Topogenic properties of transmembrane segments of Arabidopsis thaliana NHX1 reveal a common topology model of the Na+/H+ exchanger family

The membrane topology of the Arabidopsis thaliana Na(+)/H(+) exchanger isoform 1 (AtNHX1) was investigated by examining the topogenic function of transmembrane (TM) segments using a cell-free system. Even though the signal peptide found in the human Na(+)/H(+) exchanger (NHE) family is missing, the N-terminal hydrophobic segment was efficiently inserted into the membrane and had an N-terminus lumen topology depending on the next TM segment. The two N-terminal TM segments had the same topology as those of TM2 and TM3 of human NHE1. In contrast, TM2 and TM3 of human NHE1 did not acquire the correct topology when the signal peptide (denoted as TM1) was deleted. Furthermore, there were three hydrophobic segments with the same topogenic properties as the TM9-H10-TM10 segments of human NHE1, which has one lumenal loop (H10) and two flanking TM segments (TM9 and TM10). These data indicate that the plant NHX isoforms can form the common membrane topology proposed for the human NHE family, even though it does not have a signal peptide.     

Competition between neighboring topogenic signals during membrane protein insertion into the ER

To better define the mechanism of membrane protein insertion into the membrane of the endoplasmic reticulum, we measured the kinetics of translocation across microsomal membranes of the N-terminal lumenal tail and the lumenal domain following the second transmembrane segment (TM2) in the multispanning mouse protein Cig30. In the wild-type protein, the N-terminal tail translocates across the membrane before the downstream lumenal domain. Addition of positively charged residues to the N-terminal tail dramatically slows down its translocation and allows the downstream lumenal domain to translocate at the same time as or even before the N-tail. When TM2 is deleted, or when the loop between TM1 and TM2 is lengthened, addition of positively charged residues to the N-terminal tail causes TM1 to adopt an orientation with its N-terminal end in the cytoplasm. We suggest that the topology of the TM1-TM2 region of Cig30 depends on a competition between TM1 and TM2 such that the transmembrane segment that inserts first into the ER membrane determines the final topology.     

Switching the sorting mode of membrane proteins from cotranslational endoplasmic reticulum targeting to posttranslational mitochondrial import

Hydrophobic membrane proteins are cotranslationally targeted to the endoplasmic reticulum (ER) membrane, mediated by hydrophobic signal sequence. Mitochondrial membrane proteins escape this mechanism despite their hydrophobic character. We examined sorting of membrane proteins into the mitochondria, by using mitochondrial ATP-binding cassette (ABC) transporter isoform (ABC-me). In the absence of 135-residue N-terminal hydrophilic segment (N135), the membrane domain was integrated into the ER membrane in COS7 cells. Other sequences that were sufficient to import soluble protein into mitochondria could not import the membrane domain. N135 imports other membrane proteins into mitochondria. N135 prevents cotranslational targeting of the membrane domain to ER and in turn achieves posttranslational import into mitochondria. In a cell-free system, N135 suppresses targeting to the ER membranes, although it does not affect recognition of hydrophobic segments by signal recognition particle. We conclude that the N135 segment blocks the ER targeting of membrane proteins even in the absence of mitochondria and switches the sorting mode from cotranslational ER integration to posttranslational mitochondrial import.     

Sequence requirements for membrane assembly of polytopic membrane proteins: molecular dissection of the membrane insertion process and topogenesis of the human MDR3 P-glycoprotein.

The biogenesis of membrane proteins with a single transmembrane (TM) segment is well understood. However, understanding the biogenesis and membrane assembly of membrane proteins with multiple TM segments is still incomplete because of the complexity and diversity of polytopic membrane proteins. In an attempt to investigate further the biogenesis of polytopic membrane proteins, I used the human MDR3 P-glycoprotein (Pgp) as a model polytopic membrane protein and expressed it in a coupled cell-free translation/translocation system. I showed that the topogenesis of the C-terminal half MDR3 Pgp molecule is different from that of the N-terminal half. This observation is similar to that of the human MDR1 Pgp. The membrane insertion properties of the TM1 and TM2 in the N-terminal half molecule are different. The proper membrane anchorage of both TM1 and TM2 of the MDR3 Pgp is affected by their C-terminal amino acid sequences, whereas only the membrane insertion of the TM1 is dependent on the N-terminal amino acid sequences. The efficient membrane insertion of TM3 and TM5 of MDR3 Pgp, on the other hand, requires the presence of the putative TM4 and TM6, respectively. The TM8 in the C-terminal half does not contain an efficient stop-transfer activity. These observations suggest that the membrane insertion of putative TM segments in the human MDR3 Pgp does not simply follow the prevailing sequential event of the membrane insertion by signal-anchor and stop-transfer sequences. These results, together with my previous findings, suggest that different isoforms of Pgp can be used in comparison as a model system to understand the molecular mechanism of topogenesis of polytopic membrane proteins.     

