Here, we report that a two-hybrid screen identified yeast genes SED1, ACS2 and PLB3 as encoding proteins physically interacting with both ribosomal RpL10p/Grc5p and its human homologue hRpL10p/QMp. SED1 encodes a differentially expressed cell wall protein which is proposed to be first transiently secreted to the plasma membrane as a GPI (glycosylated derivative of phosphoinositol)-anchored form and to be then transferred to the glucan layer of the cell wall. Ectopic expression of SED1 rescues both the aberrant growth phenotype and the translation defect of grc5-1(ts) temperature-sensitive cells. Furthermore, we report that Sed1p associates with translating ribosomes suggesting a novel, cytoplasmic role for Sed1p. ACS2 encodes one of the two yeast acetyl-CoA synthases and represents a key enzyme in one of several metabolic routes to produce acetyl-CoA, which in turn is indispensable for lipid biosynthesis. PLB3 encodes a phospholipase, which is active in the breakdown of membrane lipids. Our results support the view that Grc5p/RpL10p links ribosome function to membrane turnover and cell surface biogenesis.     

Characterization of bovine glucose transporter 1 kinetics and substrate specificities in Xenopus oocytes

Glucose is an essential substrate for lactose synthesis and an important energy source in milk production. Glucose uptake in the mammary gland, therefore, plays a critical role in milk synthesis. Facilitative glucose transporters (GLUT) mediate glucose uptake in the mammary gland. Glucose transporter 1 (GLUT1) is the major facilitative glucose transporter expressed in the bovine mammary gland and has been shown to localize to the basolateral membrane of mammary epithelial cells. Glucose transporter 1 is, therefore, thought to play a major role in glucose uptake during lactation. The objective of this study was to determine the transport kinetic properties and substrate specificity of bovine GLUT1 using the Xenopus oocyte model. Bovine GLUT1 (bGLUT1) was expressed in Xenopus oocytes by microinjection of in vitro transcribed cRNA and was found to be localized to the plasma membrane, which resulted in increased glucose uptake. This bGLUT1-mediated glucose uptake was dramatically inhibited by specific facilitative glucose transport inhibitors, cytochalasin B, and phloretin. Kinetic analysis of bovine and human GLUT1 was conducted under zero-trans conditions using radio-labeled 2-deoxy-D-glucose and the principles of Michaelis-Menten kinetics. Bovine GLUT1 exhibited a Michaelis constant (K(m)) of 9.8 ± 3.0mM for 2-deoxy-d-glucose, similar to 11.7 ± 3.7 mM for human GLUT1. Transport by bGLUT1 was inhibited by mannose and galactose, but not fructose, indicating that bGLUT1 may also be able to transport mannose and galactose. Our data provides functional insight into the transport properties of bGLUT1 in taking up glucose across mammary epithelial cells for milk synthesis.     

Ady2p is essential for the acetate permease activity in the yeast Saccharomyces cerevisiae

To identify new genes involved in acetate uptake in Saccharomyces cerevisiae, an analysis of the gene expression profiles of cells shifted from glucose to acetic acid was performed. The gene expression reprogramming of yeast adapting to a poor non-fermentable carbon source was observed, including dramatic metabolic changes, global activation of translation machinery, mitochondria biogenesis and the induction of known or putative transporters. Among them, the gene ADY2/YCR010c was identified as a new key element for acetate transport, being homologous to the Yarrowia lipolytica GPR1 gene, which has a role in acetic acid sensitivity. Disruption of ADY2 in S. cerevisiae abolished the active transport of acetate. Microarray analyses of ady2Delta strains showed that this gene is not a critical regulator of acetate response and that its role is directly connected to acetate transport. Ady2p is predicted to be a membrane protein and is a valuable acetate transporter candidate.     

Rice sodium-insensitive potassium transporter, OsHAK5, confers increased salt tolerance in tobacco BY2 cells

Potassium ion (K(+)) plays vital roles in many aspects of cellular homeostasis including competing with sodium ion (Na(+)) during potassium starvation and salt stress. Therefore, one way to engineer plant cells with improved salt tolerance is to enhance K(+) uptake activity of the cells, while keeping Na(+) out during salt stress. Here, in search for Na(+)-insensitive K(+) transporter for this purpose, bacterial expression system was used to characterize two K(+) transporters, OsHAK2 and OsHAK5, isolated from rice (Oryza sativa cv. Nipponbare). The two OsHAK transporters are members of a KT/HAK/KUP transporter family, which is one of the major K(+) transporter families in bacteria, fungi and plants. When expressed in an Escherichia coli K(+) transport mutant strain LB2003, both OsHAK transporters rescued the growth defect in K(+)-limiting conditions by significantly increasing the K(+) content of the cells. Under the condition with a large amount of extracellular Na(+), we found that OsHAK5 functions as a Na(+)-insensitive K(+) transporter, while OsHAK2 is sensitive to extracellular Na(+) and exhibits higher Na(+) over K(+) transport activities. Moreover, constitutive expression of OsHAK5 in cultured-tobacco BY2 (Nicotiana tabacum cv. Bright Yellow 2) cells enhanced the accumulation of K(+) but not Na(+) in the cells during salt stress and conferred increased salt tolerance to the cells. Transient expression experiment indicated that OsHAK5 is localized to the plant plasma membrane. These results suggest that the plasma-membrane localized Na(+) insensitive K(+) transporters, similar to OsHAK5 identified here, could be used as a tool to enhance salt tolerance in plant cells.     

A novel mechanism regulates H(2) S and SO(2) production in Saccharomyces cerevisiae

Sulfite (SO(2) ) plays an important role in flavour stability in alcoholic beverages, whereas hydrogen sulfide (H(2) S) has an undesirable aroma. To discover the cellular processes that control SO(2) and H(2) S production, we screened a library of Saccharomyces cerevisiae deletion mutants. Deletion of 12 genes led to increased H(2) S productivity. Ten of these genes are known to be involved in sulfur-containing amino acid metabolism, whereas UBI4 functions in the ubiquitin-proteasome system and SKP2 encodes an F-box-containing protein whose function is unknown. We found that the skp2 mutant accumulated H(2) S and SO(2) , because the adenosylphophosulfate kinase Met14p is a substrate of SCF(Skp2) and more stable in the skp2 mutant than in the wild-type strain. Furthermore, the skp2 mutant grew more slowly than the wild-type strain under nutrient-limited conditions. Metabolome analysis showed that the concentration of intracellular cysteine is lower in the skp2 mutant than in the wild-type strain. The slow growth of the skp2 mutant was due to a lower concentration of intracellular cysteine, because the addition of cysteine suppressed the slow growth. In the skp2 mutant, the cysteine biosynthesis proteins Str2p, Str3p and Str4p are more stable than in the wild-type strain. Moreover, supplementation with methionine, S-adenosylmethionine, S-adenosylhomocysteine and homocysteine also suppressed the slow growth. Overexpression of STR1 or STR4 caused a more severe defect in the skp2 mutant. These results suggest that the balance of methionine and cysteine biosynthesis is important for yeast cell growth. Thus, Skp2p is one of the key components regulating this balance and H(2) S/SO(2) production.