Ssh1p determines the translocation and dislocation capacities of the yeast endoplasmic reticulum.

Sec61p is required both for protein translocation and dislocation across the membrane of the endoplasmic reticulum (ER). However, the cellular role of the Sec61p homolog Ssh1p has not been clearly defined. We show that deltassh1 mutant cells have strong defects in both SRP-dependent and -independent translocation. Moreover, these cells were also found to be induced for the unfolded protein response and to be defective in dislocation of a misfolded ER protein. In addition, deltassh1 mutant cells rapidly became respiratory deficient. The other defects discussed above were suppressed in the respiratory-deficient state or under conditions where the rate of polypeptide translation was artificially reduced. These data identify Ssh1p as a component of a second, functionally distinct translocon in the yeast ER membrane.

Sec63p and Kar2p are required for the translocation of SRP-dependent precursors into the yeast endoplasmic reticulum in vivo.

The translocation of secretory polypeptides into the endoplasmic reticulum (ER) occurs at the translocon, a pore-forming structure that orchestrates the transport and maturation of polypeptides at the ER membrane. In yeast, targeting of secretory precursors to the translocon can occur by two distinct pathways that are distinguished by their dependence upon the signal recognition particle (SRP). The SRP-dependent pathway requires SRP and its membrane-bound receptor, whereas the SRP-independent pathway requires a separate receptor complex consisting of Sec62p, Sec63p, Sec71p, Sec72p plus lumenal Kar2p/BiP. Here we demonstrate that Sec63p and Kar2p are also required for the SRP-dependent targeting pathway in vivo. Furthermore, we demonstrate multiple roles for Sec63p, at least one of which is exclusive to the SRP-independent pathway.

LHS1 and SIL1 provide a lumenal function that is essential for protein translocation into the endoplasmic reticulum.

Lhs1p is an Hsp70-related chaperone localized in the endoplasmic reticulum (ER) lumen. Deltalhs1 mutant cells are viable but are constitutively induced for the unfolded protein response (UPR). Here, we demonstrate a severe growth defect in Deltaire1Deltalhs1 double mutant cells in which the UPR can no longer be induced. In addition, we have identified a UPR- regulated gene, SIL1, whose overexpression is sufficient to suppress the Deltaire1Deltalhs1 growth defect. SIL1 encodes an ER-localized protein that interacts directly with the ATPase domain of Kar2p (BiP), suggesting some role in modulating the activity of this vital chaperone. SIL1 is a non-essential gene but the Deltalhs1Deltasil1 double mutation is lethal and correlates with a complete block of protein translocation into the ER. We conclude that the IRE1-dependent induction of SIL1 is a vital adaptation in Deltalhs1 cells, and that the activities associated with the Lhs1 and Sil1 proteins constitute an essential function required for protein translocation into the ER. The Sil1 protein appears widespread amongst eukaryotes, with homologues in Yarrowia lipolytica (Sls1p), Drosophila and mammals.

Disruption and functional analysis of six ORFs on chromosome XII of saccharomyces cerevisiae: YLR124w, YLR125w, YLR126c, YLR127c, YLR128w and YLR129w.

In the context of the EUROFAN programme, we report the deletion and functional analysis of six open reading frames (ORFs) on the right arm of chromosome XII of Saccharomyces cerevisiae. Using a PCR-based gene replacement strategy, we have systematically deleted individual ORFs and subjected the heterozygous diploids and haploid knockout strains to basic genetic and phenotypic characterization. Two ORFs, YLR127c and YLR129w, are essential for viability, whereas no growth phenotype could be detected following deletion of YLR124w, YLR125w, YLR126c or YLR128w. For each of the individual ORFs, a kanMX4 replacement cassette and the corresponding cognate wild-type gene were cloned into appropriate plasmids.

In vivo targeting of a sunflower oil body protein in yeast secretory (sec) mutants.

