Probing the environment of signal-anchor sequences during topogenesis in the endoplasmic reticulum

Signal sequences for insertion of protein into the mammalian endoplasmic reticulum orient themselves in the translocon on the basis of their flanking charges. It has recently been shown that hydrophobic N-terminal signals initially insert head-on before they invert their orientation to translocate the C-terminus. The rate of inversion is reduced with the increasing hydrophobicity of the signal due to an increased affinity for the initial bound state at the translocon. To probe the environment of the signal while its orientation is determined, different hydrophobic residues were inserted at various positions throughout a uniform oligoleucine signal sequence and the constructs were expressed in transfected COS-7 cells. The resulting topologies revealed a strikingly symmetric position dependence specifically for bulky aromatic amino acids, reflecting the structure of a lipid bilayer. Maximal N-translocation was observed when the guest residues were placed at the N- or C-terminus of the hydrophobic sequence or in the very center, corresponding to the positions of highest expected affinity of the signal sequence as a membrane-spanning helix for the bilayer. The results support the model that during topogenesis in vivo the signal sequence is exposed to the lipid membrane.     

TRAP assists membrane protein topogenesis at the mammalian ER membrane

Membrane protein insertion and topogenesis generally occur at the Sec61 translocon in the endoplasmic reticulum membrane. During this process, membrane spanning segments may adopt two distinct orientations with either their N- or C-terminus translocated into the ER lumen. While different topogenic determinants in membrane proteins, such as flanking charges, polypeptide folding, and hydrophobicity, have been identified, it is not well understood how the translocon and/or associated components decode them. Here we present evidence that the translocon-associated protein (TRAP) complex is involved in membrane protein topogenesis in vivo. Small interfering RNA (siRNA)-mediated silencing of the TRAP complex in HeLa cells enhanced the topology effect of mutating the flanking charges of a signal-anchor, but not of increasing signal hydrophobicity. The results suggest a role of the TRAP complex in moderating the ‘positive-inside’ rule.     

Characterization of the signal that directs Tom20 to the mitochondrial outer membrane

Tom20 is a major receptor of the mitochondrial preprotein translocation system and is bound to the outer membrane through the NH(2)-terminal transmembrane domain (TMD) in an Nin-Ccyt orientation. We analyzed the mitochondria-targeting signal of rat Tom20 (rTom20) in COS-7 cells, using green fluorescent protein (GFP) as the reporter by systematically introducing deletions or mutations into the TMD or the flanking regions. Moderate TMD hydrophobicity and a net positive charge within five residues of the COOH-terminal flanking region were both critical for mitochondria targeting. Constructs without net positive charges within the flanking region, as well as those with high TMD hydrophobicity, were targeted to the ER-Golgi compartments. Intracellular localization of rTom20-GFP fusions, determined by fluorescence microscopy, was further verified by cell fractionation. The signal recognition particle (SRP)-induced translation arrest and photo-cross-linking demonstrated that SRP recognized the TMD of rTom20-GFP, but with reduced affinity, while the positive charge at the COOH-terminal flanking segment inhibited the translation arrest. The mitochondria-targeting signal identified in vivo also functioned in the in vitro system. We conclude that NH(2)-terminal TMD with a moderate hydrophobicity and a net positive charge in the COOH-terminal flanking region function as the mitochondria-targeting signal of the outer membrane proteins, evading SRP-dependent ER targeting.     

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.     

Critical amino acids of ornitin decarboxylase degron: the presence and C-terminal arrangement is insufficient for alfa-fetoprotein degradation

Mouse ornithine decarboxylase (ODC) degrades in proteasome in an ubiquitin-independent manner with an averagehalf-life of 2 h. The 37 amino acid long C-terminal fragment known as a degradation signal (degron) is responsible for the effective degradation of ODC. Recently, amino acids being critical for degradation in the ODC-degron have been mapped. Mutations of Cys441 and Ala442 led to protein stabilization, while a substitution of other amino acids composing ODC-degron had almost no effect on the protein turnover; whereas insertions or deletions in region between Ala442 and ODC C-terminus diminished greatly rate of protein degradation, e.g. positioning of the key amino acids from the C-terminus was shown to be crucial. Using these data we introduced both key amino acids into the alfa-fetoprotein with truncated exportation signal (deltaAFP), at the same distance from the C-terminus as they being in the ODC (deltaAFPCAG and deltaAFPLCAG). Removal of N-terminal exportation signal prevented secretion of modified proteins. Using in silico approach we demonstrated no significant difference in hydrophobicity or secondary structure between C-terminus of deltaAFP and mutated proteins. The degradation kinetics of deltaAFP, deltaAFPCAG, deltaAFPLCAG in cyloheximide-chase and proteasome inhibition assay (using MG132) was identical. Obtained results suggest that introduced substitutions are insufficient for effective recognition of mutated deltaAFP by26S proteasome. We assume thatadditional amino aci ds composing ODC-degron or their combine action could also affect degradation. Besides that, one cannot exclude that conformation of the mutated deltaAFP limits its C-terminus accessibility to proteasome.     

