Transport of hepatitis B virus precore protein into the nucleus after cleavage of its signal peptide.

The precore and core proteins of hepatitis B virus have identical deduced amino acid sequences other than a 29-residue amino-terminal extension (precore region) on the precore protein. The first 19 of these residues serve as a signal sequence to direct the precore protein to the endoplasmic reticulum, where they are cleaved off with formation of precore protein derivative P22 for secretion. In this report, we show that P22 can alternatively be transported into the nucleus following signal peptide cleavage. Experiments with deletion mutants indicated that this nuclear transport proceeds via the cytosol and is dependent on the amino-terminal portion of P22. Thus, the hepatitis B virus precore protein is a secreted, cytosolic, and nuclear protein.     

The arginine-rich domain of hepatitis B virus precore and core proteins contains a signal for nuclear transport.

Precore and core proteins are two related co-carboxy-terminal proteins of hepatitis B virus. Precore protein contains the entire sequence of core protein plus an amino-terminal extension of 29 amino acid residues. Both proteins can display a common antigenic determinant known as core antigen (HBcAg). Clinically, HBcAg is detected in the nucleus, cytoplasm, or both of hepatitis B virus-infected hepatocytes. In order to understand the mechanism that regulates nuclear transport of HBcAg, various portions of precore and core proteins were linked to a reporter protein, human alpha-globin, and expressed in mammalian cells. Our results indicate that the precore protein-specific sequence, although important for nuclear transport, does not contain a nuclear localization signal. Instead, a signal for nuclear transport is located near the carboxy termini of precore and core proteins in the arginine-rich domain. This signal is made up of a set of two direct PRRRRSQS repeats and is highly conserved among mammalian hepadnaviruses.     

An Artificial Mitochondrial Tail Signal/Anchor Sequence Confirms a Requirement for Moderate Hydrophobicity for Targeting

Tail-anchored proteins are a group of membrane proteins oriented with their amino terminus in the cytoplasm and their carboxy terminus embedded in intracellular membranes. This group includes the apoptosis-mediating proteins of the Bcl-2 family as well as the vesicle targeting proteins of the SNARE group, among others. A stretch of hydrophobic amino acids at the extreme carboxy terminus of these proteins serves both as a membrane anchor and as a targeting signal. Tail-anchored proteins are differentially targeted to either the endoplasmic reticulum or the mitochondrial outer membrane and the mechanism which accomplishes this selective targeting is poorly understood. Here we define important characteristics of the signal/anchor region which directs proteins to the mitochondrial outer membrane. We have created an artificial sequence consisting of a stretch of 16 leucines bounded by positively charged amino acids. Using this template we demonstrate that moderate hydrophobicity distinguishes the mitochondrial tail-anchor sequence from that of the endoplasmic reticulum tail-anchor sequence. A change as small as introduction of a single polar residue into a sequence that otherwise targets to the endoplasmic reticulum can substantially switch targeting to the mitochondrial outer membrane. Further we show that a mitochondrially targeted tail-anchor has a higher propensity for the formation of alpha-helical structure than a sequence directing tail-anchored proteins to the endoplasmic reticulum.     

Tyrosine Phosphorylation Regulates Cell Cycle-dependent Nuclear Localization of Cdc48p

Cdc48p from Saccharomyces cerevisiae and its highly conserved mammalian homologue VCP (valosin-containing protein) are ATPases with essential functions in cell division and homotypic fusion of endoplasmic reticulum vesicles. Both are mainly attached to the endoplasmic reticulum, but relocalize in a cell cycle-dependent manner: Cdc48p enters the nucleus during late G1; VCP aggregates at the centrosome during mitosis. The nuclear import signal sequence of Cdc48p was localized near the amino terminus and its function demonstrated by mutagenesis. The nuclear import is regulated by a cell cycle-dependent phosphorylation of a tyrosine residue near the carboxy terminus. Two-hybrid studies indicate that the phosphorylation results in a conformational change of the protein, exposing the nuclear import signal sequence previously masked by a stretch of acidic residues.     

cDNA-derived primary structure of the glycoprotein component of canine microsomal signal peptidase complex

