A mammalian homolog of SEC61p and SECYp is associated with ribosomes and nascent polypeptides during translocation

Binding of ribosomes to the rough endoplasmic reticulum mediated by the Sec61p-complex

The cotranslational translocation of proteins across the ER membrane involves the tight binding of translating ribosomes to the membrane, presumably to ribosome receptors. The identity of the latter has been controversial. One putative receptor candidate is Sec61 alpha, a multi-spanning membrane protein that is associated with two additional membrane proteins (Sec61 beta and gamma) to form the Sec61p-complex. Other receptors of 34 and 180 kD have also been proposed on the basis of their ability to bind at low salt concentration ribosomes lacking nascent chains. We now show that the Sec61p-complex has also binding activity but that, at low salt conditions, it accounts for only one third of the total binding sites in proteoliposomes reconstituted from a detergent extract of ER membranes. Under these conditions, the assay has also limited specificity with respect to ribosomes. However, if the ribosome-binding assay is performed at physiological salt concentration, most of the unspecific binding is lost; the Sec61p-complex then accounts for the majority of specific ribosome-binding sites in reconstituted ER membranes. To study the membrane interaction of ribosomes participating in protein translocation, native rough microsomes were treated with proteases. The amount of membrane-bound ribosomes is only slightly reduced by protease treatment, consistent with the protease-resistance of Sec61 alpha which is shielded by these ribosomes. In contrast, p34 and p180 can be readily degraded, indicating that they are not essential for the membrane anchoring of ribosomes in protease-treated microsomes. These data provide further evidence that the Sec61p-complex is responsible for the membrane-anchoring of ribosomes during translocation and make it unlikely that p34 or p180 are essential for this process.

Post-translational protein import and folding

Significant advances have been made over the past year in analyzing the membrane machineries for the post-translational export of proteins in bacteria and for the import of proteins into mitochondria. Another important development is the identification in mitochondria of homologs of the bacterial heat-shock proteins DnaJ and GrpE, which function together with Hsp70 in membrane translocation and folding of imported proteins. A number of gene products involved in peroxisomal protein uptake have been identified, which are now awaiting biochemical analysis.

Signal sequence recognition and targeting of ribosomes to the endoplasmic reticulum by the signal recognition particle do not require GTP

The identification of GTP-binding sites in the 54-kDa subunit of the signal recognition particle (SRP) and in both the alpha and beta subunits of the SRP receptor has complicated the task of defining the step in the protein translocation reaction that is controlled by the GTP-binding site in the SRP. Ribonucleotide binding assays show that the purified SRP can bind GDP or GTP. However, crosslinking experiments show that SRP54 can recognize the signal sequence of a nascent polypeptide in the absence of GTP. Targeting of SRP-ribosome-nascent polypeptide complexes, formed in the absence of GTP, to microsomal membranes likewise proceeds normally. To separate the GTPase cycles of SRP54 and the alpha subunit of the SRP receptor (SR alpha), we employed an SR alpha mutant that displays a markedly reduced affinity for GTP. We observed that the dissociation of SRP54 from the signal sequence and the insertion of the nascent polypeptide into the translocation site could only occur when GTP binding to SR alpha was permitted. These data suggest that the GTP binding and hydrolysis cycles of both SRP54 and SR alpha are initiated upon formation of the SRP-SRP receptor complex.

Protein translocation across the endoplasmic reticulum

In the past year, dramatic progress has been made in our understanding of protein biogenesis at the initial steps of the eukaryotic secretory pathway. New insights have refined our view of protein targeting to the endoplasmic reticulum membrane and provided the best glimpse so far of the subsequent translocation step. The interactions of three GTP-binding proteins have been found to result in a novel cycle of GTP binding and hydrolysis to regulate protein targeting. Experiments with fluorescent probes have revealed that the nascent chain enters an aqueous environment within the membrane sealed off from the cytosol. In vitro reconstitution experiments have shown surprising simplicity in the number of polypeptides required to facilitate translocation across a synthetic membrane and to promote the integration of membrane proteins. Furthermore, new genetic and functional similarities between divergent organisms have been discovered, providing convincing evidence of the evolutionary conservation of strategies used in the targeting and translocation of polypeptides.

