Investigation of stress tolerance of Pichia kudriavzevii for high gravity bioethanol production from steam-exploded wheat straw hydrolysate.

This study investigated a newly isolated thermotolerant strain of Pichia kudriavzevii with respect to its stress tolerance and fermentation performance. Response surface methodology was applied to evaluate the combined effects of furfural, osmotic and thermal stress on ethanol yield. The proposed model shows that P. kudriavzevii has a natural resistance against multiple stress factors. Further evolutionary adaptation of the isolated strain in lignocellulosic hydrolysates improved the ethanol yield by ≥ 24 %. The adapted strain HYPK213_ELA was able to produce ethanol from wheat straw hydrolysates at a high solid loading of 37 %ww-1 at 40 °C and anaerobic conditions. The highest ethanol concentration of 56.8 ± 1.0 gL-1 was reached at 40°C with an inoculum size of 2.5 × 106cellsmL-1. The results show that Pichia kudriavzevii has the potential to enable high gravity bioethanol production under conditions where most yeast strains are unable to grow.

Vps68 cooperates with ESCRT-III in intraluminal vesicle formation.

The endosomal sorting complex required for transport (ESCRT)-III mediates budding and abscission of intraluminal vesicles (ILVs) into multivesicular endosomes. To further define the role of the yeast ESCRT-III-associated protein Mos10 (also known as Vps60) in ILV formation, we screened for new interaction partners by using stable isotope labeling of amino acids in cell culture (SILAC) and mass spectrometry. Here, we focused on the newly identified interaction partner Vps68. Our data suggest that Vps68 cooperates with ESCRT-III in ILV formation. The deletion of VPS68 caused a sorting defect similar to that of the SNF7 deletion strain when the cargo load was high. The composition of ESCRT-III was altered, the level of core components was higher and the level of associated proteins was lower in the VPS68 deletion strain. Our data further indicate that at some point in the functional cycle of ESCRT-III, Snf7 could be replaced by Mos10. Vps68 has an unusual membrane topology. Two of its potential membrane helices are amphipathic helices that localize to the luminal side of the endosomal membrane. Based on this membrane topology, we propose that Vps68 and ESCRT-III cooperate in the abscission step by weakening the luminal and cytosolic leaflets of the bilayer at the abscission site.

Comprehensive analysis of yeast ESCRT-III composition in single ESCRT-III deletion mutants.

The endosomal sorting complex required for transport (ESCRT)-III is associated with a multitude of cellular processes involving membrane remodeling and abscission. The exact composition of ESCRT-III and the contribution of individual ESCRT-III family members to these diverse functions is unclear. Most of the currently available information about ESCRT-III was obtained with tagged, largely non-functional proteins, which may not correctly reflect the in vivo situation. Here, we performed a comprehensive biochemical analysis of ESCRT-III localization and composition in yeast under purely native conditions. Most of our findings are in line with the current concepts about ESCRT-III, but some findings are unexpected and call for adjustments to the model. In particular, our data suggest that the distinction between bona fide ESCRT-III components and ESCRT-III associated proteins is not justified. We detected a single complex containing all ESCRT-III members (except of Chm7) with Did2 as its main component. The classical core components were present in equimolar amounts. Our analysis of the impact of single deletions on the composition of ESCRT-III confirmed the central role of Snf7 for ESCRT-III assembly. For the other ESCRT-III family members predictions could be made about their role in ESCRT-III assembly. Furthermore, our cell fractionation points to a role of Vps20 at the endoplasmic reticulum.

Interactions in the ESCRT-III network of the yeast Saccharomyces cerevisiae.

