Glycerol and other polyols are used as osmoprotectants by many organisms. Several yeasts and other fungi can take up glycerol by proton symport. To identify genes involved in active glycerol uptake in Saccharomyces cerevisiae we screened a deletion mutant collection comprising 321 genes encoding proteins with 6 or more predicted transmembrane domains for impaired growth on glycerol medium. Deletion of STL1, which encodes a member of the sugar transporter family, eliminates active glycerol transport. Stl1p is present in the plasma membrane in S. cerevisiae during conditions where glycerol symport is functional. Both the Stl1 protein and the active glycerol transport are subject to glucose-induced inactivation, following identical patterns. Furthermore, the Stl1 protein and the glycerol symporter activity are strongly but transiently induced when cells are subjected to osmotic shock. STL1 was heterologously expressed in Schizosaccharomyces pombe, a yeast that does not contain its own active glycerol transport system. In S. pombe, STL1 conferred the ability to take up glycerol against a concentration gradient in a proton motive force-dependent manner. We conclude that the glycerol proton symporter in S. cerevisiae is encoded by STL1. INTRODUCTIONGlycerol, a C 3 polyalcohol, is an important intermediate in energy metabolism in both prokaryotes and eukaryotes. It has long been used for therapeutic and industrial processes. Aspects of glycerol metabolism are also important in biotechnology, e.g., for bio-alcohol production yields or wine smoothness. Essential roles of glycerol in basic biochemical aspects have been extensively studied in several yeasts and fungi. These include biosynthesis of glycerophospholipid and triacylglycerol from glycerol 3-phosphate and dihydroxyacetone phosphate (Kohlwein et al., 1996;Mü llner and Daum, 2004), redox balance (Ansell et al., 1997;Valadi et al., 2004), osmoadaptation (reviewed by Hohmann, 2002, oxidative stress protection (Påhlman et al., 2001), and response to heat shock (Siderius et al., 2000). Responses to elevated temperatures and high osmolarity involve several signaling pathways including the protein kinase C pathway and the HOG pathway, which regulates intracellular levels of glycerol (Hohmann, 2002;Wojda et al., 2003).In cells ranging from mammals (Lang et al., 1998) to archea (Kempf and Bremer, 1998), osmolytes play an important role in the response to osmotic stress caused by low water availability in environments as diverse as poorly irrigated soils or high-sugar musts. In eukaryotic microorganisms like algae or yeasts, polyols, primarily glycerol, act as osmolytes (reviewed by Brown, 1977 andWang et al., 2001). Their production, consumption and retention are consequently tightly regulated and dynamic processes (reviewed by Hohmann, 2002). Magnaporthe grisea (rice blast) a phytopathogenic fungus with a strong impact on world economy, accumulates glycerol, which allows the penetration of the appressorium into the plant host cell (Thines et al., 2000). Glycerol has also...
The Saccharomyces cerevisiae deletion collection was screened for impaired growth on glucose-based complex medium containing 6% ethanol. Forty-six mutants were found. Genes encoding proteins involved in vacuolar function, the cell integrity pathway, mitochondrial function, subunits of the co-chaperone complex GimC and components of the SAGA transcription factor complex were in this way found to be important for the growth of wild-type Saccharomyces yeast in the presence of ethanol. Several mutants were also sensitive to Calcofluor white (14 mutants), sorbic acid (9), increased temperature (5) and NaCl (3). The transcription factors Msn2p and Ars1p, tagged with green fluorescent protein, were translocated to the nucleus upon ethanol stress. Only one of the genes that contain STRE elements in the promoter was important under ethanol stress; this was TPS1, encoding trehalose 6-phosphate synthase. The map kinase of the cell integrity pathway, Slt2p, was phosphorylated when cells were treated with 6% ethanol. Two out of three mutants tested fermented 20% glucose more slowly than the wild-type.
Saccharomyces cerevisiae Gup1p and its homologue Gup2p, members of the superfamily of membrane-bound O-acyl transferases, were previously associated with glycerol-mediated salt-stress recovery and glycerol symporter activity. Several other phenotypes suggested Gup1p involvement in processes connected with cell structure organization and biogenesis. The gup1Delta mutant is also thermosensitive and exhibits an altered plasma membrane lipid composition. The present work shows that the thermosensitivity is independent of glycerol production and retention. Furthermore, the mutant grows poorly on salt, ethanol and weak carboxylic acids, suggestive of a malfunctioning membrane potential. Additionally, gup1Delta is sensitive to cell wall-perturbing agents, such as Calcofluor white, Zymolyase, lyticase and sodium dodecyl sulphate and exhibits a sedimentation/aggregation phenotype. Quantitative analysis of cell wall components yielded increased contents of chitin and beta-1,3-glucans and lower amounts of mannoproteins. Consistently, scanning electron microscopy showed a strikingly rough surface morphology of the mutant cells. These results suggest that the gup1Delta is affected in cell wall assembly and stability, although the Slt2p/MAP kinase from the PKC pathway was phosphorylated during hypo-osmotic shock to a normal extent. Results emphasize the pleiotropic nature of gup1Delta, and are consistent with a role of Gulp1p in connection with several pathways for cell maintenance and construction/remodelling.
