An artificial transmembrane segment directs SecA, SecB, and electrochemical potential-dependent translocation of a long amino-terminal tail

Many integral membrane proteins contain an amino-terminal segment, often referred to as an N-tail, that is translocated across a membrane. In many cases, translocation of the N-tail is initiated by a cleavable, amino-terminal signal peptide. For N-tail proteins lacking a signal peptide, translocation is initiated by a transmembrane segment that is carboxyl to the translocated segment. The mechanism of membrane translocation of these segments, although poorly understood, has been reported to be independent of the protein secretion machinery. In contrast, here we describe alkaline phosphatase mutants containing artificial transmembrane segments that demonstrate that translocation of a long N-tail across the membrane is dependent upon SecA, SecB, and the electrochemical potential in the absence of a signal peptide. The corresponding mutants containing signal peptides also use the secretion machinery but are less sensitive to inhibition of its components. We present evidence that inhibition of SecA by sodium azide is incomplete even at high concentrations of inhibitor, which suggests why SecA-dependent translocation may not have been detected in other systems. Furthermore, by varying the charge around the transmembrane segment, we find that in the absence of a signal peptide, the orientation of the membrane-bound alkaline phosphatase is dictated by the positive inside rule. However, the presence of a signal peptide is an overriding factor in membrane orientation and renders all mutants in an Nout-Cin orientation.     

A part of the transmembrane domain of pro-TNF can function as a cleavable signal sequence that generates a biologically active secretory form of TNF.

To determine the minimum requirement in the 76-residue leader sequence of pro-tumor necrosis factor (TNF) for membrane translocation across the endoplasmic reticulum (ER) and for the maturation of pro-TNF, we constructed pro-TNF mutants in which a part of the transmembrane domain of pro-TNF was directly linked to the N-terminus of the mature domain, and evaluated their translocational behavior across the ER-membrane and their secretion from the transfected cells. The in vitro translation/translocation assay involving a canine pancreatic microsomal membrane system including a mutant, Delta-75-47, -32-1, revealed that the N-terminal half of the transmembrane domain of pro-TNF consisting of 14 residues functioned as a cleavable signal sequence; it generated a cleaved form of TNF having a molecular mass similar to that of mature TNF. Analysis of the cleavage site by site-directed mutagenesis indicated that the site was inside the leader sequence of this mutant. When the mutant, Delta-75-47, -32-1, was expressed in COS-1 cells, efficient secretion of a biologically active soluble TNF was observed. Further deletion of the hydrophobic domain from this mutant inhibited the translocation, indicating that some extent of hydrophobicity is indispensable for the membrane translocation of the mature domain of TNF. Thus, the N-terminal half of the transmembrane domain of pro-TNF could function as a cleavable signal sequence when linked to the mature domain of TNF, and secretion of a biologically active secretory form of TNF could be achieved with this 14-residue hydrophobic segment. In intact pro-TNF, however, this 14-residue sequence could not function as a cleavable signal sequence during intracellular processing, indicating that the remainder of the 76-residue leader sequence of pro-TNF inhibits the signal peptide cleavage and thus enables the leader sequence to function as a type II signal-anchor sequence that generates a transmembrane form of TNF.     

Insertion of a signal peptide-derived hydrophobic segment into the mature domain of OmpC, an outer membrane protein, does not interfere with the export of the following polypeptide chain across the cytoplasmic membrane of E. coli

