The polar region consecutive to the HIV fusion peptide participates in membrane fusion

The fusion peptide of HIV-1 gp41 is formed by the 16 N-terminal residues of the protein. This 16-amino acid peptide, in common with several other viral fusion peptides, caused a reduction in the bilayer to hexagonal phase transition temperature of dipalmitoleoylphosphatidylethanolamine (T(H)), suggesting its ability to promote negative curvature in membranes. Surprisingly, an elongated peptide corresponding to the 33 N-terminal amino acids raised T(H), although it was more potent than the 16-amino acid fusion peptide in inducing lipid mixing with large unilamellar liposomes of 1:1:1 dioleoylphosphatidylethanolamine/dioleoylphosphatidylcholine/choleste rol. The 17-amino acid C-terminal fragment of the peptide can induce membrane fusion by itself, if it is anchored to a membrane by palmitoylation of the amino terminus, indicating that the additional 17 hydrophilic amino acids contribute to the fusogenic potency of the peptide. This is not solely a consequence of the palmitoylation, as a random peptide with the same amino acid composition with a palmitoyl anchor was less potent in promoting membrane fusion and palmitic acid itself had no fusogenic activity. The 16-amino acid N-terminal fusion peptide and the longer 33-amino acid peptide were labeled with NBD. Fluorescence binding studies indicate that both peptides bind to the membrane with similar affinities, indicating that the increased fusogenic activity of the longer peptide was not a consequence of a greater extent of membrane partitioning. We also determined the secondary structure of the peptides using FTIR spectroscopy. We find that the amino-terminal fusion peptide is inserted into the membrane as a beta-sheet and the 17 C-terminal amino acids lie on the surface of the membrane, adopting an alpha-helical conformation. It was further demonstrated with the use of rhodamine-labeled peptides that the 33-amino acid peptide self-associated in the membrane while the 16-amino acid N-terminal peptide did not. Thus, the 16-amino acid N-terminal fusion peptide of HIV inserts into the membrane and, like other viral fusion peptides, lowers T(H). In addition, the 17 consecutive amino acids enhance the fusogenic activity of the fusion peptide presumably by promoting its self-association.     

The C-terminal domain of yeast Ero1p mediates membrane localization and is essential for function.

In eukaryotes, members of the Ero1 family control oxidative protein folding in the endoplasmic reticulum (ER). Yeast Ero1p is tightly associated with the ER membrane, despite cleavage of the leader peptide, the only hydrophobic sequence that could mediate lipid insertion. In contrast, human Ero1-Lalpha and a yeast mutant (Ero1pDeltaC) lacking the 127 C-terminal amino acids are soluble when expressed in yeast. Neither Ero1-Lalpha nor Ero1pDeltaC complements an ERO1 disrupted strain. Appending the yeast C-terminal tail to human Ero1-Lalpha restores membrane association and allows growth of ERO1 disrupted cells. Therefore, the tail of Ero1p mediates membrane association and is crucial for function.     

Topology and membrane association of lecithin: retinol acyltransferase

Fatty acid retinyl esters are the storage form of vitamin A (all-trans-retinol) and serve as metabolic intermediates in the formation of the visual chromophore 11-cis-retinal. Lecithin:retinol acyltransferase (LRAT), the main enzyme responsible for retinyl ester formation, acts by transferring an acyl group from the sn-1 position of phosphatidylcholine to retinol. To define the membrane association and localization of LRAT, we produced an LRAT-specific monoclonal antibody, which we used to study enzyme partition under different experimental conditions. Furthermore, we examined the membrane topology of LRAT through an N-linked glycosylation scanning approach and protease protection assays. We show that LRAT is localized to the membrane of the endoplasmic reticulum (ER) and assumes a single membrane-spanning topology with an N-terminal cytoplasmic/C-terminal luminal orientation. In eukaryotic cells, the C-terminal transmembrane domain is essential for the activity and ER membrane targeting of LRAT. In contrast, the N-terminal hydrophobic region is not required for ER membrane targeting or enzymatic activity, and its amino acid sequence is not conserved in other species examined. We present experimental evidence of the topology and subcellular localization of LRAT, a critical enzyme in vitamin A metabolism.     