A sunflower oleosin was expressed in yeast to study the in vivo insertion of the protein into the endoplasmic reticulum (ER) and subsequent transfer to lipid bodies. The oleosin cDNA was expressed in a range of yeast secretory (sec) mutants to determine the precise targeting pathway of the oleosin to the ER. Subcellular fractionation experiments indicated that the signal recognition particle (SRP) is required for oleosin targeting to the ER and hence subsequent deposition on the lipid bodies in vivo. The expression of oleosin in a range of sec61 mutant alleles confirmed the role of the SEC61 translocon in insertion of oleosin into the ER membrane, as well as indicating an unusual substrate/translocon interaction for one particular allele (sec61-3). Mistargeting of the oleosin due to impaired SRP function resulted in enhanced proteolysis of the plant protein in the transformed yeast, as determined by pulse-chase analysis. These data therefore provide the first in vivo evidence for the SRP-dependent targeting of the oleosin to the ER, and the subsequent requirement for a functional SEC61 translocon to mediate the correct insertion of the protein into the membrane.

Distinct domains within yeast Sec61p involved in post-translational translocation and protein dislocation.

The translocation of secretory polypeptides into and across the membrane of the endoplasmic reticulum (ER) occurs at the translocon, a pore-forming structure that orchestrates the transport and maturation of polypeptides at the ER membrane. Recent data also suggest that misfolded or unassembled polypeptides exit the ER via the translocon for degradation by the cytosolic ubiquitin/proteasome pathway. Sec61p is a highly conserved multispanning membrane protein that constitutes a core component of the translocon. We have found that the essential function of the Saccharomyces cerevisiae Sec61p is retained upon deletion of either of two internal regions that include transmembrane domains 2 and 3, respectively. However, a deletion mutation encompassing both of these domains was found to be nonfunctional. Characterization of yeast mutants expressing the viable deletion alleles of Sec61p has revealed defects in post-translational translocation. In addition, the transmembrane domain 3 deletion mutant is induced for the unfolded protein response and is defective in the dislocation of a misfolded ER protein. These data demonstrate that the various activities of Sec61p can be functionally dissected. In particular, the transmembrane domain 2 region plays a role in post-translational translocation that is required neither for cotranslational translocation nor for protein dislocation.

The yeast CDC9 gene encodes both a nuclear and a mitochondrial form of DNA ligase I.

BACKGROUND: The yeast CDC9 gene encodes a DNA ligase I activity required during nuclear DNA replication to ligate the Okazaki fragments formed when the lagging DNA strand is synthesised. The only other DNA ligase predicted from the yeast genome sequence, DNL4/LIG4, is specifically involved in a non-homologous DNA end-joining reaction. What then is the source of the DNA ligase activity required for replication of the yeast mitochondrial genome? RESULTS: We report that CDC9 encodes two distinct polypeptides expressed from consecutive in-frame AUG codons. Translational initiation at these two sites gives rise to polypeptides differing by a 23 residue amino-terminal extension, which corresponds to a functional mitochondrial pre-sequence sufficient to direct import into yeast mitochondria. Initiation at the first AUG codon results in a 755 amino-acid polypeptide that is imported into mitochondria, whereupon the pre-sequence is proteolytically removed to yield the mature mitochondrial form of Cdc9p. Initiation at the second AUG codon produces a 732 amino-acid polypeptide, which is localised to the nucleus. Cells expressing only the nuclear isoform were found to be specifically defective in the maintenance of the mitochondrial genome. CONCLUSIONS: CDC9 encodes two distinct forms of DNA ligase I. The first is targeted to the mitochondrion and is required for propagation and maintenance of mitochondrial DNA, the second localises to the nucleus and is sufficient for the essential cell-division function associated with this gene.

Signal sequence recognition in posttranslational protein transport across the yeast ER membrane.

We have analyzed how the signal sequence of prepro-alpha-factor is recognized during the first step of posttranslational protein transport into the yeast endoplasmic reticulum. Cross-linking studies indicate that the signal sequence interacts in a Kar2p- and ATP-independent reaction with Sec61p, the multispanning membrane component of the protein-conducting channel, by intercalation into transmembrane domains 2 and 7. While bound to Sec61p, the signal sequence forms a helix that is contacted on one side by Sec62p and Sec71p. The binding site is located at the interface of the protein channel and the lipid bilayer. Signal sequence recognition in cotranslational translocation in mammals appears to occur similarly. These results suggest a general mechanism by which the signal sequence could open the channel for polypeptide transport.

Deletion analysis of yeast Sec65p reveals a central domain that is sufficient for function in vivo.

