Organization of the membrane domain of the human liver sodium/bile acid cotransporter

Mammalian sodium/bile acid cotransporters (SBATs) are glycoproteins with an exoplasmic N-terminus, an odd number of transmembrane regions, and a cytoplasmic C-terminus. Various algorithms predict eight or nine membrane-embedded regions derived from nine hydrophobic stretches of the protein (H1-H9). Three methods were used to define which of these were transmembrane or membrane-associated segments in the liver bile acid transporter. The first was in vitro translation/insertion scanning using either single hydrophobic sequences between the N-terminal domain of the alpha-subunit of the gastric H,K-ATPase and the C-terminal domain of the beta-subunit that contains five N-linked glycosylation exoplasmic flags or using constructs beginning with the N-terminus of the transporter of various lengths and again ending in the C-terminus of the H,K-ATPase beta-subunit. Seven of the predicted segments, but not the amphipathic H3 and H8 sequences, insert as both individual signal anchor and stop transfer sequences in the reporter constructs. These sequences, H3 and H8, are contained within two postulated long exoplasmic loops in the classical seven-transmembrane segment model. The H3 segment acts as a partial stop transfer signal when expressed downstream of the endogenous H2. In a similar manner, the other amphipathic segment, H8, inserts as a signal anchor sequence when translated in the context with the upstream transporter sequence in two different glycosylation constructs. Alanine insertion scanning identified regions of the transporter requiring precise alignment of sequence to form competent secondary structures. The transport activity of these mutants was evaluated either in native protein or in a yellow fluorescent protein (YFP) fusion protein construct. All alanine insertions in H3 and H8 abolished taurocholate uptake, suggesting that both these regions have structures with critical intramolecular interactions. Moreover, these insertions also prevented trafficking to the plasma membrane as assessed by confocal microscopy with a polyclonal antibody against either the C-terminus of the transporter or the YFP signal of the YFP-transporter fusion protein. Two glycosylation signals inserted in the first postulated loop region and four of five such signals in the second postulated loop region were not recognized by the oligosaccharide transferase, and the L256N mutation exhibited 10% glycosylation and was inactive. These findings support a topography with nine membrane-spanning or membrane-associated segments.     

Membrane insertion scanning of the human ileal sodium/bile acid co-transporter.

Mammalian sodium-dependent bile acid transporters (SBATs) responsible for bile salt uptake across the liver sinusoidal or ileal/renal brush border membrane have been identified and share approximately 35% amino acid sequence identity. Programs for prediction of topology and localization of transmembrane helices identify eight or nine hydrophobic regions for the SBAT sequences as membrane spanning. Analysis of N-linked glycosylation has provided evidence for an exoplasmic N-terminus and a cytoplasmic C-terminus, indicative of an odd number of transmembrane segments. To determine the membrane topography of the human ileal SBAT (HISBAT), an in vitro translation/translocation protocol was employed using three different fusion protein constructs. Individual HISBAT segments were analyzed for signal anchor or stop translocation (stop transfer) activity by insertion between a cytoplasmic anchor (HK M0) or a signal anchor segment (HK M1) and a glycosylation flag (HK beta). To examine consecutive HISBAT sequences, sequential hydrophobic sequences were inserted into the HK M0 vector or fusion vectors were made that included the glycosylated N-terminus of HISBAT, sequential hydrophobic sequences, and the glycosylation flag. Individual signal anchor (SA) and stop transfer (ST) properties were found for seven out of the nine predicted hydrophobic segments (H1, H2, H4, H5, H6, H7, and H9), supporting a seven transmembrane segment model. However, the H3 region was membrane inserted when translated in the context of the native HISBAT flanking sequences. Furthermore, results from translations of sequential constructs ending after H7 provided support for integration of H8. These data provide support for a SBAT transmembrane domain model with nine integrated segments with an exoplasmic N-terminus and a cytoplasmic C-terminus consistent with a recent predictive analysis of this transporter topology.     