Cloning, nucleotide sequence, and expression of Achromobacter protease I gene

Achromobacter protease I (API) is a lysine-specific serine protease which hydrolyzes specifically the lysyl peptide bond. A gene coding for API was cloned from Achromobacter lyticus M497-1. Nucleotide sequence of the cloned DNA fragment revealed that the gene coded for a single polypeptide chain of 653 amino acids. The N-terminal 205 amino acids, including signal peptide and the threonine/serine-rich C-terminal 180 amino acids are flanking the 268 amino acid-mature protein which was identified by protein sequencing. Escherichia coli carrying a plasmid containing the cloned API gene overproduced and secreted a protein of Mr 50,000 (API') into the periplasm. This protein exhibited a distinct endopeptidase activity specific for lysyl bonds as well. The N-terminal amino acid sequence of API' was the same as mature API, suggesting that the enzyme retained the C-terminal extended peptide chain. The present experiments indicate that API, an extracellular protease produced by gram-negative bacteria, is synthesized in vivo as a precursor protein bearing long extended peptide chains at both N and C termini.     

A second lysine-specific serine protease from Lysobacter sp. strain IB-9374

A second lysyl endopeptidase gene (lepB) was found immediately upstream of the previously isolated lepA gene encoding a highly active lysyl endopeptidase in Lysobacter genomic DNA. The lepB gene consists of 2,034 nucleotides coding for a protein of 678 amino acids. Amino acid sequence alignment between the lepA and lepB gene products (LepA and LepB) revealed that the LepB precursor protein is composed of a prepeptide (20 amino acids [aa]), a propeptide (184 aa), a mature enzyme (274 aa), and a C-terminal extension peptide (200 aa). The mature enzyme region exhibited 72% sequence identity to its LepA counterpart and conserved all essential amino acids constituting the catalytic triad and the primary determining site for lysine specificity. The lepB gene encoding the propeptide and mature-enzyme portions was overexpressed in Escherichia coli, and the inclusion body produced generated active LepB through appropriate refolding and processing. The purified enzyme, a mature 274-aa lysine-specific endopeptidase, was less active and more sensitive to both temperature and denaturation with urea, guanidine hydrochloride, or sodium dodecyl sulfate than LepA. LepA-based modeling implies that LepB can fold into essentially the same three-dimensional structure as LepA by placing a peptide segment, composed of several inserted amino acids found only in LepB, outside the molecule and that the Tyr169 side chain occupies the site in which the indole ring of Trp169, a built-in modulator for unique peptidase functions of LepA, resides. The results suggest that LepB is an isozyme of LepA and probably has a tertiary structure quite similar to it.     

The role of 11β-hydroxysteroid dehydrogenase in steroid hormone specificity

11β-hydroxysteroid dehydrogenase (11β-HSD) is thought to confer aldosterone specificity to mineralocorticoid target cells by protecting the mineralocorticoid receptor (MR) from occupancy by endogenous glucocorticoids. In aldosterone target cells the type 2 11β-HSD is present, which, in contrast to the type 1 11β-HSD, has very high affinity for its substrate, is unidirectional and prefers NAD as cofactor. cDNAs encoding 11β-HSD2 have been recently cloned from different species, and the cell-specific expression of its mRNA and protein were determined. 11β-HSD2 is expressed in every aldosterone target tissue. Northern analysis revealed that the rabbit 11β-HSD2 is expressed at high levels in the renal collecting duct and at much lower levels in the colon. RT-PCR experiments demonstrated that 11β-HSD2 mRNA is present only in aldosterone target cells within the kidney. We determined the subcellular localization of the rabbit 11β-HSD2 using a chimera encoding 11β-HSD2 and the green fluorescent protein (GFP). This construct was stably transfected into CHO and MDCK cells. The expressed 11β-HSD2/GFP protein retained high enzymatic activity, and its characteristics were undistinguishable from those of the native enzyme. The intracellular localization of this protein was determined by fluorescence microscopy. 11β-HSD2-associated fluorescence was observed as a reticular network over the cytoplasm whereas the plasma membrane and the nucleus were negative, suggesting endoplasmic reticulum (ER) localization. Co-staining with markers for ER proteins, the Golgi membrane, mitochondria and nucleus confirmed that 11β-HSD2 is localized exclusively to the ER. To determine what structural motifs are responsible for the ER localization, we generated deletion mutants missing the C-terminal 42 and 118 amino acids, and fused them to GFP. Similarly as with the intact 11β-HSD2, these mutants localized exclusively to the ER. Both C-terminal deletion mutants completely lost dehydrogenase activity, independently whether activity was determined in intact cells or homogenates. These results indicate that 11β-HSD2 has a novel ER retrieval signal which is not localized to the C-terminal region. In addition, the C-terminal 118 amino acids are essential for NAD-dependent 11β-HSD activity.     