The Saccharomyces cerevisiae SEC65 gene encodes a 32 kDa subunit of yeast signal recognition particle that is homologous to human SRP19. Sequence comparisons suggest that the yeast protein comprises three distinct domains. The central domain (residues 98-171) exhibits substantial sequence similarity to the 144 residue SRP19. In contrast, the N-terminal and C-terminal domains (residues 1-97 and 172-273 respectively) share no similarity to SRP19, with the exception of a cluster of positively charged residues at the extreme C-terminus of both proteins. Here, we report the cloning of a Sec65p homologue from the yeast Candida albicans that shares the same extended domain structure as its S. cerevisiae counterpart. This conservation of sequence is reflected at the functional level, as the C. albicans gene can complement the conditional lethal sec65-1 mutation in S. cerevisiae. In order to examine the role of the N- and C- terminal domains in Sec65p function, we have engineered truncation mutants of S. cerevisiae SEC65 and tested these for complementing activity in vivo and for SRP integrity in vitro. These studies indicate that a minimal Sec65p comprising residues 76-209, which includes the entire central SRP19-like domain, is sufficient for SRP function in yeast.

Molecular architecture of the ER translocase probed by chemical crosslinking of Sss1p to complementary fragments of Sec61p.

The heterotrimeric Sec61p complex is a key component of the protein translocation apparatus of the endoplasmic reticulum membrane. The complex characterized from yeast includes Sec61p, a 10-transmembrane-domain membrane protein which has a direct interaction with Sss1p, a small C-terminal anchor protein. In order to gain some insight into the architecture of this complex we have functionally expressed Sec61p as complementary N- and C-terminal fragments. Chemical crosslinking of Sss1p to specific Sec61p fragments in these functional combinations and suppression of sec61 mutants by over-expression of Sss1p have led to identification of the region which includes transmembrane domains TM6, TM7 and TM8 (amino acid residues L232-R406) of Sec61p as a major site of interaction with Sss1p.

A novel subfamily of Hsp70s in the endoplasmic reticulum.

The endoplasmic reticulum contains a number of proteins involved in the processing of secretory polypeptides. These include BiP, which is an Hsp70-family member highly conserved throughout evolution. BiP is known to be intimately involved in several aspects of protein biogenesis, but our understanding of these events has been complicated by the recent description of a novel Hsp70-related protein in yeast, Lhauthorp, whose functions overlap with those of BiP. Current indications are that this protein is distributed widely among eukaryotes and that it represents a distinct subfamily of the Hsp70 class of molecular chaperones.

The Hsp70 homologue Lhs1p is involved in a novel function of the yeast endoplasmic reticulum, refolding and stabilization of heat-denatured protein aggregates.

Heat stress is an obvious hazard, and mechanisms to recover from thermal damage, largely unknown as of yet, have evolved in all organisms. We have recently shown that a marker protein in the ER of Saccharomyces cerevisiae, denatured by exposure of cells to 50 degrees C after preconditioning at 37 degrees C, was reactivated by an ATP-dependent machinery, when the cells were returned to physiological temperature 24 degrees C. Here we show that refolding of the marker enzyme Hsp150Delta-beta-lactamase, inactivated and aggregated by the 50 degrees C treatment, required a novel ER-located homologue of the Hsp70 family, Lhs1p. In the absence of Lhs1p, Hsp150Delta-beta-lactamase failed to be solubilized and reactivated and was slowly degraded. Coimmunoprecipitation experiments suggested that Lhs1p was somehow associated with heat-denatured Hsp150Delta- beta-lactamase, whereas no association with native marker protein molecules could be detected. Similar findings were obtained for a natural glycoprotein of S. cerevisiae, pro-carboxypeptidase Y (pro-CPY). Lhs1p had no significant role in folding or secretion of newly synthesized Hsp150Delta-beta-lactamase or pro-CPY, suggesting that the machinery repairing heat-damaged proteins may have specific features as compared to chaperones assisting de novo folding. After preconditioning and 50 degrees C treatment, cells lacking Lhs1p remained capable of protein synthesis and secretion for several hours at 24 degrees C, but only 10% were able to form colonies, as compared to wild-type cells. We suggest that Lhs1p is involved in a novel function operating in the yeast ER, refolding and stabilization against proteolysis of heatdenatured protein. Lhs1p may be part of a fundamental heat-resistant survival machinery needed for recovery of yeast cells from severe heat stress.

