New variation on the translocation of proteins during early biogenesis of apolipoprotein B

Apolipoprotein B (apo B) is crucial for the transport of cholesterol in humans. It is a large secretory protein that mediates the uptake of low-density lipoproteins and renders several forms of lipid droplets soluble in the blood. The binding of lipid by apo B also prevents this hydrophobic protein from precipitating in aqueous solution. In the endoplasmic reticulum, nascent secretory proteins must be translocated through an aqueous channel in the membrane into the aqueous lumen, so some novel form of processing may be necessary to maintain the solubility of apo B during its translocation. We have discovered that the biogenesis of apo B in cell-free systems does indeed involve a new variation on protein translocation: unlike typical secretory proteins, apo B is synthesized as a series of transmembrane chains with large cytoplasmic domains and progressively longer amino-terminal regions that are protected against added proteases during the translocation process. In contrast to typical transmembrane proteins, these transmembrane chains are not integrated into the bilayer. Moreover, the transmembrane chains with the shortest protected domains are precursors of forms whose protection is progressively extended to cover the length of the protein. This stepwise conversion occurs post-translationally for the most part. We propose a model on the basis of these findings for the biogenesis of apo B.     

Xenopus oocytes can secrete bacterial beta-lactamase

Most secretory proteins are synthesized as precursor polypeptides carrying N-terminal, hydrophobic sequences which, by means of a signal recognition particle (SRP), trigger the membrane transfer of the polypeptide and are subsequently cleaved off. The signal sequences appear to be interchangeable between prokaryotes and eukaryotes. In bacteria, secretion only involves the crossing of a membrane, whereas in eukaryotes the secretory process can be separated into two distinct phases: translocation across the membrane of the rough endoplasmic reticulum and subsequent intraluminal transport by processes involving vesicle budding and fusion. Since secretory proteins must be distinguished from other soluble proteins destined for various sites in the reticular system, it is conceivable that eukaryotic secretory proteins possess additional markers distinct from the signal peptide to guide the polypeptide after its transfer through the membrane. Proteins are secreted at different rates from a eukaryotic cell, suggesting a role in intracellular transport for receptors with differing affinities for some topogenic features in secretory proteins. We have tested this possibility by introducing into the lumen of eukaryotic rough endoplasmic reticulum a prokaryotic protein which, by virtue of its origin, had not been adapted to the eukaryotic secretory pathway. We reasoned that secretion of the bacterial protein would indicate that after membrane transfer no topogenic signal(s) and corresponding recognition system(s) are required. We report here that this is indeed the case.     

A substrate-specific inhibitor of protein translocation into the endoplasmic reticulum

The segregation of secretory and membrane proteins to the mammalian endoplasmic reticulum is mediated by remarkably diverse signal sequences that have little or no homology with each other. Despite such sequence diversity, these signals are all recognized and interpreted by a highly conserved protein-conducting channel composed of the Sec61 complex. Signal recognition by Sec61 is essential for productive insertion of the nascent polypeptide into the translocation site, channel gating and initiation of transport. Although subtle differences in these steps can be detected between different substrates, it is not known whether they can be exploited to modulate protein translocation selectively. Here we describe cotransin, a small molecule that inhibits protein translocation into the endoplasmic reticulum. Cotransin acts in a signal-sequence-discriminatory manner to prevent the stable insertion of select nascent chains into the Sec61 translocation channel. Thus, the range of substrates accommodated by the channel can be specifically and reversibly modulated by a cell-permeable small molecule that alters the interaction between signal sequences and the Sec61 complex.     

YidC mediates membrane protein insertion in bacteria

The basic machinery for the translocation of proteins into or across membranes is remarkably conserved from Escherichia coli to humans. In eukaryotes, proteins are inserted into the endoplasmic reticulum using the signal recognition particle (SRP) and the SRP receptor, as well as the integral membrane Sec61 trimeric complex (composed of alpha, beta and gamma subunits). In bacteria, most proteins are inserted by a related pathway that includes the SRP homologue Ffh, the SRP receptor FtsY, and the SecYEG trimeric complex, where Y and E are related to the Sec61 alpha and gamma subunits, respectively. Proteins in bacteria that exhibit no dependence on the Sec translocase were previously thought to insert into the membrane directly without the aid of a protein machinery. Here we show that membrane insertion of two Sec-independent proteins requires YidC. YidC is essential for E. coli viability and homologues are present in mitochondria and chloroplasts. Depletion of YidC also interferes with insertion of Sec-dependent membrane proteins, but it has only a minor effect on the export of secretory proteins. These results provide evidence for an additional component of the translocation machinery that is specialized for the integration of membrane proteins.     