Targeting proteins to the lumen of endoplasmic reticulum using N-terminal domains of 11beta-hydroxysteroid dehydrogenase and the 50-kDa esterase.

Previous studies identified two intrinsic endoplasmic reticulum (ER) proteins, 11beta-hydroxysteroid dehydrogenase, isozyme 1 (11beta-HSD) and the 50-kDa esterase (E3), sharing some amino acid sequence motifs in their N-terminal transmembrane (TM) domains. Both are type II membrane proteins with the C terminus projecting into the lumen of the ER. This finding implied that the N-terminal TM domains of 11beta-HSD and E3 may constitute a lumenal targeting signal (LTS). To investigate this hypothesis we created chimeric fusions using the putative targeting sequences and the reporter gene, Aequorea victoria green fluorescent protein. Transfected COS cells expressing LTS-green fluorescent protein chimeras were examined by fluorescent microscopy and electron microscopic immunogold labeling. The orientation of expressed chimeras was established by immunocytofluorescent staining of selectively permeabilized COS cells. In addition, protease protection assays of membranes in the presence and absence of detergents was used to confirm lumenal or the cytosolic orientation of the constructed chimeras. To investigate the general applicability of the proposed LTS, we fused the N terminus of E3 to the N terminus of the NADH-cytochrome b5 reductase lacking the myristoyl group and N-terminal 30-residue membrane anchor. The orientation of the cytochrome b5 reductase was reversed, from cytosolic to lumenal projection of the active domain. These observations establish that an amino acid sequence consisting of short basic or neutral residues at the N terminus, followed by a specific array of hydrophobic residues terminating with acidic residues, is sufficient for lumenal targeting of single-pass proteins that are structurally and functionally unrelated.     

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.     

Insertion into the mitochondrial inner membrane of a polytopic protein, the nuclear-encoded Oxa1p.

Oxa1p, a nuclear-encoded protein of the mitochondrial inner membrane with five predicted transmembrane (TM) segments is synthesized as a precursor (pOxa1p) with an N-terminal presequence. It becomes imported in a process requiring the membrane potential, matrix ATP, mt-Hsp70 and the mitochondrial processing peptidase (MPP). After processing, the negatively charged N-terminus of Oxa1p (approximately 90 amino acid residues) is translocated back across the inner membrane into the intermembrane space and thereby attains its native N(out)-C(in) orientation. This export event is dependent on the membrane potential. Chimeric preproteins containing N-terminal stretches of increasing lengths of Oxa1p fused on mouse dehydrofolate reductase (DHFR) were imported into isolated mitochondria. In each case, their DHFR moieties crossed the inner membrane into the matrix. Thus Oxa1p apparently does not contain a stop transfer signal. Instead the TM segments are inserted into the membrane from the matrix side in a pairwise fashion. The sorting pathway of pOxa1p is suggested to combine the pathways of general import into the matrix with a bacterial-type export process. We postulate that at least two different sorting pathways exist in mitochondria for polytopic inner membrane proteins, the evolutionarily novel pathway for members of the ADP/ATP carrier family and a conserved Oxa1p-type pathway.     

An amino acid sequence which directs membrane insertion causes loss of membrane potential

A 55-amino acid segment, normally present between residues 241 and 295 of the 348-residue gene I protein of the filamentous bacteriophage f1, acts as an internal signal sequence for gene I protein or, when present in fusion proteins, for EcoRI endonuclease or alkaline phosphatase. The resulting proteins are inserted so that they span the membrane with sequences on the amino side of the 55-residue segment in the cytoplasm and those near the carboxy side outside the cytoplasmic membrane. The presence of these proteins in the membrane results in the rapid inhibition of cell growth, probably from a loss of the membrane potential. We describe some of the elements in this 55-residue segment that appear to be crucial for its interaction with the membrane.     