Protein translocation across the membrane of the endoplasmic reticulum.

Eukaryotic cells are characterized by the existence of membrane-bound subcellular compartments which perform a variety of specialized functions. Proteins destined for these compartments begin their synthesis in the cytosol and must be subsequently targeted to their functional compartment by specific signal sequences present in the newly synthesized polypeptide chain. The translocation of preproteins across biological membranes is a fundamental process of intracellular trafficking and organelle biogenesis. Entry into the secretory pathway occurs by translocation of proteins into or across the membrane of the endoplasmic reticulum (ER). This process involves two distinct steps which are dependent on the orchestrated action of several proteins. The initial step of targeting involves recognition of the signal sequence and delivery of the protein precursor to the ER in a translocation competent conformation. The subsequent translocation event is characterized by interaction of the preprotein with the translocation channel followed by unidirectional movement across the lipid bilayer of the ER membrane into the lumenal space. The study of the mechanism of the translocation process is one of the most intriguing and rapidly advancing areas in cell biology. Here we review recent findings in both the yeast Saccharomyces cerevisiae and mammals concerning the mechanisms of the translocation step and discuss the roles of the proteins implicated in this process.

Cloning of SEC61 homologues from Schizosaccharomyces pombe and Yarrowia lipolytica reveals the extent of functional conservation within this core component of the ER translocation machinery.

The Sec61 protein is required for protein translocation across the ER membrane in both yeast and mammals and is found in close association with polypeptides during their membrane transit. In Saccharomyces cerevisiae Sec61p is essential for viability and the extent of sequence similarity between the yeast and mammalian proteins (55% sequence identity) suggests that the role of Sec61p in the translocation mechanism is likely to be conserved. In order to further our understanding of the structure and function of Sec61p we have cloned homologues from both Schizosaccharomyces pombe and Yarrowia lipolytica. The S. pombe gene comprises six exons encoding a 479 residue protein which we have immunolocalised to the endoplasmic reticulum. Sequence comparisons reveal that S. pombe Sec61p is 58.6% identical to that of S. cerevisiae. The deduced amino acid sequence of the Y. lipolytica protein shares 68.8% sequence identity with S. cerevisiae Sec61p. Gene disruption studies have shown that the SEC61 is required for viability in both S. pombe and Y. lipolytica demonstrating that the essential nature of this protein is not unique to S. cerevisiae. Moreover, heterologous complementation studies indicate that the Y. lipolytica SEC61 gene can complement a null mutation in S. cerevisiae. Sequence comparisons between the various eukaryotic Sec61p homologues reveal a number of highly conserved domains, including several transmembrane sequences and the majority of cytosolic loops. These comparisons will provide an important framework for the detailed analysis of interactions between Sec61p and other components of the translocation machinery and between Sec61p and translocating polypeptide chains.

Determination of the transmembrane topology of yeast Sec61p, an essential component of the endoplasmic reticulum translocation complex.

Sec61p is a highly conserved integral membrane protein that plays a role in the formation of a protein-conducting channel required for the translocation of polypeptides into, and across, the membrane of the endoplasmic reticulum. As a major step toward elucidating the structure of the endoplasmic reticulum translocation apparatus, we have determined the transmembrane topology of Sec61p using a combination of C-terminal reporter-domain fusions and the in situ digestion of specifically inserted factor Xa protease cleavage sites. Our data indicate the presence of 10 transmembrane domains, including several with surprisingly limited hydrophobicity. Furthermore, we provide evidence for complex intramolecular interactions in which these weakly hydrophobic domains require C-terminal sequences for their correct topogenesis. The incorporation of sequences with limited hydrophobicity into the bilayer may play a vital role in the formation of an aqueous membrane channel required for the translocation of hydrophilic polypeptide chains.

Functional conservation of cytosolic proteins required for endosomal vesicle fusion.