Photoaffinity labeling study of the interaction of calmodulin with the plasma membrane Ca2+ pump.

Bovine brain calmodulin was labeled with synthetic peptides corresponding to the calmodulin-binding domain of the erythrocyte plasma membrane Ca(2+)-ATPase. One 20-amino acid peptide and two 28-amino acid peptides were used, carrying L-4'-(1-azi-2,2,2-trifluoroethyl)phenylalanine residues in position 9 (peptides C20W* and C28W*) and position 25 (peptide C28WC*), respectively. The localization of the contact regions between calmodulin and the N- and C-terminal portions of the peptides was the aim of this study. The three peptides were N-terminally blocked with a 3H-labeled acetyl group to facilitate the identification of labeled fragments after isolation and digestion. The binding site for phenylalanine 25 was identified in the N-terminal domain of calmodulin while the phenylalanine derivative in position 9 labeled the C-terminal domain. Fluorescence studies using the dansylated N- and C-terminal halves of calmodulin and peptide C20W corresponding to the first 20 amino acids of the calmodulin-binding domain showed that only the C-terminal lobe of calmodulin had high affinity for the peptide (KD in the nanomolar range).     

Foreign transmembrane peptides replacing the internal signal sequence of transferrin receptor allow its translocation and membrane binding

Each subunit of the human transferrin receptor (TR) dimer is inserted into the ER membrane as a transmembrane polypeptide having its N-terminus in the cytoplasm. The transmembrane segment of the molecule serves both as a signal for chain translocation and as a membrane anchor. To study which structural features of this segment are required for its dual function, we have essentially replaced the transmembrane peptide with the C-terminal membrane-spanning segment of two proteins having a separate N-terminal translocation signal and with an artificial uncharged peptide. In each case the mutant TR molecules are efficiently translocated in vitro. In contrast, substitution of the transmembrane peptide of TR with a hydrophilic peptide results in no detectable translocation activity of the mutant TR. This suggests that the hydrophobic character of the transmembrane peptide of TR, rather than its actual amino acid sequence, is important for chain translocation and membrane binding.     

Beyond KDEL: the role of positions 5 and 6 in determining ER localization

The C-terminal amino acid sequence of a protein plays an important role in determining the endoplasmic reticulum (ER) localization of many soluble proteins that enter the secretory pathway. While it is known that the four amino acids found at the extreme C-terminus of the protein (e.g., KDEL) play a critical role in the interaction with the receptors that mediate retrograde transport back to the ER, other factors within the protein are less well known. Here we show that positions − 5 and − 6 play an important role in determining the ER localization of soluble proteins, with the amino acids at these positions playing an essential role in ER localization of the human protein disulfide isomerase family member, ERp18. Three other naturally occurring C-terminal motifs were also found that work efficiently in ER localization as six-amino-acid variants, but inefficiently as the four-amino-acid variant. Using bimolecular fluorescence complementation, we demonstrate that positions − 5 and − 6 from the C-terminus of the protein play an important role in the recognition of KDEL-like ER retrieval motifs, with the three different human KDEL receptors showing different specificities for changes at these positions for both inefficient and efficient ER localization four-amino-acid motifs.     

Frog Virus 3 Open Reading Frame 97R Localizes to the Endoplasmic Reticulum and Induces Nuclear Invaginations

