Sec-dependent membrane protein biogenesis: SecYEG, preprotein hydrophobicity and translocation kinetics control the stop-transfer function.

Preprotein translocase catalyzes membrane protein integration as well as complete translocation. Membrane proteins must interrupt their translocation and be laterally released from the translocase into the lipid bilayer. We have analyzed the translocation arrest and lateral release activities of Escherichia coli preprotein translocase with an in vitro reaction and the preprotein proOmpA carrying a synthetic stop-transfer sequence. Membrane protein integration is catalytic, occurs with kinetics similar to those of proOmpA itself and only requires the functions of SecYEG and SecA. Though a strongly hydrophobic segment will direct the protein to leave the translocase and enter the lipid bilayer, a protein with a segment of intermediate hydrophobicity partitions equally between the translocated and membrane-integrated states. Analysis of the effects of PMF, varied ATP concentrations or synthetic translocation arrest show that the stop-translocation efficiency of a mildly hydrophobic segment depends on the translocation kinetics. In contrast, the lateral partitioning from translocase to lipids depends solely on temperature and does not require SecA ATP hydrolysis or SecA membrane cycling. Thus translocation arrest is controlled by the SecYEG translocase activity while lateral release and membrane integration are directed by the hydrophobicity of the segment itself. Our results suggest that a greater hydrophobicity is required for efficient translocation arrest than for lateral release into the membrane.     

Positive Charges of Translocating Polypeptide Chain Retrieve an Upstream Marginal Hydrophobic Segment from the Endoplasmic Reticulum Lumen to the Translocon

Positively charged amino acid residues are well recognized topology determinants of membrane proteins. They contribute to the stop-translocation of a polypeptide translocating through the translocon and to determine the orientation of signal sequences penetrating the membrane. Here we analyzed the function of these positively charged residues during stop-translocation in vitro. Surprisingly, the positive charges facilitated membrane spanning of a marginally hydrophobic segment, even when separated from the hydrophobic segment by 70 residues. In this case, the hydrophobic segment was exposed to the lumen, and then the downstream positive charges triggered the segment to slide back into the membrane. The marginally hydrophobic segment spanned the membrane, but maintained access to the water environment. The positive charges not only fix the hydrophobic segment in the membrane at its flanking position, but also have a much more dynamic action than previously realized.     

Membrane protein topology of oleosin is constrained by its long hydrophobic domain.

Oleosin proteins from Arabidopsis assume a unique endoplasmic reticulum (ER) topology with a membrane-integrated hydrophobic (H) domain of 72 residues, flanked by two cytosolic hydrophilic domains. We have investigated the targeting and topological determinants present within the oleosin polypeptide sequence using ER-derived canine pancreatic microsomes. Our data indicate that oleosins are integrated into membranes by a cotranslational, translocon-mediated pathway. This is supported by the identification of two independent functional signal sequences in the H domain, and by demonstrating the involvement of the SRP receptor in membrane targeting. Oleosin topology was manipulated by the addition of an N-terminal cleavable signal sequence, resulting in translocation of the N terminus to the microsomal lumen. Surprisingly, the C terminus failed to translocate. Inhibition of C-terminal translocation was not dependent on either the sequence of hydrophobic segments in the H domain, the central proline knot motif or charges flanking the H domain. Therefore, the topological constraint results from the length and/or the hydrophobicity of the H domain, implying a general case that long hydrophobic spans are unable to translocate their C terminus to the ER lumen.     

Stop-transfer efficiency of marginally hydrophobic segments depends on the length of the carboxy-terminal tail

Hydrophobic stop-transfer sequences generally serve to halt the translocation of polypeptide chains across the endoplasmic reticulum membrane and become integrated as transmembrane α-helices. Using engineered glycosylation sites as topology reporters, we show that the length of the nascent chain between a hydrophobic segment and the carboxy terminus of the protein can affect stop-transfer efficiency. We also show that glycosylation sites located close to a protein's C terminus are modified in two distinct kinetic phases, one fast and one slow. Our findings suggest that membrane integration of a hydrophobic segment is not simply a question of thermodynamic equilibrium, but can be influenced by details of the translocation mechanism.     