Biochemical characterization of the presecretory protein translocation machinery of Escherichia coli

The protein translocation apparatus in Escherichia coli has been studied both genetically and biochemically. In vitro protein translocation systems involving everted membrane vesicles or reconstituted proteoliposomes have significantly contributed to biochemical clarification of the structure, mechanism and energetics of the apparatus. It is established that SecA, SecY and SecE are essential components, and play fundamental roles in the translocation reaction, and that both ATP and a proton motive force are required for the translocation. A new membrane factor, SecG, was found to participate in the formation of the apparatus, causing significant enhancement of the activity. SecD was found to play a role in the release of translocated proteins from the outer surface of the cytoplasmic membrane.

Protein translocation: common themes from bacteria to man

Protein transport across the endoplasmic reticulum membrane in eukaryotes and across the cytoplasmic membrane in bacteria have turned out to be highly related. The core component of the translocation apparatus is the Sec61/SecYp complex; at least two of its subunits are conserved in evolution. The Sec61/SecYp complex is involved in both co- and post-translational transport pathways. The two modes require probably distinct additional components.

The genetic interaction of kar2 and wbp1 mutations. Distinct functions of binding protein BiP and N-linked glycosylation in the processing pathway of secreted proteins in Saccharomyces cerevisiae

The endoplasmic binding protein BiP and N-linked glycosylation are proposed to be essential components in the processing pathway of secreted protein. In Saccharomyces cerevisiae, BiP is encoded by the KAR2 gene; WBP1 encodes an essential component of the N-oligosaccharyltransferase complex. wbp1 mutations result in reduced oligosaccharyltransferase activity and a temperature-sensitive phenotype. We show that a combination of kar2 and wbp1 mutations results in a synthetic phenotype with a strongly reduced growth rate at the permissive temperature. To investigate the role of N-linked glycosylation in BiP function, the processing of non-glycosylated carboxypeptidase was followed in different kar2 strains at the permissive temperature. In all kar2 strains, the processing of non-glycosylated carboxypeptidase Y was drastically reduced. A specific BiP/non-glycosylated carboxypeptidase Y complex was detected in kar2-159 and kar2-203 cells whereas the kar2-1 mutation did not result in such a complex. Our data show that BiP and N-linked glycosylation are directly involved in the processing of secreted proteins. The results support the hypothesis that BiP stabilizes the folding-competent and assembly-competent state of a polypeptide, whereas N-linked oligosaccharides are structural components required in the folding process after the polypeptide is released from BiP.

Genetic analysis of SecY: additional export-defective mutations and factors affecting their phenotypes

A number of secY mutants of Escherichia coli showing protein export defects were isolated by a combination of localized mutagenesis and secA-lacZ screening. Most of them were cold sensitive and contained single base substitutions in secY leading to amino acid replacements in various parts of the SecY protein, mainly in the cytoplasmic and the transmembrane domains. A temperature-sensitive mutant with an export defect had the same base substitution as secY24, which was characterized previously. Many cold-sensitive secY mutants exhibited rapid responses to temperature lowering but their apparent defects varied at the permissive temperature. Others exhibited delayed responses to the temperature shift. Some secY mutations, including secY39, interfered with protein export when expressed from a multicopy plasmid, even in the presence of wild-type secY on the chromosome. Such "dominant negative" mutations, including secY-d1, which was studied previously, were all located in either cytoplasmic domain 5 or 6, which is consistent with our previous proposal that the C-terminal region of SecY is important for its function as a protein translocator. We also studied the phenotypes of strains in which one of the secY mutations was combined with the components of the secD operon. Overexpression of secD partially suppressed the secY39 mutation, while overexpression of secF exacerbated the export defects of secY122 and secY125 mutations. Overexpression of "yajC", located within the secD operon, suppressed secY-d1. Although yajC itself proved to be dispensable, its disruption impaired the growth of the secY39 mutant at 42 degrees C. These observations suggest that SecY interacts with SecD, SecF, and the product of yajC.