The signal sequence of nascent preprolactin interacts with the 54K polypeptide of the signal recognition particle

Hydrophobic signal sequences direct the translocation of nascent secretory proteins and many membrane proteins across the membrane of the endoplasmic reticulum. Initiation of this process involves the signal recognition particle (SRP), which consists of six polypeptide chains and a 7S RNA and interacts with ribosomes carrying nascent secretory polypeptide chains. In the case of aminoterminal, cleavable signal sequences, in the absence of microsomal membranes it exerts a site-specific translational arrest in vitro. The size of the arrested fragment (60-70 amino-acid residues) suggests that elongation stops when the signal sequence has emerged fully from the ribosome. However, a direct interaction between the signal sequence and SRP has not previously been demonstrated and has even been questioned recently. We now show for the first time a direct interaction between the signal sequence of a secretory protein and a component of SRP, the 45K polypeptide (relative molecular mass (Mr) 54,000). This was achieved by means of a new method of affinity labelling which involves the translational incorporation of an amino acid, carrying a photoreactive group, into nascent polypeptides.     

A role for the two-helix finger of the SecA ATPase in protein translocation

An important step in the biosynthesis of many proteins is their partial or complete translocation across the plasma membrane in prokaryotes or the endoplasmic reticulum membrane in eukaryotes. In bacteria, secretory proteins are generally translocated after completion of their synthesis by the interaction of the cytoplasmic ATPase SecA and a protein-conducting channel formed by the SecY complex. How SecA moves substrates through the SecY channel is unclear. However, a recent structure of a SecA-SecY complex raises the possibility that the polypeptide chain is moved by a two-helix finger domain of SecA that is inserted into the cytoplasmic opening of the SecY channel. Here we have used disulphide-bridge crosslinking to show that the loop at the tip of the two-helix finger of Escherichia coli SecA interacts with a polypeptide chain right at the entrance into the SecY pore. Mutagenesis demonstrates that a tyrosine in the loop is particularly important for translocation, but can be replaced by some other bulky, hydrophobic residues. We propose that the two-helix finger of SecA moves a polypeptide chain into the SecY channel with the tyrosine providing the major contact with the substrate, a mechanism analogous to that suggested for hexameric, protein-translocating ATPases.     

Control of transmembrane lipid asymmetry in chromaffin granules by an ATP-dependent protein

The Ca2+-dependent binding of annexin proteins to secretory granule membranes seems to be involved in the early stage of exocytosis. Binding studies have shown that these proteins have a specificity for phosphatidylserine (PtdS) interfaces. Furthermore, aminolipids are necessary for contact and fusion between lipid vesicles or between liposomes and chromaffin granules. Thus, PtdS must be present on the granule outer (cytoplasmic) monolayer. We report here that chromaffin granules possess a mechanism to maintain PtdS orientation, comparable to the ATP-dependent aminophospholipid translocase from human erythrocytes. The translocase, in granules, selectively transports PtdS from the luminal to the cytoplasmic monolayer, provided the incubation medium contains ATP. As this protein shares several properties with the granule vanadate-sensitive ATPase II, we infer that this ATPase, of relative molecular mass 115,000, is the protein responsible for aminophospholipid translocation. This is the first evidence for an ATP-dependent specific phospholipid 'flippase' in intracellular organelles.     

The S. cerevisiae SEC65 gene encodes a component of yeast signal recognition particle with homology to human SRP19.

Translocation of proteins across the endoplasmic reticulum (ER) membrane represents the first step in the eukaryotic secretory pathway. In mammalian cells, the targeting of secretory and membrane protein precursors to the ER is mediated by signal recognition particle (SRP), a cytosolic ribonucleoprotein complex comprising a molecule of 7SL RNA and six polypeptide subunits (relative molecular masses 9, 14, 19, 54, 68 and 72K). In Saccharomyces cerevisiae, a homologue of the 54K subunit (SRP54) co-purifies with a small cytoplasmic RNA, scR1 (refs 4, 5). Genetic data indicate that SRP54 and scR1 are involved in translocation in vivo, suggesting the existence of an SRP-like activity in yeast. Whether this activity requires additional components similar to those found in mammalian SRP is not known. We have recently reported a genetic selection that led to the isolation of a yeast mutant, sec65-1, which is conditionally defective in the insertion of integral membrane proteins into the ER. Here we report the cloning and sequencing of the SEC65 gene, which encodes a 31.2K protein with significant sequence similarity to the 19K subunit of human SRP (SRP19). We also report the cloning of a multicopy suppressor of sec65-1, and its identification as the previously defined SRP54 gene, providing genetic evidence for an interaction between these gene products in vivo.     