Alteration of N-terminal residues of mature human lysozyme affects its secretion in yeast and translocation into canine microsomal vesicles

Signal sequences play a central role in the initial membrane translocation of secretory proteins. Their functions depend on factors such as hydrophobicity and conformation of the signal sequences themselves. However, some characteristics of mature proteins, especially those of the N-terminal region, might also affect the function of the signal sequences. To examine this possibility, several mutants of human lysozyme modified in the N-terminal region of the mature protein were constructed, and their secretion in yeast as well as in vitro translocation into canine pancreatic microsomes were analyzed using an idealized signal sequence L8 (MR(L)8PLAALG). Our results show the following. (1) Change in the charge at the N-terminal residue of the mature protein does not affect secretion drastically. (2) Substitution of a proline residue at the N terminus prevents cleavage of the signal sequence, although translocation itself is not impaired. (3) Excessive positive charges in the N-terminal region delay translocation of the precursor protein across the membrane. (4) Polar and negatively charged residues introduced into the N-terminal region affect the secretion of the mature protein by preventing its correct folding.     

Sec61p contributes to signal sequence orientation according to the positive-inside rule

Protein targeting to the endoplasmic reticulum is mediated by signal or signal-anchor sequences. They also play an important role in protein topogenesis, because their orientation in the translocon determines whether their N- or C-terminal sequence is translocated. Signal orientation is primarily determined by charged residues flanking the hydrophobic core, whereby the more positive end is predominantly positioned to the cytoplasmic side of the membrane, a phenomenon known as the "positive-inside rule." We tested the role of conserved charged residues of Sec61p, the major component of the translocon in Saccharomyces cerevisiae, in orienting signals according to their flanking charges by site-directed mutagenesis by using diagnostic model proteins. Mutation of R67, R74, or E382 in Sec61p reduced C-terminal translocation of a signal-anchor protein with a positive N-terminal flanking sequence and increased it for signal-anchor proteins with positive C-terminal sequences. These mutations produced a stronger effect on substrates with greater charge difference across the hydrophobic core of the signal. For some of the substrates, a charge mutation in Sec61p had a similar effect as one in the substrate polypeptides. Although these three residues do not account for the entire charge effect in signal orientation, the results show that Sec61p contributes to the positive-inside rule.     

Topogenesis of membrane proteins at the endoplasmic reticulum

Most eukaryotic membrane proteins are cotranslationally integrated into the endoplasmic reticulum membrane by the Sec61 translocation complex. They are targeted to the translocon by hydrophobic signal sequences, which induce the translocation of either their N- or their C-terminal sequence. Signal sequence orientation is largely determined by charged residues flanking the apolar sequence (the positive-inside rule), folding properties of the N-terminal segment, and the hydrophobicity of the signal. Recent in vivo experiments suggest that N-terminal signals initially insert into the translocon head-on to yield a translocated N-terminus. Driven by a local electrical potential, the signal may invert its orientation and translocate the C-terminal sequence. Increased hydrophobicity slows down inversion by stabilizing the initial bound state. In vitro cross-linking studies indicate that signals rapidly contact lipids upon entering the translocon. Together with the recent crystal structure of the homologous SecYEbeta translocation complex of Methanococcus jannaschii, which did not reveal an obvious hydrophobic binding site for signals within the pore, a model emerges in which the translocon allows the lateral partitioning of hydrophobic segments between the aqueous pore and the lipid membrane. Signals may return into the pore for reorientation until translation is terminated. Subsequent transmembrane segments in multispanning proteins behave similarly and contribute to the overall topology of the protein.     

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.     