The sequence of a 32,420 bp segment located on the right arm of chromosome II from Saccharomyces cerevisiae

The sequence of a 32,420 bp segment of Saccharomyces cerevisiae chromosome II has been deduced. The sequence data revealed 19 potential new genes covering 83.5% of the sequence. Four genes had already been cloned and sequenced: part of RIF1, DPB3, MRP-L27 and SNF5. Besides these four genes, 15 open reading frames (ORFs) of at least 100 amino acids encoding potential new genes were identified. Two of these ORFs are overlapping and a third is located within another ORF. The putative gene product of ORF YBR2039 was homologous to the group of uncoupling proteins involved in the mitochondrial energy transfer system. We propose a remapping of the MRP-L27 gene encoding the mitoribosomal protein YmL27 as it previously has been mapped on chromosome X. The ORF YBR2020 has a strong homology with a 31.9% identity in a 473 amino acid region to the yeast gene SEC61, suggesting that YBR2020 is a new gene encoding a protein involved in translocation of proteins in the yeast cell. Six of the potential genes do not exhibit any significant homology to previously sequenced genes as predicted in the Fast A analysis.

Residues essential for the function of SecE, a membrane component of the Escherichia coli secretion apparatus, are located in a conserved cytoplasmic region

Protein export in Escherichia coli is absolutely dependent on two integral membrane proteins, SecY and SecE. Previous deletion mutagenesis of the secE gene showed that only the third of three membrane-spanning segments and a portion of the second cytoplasmic region are necessary for its function in protein export. Here we further define the residues important for SecE function. Alignment of the SecE homologues of various eubacteria reveals that they all contain one membrane-spanning segment, compared with three in E. coli SecE, and that the most conserved region among them lies in their putative cytoplasmic amino termini; little homology exists in their membrane-spanning segments. The SecE homologue of the extreme thermophilic bacterium Thermotoga maritima was cloned and found to complement a deletion of secE in E. coli. Deletion or replacement of the cytoplasmic region of E. coli SecE eliminated SecE function, indicating that this sequence is essential for a functional secretion machinery. Mutant analysis suggests that the most important function of the third membrane-spanning segment is to maintain the proper topological arrangement of the conserved cytoplasmic domain.

The membrane proteins TRAMp and sec61 alpha p may be involved in post-translational transport of presecretory proteins into mammalian microsomes

The presecretory protein ppcecDHFR, a hybrid between preprocecropinA and dihydrofolate reductase, is transported into mammalian microsomes post-translationally, i.e. independent of ribosome and signal recognition particle. Here, the involvement of microsomal proteins in ribonucleoparticle-independent transport of ppcecDHFR was analyzed by transport into trypsin-pretreated microsomes and by transport of a truncated version of ppcecDHFR and subsequent chemical cross-linking. We observed that post-translational transport of ppcecDHFR can occur into microsomes which had been pretreated with trypsin (final concentration, 100 micrograms/ml) and that of the known transport components only TRAMp and sec61 alpha p are still present under these conditions. Furthermore, we found that the truncated ppcecDHFR, ppcecDHFR-98mer', can be cross-linked to 36 kDa microsomal membrane proteins during post-translational transport. Therefore, the two microsomal membrane proteins with molecular masses of about 36 kDa, TRAMp and sec61 alpha p, appear to be involved in the post-translational transport of ppcecDHFR and ppcecDHFR-98mer.