The effects of a hydrophobic peptide segment inserted into the amino-terminal region of the mature domain of OmpC, an outer membrane protein, on its translocation across the cytoplasmic membrane was studied. Both the intact OmpC and central domain-deleted OmpC were examined. The hydrophobic segment was derived from the signal peptide of OmpF. Secretory translocation across the cytoplasmic membrane was examined by means of proteinase K treatment. Four monoclonal antibodies that recognize different regions of OmpC were used to characterize proteinase K-resistant fragments. Insertion of the hydrophobic segment did not appreciably prevent the translocation of these proteins across the cytoplasmic membrane, larger parts of them being found as mature forms, which were mostly localized outside the cytoplasmic membrane. Circumstantial evidence supports the view, on the other hand, that the inserted hydrophobic domain was retained in the cytoplasmic membrane. It is concluded, therefore, that the hydrophobic segment, although it is not exported across the cytoplasmic membrane, does not prevent the secretion of the following polypeptide chain. The secretion was dependent on the amino-terminal signal peptide. Insertion of positive charges immediately after the hydrophobic segment resulted in suppression of the translocation. Based on these results possible mechanisms by which the secretion of the polypeptide chain after the hydrophobic segment are discussed.     

A functional interaction between the signal peptide and the translation apparatus is detected by the use of a single point mutation which blocks translocation across mammalian endoplasmic reticulum

A functional interaction between the signal sequence and the translation apparatus which may serve as a first step in chain targeting to the membrane is described. To this end, we exploited the powerful technique of molecular cloning in a procaryotic system and the well characterized translocation system of mammalian endoplasmic reticulum. The signal peptide of subunit B of the heat labile enterotoxin of Escherichia coli (EltB) was fused to several proteins. Single base substitutions were introduced in the signal peptide and their effect on protein synthesis and translocation was studied. We sought a single amino acid substitution which may define certain steps in the coordinated regulation of chain synthesis and targeting to the membrane. The substitution of proline for leucine at residue -8 in the signal peptide abolished all known functions of the signal peptide. In contrast to wild type signal peptide, the mutant signal peptide did not lead to arrest of nascent chain synthesis by signal recognition particle or translocation of the precursor protein across the membrane of the endoplasmic reticulum. Furthermore, the mutant signal peptide was not cleaved by purified E. coli signal peptidase. Interestingly, the mutation resulted in about a 2-fold increase in the rate of synthesis of the precursor protein, suggesting a role for the signal peptide in regulating the synthesis of the nascent secretory chain as a means of ensuring early and efficient targeting of this chain to the membrane. This role might involve interaction of the signal peptide with components of the translation apparatus and/or endogenous signal recognition particle. These results were obtained with three different fusion proteins carrying the signal peptide of EltB thus leading to the conclusion that the effect of the mutation on the structure and function of the signal peptide is independent of the succeeding sequence to which the signal peptide is attached.     

NHE6 protein possesses a signal peptide destined for endoplasmic reticulum membrane and localizes in secretory organelles of the cell

The NHE6 protein is a unique Na(+)/H(+) exchanger isoform believed to localize in mitochondria. It possesses a hydrophilic N-terminal portion that is rich in positively charged residues and many hydrophobic segments. In the present study, signal sequences in the NHE6 molecule were examined for organelle localization and membrane topogenesis. When the full-length protein was expressed in COS7 cells, it localized in the endoplasmic reticulum and on the cell surface. Furthermore, the protein was fully N-glycosylated. When green fluorescent protein was fused after the second (H2) or third (H3) hydrophobic segment, the fusion proteins were targeted to the endoplasmic reticulum (ER) membrane. The localization pattern was the same as that of fusion proteins in which green fluorescent protein was fused after H2 of NHE1. In an in vitro system, H1 behaved as a signal peptide that directs the translocation of the following polypeptide chain and is then processed off. The next hydrophobic segment (H2) halted translocation and eventually became a transmembrane segment. The N-terminal hydrophobic segment (H1) of NHE1 also behaved as a signal peptide. Cell fractionation studies using antibodies against the 15 C-terminal residues indicated that NHE6 protein localized in the microsomal membranes of rat liver cells. All of the NHE6 molecules in liver tissue possess an endoglycosidase H-resistant sugar chain. These findings indicate that NHE6 protein is targeted to the ER membrane via the N-terminal signal peptide and is sorted to organelle membranes derived from the ER membrane.     