Protein translocation in Escherichia coli is mediated by the SecA ATPase bound to the SecYEG membrane protein complex. SecA translocation ATPase activity as well as protein translocation is dependent on the presence of negatively charged lipids. By using a phospholipid with an acyl chain linked photoactivatable group, the lipid accessibility of SecA bound at the translocase was explored. SecA bound to lipid vesicles containing negatively charged lipids was found to be readily accessible for labeling by the photoactivatable phospholipid. The presence of an excess amount of SecYEG complex resulted in a remarkable reduction in the amount of lipid-accessible SecA irrespective of the nucleotide-bound form of SecA. These data demonstrate that the SecYEG-bound SecA is largely shielded from the phospholipid acyl chains and suggest the presence of two distinct pools of membrane-bound SecA that differ in the degree of lipid association.
In search of mitochondrial proteins interacting with phosphatidylcholine (PC), a photolabeling approach was applied, in which photoactivatable probes were incorporated into isolated yeast mitochondria. Only a limited number of proteins were labeled upon photoactivation, using either the PC analogue [125I]TID-PC or the small hydrophobic probe [125I]TID-BE. The most prominent difference was the very specific labeling of a 70 kDa protein by [125I]TID-PC. Mass spectrometric analysis of a tryptic digest of the corresponding 2D-gel spot identified the protein as the GUT2 gene product, the FAD-dependent mitochondrial glycerol-3-phosphate dehydrogenase. This was confirmed by the lack of specific labeling in mitochondria from a gut2 deletion strain. Only under conditions where the inner membrane was accessible to the probe, Gut2p was labeled by [125I]TID-PC, in parallel with increased labeling of the phosphate carrier (P(i)C) in the inner membrane. A hemagglutinin-tagged version of Gut2p was shown to be membrane-bound. Carbonate extraction released the protein from the membrane, whereas a high concentration of NaCl did not, demonstrating that Gut2p is a peripheral membrane protein bound to the inner membrane via hydrophobic interactions. The significance of the observed interactions between Gut2p and PC is discussed.
. In order to determine the sequence specificity of the interaction with the sorting receptor, substitutions were introduced into this part of the propeptide by semirandom site-directed mutagenesis. The efficiency of vacuolar sorting by the mutants was determined by immunoprecipitation of CPY from pulse-labeled cells. It was found that amino acid residues Gln 24 and Leu 27 were the most important ones. While it appears that Gln 24 is essential for proper function, Leu 27 can be exchanged with the other hydrophobic amino acid residues, isoleucine, valine, and phenylalanine. Tolerance toward various substitutions for Arg 25 is fairly high, while substitution of Pro 26 for uncharged amino acid residues also resulted in only weak missorting. In addition to the low requirement for sequence conservation, the position of the targeting element relative to the amino terminus of the propeptide was analyzed and found not to be critical.
The architecture of cells, with various membrane-bound compartments and with the protein synthesizing machinery confined to one location, dictates that many proteins have to be transported through one or more membranes during their biogenesis. A lot of progress has been made on the identification of protein translocation machineries and their sorting signals in various organelles and organisms. Biochemical characterization has revealed the functions of several individual protein components. Interestingly, lipid components were also found to be essential for the correct functioning of these translocases. This led to the idea that there is a very intimate relationship between the lipid and protein components that enables them to fulfil their intriguing task of transporting large biopolymers through a lipid bilayer without leaking their contents. In this review we focus on the Sec translocases in the endoplasmic reticulum and the bacterial inner membrane. We also highlight the interactions of lipids and proteins during the process of translocation and integrate this into a model that enables us to understand the role of membrane lipid composition in translocase function.
SecA is the central component of the proteintranslocation machinery of Escherichia coli. It is able to interact with the precursor protein, the chaperone SecB, the integral membrane protein complex SecYEG, acidic phospholipids and its own mRNA. We studied the interaction between prePhoE and SecA by using a site-specific photocrosslinking strategy. We found that SecA is able to interact with both the signal sequence and the mature domain of prePhoE. Furthermore, this interaction was dependent on the type of nucleotide bound. SecA in the ADP-bound conformation was unable to crosslink with the precursor, whereas the ATP-bound conformation was active in precursor crosslinking. The SecA^precursor interaction was maintained in the presence of E. coli phospholipids but was loosened by the presence of phosphatidylglycerol bilayers. Examining SecA ATP binding site mutants demonstrated that ATP hydrolysis at the N-terminal high affinity binding site is responsible for the changed interaction with the preprotein.ß 2000 Federation of European Biochemical Societies. Published by Elsevier Science B.V. All rights reserved.
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