Post-translational insertion of a fragment of the glucose transporter into microsomes requires phosphoanhydride bond cleavage

Most eukaryotic secretory and membrane proteins insert co-translationally into the membrane of the rough endoplasmic reticulum (RER), and are targeted there by one or more NH2-terminal or internal signal sequences. However, little is known about the actual translocation and membrane integration processes. In particular, any energy requirements for targeting and integration have remained obscure because of the inability to uncouple the processes from concomitant protein synthesis. We recently showed that the human glucose transporter (GT), an integral membrane glycoprotein, can insert post-translationally into dog pancreatic microsomes with low but demonstrable efficiency in vitro, and that a fragment corresponding to the NH2-terminal 340 amino acids and 8 of the 12 membrane-spanning alpha-helixes of GT (GT-N) can insert with significantly greater efficiency. We report here that post-translational insertion of GT-N into pancreatic microsomes requires energy in the form of a phosphodiester bond, and suggest that co-translational insertion of proteins into the RER may also require energy independent of that used for polypeptide synthesis.     

Golgi maturation visualized in living yeast

The Golgi apparatus is composed of biochemically distinct early (cis, medial) and late (trans, TGN) cisternae. There is debate about the nature of these cisternae. The stable compartments model predicts that each cisterna is a long-lived structure that retains a characteristic set of Golgi-resident proteins. In this view, secretory cargo proteins are transported by vesicles from one cisterna to the next. The cisternal maturation model predicts that each cisterna is a transient structure that matures from early to late by acquiring and then losing specific Golgi-resident proteins. In this view, secretory cargo proteins traverse the Golgi by remaining within the maturing cisternae. Various observations have been interpreted as supporting one or the other mechanism. Here we provide a direct test of the two models using three-dimensional time-lapse fluorescence microscopy of the yeast Saccharomyces cerevisiae. This approach reveals that individual cisternae mature, and do so at a consistent rate. In parallel, we used pulse-chase analysis to measure the transport of two secretory cargo proteins. The rate of cisternal maturation matches the rate of protein transport through the secretory pathway, suggesting that cisternal maturation can account for the kinetics of secretory traffic.     

Re-routing of a secretory protein by fusion with human growth hormone sequences

Cells with electron-dense secretory vesicles use them to store only specialized secretory products such as peptide hormones; other types of secreted proteins are externalized by an alternative, constitutive route. One possible mechanism for such segregation is that proteins destined for dense secretory vesicles contain unique 'sorting domains' that allow for selective targeting. Here, we set out to determine whether a constitutively secreted protein could be diverted to the dense secretory vesicles by attachment to a peptide hormone sequence. We made use of the ability of the mouse pituitary tumour cell, AtT-20, to correctly sort exogenous secretory proteins introduced into them by DNA transfection. We constructed a plasmid encoding a hybrid protein in which a constitutively secreted viral protein was fused to the carboxy terminus of human growth hormone (hGH). Cells expressing the hybrid protein were found to target it to dense secretory vesicles with an efficiency close to that observed for the parental hGH. These results support the hypothesis that sorting domains on peptide hormones direct their packaging into dense secretory vesicles. The results also suggest that proteins secreted by the constitutive pathway either do not contain any sorting domain, or their sorting signals can be overridden by those which direct peptide hormones.     

Structure and function of a membrane component SecDF that enhances protein export

Protein translocation across the bacterial membrane, mediated by the secretory translocon SecYEG and the SecA ATPase, is enhanced by proton motive force and membrane-integrated SecDF, which associates with SecYEG. The role of SecDF has remained unclear, although it is proposed to function in later stages of translocation as well as in membrane protein biogenesis. Here, we determined the crystal structure of Thermus thermophilus SecDF at 3.3?? resolution, revealing a pseudo-symmetrical, 12-helix transmembrane domain belonging to the RND superfamily and two major periplasmic domains, P1 and P4. Higher-resolution analysis of the periplasmic domains suggested that P1, which binds an unfolded protein, undergoes functionally important conformational changes. In vitro analyses identified an ATP-independent step of protein translocation that requires both SecDF and proton motive force. Electrophysiological analyses revealed that SecDF conducts protons in a manner dependent on pH and the presence of an unfolded protein, with conserved Asp and Arg residues at the transmembrane interface between SecD and SecF playing essential roles in the movements of protons and preproteins. Therefore, we propose that SecDF functions as a membrane-integrated chaperone, powered by proton motive force, to achieve ATP-independent protein translocation.     