SecY, a multispanning integral membrane protein, contains a potential leader peptidase cleavage site.

SecY is an Escherichia coli integral membrane protein required for efficient translocation of other proteins across the cytoplasmic membrane; it is embedded in this membrane by the 10 transmembrane segments. Among several SecY-alkaline phosphatase (PhoA) fusion proteins that we constructed previously, SecY-PhoA fusion 3-3, in which PhoA is fused to the third periplasmic region of SecY just after the fifth transmembrane segment, was found to be subject to rapid proteolytic processing in vivo. Both the SecY and PhoA products of this cleavage have been identified immunologically. In contrast, cleavage of SecY-PhoA 3-3 was barely observed in a lep mutant with a temperature-sensitive leader peptidase. The full-length fusion protein accumulated in this mutant was cleaved in vitro by the purified leader peptidase. A sequence Ala-202-Ile-Ala located near the proposed interface between transmembrane segment 5 and periplasmic domain 3 of SecY was found to be responsible for the recognition and cleavage by the leader peptidase, since a mutated fusion protein with Phe-Ile-Phe at this position was no longer cleaved even in the wild-type cells. These results indicate that SecY contains a potential leader peptidase cleavage site that undergoes cleavage if the PhoA sequence is attached carboxy terminally. Thus, transmembrane segment 5 of SecY can fulfill both of the two important functions of the signal peptide, translocation and cleavage, although the latter function is cryptic in the normal SecY protein.     

N-tail translocation in a eukaryotic polytopic membrane protein: synergy between neighboring transmembrane segments.

We have used the natural N-glycosylation site in the N-tail of cig30, a eukaryotic polytopic membrane protein, as a marker for N-tail translocation across the microsomal membrane. Analysis of C-terminally truncated cig30 constructs reveals that the first transmembrane segment is sufficient for translocation of the wild-type N-tail; in contrast, in a mutant with four arginines introduced into the N-tail the second transmembrane segment is also required for efficient N-tail translocation. Our observations imply a non-sequential assembly mechanism in which the ultimate location of the N-tail relative to the membrane may depend on more than one transmembrane segment.     

The signal peptide of the G protein-coupled human endothelin B receptor is necessary for translocation of the N-terminal tail across the endoplasmic reticulum membrane

The initial step of the intracellular transport of G protein-coupled receptors, their insertion into the membrane of the endoplasmic reticulum, follows one of two different pathways. Whereas one group uses the first transmembrane domain of the mature receptor as an uncleaved signal anchor sequence for this process, a second group possesses additional cleavable signal peptides. The reason this second subset requires the additional signal peptide is not known. Here we have assessed the functional significance of the signal peptide of the endothelin B (ET(B)) receptor in transiently transfected COS.M6 cells. A green fluorescent protein-tagged ET(B) receptor mutant lacking the signal peptide was nonfunctional and retained in the endoplasmic reticulum, suggesting that it has a folding defect. To determine the defect in more detail, ET(B) receptor fragments containing the N-terminal tail, first transmembrane domain, and first cytoplasmic loop were constructed. We assessed N tail translocation across the endoplasmic reticulum membrane in the presence and absence of a signal peptide and show that the signal peptide is necessary for N tail translocation. We postulate that signal peptides are necessary for those G protein-coupled receptors for which post-translational translocation of the N terminus is impaired or blocked by the presence of stably folded domains.     

Reinitiation of translocation in the Semliki Forest virus structural polyprotein: identification of the signal for the E1 glycoprotein.