A stably folded presecretory protein associates with and upon unfolding translocates across the membrane of mammalian microsomes

The presecretory protein ppcecDHFR, a hybrid between preprocecropin A and dihydrofolate reductase, is transported into mammalian microsomes post-translationally, i.e. independently of ribosome and signal recognition particle. Upon staging the transport process, stably folded ppcecDHFR bound to mammalian microsomes and subsequently translocated across the membrane. Membrane association depended on the signal peptide but involved neither ATP nor an N-ethylmaleimide-sensitive microsomal protein. Membrane insertion of bound ppcecDHFR did not necessitate unfolding of the DHFR domain but depended on ATP and an N-ethylmaleimide-sensitive microsomal protein. Completion of translocation relied on unfolding of the DHFR domain. Thus mammalian microsomes have the capability of transporting a bound and folded precursor protein, i.e. to trigger unfolding of a precursor protein on the membrane surface.

Evolutionary conservation of components of the protein translocation complex

Protein translocation into the mammalian endoplasmic reticulum requires the Sec61p complex, which consists of three membrane proteins. The alpha-subunit, the homologue of Sec61p of yeast, shows some similarity to SecYp, a key component of the protein export apparatus of bacteria. In Escherichia coli, SecYp is also associated with two other proteins (SecEp and band-1 protein). We have now determined the sequences of the beta- and gamma-subunits of the mammalian Sec61p complex. Sec61-gamma is homologous to SSS1p, a suppressor of sec61 mutants in Saccharomyces cerevisiae, and can functionally replace it in yeast cells. Moreover, Sec61-gamma and SSS1p are structurally related to SecEp of E. coli and to putative homologues in various other bacteria. At least two subunits of the Sec61/SecYp complex therefore seem to be key components of the protein translocation apparatus in all classes of organisms.

Interaction of E. coli Ffh/4.5S ribonucleoprotein and FtsY mimics that of mammalian signal recognition particle and its receptor

The mechanism of protein translocation across the endoplasmic reticulum membrane of eukaryotic cells and the plasma membrane of prokaryotic cells are thought to be evolutionarily related. Protein targeting to the eukaryotic translocation apparatus is mediated by the signal recognition particle (SRP), a cytosolic ribonucleoprotein, and the SRP receptor, an endoplasmic reticulum membrane protein. During targeting, the 54K SRP subunit (M(r) 54,000; SRP54), a GTP-binding protein, binds to signal sequences and then interacts with the alpha-subunit of the SRP receptor (SR alpha), another GTP-binding protein. Two proteins from Escherichia coli, Ffh and FTsY, structurally resemble SRP54 and SR alpha. Like SRP54, Ffh is a subunit of a cytosolic ribonucleoprotein that also contains the E. coli 4.5S RNA. Although there is genetic and biochemical evidence that the E. coli Ffh/4.5S ribonucleoprotein has an SRP-like function, there is no evidence for an SR alpha-like role for FtsY. Here we show that the Ffh/4.5S ribonucleoprotein binds tightly to FtsY in a GTP-dependent manner. This interaction results in the stimulation of GTP hydrolysis which can be inhibited by synthetic signal peptides. These properties mimic those of mammalian SRP and its receptor, suggesting that the E. coli Ffh/4.5S ribonucleoprotein and FtsY have functions in protein targeting that are similar to those of their mammalian counterparts.

Subcellular localization of the Vif protein of human immunodeficiency virus type 1