Canine microsomal signal peptidase activity has been shown previously to co-migrate as an apparent complex of six polypeptides with molecular masses of 25, 23, 22, 21, 18, and 12 kDa. The 22- and 23-kDa species are differentially glycosylated forms of the same protein, designated SPC 22/23. The amino acid sequence of SPC 22/23 was deduced from cDNA clones. The protein is synthesized without a cleavable amino-terminal signal sequence and contains a single site for N-linked glycosylation. SPC 22/23 appears to be anchored to the rough endoplasmic reticulum membrane by a single hydrophobic segment near its amino terminus, with the remainder of the protein positioned on the lumenal side of the membrane. The amino acid sequence of SPC 22/23 shares homology with tryptic peptides derived from the hen oviduct signal peptidase glycoprotein, one of two possible proteins required for signal peptide processing in the avian system (Baker, R.K., and Lively, M.O. (1987) Biochemistry 26, 8561-8567). Therefore, the complete amino acid sequence of SPC 22/23 presented in this report corresponds to one of two possible proteins required for signal peptide processing in higher eukaryotic cells.     

Cell-surface expression of a new splice variant of the mouse signal peptide peptidase

The signal peptide peptidase (SPP) is an intramembrane-cleaving aspartyl protease that acts on type II transmembrane proteins. SPP substrates include signal peptides after they have been cleaved from a preprotein, hence the name. The known SPP isoform, which we renamed SPPalpha, contains an endoplasmic reticulum retention signal at the carboxy terminus. We found a new splice variant, SPPbeta, with an additional in-frame exon inserted between exons 11 and 12 of SPPalpha. Insertion of the new exon led to a complete change in the amino-acid sequence of the carboxy tail. A stop codon within this new exon resulted in silencing of exon 12 and eliminated the endoplasmic reticulum retention signal. The new SPP isoform predominantly localised to the cell surface in contrast to the more restricted localisation of SPPalpha in the endoplasmic reticulum. Differential expression in mouse tissues and in subcellular compartments suggests new functions for SPP in addition to cleaving signal peptides.     

Integration of membrane proteins into the endoplasmic reticulum requires GTP

We have examined the requirement for ribonucleotides and ribonucleotide triphosphate hydrolysis during early events in the membrane integration of two membrane proteins: the G protein of vesicular stomatitis virus and the hemagglutinin-neuraminidase (HN) glycoprotein of Newcastle disease virus. Both proteins contain a single transmembrane-spanning segment but are integrated in the membrane with opposite orientations. The G protein has an amino-terminal signal sequence and a stop-transfer sequence located near the carboxy terminus. The HN glycoprotein has a single sequence near the amino terminus that functions as both a signal-sequence and a transmembrane-spanning segment. Membrane insertion was explored using a cell-free system directed by transcribed mRNAs encoding amino-terminal segments of the two proteins. Ribosome-bound nascent polypeptides were assembled, ribonucleotides were removed by gel filtration chromatography, and the ribosomes were incubated with microsomal membranes under conditions of defined ribonucleotide content. Nascent chain insertion into the membrane required the presence of both the signal recognition particle and a functional signal recognition particle receptor. In the absence of ribonucleotides, insertion of nascent membrane proteins was not detected. GTP or nonhydrolyzable GTP analogues promoted efficient insertion, while ATP was comparatively ineffective. Surprisingly, the majority of the HN nascent chain remained ribosome associated after puromycin treatment. Ribosome-associated HN nascent chains remained competent for membrane insertion, while free HN chains were not competent. We conclude that a GTP binding protein performs an essential function during ribosome-dependent insertion of membrane proteins into the endoplasmic reticulum that is unrelated to protein synthesis.     

Retention of a type II surface membrane protein in the endoplasmic reticulum by the Lys-Asp-Glu-Leu sequence.

Soluble luminal proteins of the endoplasmic reticulum (ER) are known to be retained by a tetrapeptide retention signal, KDEL. We report in this communication that the KDEL sequence when appended to the carboxy terminus of a cell surface membrane protein, dipeptidyl peptidase IV (DPPIV), resulted in its retention in the endoplasmic reticulum of transfected Madin-Darby canine kidney cells as assessed by indirect immunofluorescence. Selective surface biotinylation revealed that about 90-95% of the expressed DPPIV was retained in the ER. Appendance of the sequence KDEV did not, however, result in ER retention, illustrating the functional specificity of the retention signal. The ER retention was not due to misfolding of the mutant protein, as the mutant proteins remained enzymatically active. Our data suggest that the KDEL receptor is able to recognize and recycle type II membrane proteins containing a carboxyl-terminal KDEL sequence and postulates the existence of such yet to be identified endogenous proteins.     