A tripartite structure of the signals that determine protein insertion into the endoplasmic reticulum membrane

Multilineage colony stimulating factor is a secretory protein with a cleavable signal sequence that is unusually long and hydrophobic. Using molecular cloning techniques we exchanged sequences NH2- or COOH-terminally flanking the hydrophobic signal sequence. Such modified fusion proteins still inserted into the membrane but their signal sequence was not cleaved. Instead the proteins were now anchored in the membrane by the formerly cleaved signal sequence (signal-anchor sequence). They exposed the NH2 terminus on the exoplasmic and the COOH terminus on the cytoplasmic side of the membrane. We conclude from our results that hydrophilic sequences flanking the hydrophobic core of a signal sequence can determine cleavage by signal peptidase and insertion into the membrane. It appears that negatively charged amino acid residues close to the NH2 terminal side of the hydrophobic segment are compatible with translocation of this segment across the membrane. A tripartite structure is proposed for signal-anchor sequences: a hydrophobic core region that mediates targeting to and insertion into the ER membrane and flanking hydrophilic segments that determine the orientation of the protein in the membrane.     

Insertion of a multispanning membrane protein occurs sequentially and requires only one signal sequence

To study the insertion of multispanning membrane proteins into the endoplasmic reticulum, we constructed novel proteins on the cDNA level by repeating, up to four times, the internal signal-anchor domain of the asialoglycoprotein receptor H1. Upon in vitro translation in the presence of microsomes, these polypeptides are indeed inserted as polytopic membrane proteins. The first hydrophobic domain functions as a signal and the second as a stop-transfer sequence, while the third initiates a second translocation process, halted again by the fourth. We were able to demonstrate that insertion occurs sequentially, starting with the first apolar segment from the amino terminus. By replacing the original signal-anchor domains by a mutant sequence not recognized by signal recognition particle (SRP), it was shown that only the first hydrophobic domain needs to be a signal sequence and that the second translocation event does not require SRP.     

Negatively charged residues in the IgM stop-transfer effector sequence regulate transmembrane polypeptide integration

A non-hydrophobic sequence that contributes to the biogenesis of a transmembrane protein is termed a stop-transfer effector (STE). To examine the mechanism of STE-mediated stop-transfer, a series of fusion proteins were constructed containing variants of a putative STE from murine IgM fused to an otherwise translocated hydrophobic sequence. Unexpectedly, the fraction of molecules adopting transmembrane topology was insensitive to many amino acid substitutions within the STE sequence but varied directly with the number of negative charges. Furthermore, when present at the amino terminus of a reporter, mutants were observed that adopted type I (amino terminus lumenal) and type II (amino terminus cytoplasmic) transmembrane topologies, demonstrating that the STE sequence can be located at either side of the endoplasmic reticulum membrane. Our results suggest that recognition of a broad structural feature formed primarily by negatively charged residues within the STE halts translocation and triggers membrane integration, even when the negative charges end up on the cytoplasmic side of the membrane. Since functional STE sequences photocross-link to two membrane proteins not previously identified at the translocon, these unique proteins are presumably involved in recognizing STE sequences and/or facilitating STE function.     

Parallel effects of signal peptide hydrophobic core modifications on co-translational translocation and post-translational cleavage by purified signal peptidase

The length of the hydrophobic core of the bovine parathyroid hormone signal peptide was modified by in vitro mutagenesis. Extension of the hydrophobic core by three amino acids at the NH2-terminal end had little effect on the proteolytic processing of the signal peptide by microsomal membranes. Deletion of 6 of the 12 amino acids in the core eliminated translocation and processing of the modified protein. Deletion of pairs of amino acids across the core resulted in position-dependent inhibition of signal activity unrelated to hydrophobicity but inversely related to the hydrophobic moments of the modified cores. Deletions in the NH2-terminal region of the core were strongly inhibitory for proteolytic processing whereas deletions in the COOH-terminal region had no effect or increased processing when assessed either co-translationally with microsomal membranes or post-translationally with purified hen oviduct signal peptidase. Deletion of cysteine 18 and alanine 19 increased processing, but deletion of cysteine alone or substitution of leucine for cysteine did not increase processing more than deletion of both residues at 18 and 19. Translations of the translocation-defective mutants with pairs of amino acids deleted in a wheat germ system were inhibited by addition of exogenous signal recognition particle suggesting that interactions of the modified signal peptides with signal recognition particle were normal. The position-dependent effects of the hydrophobic core modifications indicate that structural properties of the core in addition to hydrophobicity are important for signal activity. The parallel effects of the modifications on co-translational translocation and post-translational processing by purified signal peptidase suggest that proteins in the signal peptidase complex might be part of, or intimately associated with, membrane proteins involved in the translocation. A model is proposed in which the NH2-terminal region of the hydrophobic core binds to one subunit of the signal peptidase while the other subunit catalyzes the cleavage.     