A stop transfer sequence recognizes receptors for nascent chain translocation across the endoplasmic reticulum membrane

A stop transfer sequence derived from the extreme carboxyl terminus of membrane IgM heavy chain has been shown to confer predictable transmembrane orientation to secretory proteins by aborting translocation of subsequently synthesized protein domains. Here we demonstrate that, in certain peptide sequence contexts, the same stop transfer sequence is also capable of initiating domain translocation across the endoplasmic reticulum (ER) membrane. Translocation directed by a stop transfer sequence is similar to, but distinguishable from, the action of a conventional signal sequence. Translocation is dependent on participation of the ribosome and protein receptors both in the cytoplasm and in the ER membrane. Moreover, both amino- and carboxy-terminal flanking protein domains can be translocated. Unlike a signal sequence, the stop transfer sequence is not itself translocated across the membrane. These results have implications for the nature of signal sequences, stop transfer sequences, and their receptor interactions.     

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.     

Efficient glycosylphosphatidylinositol (GPI) modification of membrane proteins requires a C-terminal anchoring signal of marginal hydrophobicity

Many plasma membrane proteins are anchored to the membrane via a C-terminal glycosylphosphatidylinositol (GPI) moiety. The GPI anchor is attached to the protein in the endoplasmic reticulum by transamidation, a reaction in which a C-terminal GPI-attachment signal is cleaved off concomitantly with addition of the GPI moiety. GPI-attachment signals are poorly conserved on the sequence level but are all composed of a polar segment that includes the GPI-attachment site followed by a hydrophobic segment located at the very C terminus of the protein. Here, we show that efficient GPI modification requires that the hydrophobicity of the C-terminal segment is "marginal": less hydrophobic than type II transmembrane anchors and more hydrophobic than the most hydrophobic segments found in secreted proteins. We further show that the GPI-attachment signal can be modified by the transamidase irrespective of whether it is first released into the lumen of the endoplasmic reticulum or is retained in the endoplasmic reticulum membrane.     

C-terminal sequences can inhibit the insertion of membrane proteins into the endoplasmic reticulum of Saccharomyces cerevisiae.

We have constructed three gene fusions that encode portions of a membrane protein, arginine permease, fused to a reporter domain, the cytoplasmic enzyme histidinol dehydrogenase (HD), located at the C-terminal end. These fusion proteins contain at least one of the internal signal sequences of arginine permease. When the fusion proteins were expressed in Saccharomyces cerevisiae and inserted into the endoplasmic reticulum (ER), two of the fusion proteins placed HD on the luminal side of the ER membrane, but only when a piece of DNA encoding a spacer protein segment was inserted into the fusion joint. The third fusion protein, with or without the spacer included, placed HD on the cytoplasmic side of the membrane. These results suggest that (i) sequences C-terminal to the internal signal sequence can inhibit membrane insertion and (ii) HD requires a preceding spacer segment to be translocated across the ER membrane.     

A class of membrane proteins with a C-terminal anchor

Integral membrane proteins are generally targeted to translocation-competent membranes by virtue of signal sequences located close to the N-terminus of the polypeptide chain. Membrane anchoring is caused by the signal sequence or other hydrophobic segments located after it in the amino acid sequence. However, some integral membrane proteins do not follow these rules. The members of one class of nonconformist membrane proteins have no signal sequence, but instead possess a hydrophobic segment near the C-terminus that orients them with their N-termini in the cytoplasm. Members of this class are found in many organelles and are probably inserted into membranes by an unusual mechanism.     

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.     

Targeting and assembly of mitochondrial tail-anchored protein Tom5 to the TOM complex depend on a signal distinct from that of tail-anchored proteins dispersed in the membrane

Mitochondrial outer membrane proteins are synthesized without a cleavable presequence but instead contain segments responsible for mitochondrial targeting and membrane integration within the molecule: the transmembrane segment (TMS) and N- or C-terminal flanking segment. We analyzed targeting and integration of Tom5, a C-tail anchor protein associated with the preprotein translocase of the outer membrane, to the yeast mitochondrial outer membrane in vivo using green fluorescent protein as the reporter and compared the signal with other signals for proteins dispersed in the membrane. The functional assembly of Tom5 into the TOM complex was assessed by blue native PAGE and complementation of temperature-sensitive deltatom5 cells. Correct targeting and assembly required (i). an appropriate length TMS rather than hydrophobicity, (ii). a proline residue located at correct position in the TMS and specific residues near the proline, and (iii). that, in contrast to proteins dispersed in the outer membrane, the positive C-terminal segment was dispensable. Based on these findings, we constructed green fluorescent protein fusions with a C-terminal TMS in which the deduced sequences (minimum: Ser-Pro-Met) were inserted at an appropriate position within artificial Leu-Ala repeats. They were targeted to mitochondria and complemented the temperature-sensitive growth phenotype of deltatom5 yeast cells. The membrane-targeting mechanism of Tom5 appears to be distinct from that for proteins that are dispersed in the outer membrane.     