The membrane-spanning segment of invariant chain (I gamma) contains a potentially cleavable signal sequence

The human invariant chain (I gamma) of class II histocompatibility antigens spans the membrane of the endoplasmic reticulum once. It exposes a small amino-terminal domain on the cytoplasmic side and a carboxy-terminal, glycosylated domain on the exoplasmic side of the membrane. When the exoplasmic domain of I gamma is replaced by the cytoplasmic protein chloramphenicol acetyltransferase (CAT), CAT becomes the exoplasmic, glycosylated domain of the resulting membrane protein I gamma CAT. Deletion of the hydrophilic cytoplasmic domain from I gamma CAT gives rise to a secreted protein from which an amino-terminal segment is cleaved, most likely by signal peptidase. We conclude that the membrane-spanning region of I gamma contains a signal sequence in its amino-terminal half and that hydrophilic residues at the amino-terminal end of a signal sequence can determine cleavage by signal peptidase.     

Rubella virus E2 signal peptide is required for perinuclear localization of capsid protein and virus assembly

The rubella virus (RV) structural proteins capsid, E2, and E1 are synthesized as a polyprotein precursor. The signal peptide that initiates translocation of E2 into the lumen of the endoplasmic reticulum remains attached to the carboxy terminus of the capsid protein after cleavage by signal peptidase. Among togaviruses, this feature is unique to RV. The E2 signal peptide has previously been shown to function as a membrane anchor for the capsid protein. In the present study, we demonstrate that this domain is required for RV glycoprotein-dependent localization of the capsid protein to the juxtanuclear region and subsequent virus assembly at the Golgi complex.     

Fibroblast growth factor 9 secretion is mediated by a non-cleaved amino-terminal signal sequence

Fibroblast growth factors are a family of intercellular signaling molecules with multiple and varied roles in animal development. Most are exported from cells by means of a classical amino-terminal signal sequence that is cleaved from the mature protein during its passage through the secretory pathway. Fibroblast growth factor-9 (Fgf-9) does not contain a recognizable signal sequence, although it is efficiently secreted. In this study, we show that Fgf-9 enters the endoplasmic reticulum and traverses the Golgi complex in a similar manner to other constitutively secreted proteins. Deletion and point mutation analysis has revealed an atypical non-cleaved signal sequence within the amino-terminal region of Fgf-9. Moreover, the first 28 amino acids of Fgf-9 can function as an efficient non-cleaved signal peptide when appended to the amino terminus of green fluorescent protein.     

Functional expression of bovine 17 alpha-hydroxylase in COS 1 cells is dependent upon the presence of an amino-terminal signal anchor sequence.

Microsomal forms of eukaryotic cytochrome P450 proteins are integral membrane proteins of the endoplasmic reticulum (ER) membrane which are targeted to the ER via the signal recognition particle pathway. A hydrophobic amino terminus serves as a combined signal sequence and major membrane anchor (signal-anchor sequence) for the microsomal P450s. We have examined the insertion of bovine 17 alpha-hydroxylase (P45017 alpha) into the ER of COS 1 cells in order to evaluate the role of membrane insertion of the amino-terminal signal-anchor of microsomal P450s as a functional determinant for these enzymes. Previously, we have shown that deletion of the hydrophobic amino terminus from P45017 alpha reduced membrane targeting and insertion by 5-fold compared with the wild-type protein, abolished enzymatic activity, and resulted in an aberrant CO difference spectrum. In the present study we have replaced the amino terminus of P45017 alpha with two heterologous signal-anchor sequences, one that is similar and one that is very different from the P45017 alpha sequence. The chimeric proteins were expressed in COS 1 cells. Immunoblot analysis of isolated microsomal membranes show that the heterologous signal-anchor sequences functioned to target the P45017 alpha protein to the ER. Enzymatic assays in intact COS 1 cells indicate that both the chimeric proteins are efficient 17 alpha-hydroxylase enzymes. The amino terminus of P45017 alpha was also replaced with a sequence that is not a signal-anchor, and the expressed protein was neither targeted to the ER nor was functional in COS 1 cells. In conclusion, both the structure and catalytic activity of P45017 alpha in COS 1 cells is dependent upon an amino-terminal sequence that functions as a signal-anchor sequence and not upon the precise sequence of the amino terminus.     

Enhancement of membrane insertion and function in a type IIIb membrane protein following introduction of a cleavable signal peptide.