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.     

Proprotein convertase PC3 is not a transmembrane protein

Proprotein convertase PC3 (also known as PC1) is an endopeptidase involved in proteolytic processing of peptide hormone precursors in granules of the regulated secretory pathway of endocrine cells. Lacking any extended hydrophobic segments, PC3 was considered to be a secretory protein only peripherally attached to the granule membrane. Recently, evidence has been presented that PC3 is a transmembrane protein with a 115-residue cytoplasmic domain and a membrane-spanning segment containing eight charged amino acids [Arnaoutova, I., et al. (2003) Biochemistry 42, 10445-10455]. Here, we analyzed the membrane topology of PC3 and of a PC3 construct containing a conventional transmembrane segment of 19 leucines. Alkaline extraction was performed to assess membrane integration. Exposure to the cytosol or to the ER lumen was tested by addition of C-terminal tags for phosphorylation or glycosylation, respectively. Protease sensitivity was assayed in permeabilized cells. The results show that the C-terminus of PC3 is translocated across the endoplasmic reticulum membrane. Furthermore, the proposed transmembrane segment of PC3 and a similar one of carboxypeptidase E did not stop polypeptide translocation when inserted into a stop-transfer tester construct. PC3 is thus not a transmembrane protein. These results have implications for the mechanism of granule sorting of PC3 as well as for the topology of PC2 and carboxypeptidase E, which have been reported to span the lipid membrane by homologous charged sequences.     

Type II transmembrane domain hydrophobicity dictates the cotranslational dependence for inversion

Membrane insertion by the Sec61 translocon in the endoplasmic reticulum (ER) is highly dependent on hydrophobicity. This places stringent hydrophobicity requirements on transmembrane domains (TMDs) from single-spanning membrane proteins. On examining the single-spanning influenza A membrane proteins, we found that the strict hydrophobicity requirement applies to the N_out-C_in HA and M2 TMDs but not the N_in-C_out TMDs from the type II membrane protein neuraminidase (NA). To investigate this discrepancy, we analyzed NA TMDs of varying hydrophobicity, followed by increasing polypeptide lengths, in mammalian cells and ER microsomes. Our results show that the marginally hydrophobic NA TMDs (ΔG_app > 0 kcal/mol) require the cotranslational insertion process for facilitating their inversion during translocation and a positively charged N-terminal flanking residue and that NA inversion enhances its plasma membrane localization. Overall the cotranslational inversion of marginally hydrophobic NA TMDs initiates once ∼70 amino acids past the TMD are synthesized, and the efficiency reaches 50% by ∼100 amino acids, consistent with the positioning of this TMD class in type II human membrane proteins. Inversion of the M2 TMD, achieved by elongating its C-terminus, underscores the contribution of cotranslational synthesis to TMD inversion.     

The topogenic contribution of uncharged amino acids on signal sequence orientation in the endoplasmic reticulum

Signal sequences for insertion of proteins into the endoplasmic reticulum induce translocation of either the C- or the N-terminal sequence across the membrane. The end that is translocated is primarily determined by the flanking charges and the hydrophobic domain of the signal. To characterize the hydrophobic contribution to topogenesis, we have challenged the translocation machinery in vivo in transfected COS cells with model proteins differing exclusively in the apolar segment of the signal. Homo-oligomers of hydrophobic amino acids as different in size and shape as Val(19), Trp(19), and Tyr(22) generated functional signal sequences with similar topologies in the membrane. The longer a homo-oligomeric sequence of a given residue, the more N-terminal translocation was obtained. To determine the topogenic contribution of all uncharged amino acids in the context of a hydrophobic signal sequence, two residues in a generic oligoleucine signal were exchanged for all uncharged amino acids. The resulting scale resembles a hydrophobicity scale with the more hydrophobic residues promoting N-terminal translocation. In addition, the helix breakers glycine and proline showed a position-dependent effect, which raises the possibility of a conformational contribution to topogenesis.     