The Vif (viral infectivity factor) protein of human immunodeficiency virus type 1 (HIV-1) has been shown to dramatically enhance the infectivity of HIV-1 virus particles during virus production. The subcellular localization of Vif was examined to elucidate cellular pathways which may be important for Vif function. Indirect immunofluorescence staining of Vif demonstrated a diffuse cytoplasmic distribution and showed that most Vif was not associated with the Golgi complex, a proposed site of localization (B. Guy, M. Geist, K. Dott, D. Spehner, M.-P. Kieny, and J.-P. Lecocq, J. Virol. 65:1325-1331, 1991). Subcellular fractionation of transfected COS cells and HIV-1-infected Jurkat and CEM cells demonstrated that Vif is a cytoplasmic protein which exists in both a soluble cytosolic form and membrane-associated form. The membrane-associated form of Vif is a peripheral membrane protein which is tightly associated with the cytoplasmic side of cellular membranes. The C terminus of Vif was required for the stable association of Vif with membranes. The C terminus was also essential for Vif function, suggesting that the association of Vif with membranes is likely to be important for its biological activity. The highly conserved regions at residues 103 to 115 and 142 to 150 were important for Vif function but did not affect membrane association, indicating that these regions are likely to be important for other, as-yet-unknown functions.

Bioenergetic aspects of the translocation of macromolecules across bacterial membranes

Bacteria are extremely versatile in the sense that they have gained the ability to transport all three major classes of biopolymers through their cell envelope: proteins, nucleic acids, and polysaccharides. These macromolecules are translocated across membranes in a large number of cellular processes by specific translocation systems. Members of the ABC (ATP binding cassette) superfamily of transport ATPases are involved in the translocation of all three classes of macromolecules, in addition to unique transport ATPases. An intriguing aspect of these transport processes is that the barrier function of the membrane is preserved despite the fact the dimensions of the translocated molecules by far surpasses the thickness of the membrane. This raises questions like: How are these polar compounds translocated across the hydrophobic interior of the membrane, through a proteinaceous pore or through the lipid phase; what drives these macromolecules across the membrane; which energy sources are used and how is unidirectionality achieved? It is generally believed that macromolecules are translocated in a more or less extended, most likely linear form. A recurring theme in the bioenergetics of these translocation reactions in bacteria is the joint involvement of free energy input in the form of ATP hydrolysis and via proton sym- or antiport, driven by a proton gradient. Important similarities in the bioenergetic mechanisms of the translocation of these biopolymers therefore may exist.

Mammalian and Escherichia coli signal recognition particles

Recent evidence from both biochemical and genetic studies indicates that protein targeting to the prokaryotic cytoplasmic membrane and the eukaryotic endoplasmic reticulum membrane may have more in common than previously thought. A ribonucleoprotein particle was identified in Escherichia coli that consists of at least one protein (P48 or Ffh) and one RNA molecule (4.5S RNA), both of which exhibit strong sequence similarity with constituents of the mammalian signal recognition particle (SRP). Like the mammalian SRP, the E. coli SRP binds specifically to the signal sequence of presecretory proteins. Depletion of either P48 or 4.5S RNA affects translation and results in the accumulation of precursors of several secreted proteins. This review discusses the recent studies and speculates on the position of the SRP in the complex network of protein interactions involved in translation and membrane targeting in E. coli.

GTP hydrolysis by complexes of the signal recognition particle and the signal recognition particle receptor

Translocation of proteins across the endoplasmic reticulum membrane is a GTP-dependent process. The signal recognition particle (SRP) and the SRP receptor both contain subunits with GTP binding domains. One GTP-dependent reaction during protein translocation is the SRP receptor-mediated dissociation of SRP from the signal sequence of a nascent polypeptide. Here, we have assayed the SRP and the SRP receptor for GTP binding and hydrolysis activities. GTP hydrolysis by SRP was not detected, so the maximal GTP hydrolysis rate for SRP was estimated to be < 0.002 mol GTP hydrolyzed x mol of SRP-1 x min-1. The intrinsic GTP hydrolysis activity of the SRP receptor ranged between 0.02 and 0.04 mol GTP hydrolyzed x mol of SRP receptor-1 x min-1. A 40-fold enhancement of GTP hydrolysis activity relative to that observed for the SRP receptor alone was obtained when complexes were formed between SRP and the SRP receptor. GTP hydrolysis activity was inhibited by GDP, but not by ATP. Extended incubation of the SRP or the SRP receptor with GTP resulted in substoichiometric quantities of protein-bound ribonucleotide. SRP-SRP receptor complexes engaged in GTP hydrolysis were found to contain a minimum of one bound guanine ribonucleotide per SRP-SRP receptor complex. We conclude that the GTP hydrolysis activity described here is indicative of one of the GTPase cycles that occur during protein translocation across the endoplasmic reticulum.