The human beta 2 adrenergic receptor is a type IIIb membrane protein. It has a putative seven-transmembrane topology but lacks an amino-terminal cleavable signal sequence. The mechanism by which the amino terminus of the beta 2 receptor is translocated across the endoplasmic reticulum membrane is unknown. Furthermore, it is not known if translocation as a type IIIb protein is essential for the proper folding. Our studies indicate that conversion of beta 2 receptor from a type IIIb to a type IIIa membrane protein by introducing an NH2-terminal cleavable signal sequence enhances translocation of the receptor into the endoplasmic reticulum membrane, thereby facilitating expression of functional receptor.     

The hepatitis B virus precore protein is retrotransported from endoplasmic reticulum (ER) to cytosol through the ER-associated degradation pathway

The hepatitis B virus precore protein is closely related to the nucleocapsid core protein but is processed distinctly in the cell and plays a different role in the viral cycle. Precore is addressed to the endoplasmic reticulum (ER) through a signal peptide, and the form present in the ER is the P22 protein. P22 is then cleaved in its C-terminal part to be secreted as HBe antigen. In addition, a cytosolic form of 22 kDa less characterized has been observed. Precore gene was shown to be implicated in viral persistence, but until now, the actual protein species involved has not been determined. Our work focuses on the cytosolic form of precore. Using human cells expressing precore and a convenient fractionation assay, we demonstrated that the cytosolic form is identical to the ER form and retrotransported in the cytoplasm through the ER-associated degradation pathway. This cellular machinery translocates misfolded proteins to the cytoplasm, where they are ubiquitinated on lysine residues and degraded by proteasome. We showed that precore escapes proteasome due to its low lysine content and accumulates in the cytosol. The role of this retrotransport was investigated. In the presence of precore, we found a specific redistribution of the Grp78/BiP chaperone protein to cytosol and demonstrated a specific interaction between precore and Grp78/BiP. Altogether, these data support the idea that the hepatitis B virus develops a strategy to take advantage of the ER-associated degradation pathway, allowing distinct subcellular localization and probably distinct roles for the viral precore protein.     

Cloning of cDNA encoding the sweet-tasting plant protein thaumatin and its expression in Escherichia coli

The structural gene of the sweet-tasting plant protein (prepro)thaumatin was cloned and expressed in Escherichia coli. Expression was effected under control of lac and trp promoter/operator systems and through the use of bacterial ribosome-binding sites. The naturally occurring thaumatin II represents a processed form. The primary translation product, preprothaumatin, of the cloned mRNA-derived cDNA contains extensions at both the amino terminus and the carboxy terminus. The amino terminal extension of 22 amino acids is hydrophobic and very much resembles an excretion-related signal sequence. The six amino acids-long carboxy terminal extension is very acidic in character, in contrast to the overall highly basic thaumatin molecule. The possible role of such an acidic tail with respect to compartmentalization is discussed.     

Prepro-alpha-factor has a cleavable signal sequence

MAT alpha Saccharomyces cerevisiae secrete a small peptide mating pheromone termed alpha-factor. Its precursor, prepro-alpha-factor, is translocated into the endoplasmic reticulum and glycosylated at three sites. The glycosylated form is the major product in a yeast in vitro translation/translocation system. However, there is another translocated, nonglycosylated product that contains a previously unidentified modification. Contrary to previous results suggesting that the signal sequence of prepro-alpha-factor is not cleaved, amino-terminal radiosequencing has identified this product as prepro-alpha-factor without its signal sequence, that is, pro-alpha-factor. The translocated, glycosylated proteins are also processed by signal peptidase. Moreover, we have found that both purified eukaryotic and prokaryotic signal peptidase can process prepro-alpha-factor. Experiments using a yeast secretory mutant (sec 18) blocked in transport from the endoplasmic reticulum to the Golgi indicate that the protein is also cleaved in vivo. Finally, characterization of the Asn-linked oligosaccharide present on pro-alpha-factor in the yeast in vitro system by use of specific glucosidase and mannosidase inhibitors indicates that they have had the three terminal glucoses and probably one mannose removed. Therefore they most likely consist of Man8GlcNAc2 structures, identical to those found in the endoplasmic reticulum in vivo.     