Reorientation of aquaporin-1 topology during maturation in the endoplasmic reticulum

The topology of most eukaryotic polytopic membrane proteins is established cotranslationally in the endoplasmic reticulum (ER) through a series of coordinated translocation and membrane integration events. For the human aquaporin water channel AQP1, however, the initial four-segment-spanning topology at the ER membrane differs from the mature six-segment-spanning topology at the plasma membrane. Here we use epitope-tagged AQP1 constructs to follow the transmembrane (TM) orientation of key internal peptide loops in Xenopus oocyte and cell-free systems. This analysis revealed that AQP1 maturation in the ER involves a novel topological reorientation of three internal TM segments and two peptide loops. After the synthesis of TMs 4-6, TM3 underwent a 180-degree rotation in which TM3 C-terminal flanking residues were translocated from their initial cytosolic location into the ER lumen and N-terminal flanking residues underwent retrograde translocation from the ER lumen to the cytosol. These events convert TM3 from a type I to a type II topology and reposition TM2 and TM4 into transmembrane conformations consistent with the predicted six-segment-spanning AQP1 topology. AQP1 topological reorientation was also associated with maturation from a protease-sensitive conformation to a protease-resistant structure with water channel function. These studies demonstrate that initial protein topology established via cotranslational translocation events in the ER is dynamic and may be modified by subsequent steps of folding and/or maturation.     

Defining the regions of Escherichia coli YidC that contribute to activity

The YidC/Oxa1/Alb3 family of proteins catalyzes membrane protein insertion in bacteria, mitochondria, and chloroplasts. In this study, we investigated which regions of the bacterial YidC protein are important for its function in membrane protein biogenesis. In Escherichia coli, YidC spans the membrane six times, with a large 319-residue periplasmic domain following the first transmembrane domain. We found that this large periplasmic domain is not required for YidC function and that the residues in the exposed hydrophilic loops or C-terminal tail are not critical for YidC activity. Rather, the five C-terminal transmembrane segments that contain the three consensus sequences in the YidC/Oxa1/Alb3 family are important for its function. However, by systematically replacing all the residues in transmembrane segment (TM) 2, TM3, and TM6 with serine and by swapping TM4 and TM5 with unrelated transmembrane segments, we show that the precise sequence of these transmembrane regions is not essential for in vivo YidC activity. Single serine mutations in TM2, TM3, and TM6 impaired the membrane insertion of the Sec-independent procoat-leader peptidase protein. We propose that the five C-terminal transmembrane segments of YidC function as a platform for the translocating substrate protein to support its insertion into the membrane.     

Targeting and assembly of rat mitochondrial translocase of outer membrane 22 (TOM22) into the TOM complex

Tom22 is a preprotein receptor and organizer of the mitochondrial outer membrane translocase complex (TOM complex). Rat Tom22 (rTOM22) is a 142-residue protein, embedded in the outer membrane through the internal transmembrane domain (TMD) with 82 N-terminal residues in the cytosol and 41 C-terminal residues in the intermembrane space. We analyzed the signals that target rTOM22 to the mitochondrial outer membrane and assembly into the TOM complex in cultured mammalian cells. Deletions or mutations were systematically introduced into the molecule, and the intracellular localization of the mutant constructs in HeLa cells was examined by confocal microscopy and cell fractionation. Their assembly into the TOM complex was also examined using blue native gel electrophoresis. These experiments revealed three separate structural elements: a cytoplasmic 10-residue segment with an acidic alpha-helical structure located 30 residues upstream of the TMD (the import sequence), TMD with an appropriate hydrophobicity, and a 20-residue C-terminal segment located 22 residues downstream of the TMD (C-tail signal). The import sequence and TMD were both essential for targeting and integration into the TOM complex, whereas the C-tail signal affected the import efficiency. The import sequence combined with foreign TMD functioned as a mitochondrial targeting and anchor signal but failed to integrate the construct into the TOM complex. Thus, the mitochondrial-targeting and TOM integration signal could be discriminated. A yeast two-hybrid assay revealed that the import sequence interacted with two intramolecular elements, the TMD and C-tail signal, and that it also interacted with the import receptor Tom20.     