Glycosylation can influence topogenesis of membrane proteins and reveals dynamic reorientation of nascent polypeptides within the translocon.

The topology of multispanning membrane proteins in the mammalian endoplasmic reticulum is thought to be dictated primarily by the first hydrophobic sequence. We analyzed the in vivo insertion of a series of chimeric model proteins containing two conflicting signal sequences, i.e., an NH(2)-terminal and an internal signal, each of which normally directs translocation of its COOH-terminal end. When the signals were separated by more than 60 residues, linear insertion with the second signal acting as a stop-transfer sequence was observed. With shorter spacers, an increasing fraction of proteins inserted with a translocated COOH terminus as dictated by the second signal. Whether this resulted from membrane targeting via the second signal was tested by measuring the targeting efficiency of NH(2)-terminal signals followed by polypeptides of different lengths. The results show that targeting is mediated predominantly by the first signal in a protein. Most importantly, we discovered that glycosylation within the spacer sequence affects protein orientation. This indicates that the nascent polypeptide can reorient within the translocation machinery, a process that is blocked by glycosylation. Thus, topogenesis of membrane proteins is a dynamic process in which topogenic information of closely spaced signal and transmembrane sequences is integrated.     

Membrane insertion of uracil permease, a polytopic yeast plasma membrane protein.

Uracil permease is a multispanning protein of the Saccharomyces cerevisiae plasma membrane which is encoded by the FUR4 gene and produced in limited amounts. It has a long N-terminal hydrophilic segment, which is followed by 10 to 12 putative transmembrane segments, and a hydrophilic C terminus. The protein carries seven potential N-linked glycosylation sites, three of which are in its N-terminal segment. Overexpression of this permease and specific antibodies were used to show that uracil permease undergoes neither N-linked glycosylation nor proteolytic processing. Uracil permease N-terminal segments of increasing lengths were fused to a reporter glycoprotein, acid phosphatase. The in vitro and in vivo fates of the resulting hybrid proteins were analyzed to identify the first signal anchor sequence of the permease and demonstrate the cytosolic orientation of its N-terminal hydrophilic sequence. In vivo insertion of the hybrid protein bearing the first signal anchor sequence of uracil permease into the endoplasmic reticulum membrane was severely blocked in sec61 and sec62 translocation mutants.     

Biogenesis and transmembrane topology of the CHIP28 water channel at the endoplasmic reticulum

CHIP28 is a 28-kD hydrophobic integral membrane protein that functions as a water channel in erythrocytes and renal tubule epithelial cell membranes. We examined the transmembrane topology of CHIP28 in the ER by engineering a reporter of translocation (derived from bovine prolactin) into nine sequential sites in the CHIP28 coding region. The resulting chimeras were expressed in Xenopus oocytes, and the topology of the reporter with respect to the ER membrane was determined by protease sensitivity. We found that although hydropathy analysis predicted up to seven potential transmembrane regions, CHIP28 spanned the membrane only four times. Two putative transmembrane helices, residues 52-68 and 143-157, reside on the lumenal and cytosolic surfaces of the ER membrane, respectively. Topology derived from these chimeric proteins was supported by cell-free translation of five truncated CHIP28 cDNAs, by N-linked glycosylation at an engineered consensus site in native CHIP28 (residue His69), and by epitope tagging of the CHIP28 amino terminus. Defined protein chimeras were used to identify internal sequences that direct events of CHIP28 topogenesis. A signal sequence located within the first 52 residues initiated nascent chain translocation into the ER lumen. A stop transfer sequence located in the hydrophobic region from residues 90-120 terminated ongoing translocation. A second internal signal sequence, residues 155-186, reinitiated translocation of a COOH-terminal domain (residues 186-210) into the ER lumen. Integration of the nascent chain into the ER membrane occurred after synthesis of 107 residues and required the presence of two membrane-spanning regions. From this data, we propose a structural model for CHIP28 at the ER membrane in which four membrane- spanning alpha-helices form a central aqueous channel through the lipid bilayer and create a pathway for water transport.     