70K heat shock related proteins stimulate protein translocation into microsomes

A yeast cytosol is shown to contain two distinct activities that stimulate protein translocation across microsomal membranes. One activity was purified. It consists of two constitutively expressed 70K heat shock related proteins that increase the rate of translocation. Possible mechanisms of action of these proteins are discussed.     

Exposure of an antigen of chromaffin granules on cell surface during exocytosis

The synthesis rate of the membrane proteins of the catecholamine-storing vesicles (chromaffin granules) of the adrenal medulla is lower than that of the secretory proteins of the contents. Based on these results we proposed that after exocytosis the membranes of chromaffin granules are retrieved and are re-used for several secretion cycles (see also ref. 4). This concept of re-use of granule membranes has been further strengthened by the finding that exogenous markers which are taken up by secretory cells during stimulation can be traced to the Golgi region and to immature secretory organelles. However, one basic question remains: are the membranes of secretory organelles specifically and completely removed from the plasma membrane and if so, how fast is this process? By using an antiserum against a membrane glycoprotein of chromaffin granules we have now obtained quantitative data which demonstrate that during exocytosis this antigen becomes exposed on the cell surface and disappears again to a large degree within 30 min.     

Evidence for the involvement of ATP in co-translational protein translocation

Identification of the source of energy for protein translocation across biological membranes is important in understanding the mechanism of this process. In eukaryotic cells, the tight coupling between translation and translocation and firm attachment of the secreting ribosomes to membranes, as well as theoretical calculations, have led to the suggestion that energy derived from protein synthesis is sufficient for protein translocation. On the other hand, in bacterial systems neither the attachment of ribosomes to membrane (other than nascent chains) nor tight coupling of translocation to translocation has been observed. Moreover, certain proteins can be translocated across membranes either at the time of, or after, translation. The separation of protein translocation from translation has made possible the demonstration that ATP hydrolysis is essential for post-translational protein translocation across bacterial membranes and, more recently, also across canine and yeast endoplasmic reticulum membranes. Here we report that certain ATP analogues inhibit co-translational protein translocation at concentrations that do not interfere with protein synthesis, suggesting that ATP is also required for co-translational protein translocation.     

Assembly of yeast Sec proteins involved in translocation into the endoplasmic reticulum into a membrane-bound multisubunit complex

Secretory-protein translocation into the endoplasmic reticulum (ER) is thought to be catalysed by integral membrane proteins. Genetic selections uncovered three Saccharomyces cerevisiae genes (SEC61, SEC62 and SEC63), mutations in which block import of precursor proteins into the ER lumen in vivo and in vitro. The DNA sequences of SEC62 and SEC63 predict multispanning membrane proteins, and biochemical characterization of the SEC62 protein (Sec62) confirms that it is an integral ER membrane protein. Here we show that Sec61, Sec62 and Sec63 are assembled with two additional proteins into a multisubunit membrane-associated complex. These results confirm previous predictions, based upon genetic interactions between the SEC genes, that Sec61, Sec62 and Sec63 act together to facilitate protein translocation into the ER.     

Phosphatidylglycerol is involved in protein translocation across Escherichia coli inner membranes

Newly synthesized proteins to be exported out of the cytoplasm of bacterial cells have to pass across the inner membrane. In Gram-negative bacteria ATP, a membrane potential, the products of the sec genes and leader peptidases (enzymes which cleave the N-terminal signal peptides of the precursor proteins) are required. The mechanism of translocation, however, remains elusive. Important additional roles for membrane lipids have been repeatedly suggested both on theoretical grounds and on the basis of experiments with model systems but no direct evidence had been obtained. We demonstrate here, using mutants of Escherichia coli defective in the synthesis of the major anionic membrane phospholipids, that phosphatidylglycerol is involved in the translocation of newly synthesized outer-membrane proteins across the inner membrane.     

Requirement for GTP hydrolysis in the formation of secretory vesicles

The specificity of vesicular transport in a cell is determined by the formation of vesicles with specific contents from a donor compartment and their selective fusion with the appropriate acceptor compartment. Several of the latter fusion steps have been investigated in detail using cell-free systems, and work with these systems as well as genetic evidence has revealed a role for GTP-binding proteins in membrane fusion processes. We have reconstituted the formation of constitutive secretory vesicles and immature secretory granules from the trans Golgi network in a cell-free system. We show here that the budding of both types of post-Golgi vesicles is inhibited by non-hydrolysable analogues of GTP, which suggests a more widespread role for GTP-binding proteins in membrane traffic than previously assumed.