Here, we examine the genetic interactions between ESCRT-III mutations in the yeast Saccharomyces cerevisiae. From the obtained interaction network, we make predictions about alternative ESCRT-III complexes. By the successful generation of an octuple deletion strain using the CRISPR/Cas9 technique, we demonstrate for the first time that ESCRT-III activity as a whole is not essential for the life of a yeast cell. Endosomal sorting complex required for transport (ESCRT)-III proteins are membrane remodeling factors involved in a multitude of cellular processes. There are eight proteins in yeast with an ESCRT-III domain. It is not clear whether the diverse ESCRT-III functions are fulfilled by a single ESCRT-III complex or by different complexes with distinct composition. Genetic interaction studies may provide a hint on the existence of alternative complexes. We performed a genetic mini-array screen by analyzing the growth phenotypes of all pairwise combinations of ESCRT-III deletion mutations under different stress conditions. Our analysis is in line with previous data pointing to a complex containing Did2/CHMP1 and Ist1/IST1. In addition, we provide evidence for the existence of a novel complex consisting of Did2/CHMP1 and Vps2/CHMP2. Some of the interactions on Congo red plates could be explained by effects of ESCRT-III mutations on Rim101 signaling.

Role of mitochondrial processing peptidase and AAA proteases in processing of the yeast acetohydroxyacid synthase precursor.

We studied presequence processing of the mitochondrial-matrix targeted acetohydroxyacid synthase (Ilv2). C-terminal 3HA-tagging altered the cleavage pattern from a single step to sequential two-step cleavage, giving rise to two Ilv2-3HA forms (A and B). Both cleavage events were dependent on the mitochondrial processing peptidase (MPP). We present evidence for the involvement of three AAA ATPases, m- and i-AAA proteases, and Mcx1, in Ilv2-3HA processing. Both, precursor to A-form and A-form to B-form cleavage were strongly affected in a ∆yme1 mutant. These defects could be suppressed by overexpression of MPP, suggesting that MPP activity is limiting in the ∆yme1 mutant. Our data suggest that for some substrates AAA ATPases could play an active role in the translocation of matrix-targeted proteins.

Evidence for a Nonendosomal Function of the Saccharomyces cerevisiae ESCRT-III-Like Protein Chm7.

Endosomal sorting complex required for transport (ESCRT) proteins are involved in a number of cellular processes, such as endosomal protein sorting, HIV budding, cytokinesis, plasma membrane repair, and resealing of the nuclear envelope during mitosis. Here we explored the function of a noncanonical member of the ESCRT-III protein family, the Saccharomyces cerevisiae ortholog of human CHMP7. Very little is known about this protein. In silico analysis predicted that Chm7 (yeast ORF YJL049w) is a fusion of an ESCRT-II and ESCRT-III-like domain, which would suggest a role in endosomal protein sorting. However, our data argue against a role of Chm7 in endosomal protein sorting. The turnover of the endocytic cargo protein Ste6 and the vacuolar protein sorting of carboxypeptidase S (CPS) were not affected by CHM7 deletion, and Chm7 also responded very differently to a loss in Vps4 function compared to a canonical ESCRT-III protein. Our data indicate that the Chm7 function could be connected to the endoplasmic reticulum (ER). In line with a function at the ER, we observed a strong negative genetic interaction between the deletion of a gene function (APQ12) implicated in nuclear pore complex assembly and messenger RNA (mRNA) export and the CHM7 deletion. The patterns of genetic interactions between the APQ12 deletion and deletions of ESCRT-III genes, two-hybrid interactions, and the specific localization of mCherry fusion proteins are consistent with the notion that Chm7 performs a novel function at the ER as part of an alternative ESCRT-III complex.

Interaction maps of the Saccharomyces cerevisiae ESCRT-III protein Snf7.

The Saccharomyces cerevisiae ESCRT-III protein Snf7 is part of an intricate interaction network at the endosomal membrane. Interaction maps of Snf7 were established by measuring the degree of binding of individual binding partners to putative binding motifs along the Snf7 sequence by glutathione S-transferase (GST) pulldown. For each interaction partner, distinct binding profiles were obtained. The following observations were made. The ESCRT-III subunits Vps20 and Vps24 showed a complementary binding pattern, suggesting a model for the series of events in the ESCRT-III functional cycle. Vps4 bound to individual Snf7 motifs but not to full-length Snf7. This suggests that Vps4 does not bind to the closed conformation of Snf7. We also demonstrate for the first time that the ALIX/Bro1 homologue Rim20 binds to the α6 helix of Snf7. Analysis of a Snf7 α6 deletion mutant showed that the α6 helix is crucial for binding of Bro1 and Rim20 in vivo and is indispensable for the multivesicular body (MVB)-sorting and Rim-signaling functions of Snf7. The Snf7Δα6 protein still appeared to be incorporated into ESCRT-III complexes at the endosomal membrane, but disassembly of the complex seemed to be defective. In summary, our study argues against the view that the ESCRT cycle is governed by single one-to-one interactions between individual components and emphasizes the network character of the ESCRT interactions.