Stop-transfer activity of hydrophobic sequences depends on the translation system

Signal and stop-transfer sequences are the known determinants involved in topogenesis of integral membrane proteins. To study the characteristics of stop-transfer sequences, artificial proteins have been created on the DNA level based on the cDNA of the asialoglycoprotein receptor H1. Its internal signal/anchor domain initiates translocation of the downstream sequence across the endoplasmic reticulum membrane. The ability of several hydrophobic sequences inserted into the translocating polypeptide to stop further transfer was analyzed by translation of the fusion proteins using the wheat germ extract and rabbit reticulocyte lysate systems with dog pancreas microsomes. We discovered that some of the sequences behave differently with respect to translocation across the membrane depending on the translation system. Expression of one of the fusion proteins in fibroblasts showed that the reticulocyte lysate system reflects more closely the in vivo situation than the wheat germ system. Our results suggest that in a homologous system the translating ribosomes interact with the translocation machinery and influence the termination of polypeptide transfer by hydrophobic sequences.     

Phosphorylation of components of the ER translocation site.

In many eukaryotic cells, protein secretion is regulated by extracellular signalling molecules giving rise to increased intracellular Ca2+ and activation of kinases and phosphatases. To test whether components involved in the first step of secretion, the translocation of proteins across the endoplasmic reticulum (ER) membrane, are regulated by Ca2+-dependent phosphorylation and dephosphorylation, we have investigated the effect of Ca2+ on kinases associated with the rough ER. Using purified rough microsomes from dog pancreas we found that Ca2+-dependent isoforms of protein kinase C (PKC) are associated with the rough ER and phosphorylate essential components of the protein translocation machinery. Phosphorylation of microsomal proteins by PKCs increased protein translocation efficiency in vitro. We also found that proteins of the translocation machinery became phosphorylated in intact cells. This suggests a further level of regulation of protein translocation across the ER membrane.     

Determination of the membrane topology of the phenobarbital-inducible rat liver cytochrome P-450 isoenzyme PB-4 using site-specific antibodies

Fifteen peptides, ranging in length from 6 to 31 amino acids and corresponding in sequence to portions of the major phenobarbital-inducible form of rat liver cytochrome P-450 (P-450 PB-4), were previously synthesized chemically and used to prepare site-specific rabbit antibodies (Frey, A. B., D.J. Waxman, and G. Kreibich, 1985, J. Biol. Chem., 260:15253-15265). The antipeptide antibodies were affinity purified using Sepharose resins derivatized with the respective peptides and 14 preparations were obtained that in an ELISA assay showed affinities to immobilized P-450 judged to be adequate for binding studies on intact rat liver microsomes. The binding of these antibodies to rough microsomes from the livers of phenobarbital treated rats was assessed using 125I-labeled IgG and by immunoelectron microscopy employing protein A-gold as a marker. It was found that many of the antibodies bound to the cytoplasmic surface of the membrane but none bound to the luminal face of ruptured or inverted microsomal vesicles or to contaminating membranes of other organelles present in the preparations. These observations eliminate previously proposed models for the transmembrane disposition of P-450 that postulate the existence of multiple transmembrane domains and the exposure of several polar segments of the polypeptide on the luminal side of the membrane. The fact that an antibody raised to the first 31 residues of P-450 bound well to the purified P-450 but very poorly to rough microsomes, whereas an antibody to a peptide comprising residues 24-38 showed relatively strong binding to intact microsomes, is consistent with the proposal that the amino terminal segment of P-450 extending approximately to residue 20 is embedded in the phospholipid bilayer and the immediately following segment is exposed on the cytoplasmic surface of the membrane. All these results favor a model in which the cytochrome P-450 molecule is largely exposed on the cytoplasmic surface of the endoplasmic reticulum membrane to which it is anchored by its short amino terminal hydrophobic segment.     

Distant downstream sequence determinants can control N-tail translocation during protein insertion into the endoplasmic reticulum membrane

We have studied the membrane insertion of ProW, an Escherichia coli inner membrane protein with seven transmembrane segments and a large periplasmic N-terminal tail, into endoplasmic reticulum (ER)-derived dog pancreas microsomes. Strikingly, significant levels of N-tail translocation is seen only when a minimum of four of the transmembrane segments are present; for constructs with fewer transmembrane segments, the N-tail remains mostly nontranslocated and the majority of the molecules adopt an "inverted" topology where normally nontranslocated parts are translocated and vice versa. N-tail translocation can also be promoted by shortening of the N-tail and by the addition of positively charged residues immediately downstream of the first trasnmembrane segment. We conclude that as many as four consecutive transmembrane segments may be collectively involved in determining membrane protein topology in the ER and that the effects of downstream sequence determinants may vary depending on the size and charge of the N-tail. We also provide evidence to suggest that the ProW N-tail is translocated across the ER membrane in a C-to-N-terminal direction.     