The biosynthesis of the Semliki Forest virus (SFV) structural proteins provides an interesting model system to study the reinitiation of translocation of membrane proteins into the endoplasmic reticulum membrane. The two transmembrane spike proteins, p62 and E1, are derived from a single polypeptide precursor. Once the first protein, p62, has been anchored and its cytoplasmic tail has been synthesized, translocation must be reinitiated to account for the insertion of the E1 protein. We have used deletion mutagenesis of the SFV cDNA to investigate the requirements for this event and map in detail the location of the signal. We have shown by deleting the region encoding the p62 signal and expressing the modified cDNA in COS cells that the p62 protein is not involved in the translocation of the E1 protein. The E1 signal was precisely mapped by progressive truncations of the 6 K peptide (located between p62 and E1 in the SFV polyprotein) and subsequent analysis in cell-free systems. A segment within the last 26 residues of the 6 K peptide was shown to be essential for translocation. This segment was then fused to the N-terminus of the chimpanzee alpha-globin and was shown to be sufficient for translocation. The E1 signal was cleaved efficiently even when attached to the alpha-globin protein. The activity of the signal was found to be SRP dependent in a wheat-germ cell-free system. We conclude that prior attachment of the ribosome to the membrane via the p62 signal peptide is not necessary for E1 translocation and that the reinitiation of translocation is mediated by an independent internal signal likely to be SRP dependent.     

A sugar chain at a specific position in the nascent polypeptide chain induces forward movement during translocation through the translocon

Nascent polypeptide chains synthesized by membrane bound ribosomes are cotranslationally translocated through and integrated into the endoplasmic reticulum translocon. Hydrophobic segments and positive charges on the chain are critical to halt the ongoing translocation. A marginally hydrophobic segment, which cannot be inserted into the membrane by itself, can be a transmembrane segment depending on its downstream positive charges. In certain conditions, positive charges even 60 residues downstream cause the marginally hydrophobic segment to span the membrane by inducing the segment to slide back from the lumen. Here we systematically examined the effect of a core sugar chain on the fate of a marginally hydrophobic segment using a cell-free translation and translocation system. A sugar chain added within 12 residues upstream of the marginally hydrophobic segment prevents the sliding back and promotes forward movement of the polypeptide chain. The sugar chain apparently functions as a ratchet to keep the polypeptide chain in the lumen. We propose that the sugar chain is a third topology determinant of membrane proteins, in addition to a hydrophobic segment and positive charges of the nascent chain.     

Polarity and Charge of the Periplasmic Loop Determine the YidC and Sec Translocase Requirement for the M13 Procoat Lep Protein

During membrane biogenesis, the M13 procoat protein is inserted into the lipid bilayer in a strictly YidC-dependent manner with both the hydrophobic signal sequence and the membrane anchor sequence promoting translocation of the periplasmic loop via a hairpin mechanism. Here, we find that the translocase requirements can be altered for PClep in a predictable manner by changing the polarity and charge of the peptide region that is translocated across the membrane. When the polarity of the translocated peptide region is lowered and the charged residues in this region are removed, translocation of this loop region occurs largely by a YidC- and Sec-independent mechanism. When the polarity is increased to that of the wild-type procoat protein, the YidC insertase is essential for translocation. Further increasing the polarity, by adding charged residues, switches the insertion pathway to a YidC/Sec mechanism. Conversely, we find that increasing the hydrophobicity of the transmembrane segments of PClep can decrease the translocase requirement for translocation of the peptide chain. This study provides a framework to understand why the YidC and Sec machineries exist in parallel and demonstrates that the YidC insertase has a limited capacity to translocate a peptide chain on its own.     

A cleavable signal peptide is required for the full function of the polytopic inner membrane protein FliP of Escherichia coli

FliP is a rare bacterial polytopic membrane protein synthesized with a cleavable highly hydrophobic signal peptide. It is essential for flagellum assembly and for bacterial motility. In this study, we assessed specificity of signal peptide for the FliP function. Like the wild type FliP, two altered FliPs with more hydrophilic Tat- or Sec-dependent signal peptides were both able to restore the motility of the DeltafliP mutant. Therefore, the Tat- and the Sec-dependent signal peptides seemed to be compatible with the FliP function. Moreover, deletion of the FliP signal peptide or replacing it with the transmembrane segment of MotA severely impaired the FliP function. Together these results showed that a cleavable signal peptide is required for the full function of FliP.     