Cooperation of transmembrane segments during the integration of a double-spanning protein into the ER membrane

While membrane insertion of single-spanning membrane proteins into the endoplasmic reticulum (ER) is relatively well understood, it is unclear how multi-spanning proteins integrate. We have investigated the cotranslational ER integration of a double-spanning protein that is derived from leader peptidase. Both transmembrane (TM) segments are inserted into the membrane by the Sec61 channel. While the first, long and hydrophobic TM segment (TM1) inserts into the lipid bilayer on its own, the second, shorter TM anchor (TM2) collaborates with TM1 during its integration. TM1 diffuses away from the Sec61 complex in the absence of TM2, but is close to Sec61 when TM2 arrives inside the channel. These data suggest that the exit of a weak TM segment from the Sec61 channel into the lipid phase can be facilitated by its interaction with a previously integrated strong and stabilizing TM anchor.     

Targeting of a Short Peptide Derived from the Cytoplasmic Tail of the G1 Membrane Glycoprotein of Uukuniemi Virus (Bunyaviridae) to the Golgi Complex

Members of the Bunyaviridae family acquire an envelope by budding through the lipid bilayer of the Golgi complex. The budding compartment is thought to be determined by the accumulation of the two heterodimeric membrane glycoproteins G1 and G2 in the Golgi. We recently mapped the retention signal for Golgi localization in one Bunyaviridae member (Uukuniemi virus) to the cytoplasmic tail of G1. We now show that a myc-tagged 81-residue G1 tail peptide expressed in BHK21 cells is efficiently targeted to the Golgi complex and retained there during a 3-h chase. Green-fluorescence protein tagged at either end with this peptide or with a C-terminally truncated 60-residue G1 tail peptide was also efficiently targeted to the Golgi. The 81-residue peptide colocalized with mannosidase II (a medial Golgi marker) and partially with p58 (an intermediate compartment marker) and TGN38 (a trans-Golgi marker). In addition, the 81-residue tail peptide induced the formation of brefeldin A-resistant vacuoles that did not costain with markers for other membrane compartments. Removal of the first 10 N-terminal residues had no effect on the Golgi localization but abolished the vacuolar staining. The shortest peptide still able to become targeted to the Golgi encompassed residues 10 to 40. Subcellular fractionation showed that the 81-residue tail peptide was associated with microsomal membranes. Removal of the two palmitylation sites from the tail peptide did not affect Golgi localization and had only a minor effect on the association with microsomal membranes. Taken together, the results provide strong evidence that Golgi retention of the heterodimeric G1-G2 spike protein complex of Uukuniemi virus is mediated by a short region in the cytoplasmic tail of the G1 glycoprotein.     

Expression of glucose-6-phosphatase system genes in murine cortex and hypothalamus.

The glucose-6-phosphatase (G6Pase) system participates in the regulation of glucose homeostasis by converting glucose-6-phosphate (G6P) into glucose and inorganic phosphates. We have used an RT-PCR-based cloning and sequencing approach to study the expression of components of the G6Pase system in the hypothalamus and cortex tissues of the ob/ob mouse. We observed the expression of hepatic G6Pase catalytic subunit, G6PC, in both tissues, although increased template inputs were required for its detection. Conversely, expression of both the mouse homologue of the previously-described brain-specific G6P translocase T1 (G6PT1) variant and of the hepatic G6PT1 isoform was easily detectable in hypothalamus and cortex tissues. Of the proposed G6Pase catalytic subunit homologues, the expression of murine ubiquitous G6Pase catalytic subunit-related protein (UGRP, G6PC3) was also easily detectable in both tissues. However, islet-specific G6Pase catalytic subunit-related protein (IGRP, G6PC2) was expressed in a tissue-specific manner, and was detectable only in hypothalamus tissue at increased template inputs. We conclude that cells within ob/ob mouse hypothalamus and cortex tissues express genes with either established or proposed roles in G6P hydrolysis.     