Coupled Translocation Events Generate Topological Heterogeneity at the Endoplasmic Reticulum Membrane

Topogenic determinants that direct protein topology at the endoplasmic reticulum membrane usually function with high fidelity to establish a uniform topological orientation for any given polypeptide. Here we show, however, that through the coupling of sequential translocation events, native topogenic determinants are capable of generating two alternate transmembrane structures at the endoplasmic reticulum membrane. Using defined chimeric and epitope-tagged full-length proteins, we found that topogenic activities of two C-trans (type II) signal anchor sequences, encoded within the seventh and eighth transmembrane (TM) segments of human P-glycoprotein were directly coupled by an inefficient stop transfer (ST) sequence (TM7b) contained within the C-terminus half of TM7. Remarkably, these activities enabled TM7 to achieve both a single- and a double-spanning TM topology with nearly equal efficiency. In addition, ST and C-trans signal anchor activities encoded by TM8 were tightly linked to the weak ST activity, and hence topological fate, of TM7b. This interaction enabled TM8 to span the membrane in either a type I or a type II orientation. Pleiotropic structural features contributing to this unusual topogenic behavior included 1) a short, flexible peptide loop connecting TM7a and TM7b, 2) hydrophobic residues within TM7b, and 3) hydrophilic residues between TM7b and TM8.     

An artificial hydrophobic sequence functions as either an anchor or a signal sequence at only one of two positions within the Escherichia coli outer membrane protein OmpA

The 325-residue outer membrane protein, OmpA, of Escherichia coli, like most other outer membrane proteins with known sequence, contains no long stretch of hydrophobic amino acids. A synthetic oligonucleotide, encoding the sequence Leu-Ala-Leu-Val, was inserted four times between the codons for amino acid residues 153 and 154 and two, three, or four times between the codons for residues 228 and 229, resulting in the OmpA153-4, OmpA-228-2, -3, and -4 proteins, respectively. In the first case, the lipophilic sequence anchored the protein in the plasma membrane. In the OmpA228 proteins, 16 but not 12 or 8 lipophilic residues most likely also acted as an anchor. By removal of the NH2-terminal signal peptide, the function of the insert in OmpA153-4 was converted to that of a signal-anchor sequence. Possibly due to differences in amino acid sequences surrounding the insert, no signal function was observed with the insert in OmpA228-4. Production of the OmpA153-4 protein, with or without the NH2-terminal signal sequence, resulted in a block of export of chromosomally encoded OmpA. Clearly, long hydrophobic regions are not permitted within proteins destined for the bacterial outer membrane, and these proteins, therefore, have had to evolve another mechanism of membrane assembly.     

The ultimate localization of an outer membrane protein of Escherichia coli K-12 is not determined by the signal sequence

To study the role of the signal sequences in the biogenesis of outer membrane proteins, we have constructed two hybrid genes: a phoE-ompF hybrid gene, which encodes the signal sequence of outer membrane PhoE protein and the structural sequence of outer membrane OmpF protein, and a bla-phoE hybrid gene which encodes the signal sequence as well as 158 amino acids of the structural sequence of the periplasmic enzyme beta-lactamase and the complete structural sequence of PhoE protein. The products of these genes are normally transported to and assembled into the outer membrane These results show: (i) that signal sequences of exported proteins are export signals which function independently of the structural sequence, and (ii) that the information which determines the ultimate location of an outer membrane protein is located in the structural sequence of this protein, and not in the signal sequence.     

The juxtamembrane sequence of cytochrome P-450 2C1 contains an endoplasmic reticulum retention signal

The N-terminal signal anchor of cytochrome P-450 2C1 mediates retention in the endoplasmic reticulum (ER) membrane of several reporter proteins. The same sequence fused to the C terminus of the extracellular domain of the epidermal growth factor receptor permits transport of the chimeric protein to the plasma membrane. In the N-terminal position, the ER retention function of this signal depends on the polarity of the hydrophobic domain and the sequence KQS in the short hydrophilic linker immediately following the transmembrane domain. To determine what properties are required for the ER retention function of the signal anchor in a position other than the N terminus, the effect of mutations in the linker and hydrophobic domains on subcellular localization in COS1 cells of chimeric proteins with the P-450 signal anchor in an internal or C-terminal position was analyzed. For the C-terminal position, the signal anchor was fused to the end of the luminal domain of epidermal growth factor receptor, and green fluorescent protein was additionally fused at the C terminus of the signal anchor for the internal position. In these chimeras, the ER retention function of the signal anchor was rescued by deletion of three leucines at the C-terminal side of its hydrophobic domain; however, deletion of three valines from the N-terminal side did not affect transport to the cell surface. ER retention of the C-terminal deletion mutants was eliminated by substitution of alanines for glutamine and serine in the linker sequence. These data are consistent with a model in which the position of the linker sequence at the membrane surface, which is critical for ER retention, is dependent on the transmembrane domain.     