Topology of eukaryotic type II membrane proteins: importance of N-terminal positively charged residues flanking the hydrophobic domain

We have tested the role of different charged residues flanking the sides of the signal/anchor (S/A) domain of a eukaryotic type II (N(cyt)C(exo)) integral membrane protein in determining its topology. The removal of positively charged residues on the N-terminal side of the S/A yields proteins with an inverted topology, while the addition of positively charged residues to only the C-terminal side has very little effect on orientation. Expression of chimeric proteins composed of domains from a type II protein (HN) and the oppositely oriented membrane protein M2 indicates that the HN N-terminal domain is sufficient to confer a type II topology and that the M2 N-terminal ectodomain can direct a type II topology when modified by adding positively charged residues. These data suggest that eukaryotic membrane protein topology is governed by the presence or absence of an N-terminal signal for retention in the cytoplasm that is composed in part of positive charges.     

Topogenesis of membrane proteins: determinants and dynamics

For targeting and integration of proteins into the mammalian endoplasmic reticulum, two types of signals can be distinguished: those that translocate their C-terminal sequence (cleavable signals and signal-anchors) and those that translocate their N-terminus (reverse signal-anchors). In addition to the well established effect of flanking charges, also the length and hydrophobicity of the apolar core of the signal as well as protein folding and glycosylation contribute to orienting the signal in the translocon. In multi-spanning membrane proteins, topogenic determinants are distributed throughout the sequence and may even compete with each other. During topogenesis, segments of up to 60 residues may move back and forth through the translocon, emphasizing unexpected dynamic aspects of topogenesis.     

The signal distinguishing between targeting of outer membrane β-barrel protein to plastids and mitochondria in plants

The proteome of the outer membrane of mitochondria and chloroplasts consists of membrane proteins anchored by α-helical or β-sheet elements. While proteins with α-helical transmembrane domains are present in all cellular membranes, proteins with β-barrel structure are specific for these two membranes. The organellar β-barrel proteins are encoded in the nuclear genome and thus, have to be targeted to the outer organellar membrane where they are recognized by surface exposed translocation complexes. In the last years, the signals that ensure proper targeting of these proteins have been investigated as essential base for an understanding of the regulation of cellular protein distribution. However, the organellar β-barrel proteins are unique as most of them do not contain a typical targeting information in form of an N-terminal cleavable targeting signal. Recently, it was discovered that targeting and surface recognition of mitochondrial β-barrel proteins in yeast, humans and plants depends on the hydrophobicity of the last β-hairpin of the β-barrel. However, we demonstrate that the hydrophobicity is not sufficient for the discrimination of targeting to chloroplasts or mitochondria. By domain swapping between mitochondrial and chloroplast targeted β-barrel proteins atVDAC1 and psOEP24 we demonstrate that the presence of a hydrophilic amino acid at the C-terminus of the penultimate β-strand is required for mitochondrial targeting. A mutation of the chloroplast β-barrel protein psOEP24 which mimics such profile is efficiently targeted to mitochondria. Thus, we present the properties of the signal for mitochondrial targeting of β-barrel proteins in plants.     

Calcium-Induced Folding of a Beta Roll Motif Requires C-Terminal Entropic Stabilization

Beta roll motifs are associated with several proteins secreted by the type 1 secretion system (T1SS). Located just upstream of the C-terminal T1SS secretion signal, they are believed to act as calcium-induced switches that prevent folding before secretion. Bordetella pertussis adenylate cyclase (CyaA) toxin has five blocks of beta roll motifs (or repeats-in-toxin motifs) separated by linkers. The block V motif on its own has been reported to be non-responsive to calcium. Only when the N- and C-terminal linkers, or flanking groups, were fused did the motif bind calcium and fold. In an effort to understand the requirements for beta roll folding, we have truncated the N- and C-terminal flanks at several locations to determine the minimal essential sequences. Calcium-responsive beta roll folding occurred even in the absence of the natural N-terminal flank. The natural C-terminal flank could not be truncated without decreased calcium affinity and only partially truncated before losing calcium-responsiveness. Globular protein fusion at the C-terminus likewise enabled calcium-induced folding but fusions solely at the N-terminus failed. This demonstrates that calcium-induced folding is an inherent property of the beta roll motif rather than the flanking groups. Given the disparate nature of the observed functional flanking groups, C-terminal fusions appear to confer calcium-responsiveness to the beta roll motif via a non-specific mechanism, suggesting that entropic stabilization of the unstructured C-terminus can enable beta roll folding. Increased calcium affinity was observed when the natural C-terminal flank was used to enable calcium-induced folding, pointing to its cooperative participation in beta roll formation. This work indicates that a general principle of C-terminal entropic stabilization can enable stimulus-responsive repeat protein folding, while the C-terminal flank has a specific role in tuning calcium-responsive beta roll formation. These observations are in stark contrast to what has been reported for other repeat proteins.     