Charged residues are major determinants of the transmembrane orientation of a signal-anchor sequence

Uncleaved signal-anchor sequences of membrane proteins inserted into the endoplasmic reticulum initiate the translocation of either the amino-terminal or the carboxyl-terminal polypeptide segment across the bilayer. Which topology is acquired is not determined by the apolar segment of the signal but rather by the hydrophilic sequences flanking it. To study the role of charged residues in determining the membrane topology, the insertion of mutants of the asialoglycoprotein receptor H1, a single-spanning protein with a cytoplasmic amino terminus, was analyzed in transfected COS-7 cells. When the charged amino acids flanking the hydrophobic signal were mutated to residues of opposite charge, half the polypeptides inserted with the inverted orientation. When, in addition, the amino-terminal domain of the mutant protein was truncated, approximately 90% of the polypeptides acquired the inverted topology. The transmembrane orientation appears to be primarily determined by the charges flanking the signal sequence but is modulated by the domains to be translocated.     

Pleiotropic effects of membrane cholesterol upon translocation of protein across the endoplasmic reticulum membrane

Various proteins are translocated through and inserted into the endoplasmic reticulum membrane via translocon channels. The hydrophobic segments of signal sequences initiate translocation, and those on translocating polypeptides interrupt translocation to be inserted into the membrane. Positive charges suppress translocation to regulate the orientation of the signal sequences. Here, we investigated the effect of membrane cholesterol on the translocational behavior of nascent chains in a cell-free system. We found that the three distinct translocation processes were sensitive to membrane cholesterol. Cholesterol inhibited the initiation of translocation by the signal sequence, and the extent of inhibition depended on the signal sequence. Even when initiation was not inhibited, cholesterol impeded the movement of the positively charged residues of the translocating polypeptide chain. In surprising contrast, cholesterol enhanced the translocation of hydrophobic sequences through the translocon. On the basis of these findings, we propose that membrane cholesterol greatly affects partitioning of hydrophobic segments into the membrane and impedes the movement of positive charges.     

Use of six chimeric proteins to investigate the role of intramolecular interactions in determining the kinetics of carnitine palmitoyltransferase I isoforms

The two isoforms of carnitine palmitoyltransferase I (CPT I; muscle (M)- and liver (L)-type) of the mitochondrial outer membrane have distinct kinetic characteristics with respect to their affinity for one of the substrates (l-carnitine) and the inhibitor malonyl-CoA. Moreover, they differ markedly in their hysteretic behavior with respect to malonyl-CoA and in their response to changes in the in vivo metabolic state. However, the two proteins are 62% identical and have the same overall structure. Using liver mitochondria, we have previously shown that the protein is polytopic within the outer membrane, comprising a 46-residue cytosolic N-terminal sequence, two transmembrane segments (TM1 and TM2) separated by a 27-residue loop, and a large catalytic domain (also cytosolic) (Fraser, F., Corstorphine, C. G., and Zammit, V. A. (1997) Biochem. J. 323, 711-718). We have now conducted a systematic study on six chimeric proteins constructed from combinations of three linear segments of rat L- and M-CPT I and on the two parental proteins to elucidate the effects of altered intramolecular interactions on the kinetics of CPT activity. The three segments were (i) the cytosolic N-terminal domain plus TM1, (ii) the loop plus TM2, and (iii) the cytosolic catalytic C-terminal domain. The kinetic properties of the chimeric proteins expressed in Pichia pastoris were studied. We found that alterations in the combinations of the N-terminal plus TM1 and C-terminal domains as well as in the N terminus plus TM1/TM2 pairings resulted in changes in the K(m) values for carnitine and palmitoyl-CoA and the sensitivity to malonyl-CoA of the L-type catalytic domain. The changes in affinity for malonyl-CoA and palmitoyl-CoA occurred independently of changes in the affinity for carnitine. The kinetic characteristics of the M-type catalytic domain and, in particular, its malonyl-CoA sensitivity were much less susceptible to influence by exchange of the other two segments of the protein. The marked difference in the response of the two catalytic domains to changes in the N-terminal domain and TM combinations explains the previously observed differences in the response of L- and M-CPT I to altered physiological state in intact mitochondria and to modulation of altered lipid molecular order of the mitochondrial outer membrane in vivo and in vitro.