Control of protein topology at the endoplasmic reticulum.

I have described recent work that supports several conclusions that might not have been previously expected: first, that stop transfer, like the initiation of translocation, is receptor-mediated; second, that at least some of the topology-determining events at the ER membrane can be regulated (an example is provided where regulation may occur developmentally [PrP] and a possible example where receptor interactions for stop transfer seem to have been dissociated from those of integration in the membrane, in the course of evolution [apo B]); third, that these variations on the universal mechanism of eukaryotic secretory and transmembrane protein biogenesis can occur either through the variations in sequences presented to the common machinery of translocation or through variations in the machinery with which these sequences interact. Thus, on the one hand, at least some of these variations are directed by signal and stop transfer sequence subtypes and, on the other hand, in at least one case, a special cytoplasmic factor distinct from the core machinery for chain translocation also seems to be involved (RRL cytosolic factor effect on PrP topology) in the special handling of the STE stop transfer sequence subtype. In another case, the conserved universal machinery is engaged by a protein (apo B) to carry out an unusual, if not unique, mechanism presumably related to the lipid carrying role of this soluble secretory protein. Whether stop transfer sequence subtypes are involved here remains to be demonstrated, but it is a tempting hypothesis. Taken together, these findings suggest that the ER is more than a barrier to be overcome in protein export. In some cases, it plays a regulatory role in gene expression (e.g., alternate fates of PrP), and in other cases, it plays a role as a specialized assembly line for biogenesis of proteins with unusual properties. It seems likely that many other examples of proteins using these two mechanisms will be found, as well as entirely different variations on the mechanisms of protein biogenesis. A common conceptual theme is likely to be that they are all directed by discrete sequences within the particular newly synthesized proteins engaging both/either the common and/or distinctive component of the cellular machinery for protein biogenesis.     

Signal-anchor domains of proteins of the outer membrane of mitochondria: structural and functional characteristics

We have studied the topogenesis of a class of mitochondrial outer membrane proteins that expose a hydrophilic domain to the cytosol and are anchored to the membrane by a single transmembrane domain in the N-terminal region. To determine the role of these latter sequences in the targeting and insertion of such proteins we took two approaches. First, a functional complementation assay was used to define the structural elements that together with the anchor domain make up the topogenic signal. Moderate hydrophobicity of the transmembrane domain was found to be the most important requirement. Variants with a scrambled sequence of the membrane-spanning segment were only partially functional suggesting that specificity in the amino acid sequence is also of considerable importance. A net positive charge at both flanking regions of the transmembrane domain contributes to the efficiency of targeting and membrane integration but is not an essential structural feature of this signal. Second, chimeras of Tom20, Tom70, and OM45 were generated that contained the cytosolic domain of Tom20 or Tom70 and the anchor domain of one of the other members of the class. These hybrid proteins were able to rescue the growth of cells lacking Tom20 or Tom70. Thus, anchor domains of outer membrane proteins are functionally interchangeable. They play only a minor role in the specific function of these proteins, but have a decisive role in topogenic signaling.     

Redundancy of signal and anchor functions in the NH2-terminal uncharged region of influenza virus neuraminidase, a class II membrane glycoprotein

Class II membrane glycoproteins share a common topology of the NH2 terminus inside and the COOH terminus outside the cell. Their transport to the cell surface is initiated by the function of a single hydrophobic domain near the NH2 terminus. This functional domain serves both as an uncleaved signal sequence and as a transmembrane anchor. We examined the signal and anchor functions of influenza virus neuraminidase, a prototype class II membrane glycoprotein, by deletion analysis of its long, uncharged amino-terminal region. The results presented here show that the entire stretch of 29 uncharged amino acids (7 to 35) is not required for either a signal sequence or an anchor sequence function. On the basis of translocation and membrane stability data for different mutants, we suggest that the first 20 amino acid residues (7 to 27) are likely to provide the hydrophobic core for these functions and that within this putative subdomain some sequences are more efficient than the other sequences in providing a translocation function. Finally, it appears that neuraminidase and its mutant proteins are translocated with the proper orientation, regardless of the characteristics of the flanking sequences.