Cytosolic localization of acetohydroxyacid synthase Ilv2 and its impact on diacetyl formation during beer fermentation.

Diacetyl (2,3-butanedione) imparts an unpleasant "butterscotch-like" flavor to alcoholic beverages such as beer, and therefore its concentration needs to be reduced below the sensory threshold before packaging. We examined the mechanisms that lead to highly elevated diacetyl formation in petite mutants of Saccharomyces cerevisiae during beer fermentations. We present evidence that elevated diacetyl formation is tightly connected to the mitochondrial import of acetohydroxyacid synthase (Ilv2), the key enzyme in the production of diacetyl. Our data suggest that accumulation of the matrix-targeted Ilv2 preprotein in the cytosol is responsible for the observed high diacetyl levels. We could show that the Ilv2 preprotein accumulates in the cytosol of petite yeasts. Furthermore, expression of an Ilv2 variant that lacks the N-terminal mitochondrial targeting sequence and thus cannot be imported into mitochondria led to highly elevated diacetyl levels comparable to a petite strain. We further show that expression of a mutant allele of the γ-subunit of the F(1)-ATPase (ATP3-5) could be an attractive way to reduce diacetyl formation by petite strains.

Mapping of Vps21 and HOPS binding sites in Vps8 and effect of binding site mutants on endocytic trafficking.

Vps8 is a subunit of the CORVET tethering complex, which is involved in early-to-late endosome fusion. Here, we examine the role of Vps8 in membrane fusion at late endosomes in Saccharomyces cerevisiae. We demonstrate that Vps8 associates with membranes and that this association is independent of the class C/HOPS core complex and, contrary to a previous report, also independent of the Rab GTPase Vps21. Our data indicate that Vps8 makes multiple contacts with membranes. One of these membrane binding regions could be mapped to the N-terminal part of the protein. By two-hybrid analysis, we obtained evidence for a physical interaction between Vps8 and the Rab5 homologue Vps21. In addition, the interaction with the HOPS core complex was confirmed by immunoprecipitation experiments. By deletion analysis, the Vps21 and HOPS binding sites were mapped in Vps8. Deletions that abrogated HOPS core complex binding had a strong effect on the turnover of the endocytic cargo protein Ste6 and on vacuolar sorting of carboxypeptidase Y. In contrast, deletions that abolished Vps21 binding showed only a modest effect. This suggests that the Vps21 interaction is not essential for endosomal trafficking but may be important for some other aspect of Vps8 function.

Analysis of the dual function of the ESCRT-III protein Snf7 in endocytic trafficking and in gene expression.

ESCRT (endosomal sorting complex required for transport)-III mediates the budding and scission of intralumenal vesicles into multivesicular endosomes in yeast. For the main ESCRT-III subunit Snf7, an additional role in activation of the transcription factor Rim101 (the 'Rim pathway') is now also firmly established. In the present study, we investigate how these two Snf7 functions are related to each other. By generating SNF7 mutations that severely affect endocytic trafficking, but leave the Rim pathway function intact, we show that the two functions of SNF7 can be separated genetically. We analysed in detail how the SNF7 mutations affect the interaction of Snf7 with its various binding partners. Although the interactions with proteins Rim13 and Rim20, necessary for the Rim-pathway-related functions, were not altered by the mutations, there was a strong effect on interactions with components of the ESCRT pathway. The interactions, as measured by co-immunoprecipitation, with the ESCRT-III subunits Vps20 and Vps24 were strongly increased by the mutations, whereas the interactions with proteins Vps4 and Bro1, acting downstream of ESCRT-III, were reduced. As Vps4 is required for disassembly of ESCRT-III these results suggest that ESCRT-III is more stable in our SNF7 mutants. In line with this notion, a higher fraction of mutant Snf7 protein was detected at the membrane. Upon a shift to alkaline pH, a stronger binding signal for virtually all interaction partners, except Vps4, was observed. This indicates that the ESCRT network at the endosomal membrane is more extensive under these conditions.