Caveolin-1 hydrophobic segment peptides insertion into membrane mimetic systems: role of proline residue

Caveolin-1 has a segment of hydrophobic amino acids comprising approximately residues 103-122 that are anchored to the membrane with cholesterol-rich domains. Previously, we reported that changing the Pro(110) residue to Ala (the P110A mutant) prevents not only the localization of the protein into lipid rafts but also the formation and functioning of caveolae. The conformational state of caveolin-1 can be shifted toward the transmembrane arrangement by this single amino acid mutation. To model the conformation, and extent of membrane insertion of this segment into membrane-mimetic environments, we have prepared a peptide corresponding to this hydrophobic segment of caveolin-1 having the sequence KKKKLSTIFGIPMALIWGIYFAILKKKKK-amide and the mutated version, KKKKLSTIFGIAMALIWGIYFAILKKKKK-amide. These peptides contain flanking Lys residues to facilitate purification and handling of the peptide. Circular dichroism measurements demonstrated that the mutated peptide has increased helical content compared with the wild type both in the presence and absence of lipid. The fluorescence emission from the Trp residues in the peptide showed significant blue shifts in the presence of liposomes, however the presence of cholesterol in hydrated vesicle bilayers decreases its helical content. Our overall findings support our studies with the intact protein in cells and suggest that the peptide of WT caveolin-1 hydrophobic segment has an intrinsic preference not to maintain its conformation as a rigid transmembrane helix. Substituting the Pro residue with an Ala allows the peptide to exist in a more hydrophobic environment likely as a consequence of a change in its conformation to a straight hydrophobic helix that traverses the membrane.     

Direct interaction of YidC with the Sec-independent Pf3 coat protein during its membrane protein insertion.

YidC is a newly defined translocase component that mediates the insertion of proteins into the membrane bilayer. How YidC functions in the insertion process is not known. In this study, we report that the Sec-independent Pf3 coat protein requires the YidC protein specifically for the membrane translocation step. Using photocrosslinking techniques and ribosome-bound Pf3 coat derivatives with an extended carboxyl-terminal region, we found that the transmembrane region of the Pf3 coat protein physically interacts with YidC and the bacterial signal recognition particle Ffh component. We also find that in the insertion pathway, Pf3 coat interacts strongly with YidC only after its transmembrane segment is fully exposed outside the ribosome tunnel. Interaction between Pf3 coat and YidC occurs even in the absence of the proton motive force and with a Pf3 coat mutant that is defective in transmembrane insertion. Our study demonstrates that YidC can directly interact with a Sec-independent membrane protein, and the role of YidC is at the stage of folding the Pf3 protein into a transmembrane configuration.     

The role of the membrane-spanning domain of type I signal peptidases in substrate cleavage site selection

Type I signal peptidase (SPase I) catalyzes the cleavage of the amino-terminal signal sequences from preproteins destined for cell export. Preproteins contain a signal sequence with a positively charged n-region, a hydrophobic h-region, and a neutral but polar c-region. Despite having no distinct consensus sequence other than a commonly found c-region "Ala-X-Ala" motif preceding the cleavage site, signal sequences are recognized by SPase I with high fidelity. Remarkably, other potential Ala-X-Ala sites are not cleaved within the preprotein. One hypothesis is that the source of this fidelity is due to the anchoring of both the SPase I enzyme (by way of its transmembrane segment) and the preprotein substrate (by the h-region in the signal sequence) in the membrane. This limits the enzyme-substrate interactions such that cleavage occurs at only one site. In this work we have, for the first time, successfully isolated Bacillus subtilis type I signal peptidase (SipS) and a truncated version lacking the transmembrane domain (SipS-P2). With purified full-length as well as truncated constructs of both B. subtilis and Escherichia coli (Lep) SPase I, in vitro specificity studies indicate that the transmembrane domains of either enzyme are not important determinants of in vitro cleavage fidelity, since enzyme constructs lacking them reveal no alternate site processing of pro-OmpA nuclease A substrate. In addition, experiments with mutant pro-OmpA nuclease A substrate constructs indicate that the h-region of the signal peptide is also not critical for substrate specificity. In contrast, certain mutants in the c-region of the signal peptide result in alternate site cleavage by both Lep and SipS enzymes.     