Frog virus 3 (FV3) is the type species of the genus Ranavirus, family Iridoviridae. The genome of FV3 is 105,903 bases in length and encodes 97 open reading frames (ORFs). The FV3 ORF 97R contains a B-cell lymphoma 2 (Bcl-2) homology 1 (BH1) domain and has sequence similarity to the myeloid cell leukemia-1 (Mcl-1) protein, suggesting a potential role in apoptosis. To begin to understand the role of 97R, we characterized 97R through immunofluorescence and mutagenesis. Here we demonstrated that 97R localized to the endoplasmic reticulum (ER) at 24 h posttransfection. However, at 35 h posttransfection, 97R localized to the ER but also began to form concentrated pockets continuous with the nuclear membrane. After 48 h posttransfection, 97R was still localized to the ER, but we began to observe the ER and the outer nuclear membrane invaginating into the nucleus. To further explore 97R targeting to the ER, we created a series of C-terminal transmembrane domain deletion mutants. We found that deletion of 29 amino acids from the C terminus of 97R abolished localization to the ER. In contrast, deletion of 12 amino acids from the C terminus of 97R did not affect 97R localization to the ER. In addition, a hybrid protein containing the 97R C-terminal 33 amino acids was similarly targeted to the ER. These data indicate that the C-terminal 33 amino acids of 97R are necessary and sufficient for ER targeting.     

Two hydrophobic segments of the RTN1 family determine the ER localization and retention

Reticulon (RTN) proteins are localized to the endoplasmic reticulum (ER), and are related to intracellular membrane trafficking, apoptosis, inhibiting axonal regeneration, and Alzheimer's disease. The RTN proteins are produced without an N-terminal signal peptide. Their C-terminal domain contains two long hydrophobic segments. We analyzed the ER localization signal of human RTN1-A. Mutant proteins lacking the first (39 residues) or second (36 residues) hydrophobic segment showed ER localization. On the other hand, the mutant lacking both hydrophobic segments was cytosolic. Enhanced green fluorescent protein (EGFP) tagged with the first or second hydrophobic segment of RTN1-A was localized to the ER. These results suggest that each hydrophobic segment determines the ER localization. In addition, EGFP tagged with the truncated form of the first hydrophobic segment exhibited the localization to the Golgi rather than the ER. This suggests that the length of the hydrophobic segment contributes to the ER retention of RTN1-A.     

Metabolic instability of type 2 deiodinase is transferable to stable proteins independently of subcellular localization

Thyroid hormone activation is catalyzed by two deiodinases, D1 and D2. Whereas D1 is a stable plasma membrane protein, D2 is resident in the endoplasmic reticulum (ER) and has a 20-min half-life due to selective ubiquitination and proteasomal degradation. Here we have shown that stable retention explains D2 residency in the ER, a mechanism that is nevertheless over-ridden by fusion to the long-lived plasma membrane protein, sodium-iodine symporter. Fusion to D2, but not D1, dramatically shortened sodium-iodine symporter half-life through a mechanism dependent on an 18-amino acid D2-specific instability loop. Similarly, the D2-specific loop-mediated protein destabilization was also observed after D2, but not D1, was fused to the stable ER resident protein SEC62. This indicates that the instability loop in D2, but not its subcellular localization, is the key determinant of D2 susceptibility to ubiquitination and rapid turnover rate. Our data also show that the 6 N-terminal amino acids, but not the 12 C-terminal ones, are the ones required for D2 recognition by WSB-1.     

Characterization of a unique group-specific protein (U122) of the severe acute respiratory syndrome coronavirus

A novel coronavirus (CoV) has been identified as the etiological agent of severe acute respiratory syndrome (SARS). The SARS-CoV genome encodes the characteristic essential CoV replication and structural proteins. Additionally, the genome contains six group-specific open reading frames (ORFs) larger than 50 amino acids, with no known homologues. As with the group-specific genes of the other CoVs, little is known about the SARS-CoV group-specific genes. SARS-CoV ORF7a encodes a putative unique 122-amino-acid protein, designated U122 in this study. The deduced sequence contains a probable cleaved signal sequence and a C-terminal transmembrane helix, indicating that U122 is likely to be a type I membrane protein. The C-terminal tail also contains a typical endoplasmic reticulum (ER) retrieval motif, KRKTE. U122 was expressed in SARS-CoV-infected Vero E6 cells, as it could be detected by Western blot and immunofluorescence analyses. U122 is localized to the perinuclear region of both SARS-CoV-infected and transfected cells and colocalized with ER and intermediate compartment markers. Mutational analyses showed that both the signal peptide sequence and ER retrieval motif were functional.     