Effects of total hydrophobicity and length of the hydrophobic domain of a signal peptide on in vitro translocation efficiency.

The hydrophobic domain of the signal peptide of OmpF-Lpp, a model secretory protein, was systematically engineered so as to be composed of different lengths of polyleucine residues or polymers with alternate leucine and alanine residues, and the effects of the length and nature of the hydrophobic stretch on the rate of in vitro translocation were studied using everted membrane vesicles of Escherichia coli. The translocation reaction exhibited high substrate specificity as to the number of hydrophobic residues. The results suggest that the hydrophobic domain is recognized specifically by a component(s) of the secretory machinery rather than nonspecifically by the hydrophobic region of the membrane. The in vitro translocation thus demonstrated required SecA and ATP and was markedly enhanced upon imposition of the proton motive force, as in the case of secretory proteins possessing a natural signal peptide. The highest translocation rate was obtained with the octamer in the case of polyleucine-containing signal peptides, whereas it was the decamer in the case of ones containing both leucine and alanine. These results suggest that the total hydrophobicity of the hydrophobic region of the signal peptides is an important determinant of the substrate specificity.     

Membrane integration of the second transmembrane segment of band 3 requires a closely apposed preceding signal-anchor sequence

We have investigated the topogenic rules of multispanning membrane proteins using erythrocyte band 3. Here, the fine structural requirements for the correct disposition of its second transmembrane segment (TM2) were assessed. We made fusion proteins where TM1 and the loop sequence preceding TM2 were changed and fused to prolactin. They were expressed in a cell-free system supplemented with rough microsomal membrane, and their topologies on the membrane were assessed by protease sensitivity and N-glycosylation. TM1 was demonstrated to be a signal-anchor sequence that mediates translocation of the downstream portion, and thus TM2 should be responsible to halt the translocation to acquire TM topology. When the loop between TM1 and TM2 was elongated, however, TM2 was readily translocated through the membrane and not integrated. For the membrane integration of TM2, TM2 must be in close proximity to TM1. The TM1 can be replaced with another signal-anchor sequence with a long hydrophobic segment but not with a signal sequence with shorter hydrophobic stretch. The length of the hydrophobic segment affected final topology of TM2. We concluded that the two TM segments work synergistically within the translocon to acquire the correct topology and that the length of the preceding signal sequence is critical for stable transmembrane assembly of TM2. We propose that direct interaction among the TM segments is one of the critical factors for the transmembrane topogenesis of multispanning membrane proteins.     

Design and characterization of anchoring amphiphilic peptides and their interactions with lipid vesicles.

In an effort to develop a polymer/peptide assembly for the immobilization of lipid vesicles, we have made and characterized four water-soluble amphiphilic peptides designed to associate spontaneously and strongly with lipid vesicles without causing significant leakage from anchored vesicles. These peptides have a primary amphiphilic structure with the following sequences: AAAAAAAAAAAAWKKKKKK, AALLLAAAAAAAAAAAAAAAAAAAWKKKKKK, and KKAALLLAAAAAAAAAAAAAAAAAAAWKKKKKK and its reversed homologue KKKKKKWAAAAA AAAAAAAAAAAAAALLLAAKK. Two of the four peptides have their hydrophobic segments capped at both termini with basic residues to stabilize the transmembrane orientation and to increase the affinity for negatively charged vesicles. We have studied the secondary structure and the membrane affinity of the peptides as well as the effect of the different peptides on the membrane permeability. The influence of the hydrophobic length and the role of lysine residues were clearly established. First, a hydrophobic segment of 24 amino acids, corresponding approximately to the thickness of a lipid bilayer, improves considerably the affinity to zwitterionic lipids compared to the shorter one of 12 amino acids. The shorter peptide has a low membrane affinity since it may not be long enough to adopt a stable conformation. Second, the presence of lysine residues is essential since the binding is dominated by electrostatic interactions, as illustrated by the enhanced binding with anionic lipids. The charges at both ends, however, prevent the peptide from inserting spontaneously in the bilayer since it would involve the translocation of a charged end through the apolar core of the bilayer. The direction of the amino acid sequence of the peptide has no significant influence on its behavior. None of these peptides perturbs membrane permeability even at an incubation lipid to peptide molar ratio of 0.5. Among the four peptides, AALLLAAAAAAAAAAAAAAAAAAAWKKKKKK is identified as the most suitable anchor for the immobilization of lipid vesicles.