ESCRT-III protein Snf7 mediates high-level expression of the SUC2 gene via the Rim101 pathway.

The yeast (Saccharomyces cerevisiae) Snf7 family consists of six highly charged, coiled-coil-forming proteins involved in multivesicular body (MVB) formation. Although all proteins perform a common function at late endosomes, individual mutants also show distinct phenotypes. This suggests that Snf7 homologues have additional functions separate from their role in MVB formation. In this report, we explored the molecular basis for the sucrose-nonfermenting phenotype of snf7 mutants. Our Northern blotting experiments provide evidence that Snf7 is involved in the regulation of SUC2 transcription. The Snf7-dependent regulation of SUC2 transcription does not appear to involve the transcription factor Mig1, since Mig1 phosphorylation after glucose derepression was not affected in a Deltasnf7 mutant. Instead, we show that Snf7 influences SUC2 expression by regulating the level of the transcription factor Nrg1. Snf7 exerts its effects on Nrg1 levels through activation of the transcription factor Rim101, which is part of the yeast alkaline response pathway ("Rim101 pathway"). This is supported by the findings that deletion of RIM101 or overexpression of NRG1 from the ADH1 promoter leads to the same SUC2 expression level as deletion of SNF7. In addition, deletion of other components of the Rim101 pathway, like RIM13 and RIM20, led to the same growth phenotype on raffinose media as deletion of SNF7. Furthermore, Snf7 turned out to be dispensable for SUC2 expression in an NRG1 deletion background. Thus, the effects of Snf7 on SUC2 expression can be completely accounted for by its effect on Nrg1 levels.

Role of gamma-subunit N- and C-termini in assembly of the mitochondrial ATP synthase in yeast.

The gamma-subunit is required for the assembly of ATP synthases and plays a crucial role in their catalytic activity. We stepwise shortened the N-terminus and the C-terminus of the gamma-subunit in the mitochondrial ATP synthase of yeast and investigated the relevance of these segments in the assembly of the enzyme and in the growth of the cells. We found that a deletion of 9 residues at the N-terminus or 20 residues at the C-terminus still allowed efficient import of the subunit into mitochondria; however, the assembly of both monomeric and dimeric holoenzymes was partially impaired. gamma-Subunits lacking 13 N-terminal residues or 30 C-terminal residues were not assembled. Yeast strains expressing either of the truncated gamma-subunits did not grow on non-fermentable carbon sources, indicating that non-assembled parts of the ATP synthase accumulated and impaired essential mitochondrial functions.

Control of Ste6 recycling by ubiquitination in the early endocytic pathway in yeast.

We present evidence that ubiquitination controls sorting of the ABC-transporter Ste6 in the early endocytic pathway. The intracellular distribution of Ste6 variants with reduced ubiquitination was examined. In contrast to wild-type Ste6, which was mainly localized to internal structures, these variants accumulated at the cell surface in a polar manner. When endocytic recycling was blocked by Ypt6 inactivation, the ubiquitination deficient variants were trapped inside the cell. This indicates that the polar distribution is maintained dynamically through endocytic recycling and localized exocytosis ("kinetic polarization"). Ste6 does not appear to recycle through late endosomes, because recycling was not blocked in class E vps (vacuolar protein sorting) mutants (Deltavps4, Deltavps27), which are affected in late endosome function and in the retromer mutant Deltavps35. Instead, recycling was partially affected in the sorting nexin mutant Deltasnx4, which serves as an indication that Ste6 recycles through early endosomes. Enhanced recycling of wild-type Ste6 was observed in class D vps mutants (Deltapep12, Deltavps8, and Deltavps21). The identification of putative recycling signals in Ste6 suggests that recycling is a signal-mediated process. Endocytic recycling and localized exocytosis could be important for Ste6 polarization during the mating process.

The deubiquitinating enzyme Ubp1 affects sorting of the ATP-binding cassette-transporter Ste6 in the endocytic pathway.