Identification of conserved amino acids N-terminal of the PKC epsilon C1b domain crucial for protein kinase C epsilon-mediated induction of neurite outgrowth

We have shown previously that protein kinase C (PKC) epsilon can induce neurite outgrowth independently of its catalytic activity via a region encompassing its C1 domains. In this study we aimed at identifying specific amino acids in this region crucial for induction of neurite outgrowth. Deletion studies demonstrated that only 4 amino acids N-terminal and 20 residues C-terminal of the C1 domains are necessary for neurite induction. The corresponding regions from all other novel isoforms but not from PKCalpha were also neuritogenic. Further mutation studies indicated that amino acids immediately N-terminal of the C1a domain are important for plasma membrane localization and thereby for neurite induction. Addition of phorbol ester made this construct neurite-inducing. However, mutation of amino acids flanking the C1b domain reduced the neurite-inducing capacity even in the presence of phorbol esters. Sequence alignment highlighted an 8-amino acid-long sequence N-terminal of the C1b domain that is conserved in all novel PKC isoforms. Specifically, we found that mutations of either Phe-237, Val-239, or Met-241 in PKCepsilon completely abolished the neurite-inducing capacity of PKCepsilon C1 domains. Phorbol ester treatment could not restore neurite induction but led to a plasma membrane translocation. Furthermore, if 12 amino acids were included N-terminal of the C1b domain, the C1a domain was dispensable for neurite induction. In conclusion, we have identified a highly conserved sequence N-terminal of the C1b domain that is crucial for neurite induction by PKCepsilon, indicating that this motif may be critical for some morphological effects of PKC.     

Intramembrane proteolysis and endoplasmic reticulum retention of hepatitis C virus core protein

Hepatitis C virus (HCV) core protein is suggested to localize to the endoplasmic reticulum (ER) through a C-terminal hydrophobic region that acts as a membrane anchor for core protein and as a signal sequence for E1 protein. The signal sequence of core protein is further processed by signal peptide peptidase (SPP). We examined the regions of core protein responsible for ER retention and processing by SPP. Analysis of the intracellular localization of deletion mutants of HCV core protein revealed that not only the C-terminal signal-anchor sequence but also an upstream hydrophobic region from amino acid 128 to 151 is required for ER retention of core protein. Precise mutation analyses indicated that replacement of Leu(139), Val(140), and Leu(144) of core protein by Ala inhibited processing by SPP, but cleavage at the core-E1 junction by signal peptidase was maintained. Additionally, the processed E1 protein was translocated into the ER and glycosylated with high-mannose oligosaccharides. Core protein derived from the mutants was translocated into the nucleus in spite of the presence of the unprocessed C-terminal signal-anchor sequence. Although the direct association of core protein with a wild-type SPP was not observed, expression of a loss-of-function SPP mutant inhibited cleavage of the signal sequence by SPP and coimmunoprecipitation with unprocessed core protein. These results indicate that Leu(139), Val(140), and Leu(144) in core protein play crucial roles in the ER retention and SPP cleavage of HCV core protein.     

Characterization of the C-terminal ER membrane anchor of PTP1B

The tyrosine phosphatase PTP1B is an important regulator of cell function. In living cells PTP1B activity is restricted to the vicinity of the endoplasmic reticulum (ER) by post-translational C-terminal attachment of PTP1B to the ER membrane network. In our study we investigated the membrane anchor of PTP1B by use of EGFP fusion proteins. We demonstrate that the membrane anchor of PTP1B cannot be narrowed down to a unique amino acid sequence with a defined start and stop point but rather is moveable within several amino acids. Removal of up to seven amino acids from the C-terminus, as well as exchange of single amino acids in the putative transmembrane sequence did not influence subcellular localization of PTP1B. With the method of bimolecular fluorescence complementation we could demonstrate dimerization of PTP1B in vivo. Homodimerization was, in contrast to other tail-anchored proteins, not dependent on the membrane anchor. Our data demonstrate that the C-terminal membrane anchor of PTP1B is formed by a combination of a single stretch transmembrane domain (TMD) followed by a tail. TMD and tail length are variable and there are no sequence-specific features. Our data for PTP1B are consistent with a concept that explains the ER membrane anchor of tail-anchored proteins as a physicochemical structure.     