A protein translocation defect linked to ubiquitin conjugation at the endoplasmic reticulum

Ubiquitin-conjugating enzymes function in selective proteolysis pathways and catalyse the covalent attachment of ubiquitin to proteolytic substrates. Here we report the identification of an integral membrane ubiquitin-conjugating enzyme. This enzyme, UBC6, localizes to the endoplasmic reticulum (ER), with the catalytic domain facing the cytosol. ubc6 loss-of-function mutants suppress the protein translocation defect caused by a mutation in SEC61, which encodes a key component of a multisubunit protein translocation apparatus of the ER. The expression of the sec61 mutant phenotype requires both the activity of UBC6 and its localization at the ER membrane. This suggests that UBC6 may mediate selective degradation of ER membrane proteins and that the protein translocation defect of sec61 may be caused by proteolysis of components of a structurally distorted mutant translocation apparatus.

Ribosome-binding protein p34 is a member of the leucine-rich-repeat-protein superfamily

Protein p34 is a non-glycosylated membrane protein characteristic of rough microsomes and is believed to play a role in the ribosome-membrane association. In the present study we isolated cDNA encoding p34 from a rat liver cDNA library and determined its complete amino acid sequence. p34 mRNA is 3.2 kb long and encodes a polypeptide of 307 amino acids with a molecular mass of about 34.9 kDa. Primary sequence analysis, coupled with biochemical studies on the topology, suggested that p34 is a type II signal-anchor protein; it is composed of a large cytoplasmic domain, a membrane-spanning segment and a 38-amino-acid-long luminally disposed C-terminus. The cytoplasmic domain of p34 has several noteworthy structural features, including a region of 4.5 tandem repeats of 23-24 amino acids. The repeated motif shows structural similarity to the leucine-rich repeat which is found in a variety of proteins widely distributed among eukaryotic cells and which potentially functions in mediating protein-protein interactions. The cytoplasmic domain also contains a characteristic hydrophilic region with abundant charged amino acids. These structural regions may be important for the observed ribosome-binding activity of the p34 protein.

Suppression of a sec63 mutation identifies a novel component of the yeast endoplasmic reticulum translocation apparatus

Mutations in the SEC63 gene are associated with defects in protein translocation into the endoplasmic reticulum (ER) as well as in nuclear protein localization in Saccharomyces cerevisiae. To identify proteins that might interact and/or function with SEC63p, we cloned a high copy suppressor (HSS1) of the temperature-sensitive lethal phenotype of the sec63-101 mutant. HSS1 is an allele-specific sec63 suppressor that encodes an integral ER membrane glycoprotein of 206 amino acids with the N-terminus in the ER lumen and C-terminal region in the cytoplasm. Haploid strains disrupted for HSS1 are temperature-sensitive for growth and accumulate precursor forms of Kar2p and invertase. The HSS1 null allele is synthetically lethal in combination with mutations affecting ER translocation. We propose that HSS1p is important for ER translocation and interacts with previously identified components of the yeast translocation apparatus. HSS1 is identical to SEC66, which encodes a glycoprotein complexed with SEC62p and SEC63p.