Deubiquitinating enzymes (Dubs) are potential regulators of ubiquitination-dependent processes. Here, we focus on a member of the yeast ubiquitin-specific processing protease (Ubp) family, the Ubp1 protein. We could show that Ubp1 exists in two forms: a longer membrane-anchored form (mUbp1) and a shorter soluble form (sUbp1) that seem to be independently expressed from the same gene. The membrane-associated mUbp1 variant could be localized to the endoplasmic reticulum (ER) membrane by sucrose density gradient centrifugation and by immunofluorescence microscopy. Overexpression of the soluble Ubp1 variant stabilizes the ATP-binding cassette-transporter Ste6, which is transported to the lysosome-like vacuole for degradation, and whose transport is regulated by ubiquitination. Ste6 stabilization was not the result of a general increase in deubiquitination activity, because overexpression of Ubp1 had no effect on the degradation of the ER-associated degradation substrate carboxypeptidase Y* and most importantly on Ste6 ubiquitination itself. Also, overexpression of another yeast Dub, Ubp3, had no effect on Ste6 turnover. This suggests that the Ubp1 target is a component of the protein transport machinery. On Ubp1 overexpression, Ste6 accumulates at the cell surface, which is consistent with a role of Ubp1 at the internalization step of endocytosis or with enhanced recycling to the cell surface from an internal compartment.

The HECT E3 ubiquitin ligase Rsp5 is important for ubiquitin homeostasis in yeast.

The HECT E3 ubiquitin ligase Rsp5, a yeast member of the Nedd4 family, has been implicated in many different aspects of cell physiology. Here, we present evidence that Rsp5 function is important for ubiquitin homeostasis. Several observations suggest that ubiquitin is limiting in the rsp5-1 mutant. Reduced synthesis of ubiquitin appears to contribute to ubiquitin depletion. A transient inhibition of general protein synthesis is observed in a wildtype strain upon heat-shock. While the wildtype cells quickly recover from this transient arrest, the rsp5-1 cells remain arrested. This suggests that Rsp5 is important for recovery from heat-induced protein synthesis arrest. Our results suggest that rsp5 phenotypes should be interpreted with caution, since some of the phenotypes could be simply the result of ubiquitin limitation.

Trafficking of the bile salt export pump from the Golgi to the canalicular membrane is regulated by the p38 MAP kinase.

BACKGROUND & AIMS: Bile secretion depends on the delivery and removal of transporter proteins to and from the canalicular membrane. Trafficking of the bile salt export pump (BSEP) to the canalicular membrane was investigated in HepG2 cells and rat hepatocytes. METHODS: Subcellular localization of BSEP was determined by confocal laser scanning microscopy using different BSEP antibodies. RESULTS: Ten percent of untreated HepG2 cells developed pseudocanaliculi, but only 15% of these pseudocanaliculi contained BSEP, which largely colocalized with the Golgi marker GM130. Cycloheximide, an inhibitor of protein translation, induced a microtubule- and p38(MAP) kinase-dependent decrease of Golgi-associated BSEP, accompanied by a more than 2-fold increase in BSEP-positive pseudocanaliculi. Also, tauroursodeoxycholate (TUDC), which activates p38(MAP) kinase (p38(MAPK), increased BSEP-positive pseudocanaliculi by more than 50% in rat sodium taurocholate cotransporting peptide (Ntcp)-transfected but not in untransfected HepG2 cells. The TUDC-dependent increase was sensitive to inhibitors of p38(MAPK) and microtubules and involved Ca(2+)-independent protein kinase C isoforms as suggested by its sensitivity to Gö6850 but insensitivity to Gö6976. In isolated rat hepatocytes with intact bile secretion, no colocalization of rat isoforms of the bile salt export pump (Bsep) and Golgi was found, but colocalization occurred after inhibition of p38(MAPK) and PKC, suggesting that Bsep trafficking to the canalicular membrane depends on the basal activity of these kinases in polarized cells. CONCLUSIONS: p38(MAPK) regulates BSEP trafficking from the Golgi to the canalicular membrane, and the Golgi may serve as a BSEP pool in certain forms of cholestasis or when p38(MAPK) activity is inhibited. Activation of p38(MAPK) by TUDC can recruit Golgi-associated BSEP in line with its choleretic action.