Dimerization of human lysyl hydroxylase 3 (LH3) is mediated by the amino acids 541-547

Lysyl hydroxylases (LH), which catalyze the post-translational modifications of lysines in collagen and collagen-like proteins, function as dimers. However, the amino acids responsible for dimerization and the role of dimer formation in the enzymatic activities of LH have not yet been identified. We have localized the region responsible for the dimerization of lysyl hydroxylase 3 (LH3), a multifunctional enzyme of collagen biosynthesis, to a sequence of amino acids between the glycosyltransferase activity and the lysyl hydroxylase activity domains. This area is covered by amino acids 541-547 in human LH3, but contains no cysteine residues. The region is highly conserved among LH isoforms, and is also involved in the dimerization of LH1 subunits. Dimerization is required for the LH activity of LH3, whereas it is not obligatory for the glycosyltransferase activities. In order to determine whether complex formation can occur between LH molecules originating from different species, and between different LH isoforms, double expressions were generated in a baculovirus system. Heterocomplex formation between mouse and human LH3, between human LH1 and LH3 and between human LH2 and LH3 was detected by western blot analyses. However, due to the low amount of complexes formed, the in vivo function of heterocomplexes remains unclear.     

Requirements for mouse mammary tumor virus Rem signal peptide processing and function

Mouse mammary tumor virus (MMTV) encodes a Rev-like protein, Rem, which is involved in the nuclear export and expression of viral RNA. Previous data have shown that all Rev-like functions are localized to the 98-amino-acid signal peptide (SP) at the N terminus of MMTV Rem or envelope proteins. MMTV-SP uses endoplasmic reticulum-associated degradation (ERAD) for protein trafficking. Rem cleavage by signal peptidase in the ER is necessary for MMTV-SP function in a reporter assay, but many requirements for trafficking are not known. To allow detection and localization of both MMTV-SP and the C-terminal cleavage product, we prepared plasmids expressing green fluorescent protein (GFP) tags. N-terminal Rem tagging led to protein accumulation relative to untagged Rem and allowed signal peptidase cleavage but reduced its specific activity. C-terminal tagging also led to Rem accumulation yet dramatically reduced cleavage, GFP fluorescence, and activity relative to N-terminally tagged Rem (GFPRem). Substitutions of an invariant leucine at position 71 between the known RNA-binding and nuclear export sequences interfered with GFPRem accumulation and activity but not cleavage. Similarly, deletion of 100 or 150 C-terminal amino acids from GFPRem dramatically reduced both Rem and MMTV-SP levels and function. Removal of the entire C terminus (203 amino acids) restored both protein levels and activity of MMTV-SP. Only C-terminal GFP tagging, and not other modifications, appeared to trap Rem in the ER membrane. Thus, Rem conformation in both the ER lumen and cytoplasm determines cleavage, retrotranslocation, and MMTV-SP function. These mutants further characterize intermediates in Rem trafficking and have implications for all proteins affected by ERAD.     

Lysyl hydroxylase 3 (LH3) modifies proteins in the extracellular space, a novel mechanism for matrix remodeling

Lysyl hydroxylase 3 (LH3), the multifunctional enzyme associated with collagen biosynthesis that possesses lysyl hydroxylase and collagen glycosyltransferase activities, has been characterized in the extracellular space in this study. Lysine modifications are known to occur in the endoplasmic reticulum (ER) prior to collagen triple-helix formation, but in this study we show that LH3 is also present and active in the extracellular space. Studies with in vitro cultured cells indicate that LH3, in addition to being an ER resident, is secreted from the cells and is found both in the medium and on the cell surface associated with collagens or other proteins with collagenous sequences. Furthermore, in vivo, LH3 is present in serum. LH3 protein levels correlate with the galactosylhydroxylysine glucosyltransferase (GGT) activity of mouse tissues. This, together with other data, indicates that LH3 is responsible for GGT activity in the tissues and that GGT activity assays can be used to quantify LH3 in tissues. LH3 in vivo is located in two compartments, in the ER and in the extracellular space, and the partitioning varies with tissue type. In mouse kidney the enzyme is located mainly intracellularly, whereas in mouse liver it is located solely in the extracellular space. The extracellular localization and the ability of LH3 to modify lysyl residues of extracellular proteins in their native, nondenaturated conformation reveals a new dynamic in extracellular matrix remodeling, suggesting a novel mechanism for adjusting the amount of hydroxylysine and hydroxylysine-linked carbohydrates in collagenous proteins.