The Rhodobacter sphaeroides cytochrome c2 signal peptide is not necessary for export and heme attachment.

Rhodobacter sphaeroides cytochrome c2 (cyt c2) is a member of the heme-containing cytochrome c protein family that is found in the periplasmic space of this gram-negative bacterium. This exported polypeptide is made as a higher-molecular-weight precursor with a typical procaryotic signal peptide. Therefore, cyt c2 maturation is normally expected to involve precursor translocation across the cytoplasmic membrane, cleavage of the signal peptide, and covalent heme attachment. Surprisingly, synthesis as a precursor polypeptide is not a prerequisite for cyt c2 maturation because deleting the entire signal peptide does not prevent export, heme attachment, or function. Although cytochrome levels were reduced about threefold in cells containing this mutant protein, steady-state cyt c2 levels were significantly higher than those of other exported bacterial polypeptides which contain analogous signal peptide deletions. Thus, this mutant protein has the unique ability to be translocated across the cytoplasmic membrane in the absence of a signal peptide. The covalent association of heme with this mutant protein also suggests that the signal peptide is not required for ligand attachment to the polypeptide chain. These results have uncovered some novel aspects of bacterial c-type cytochrome biosynthesis.     

Efficient in vitro translocation into Escherichia coli membrane vesicles of a protein carrying an uncleavable signal peptide. Characterization of the translocation process

The translocation into Escherichia coli cytoplasmic membrane vesicles of a protein containing an uncleavable signal peptide was studied. The signal peptide cleavage site of the ompF-lpp chimeric protein, a model secretory protein, was changed from Ala-Ala to Phe-Pro through oligonucleotide-directed site-specific mutagenesis of the ompF-lpp gene on a plasmid. The mutant protein was no longer processed by the signal peptidase. When proteinase K treatment was adopted as a probe for protein translocation into inverted membrane vesicles, the mutant protein exhibited rapid and almost complete translocation, most likely due to the lack of premature cleavage of the signal peptide before the translocation. This result also indicates that cleavage of the signal peptide is not required for translocation of the mature domain of the protein. The establishment of an efficient system made it possible to perform precise and quantitative analysis of the translocation process. The translocation was time-dependent, vesicle-dependent, and required ATP and NADH. Translocation into membrane vesicles was also observed with the uncleavable precursor protein purified by means of immunoaffinity chromatography, although the efficiency was appreciably low. The translocation required only ATP and NADH. Addition of the cytosolic fraction did not enhance the translocation.     

Role of amino-terminal positive charge on signal peptide in staphylokinase export across the cytoplasmic membrane of Escherichia coli

Staphylokinase mutants having amino acid substitutions within the amino-terminal charged segment of the signal peptide have been produced by in vitro oligonucleotide-directed mutagenesis. When the processing of the gene products was analyzed in Escherichia coli cells, the rate of processing of the mutant staphylokinase precursor decreased as the net charge became more negative. A net positive charge, but not specific amino acid residues, was required on the amino-terminal segment for efficient processing. Staphylokinase precursor having a net negative charge accumulated in the cytoplasm, tending to bind to the cytoplasmic membrane as determined by subcellular fractionation and immunoelectron microscopy. Although a mutant carrying an amino acid substitution in the hydrophobic segment and wild-type staphylokinases had an interfering effect on the processing of other normal secreted proteins, this effect was lost when they also contained charge-altering substitutions in the amino-terminal region. From these results, we concluded that a positive charge on the amino-terminal segment of the staphylokinase signal peptide is required for entrance into the protein export process.