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.     

A C-terminal translocation signal is necessary, but not sufficient for type IV secretion of the Helicobacter pylori CagA protein

Type IV secretion systems are increasingly recognized as important virulence determinants of Gram-negative bacterial pathogens. While the examination of several type IV-secreted proteins suggested that their secretion depends on C-terminal signals, the nature of these signals and their conservation among different systems remain unclear. Here, we have characterized the secretion signal of the Helicobacter pylori CagA protein, which is translocated by the Cag type IV secretion apparatus into eucaryotic cells. The production of fusion proteins of CagA and green fluorescent protein (GFP) did not result in translocation of GFP to epithelial cells, but a fusion of GFP with the CagA C-terminus exerted a dominant-negative effect upon wild-type CagA translocation. We show that CagA translocation depends on the presence of its 20 C-terminal amino acids, containing an array of positively charged residues. Interestingly, these positive charges are neither necessary nor sufficient for CagA translocation, but replacing the C-terminal region of CagA with that of other type IV-secreted proteins reconstitutes CagA translocation competence. Using a novel type IV translocation assay with a phosphorylatable peptide tag, we show that removal of the N-terminal part of the CagA protein renders the protein translocation-incompetent as well. Thus, the Cag type IV secretion system seems to diverge from other systems not only with respect to its composition and architecture, but also in terms of substrate recognition and transport.     

Solution structures and model membrane interactions of lactoferrampin, an antimicrobial peptide derived from bovine lactoferrin

Bovine lactoferrampin (LFampinB) has been identified as a novel antimicrobial peptide, which is derived from the N-terminal lobe of bovine lactoferrin. In this study, the solution structure of LFampinB bound to negatively charged sodium dodecyl sulphate micelles and zwitterionic dodecyl phosphocholine micelles was determined using 2-dimensional nuclear magnetic resonance (NMR) spectroscopy. The interaction between LFampinB and multilamellar phospholipid vesicles, containing choline and glycerol head groups, was examined using differential scanning calorimetry (DSC). In addition, the interaction between the N-terminal tryptophan residue and model membranes of varying composition was analyzed by fluorescence spectroscopy. LFampinB adopts an amphipathic alpha-helical conformation across the first 11 residues of the peptide but remains relatively unstructured at the C-terminus. The hydrophobic surface of the amphipathic helix is bordered by the side chains of Trp1 and Phe11, and is seen in both micelle-bound structures. The fluorescence results suggest that Trp1 inserts into the membrane at the lipid/water interface. The phenyl side chain of Phe11 is oriented in the same direction as the indole ring of Trp1, allowing these two residues to serve as anchors for the lipid bilayer. The DSC results also indicate that LFampinB interacts with glycerol head groups in multilamellar vesicles but has little effect on acyl chain packing. Our results support a two step model of antimicrobial activity where the initial attraction of LFampinB is mediated by the cluster of positive charges on the C-terminus followed by the formation of the N-terminal helix which binds to the surface of the bacterial lipid bilayer.     

Solution structures and model membrane interactions of lactoferrampin, an antimicrobial peptide derived from bovine lactoferrin

Bovine lactoferrampin (LFampinB) has been identified as a novel antimicrobial peptide, which is derived from the N-terminal lobe of bovine lactoferrin. In this study, the solution structure of LFampinB bound to negatively charged sodium dodecyl sulphate micelles and zwitterionic dodecyl phosphocholine micelles was determined using 2-dimensional nuclear magnetic resonance (NMR) spectroscopy. The interaction between LFampinB and multilamellar phospholipid vesicles, containing choline and glycerol head groups, was examined using differential scanning calorimetry (DSC). In addition, the interaction between the N-terminal tryptophan residue and model membranes of varying composition was analyzed by fluorescence spectroscopy. LFampinB adopts an amphipathic alpha-helical conformation across the first 11 residues of the peptide but remains relatively unstructured at the C-terminus. The hydrophobic surface of the amphipathic helix is bordered by the side chains of Trp1 and Phe11, and is seen in both micelle-bound structures. The fluorescence results suggest that Trp1 inserts into the membrane at the lipid/water interface. The phenyl side chain of Phe11 is oriented in the same direction as the indole ring of Trp1, allowing these two residues to serve as anchors for the lipid bilayer. The DSC results also indicate that LFampinB interacts with glycerol head groups in multilamellar vesicles but has little effect on acyl chain packing. Our results support a two step model of antimicrobial activity where the initial attraction of LFampinB is mediated by the cluster of positive charges on the C-terminus followed by the formation of the N-terminal helix which binds to the surface of the bacterial lipid bilayer.     