DIDS (4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid) inhibits an early step of protein translocation across the mammalian ER membrane

Protein translocation across the endoplasmic reticulum (ER) membrane of yeast can be inhibited by agents believed to specifically affect the transport of ATP through the membrane (Mayinger, P. and Meyer, D.I. (1993) EMBO J. 12, 659-666), suggesting the involvement of a translocation component in the lumen of the ER that binds ATP. We demonstrate that one of the inhibitors, 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), also affects the translocation of proteins into mammalian microsomes. Translocation is blocked at the point of transfer of the nascent chain from the signal recognition particle (SRP) into the ER-membrane. We also confirm that photoaffinity-labelling of microsomes with 8-azido-ATP inhibits the same early step of protein translocation. Since this step is reported to not require ATP, these results raise the possibility that, in both cases, factor(s) other than ATP-binding components of the translocation machinery are perturbed.

Protein import into mitochondria: a paradigm for the translocation of polypeptides across membranes

The translocation of proteins across membranes usually requires specific transport systems composed of membrane-bound and soluble components. A combination of biochemical and genetic approaches has led to the identification and preliminary characterization of some of these components.

Translocation of proteins across the endoplasmic reticulum

The past year has seen significant advances in the field of protein translocation: the roles of the signal recognition particle and its receptor have been understood in greater detail; many membrane components responsible for translocation have been identified; and insight has been gained into how proteins cross membranes.

Anti-(p34 protein) antibodies inhibit ribosome binding to and protein translocation across the rough microsomal membrane

The p34 protein is a non-glycosylated, integral membrane protein characteristic of rough microsomes and is believed to play a role in the ribosome-membrane association. Here, antibodies directed against p34 were examined as to their inhibitory effect on ribosome binding to and protein translocation across the microsomal membrane. Preincubation of the stripped (ribosome-depleted) membrane with anti-p34 immunoglobulins (IgGs) or their Fab fragments led to more than 80% inhibition of the binding of ribosomes and their large (60S) subunit to the membrane. The inhibition was dependent on the amount of antibodies used, but comparable amounts of IgGs and Fab fragments from nonimmune serum had less effect. The p34 antibodies were also inhibitory for cotranslational translocation of secretory proteins, i.e. placental lactogen and serum albumin, across the membrane. These results suggest that p34 is involved in the binding of ribosomes to the microsomal membrane and that it is in close proximity to the protein translocation site in the microsomal membrane.

The signal sequence moves through a ribosomal tunnel into a noncytoplasmic aqueous environment at the ER membrane early in translocation

The signal sequence is in an aqueous milieu at an early stage in the translocation of a nascent secretory protein across the endoplasmic reticulum membrane. This was determined using fluorescent probes incorporated into the signal sequence of fully assembled ribosome-nascent chain-membrane complexes: the fluorescence lifetimes revealed that the probes were in an aqueous environment rather than buried in the nonpolar core of the membrane. Since these membrane-bound probes were not susceptible to collisional quenching by iodide ions, the space containing the signal sequence is sealed off from the cytoplasm by a tight ribosome-membrane junction. The nascent chain inside the ribosome is also not exposed to the cytoplasm and apparently passes through an aqueous tunnel in the ribosome.

A tetrameric complex of membrane proteins in the endoplasmic reticulum

The translocation site (translocon), at which nascent polypeptides pass through the endoplasmic reticulum membrane, contains a component previously called 'signal sequence receptor' that is now renamed as 'translocon-associated protein' (TRAP). Two glycosylated subunits of the TRAP complex have been identified before (alpha and beta subunits). We now show that TRAP complex is actually comprised of four membrane proteins (alpha, beta, gamma, delta), present in a stoichiometric relation, which are genuine neighbours in intact microsomes. The amino acid sequences of the additional, non-glycosylated subunits were deduced from cloning of the corresponding cDNAs. The delta subunit spans the membrane only once and has its major portion, containing a disulfide bridge, at the lumenal side. The gamma subunit is predicted to span the membrane four times.

Temperature-sensitive sporulation caused by a mutation in the Bacillus subtilis secY gene

A thermosensitive sporulation mutant of Bacillus subtilis containing a mutation in the secY gene was isolated and characterized. No asymmetric septum specific to the sporulation was detected by electron microscopy at the nonpermissive temperature, indicating that the block occurred at a very early stage of sporulation. Furthermore, competence development in the mutant cell was affected even at the sporulation-proficient temperature. It is assumed that the SecY protein of B. subtilis has multiple roles both in the regulation of spore formation and in stationary-phase-associated phenomena.