Recent studies suggest that intracellular membrane traffic relies upon families of related proteins which confer specificity to individual transport reactions but which operate in tandem with a ubiquitous fusogenic complex containing the N-ethylmaleimide-sensitive fusion protein (NSF). The extent to which components of this process are functionally conserved is apparent from the finding that yeast Sec18 protein (Sec18p) can substitute or mammalian NSF in intra-Golgi transport reactions. Here we report that yeast cytosol can support mammalian endosomal vesicle fusion, demonstrating conservation of cytosolic components required for this reaction. Furthermore, under conditions in which the fusion reaction is NSF-dependent we show that yeast Sec18p can functionally substitute for NSF, showing that the yeast protein is capable of catalysing at least two distinct mammalian membrane fusion events. In addition we exploit the complex pattern of sensitivity of the mammalian reaction to N-ethylmaleimide (NEM), coupled with the use of yeast cytosol, to dissect a number of factors required for fusion. We reveal at least three novel NEM-sensitive activities. One of these can be restored by yeast cytosol suggesting that it is functionally conserved.

A novel Hsp70 of the yeast ER lumen is required for the efficient translocation of a number of protein precursors.

The yeast genome sequencing project predicts an open reading frame (YKL073) that would encode a novel member of the Hsp70 family of molecular chaperones. We report that this 881 codon reading frame represents a functional gene expressing a 113-119 kDa glycoprotein localized within the lumen of the endoplasmic reticulum (ER). We therefore propose to designate this gene LHS1 (Lumenal Hsp Seventy). Our studies indicate that LHS1 is regulated by the unfolded protein response pathway, as evidenced by its transcriptional induction in cells treated with tunicamycin, and in various mutants defective in precursor processing (sec11-7, sec53-6 and sec59-1). LHS1 is not essential for viability, but an Lhs1 null mutant strain exhibits a coordinated induction of genes regulated by the unfolded protein response indicating a role for Lhs1p in protein folding in the ER. Furthermore, the null mutation is synthetically lethal in combination with (delta)ire1, thus activation of the unfolded protein response pathway is essential for cells to tolerate loss of Lhs1p. Synthetically lethality is also seen with mutations in KAR2, strongly suggesting that Kar2p and Lhs1p have overlapping functions. The Lhs1 null mutant exhibits a severe constitutive defect in the translocation of several secretory preproteins. We therefore propose that Lhs1p is a molecular chaperone of the ER lumen involved in both polypeptide translocation and subsequent protein folding.

Walking, cloning, and mapping with YACs in 3q27: localization of five ESTs including three members of the cystatin gene family and identification of CpG islands.

Using yeast artificial chromosomes, we have generated a high-resolution physical map for 2.7 Mb of human chromosomal region 3q27. The YAC clones group into three contigs, one of which has also been linked to the CEPH YAC contig map of human chromosome 3. Fluorescence in sity hybridization has been used to order the contigs on the chromosome and to estimate the distance between them. Expressed sequence tags for five genes, including three members of the cystatin gene family and a gene thought to be involved in B-cell non-Hodgkin lymphoma, have been placed within the YAC contigs, and 12 putative CpG islands have been identified. These YACs provide a useful resource to complete the physical mapping of 3q27 and to begin identification and characterization of further genes that are located there.

Multiple N-ethylmaleimide-sensitive components are required for endosomal vesicle fusion.

This report examines the inhibition of endosomal vesicle fusion by the alkylating agent N-ethylmaleimide (NEM). The concentration of NEM required to inhibit vesicle fusion depended upon whether membrane and cytosolic fractions were treated separately or together, enabling the resolution of at least two components to the inhibition. The first component is inactivated at low levels of NEM when cytosolic and membrane fractions are treated together. On the contrary, inhibition of the second component required higher levels of NEM but was achieved by treating cytosol and membranes separately. Reconstitution studies indicated that both components were cytosolic and that neither corresponded to the ubiquitous NEM-sensitive fusion protein (NSF). The role of NSF in this fusion reaction was further examined using salt-washed membranes depleted of NSF protein. Under these conditions the fusion reaction was fully dependent upon added NSF whose activity, in this context, was sensitive to NEM treatment. From these data we conclude that NSF activity during endosomal vesicle fusion can be dissected into several steps, only a subset of which (perhaps attachment of NSF to the membrane) are sensitive to NEM. Fusion between salt-washed endosomal membranes was also dependent on soluble NSF attachment proteins.