Targeting of proteins derived from self-processing polyproteins containing multiple signal sequences

The 18aa 2A self-cleaving oligopeptide from foot-and-mouth disease virus can be used for co-expression of multiple, discrete proteins from a single ORF. 2A mediates a co-translational cleavage at its own C-terminus and is proposed to manipulate the ribosome into skipping the synthesis of a specific peptide bond (producing a discontinuity in the peptide backbone), rather than being involved in proteolysis. To explore the utility of the system to target discrete processing products, self-processing polyproteins comprising fluorescent proteins flanking 2A were constructed, permutating both the type of signal sequence and the location within the polyprotein. A polyprotein comprising a protein bearing an N-terminal signal sequence, 2A, then a protein lacking any signal sequence, was constructed. Interestingly, both proteins were translocated into the endoplasmic reticulum. Despite the discontinuity in the peptide backbone, the mammalian ribosome:translocon complex did not disassemble--the second protein (lacking any signal) 'slipstreamed' through the translocon formed by the first (signal-bearing) protein. These polyprotein systems provide a novel method of targeting proteins to different subcellular sites by transfection with a plasmid encoding a single ORF. The inclusion of a fluorescent reporter enables visualisation of expression levels, whilst inclusion of a selectable marker enables stable cell-lines to be established rapidly.     

Characterization of signal that directs C-tail-anchored proteins to mammalian mitochondrial outer membrane

We analyzed the signal that directs the outer membrane protein with the C-terminal transmembrane segment (TMS) to mammalian mitochondria by using yeast Tom5 as a model and green fluorescent protein as a reporter. Deletions or mutations were systematically introduced into the TMS or the flanking regions and their intracellular localization in COS-7 cells was examined using confocal microscopy and cell fractionation. 1) Three basic amino acid residues within the C-terminal five-residue segment (C-segment) contained the information required for mitochondrial-targeting. Reduction of the net positive charge in this segment decreased mitochondrial specificity, and the mutants were distributed throughout the intracellular membranes. 2) Elongation of the TMS interfered with the function of the C-segment and the mutants were delivered to the intracellular membranes. 3) Separation of the TMS and C-segment by linker insertion severely impaired mitochondrial targeting function, leading to mislocalization to the cytoplasm. 4) Mutations or small deletions in the region of the TMS flanking the C-segment also impaired the mitochondrial targeting. Therefore, the moderate length of the TMS, the positive charges in the C-segment, and the distance between or context of the TMS and C-segment are critical for the targeting signal. The structural characteristics of the signal thus defined were also confirmed with mammalian C-tail-anchored protein OMP25.     

The requirement of a positive charge at the amino terminus can be compensated for by a longer central hydrophobic stretch in the functioning of signal peptides.

A variety of model presecretory proteins, proOmpF-Lpps, possessing different numbers of lysine residues (0, 2, and 4) as positively charged amino acid residues and different numbers of leucine residues (7, 8, and 9) as hydrophobic amino acid residues in their signal peptides were constructed. The effect of positive charges on the in vitro translocation efficiency markedly differed with the number of leucine residues. Positive charges were strongly required for translocation when the hydrophobic region comprised 7 or 8 leucine residues, whereas the translocation of proOmpF-Lpps possessing 9 leucine residues took place efficiently even in the absence of positive charges and the introduction of positive charges did not significantly enhance the translocation efficiency. The translocation of all the proOmpF-Lpps, including one possessing no positive charge, was ATP-, protonmotive force-, and SecA-dependent and accompanied by signal peptide cleavage, indicating that they are translocated via the usual secretory pathway. It is likely that the requirement of positive charges can be compensated for by a longer hydrophobic stretch in the functioning of the signal peptide.