Natural resistance to infection with intracellular parasites: isolation of a candidate for Bcg

Natural resistance to infection with intracellular parasites is controlled by a dominant gene on mouse chromosome 1, called Bcg, Lsh, or Ity. Bcg affects the capacity of macrophages to destroy ingested intracellular parasites early during infection. We have assembled a 400 kb bacteriophage and cosmid contig within the genomic interval containing Bcg. A search for transcription units by exon amplification identified six novel genes in this contig. RNA expression studies showed that one of them, designated Nramp, was expressed exclusively in macrophage populations from reticuloendothelial organs and in the macrophage line J774A. Nramp encodes an integral membrane protein that has structural homology with known prokaryotic and eukaryotic transport systems, suggesting a macrophage-specific membrane transport function. Susceptibility to infection (Bcgs) in 13 Bcgr and Bcgs strains tested is associated with a nonconservative Gly-105 to Asp-105 substitution within predicted transmembrane domain 2 of Nramp.

Sec61p is adjacent to nascent type I and type II signal-anchor proteins during their membrane insertion

We have identified membrane components which are adjacent to type I and type II signal-anchor proteins during their insertion into the membrane of the ER. Using two different cross-linking approaches a 37-38-kD nonglycosylated protein, previously identified as P37 (High, S., D. Görlich, M. Wiedmann, T. A. Rapoport, and B. Dobberstein. 1991. J. Cell Biol. 113:35-44), was found adjacent to all the membrane inserted nascent chains used in this study. On the basis of immunoprecipitation, this ER protein was shown to be identical to the recently identified mammalian Sec61 protein. Thus, Sec61p is the principal cross-linking partner of both type I and type II signal-anchor proteins during their membrane insertion (this work), and of secretory proteins during their translocation (Görlich, D., S. Prehn, E. Hartmann, K.-U. Kalies, and T. A. Rapoport. 1992. Cell. 71:489-503). We propose that membrane proteins of both orientations, and secretory proteins employ the same ER translocation sites, and that Sec61p is a core component of these sites.

Changes in levels of pancreatic endoplasmic reticulum proteins that function in translocation and maturation of secretory proteins in response to cholecystokinin

Two pathways operate to target newly-synthesised proteins to the endoplasmic reticulum. In one, the signal recognition particle attaches to the signal sequences of nascent chains on ribosomes and slows or stops translation until contact is made with the docking protein at the membrane. The second operates via molecular chaperons. The pathways converge at the level of a 43 kDa signal binding protein integrated into the membrane, where translocation through a proteinaceous pore is initiated. In the lumen, proteins fold and disulphide formation is catalysed by the enzyme protein disulphide isomerase. The heavy chain binding protein may attach to unassembled or unfolded proteins and prevent their exit from the ER to the Golgi. Cholecystokinin (CCK) treatment increases the biosynthesis and secretion of pancreatic proteins, increases the levels of PDI and the 43 kDa binding protein, and reduces levels of BiP. These proteins may be possible targets for genetic manipulation to improve processing of heterologous proteins from cultured mammalian cells.

Transport of proteins across the endoplasmic reticulum membrane

The biosynthesis of many eukaryotic proteins requires their transport across the endoplasmic reticulum (ER) membrane. The process can be divided into two phases: (i) a targeting cycle, during which, by virtue of their signal sequences, nascent polypeptides are directed to translocation sites in the ER and (ii) the actual transfer of proteins across the membrane. The first phase has been well characterized, whereas the latter until recently was completely unresolved. Key components of the translocation apparatus have now been identified and it seems likely that they form a protein-conducting channel in the ER membrane. The transport process is similar to the process of protein export in bacteria.