The yeast deubiquitinating enzyme Ubp16 is anchored to the outer mitochondrial membrane.

We looked for membrane-associated Dubs (deubiquitinating enzymes) among the 16 yeast members of the ubiquitin-specific processing protease (Ubp) family to identify potential regulators of ubiquitin-dependent processes at membranes. For each of the Ubps examined, a certain fraction was found to be membrane associated. This fraction was only small for most Ubps but quite substantial for some Ubps. For Ubp4/Doa4 almost 40% of the protein was found in the membrane fraction suggesting that this protein performs a major function at membranes, probably at endosomes. Among the proteins tested, only one protein (Ubp16) was exclusively membrane associated. By cell fractionation and immunofluorescence experiments, we could show that Ubp16 is localized to mitochondria. Ubp16 contains an N-terminal hydrophobic domain that is similar to N-terminal sequences of other yeast outer mitochondrial membrane proteins. The presence of this putative signal sequence and the result of protease protection experiments suggest that Ubp16 is an integral membrane protein of the outer mitochondrial membrane with an N(in)-C(out) orientation. Phenotypic characterization of the Deltaubp16 mutant and overexpression studies further suggest that Ubp16 is probably not important for the general functioning of mitochondria, but that it rather performs a more specialized function at mitochondria.

Mutations affecting phosphorylation, ubiquitination and turnover of the ABC-transporter Ste6.

In this report, the role of phosphorylation in the regulation of ubiquitination and turnover of the ABC-transporter Ste6 was investigated. We demonstrate that Ste6 is phosphorylated in vivo and that this phosphorylation is dependent on the presence of an acidic stretch ('A-box') in the linker region previously shown to be important for ubiquitination and fast turnover of Ste6. By mutagenesis, two serine/threonine residues were identified in the A-box region that are crucial for ubiquitination and trafficking to the yeast vacuole. In the mutants there was no simple correlation between phosphorylation and ubiquitination levels, suggesting that the two events may not be coupled.

Interaction of yeast Rab geranylgeranyl transferase with its protein and lipid substrates.

Small GTPases from the Rab/Ypt family regulate events of vesicular traffic in eukaryotic cells. For their activity, Rab proteins require a posttranslational modification that is conferred by Rab geranylgeranyltransferase (RabGGTase), which attaches geranylgeranyl moieties onto two cysteines of their C terminus. RabGGTase is present in both lower and higher eukaryotes in the form of heterodimers composed of alpha and beta subunits. However, the alpha subunits of RabGGTases from lower eukaryotes, including Saccharomyces cerevisiae (yRabGGTase), are half the size of the corresponding subunit of the mammalian enzyme. This difference is due to the presence of additional immunoglobulin (Ig)-like and leucine rich (LRR) domains in the mammalian transferase. To understand the possible evolutionary implications and functional consequences of structural differences between RabGGTases of higher and lower eukaryotes, we have investigated the interactions of yeast RabGGTase with its lipid and protein substrate. We have demonstrated that geranylgeranyl pyrophosphate binds to the enzyme with an affinity of ca. 40 nM, while binding of farnesyl pyrophosphate is much weaker, with a K(d) value of ca. 750 nM. This finding suggests that despite the structural difference, yRabGGTase selects its lipid substrate in a fashion similar to mammalian RabGGTase. However, unlike the mammalian enzyme, yRabGGTase binds prenylated and unprenylated Ypt1p:Mrs6p complexes with similar affinities (K(d) ca. 200 nM). Moreover, in contrast to the mammalian enzyme, phosphoisoprenoids do not influence the affinity of Mrs6p for yRabGGTase. Using an in vitro prenylation assay, we have demonstrated that yRabGGTase can prenylate Rab proteins in complex with mammalian REP-1, thus indicating that neither the LRR nor the Ig-like domains, nor the recently discovered alternative pathway of catalytic complex assembly, are essential for the catalytic activity of RabGGTase. Despite the ability to function in concert with yRabGGTase in vitro, expression of mammalian REP-1 could not complement deletion of MRS6 gene in S. cerevisiae in vivo. The implications of these findings are discussed.