A novel type of FKBP in the secretory pathway of Neurospora crassa

FKBPs define a subfamily of peptidyl-prolyl cis/trans isomerases (PPIases). PPIases are known to play roles in cellular protein folding, protein interactions and signal transduction. Here we describe NcFKBP22 from Neurospora crassa, a novel type of FKBP. NcFKBP22 is synthesized as a precursor protein with a cleavable signal sequence. In addition to a typical FKBP domain in the amino-terminal part mature NcFKBP22 contains a novel second domain which is unique amongst all known FKBPs. The amino acid composition of this carboxy-terminal domain is highly biased. Secondary structure predictions suggest that this domain may form an amphipathic -helix. The carboxy-terminus of NcFKBP22 is –HNEL, a potential endoplasmic reticulum (ER) retention signal, suggesting that NcFKBP22 is a resident protein of the ER.     

Dual targeting of cytochrome P4502B1 to endoplasmic reticulum and mitochondria involves a novel signal activation by cyclic AMP-dependent phosphorylation at ser128.

We have investigated mechanisms of mitochondrial targeting of the phenobarbital-inducible hepatic mitochondrial P450MT4, which cross-reacts with antibody to microsomal P4502B1. Results show that P4502B1 and P450MT4 have identical primary sequence but different levels of phosphorylation and secondary structure. We demonstrate that P4502B1 contains a chimeric mitochondrial and endoplasmic reticulum (ER) targeting signal at its N-terminus. Inducers of cAMP and protein kinase A-mediated phosphorylation of P4502B1 at Ser128 activate the signal for mitochondrial targeting and modulate its mitochondrial or ER destination. S128A mutation inhibits in vitro mitochondrial transport and also in vivo mitochondrial targeting in COS cells. A fragment of P4502B1 containing the N-terminal signal and the phosphorylation site could drive the transport of dihydrofolate reductase (DHFR) into mitochondria. Ser128 phosphorylation reduced the affinity of 2B1 protein for binding to SRP, but increased the affinity of the 2B1-DHFR fusion protein for binding to yeast mitochondrial translocase proteins, TOM40 and TIM44, and matrix Hsp70. We describe a novel regulatory mechanism by which cAMP modulates the targeting of a protein to two distinct organelles.     

Identification of the insulin receptor tyrosine residues undergoing insulin-stimulated phosphorylation in intact rat hepatoma cells

Tyr(P)-containing proteins were purified from extracts of insulin-treated rat hepatoma cells (H4-II-E-C3) by antiphosphotyrosine immunoaffinity chromatography. Two major insulin-stimulated, Tyr(P) proteins were recovered: an Mr 95,000 protein (identified as the insulin receptor beta subunit by its immunoprecipitation by a patient-derived anti-insulin receptor serum and several anti-insulin receptor (peptide) antisera) and an Mr 180,000 protein (which was unreactive with all anti-insulin receptor antibodies). After purification and tryptic digestion of the Mr 95,000 protein, tryptic peptides containing Tyr(P) were purified by sequential antiphosphotyrosine immunoaffinity, reversed-phase, anion-exchange chromatography. The partial amino acid sequence obtained by gas- and solid-phase Edman degradation was compared to the amino acid sequence of the intracellular extension of the rat insulin receptor deduced from the genomic sequence. Approximately 80% of all beta subunit [32P]Tyr(P) resides on two tryptic peptides: 50-60% of [32P]Tyr(P) is found on the tryptic peptide Asp-Ile-Tyr-Glu-Thr-Asp-Tyr-Tyr-Arg from the tyrosine kinase domain, which is recovered mainly as the double phosphorylated species (predominantly in the form with Tyr(P) at residues 3 and 7 from the amino terminus; the remainder with Tyr(P) at residues 3 and 8), with 10-15% as the triple phosphorylated species. A second tryptic peptide is located near the carboxyl terminus, contains 2 tyrosines, and has the sequence, Thr-Tyr-Asp-Glu-His-Ile-Pro-Tyr-Thr-; this contains 20-30% of beta subunit [32P]Tyr(P) and is identified primarily in a double phosphorylated form. Approximately 10% of beta subunit [32P]Tyr(P) resides on an unidentified tryptic peptide of Mr 4,000-5,000. The insulin-stimulated tyrosine phosphorylation of the insulin receptor in intact rat hepatoma cells thus involves at least 6 of the 13 tyrosine residues located on the beta subunit intracellular extension. These tyrosines are clustered in several domains in a distribution virtually identical to that previously found for partially purified human insulin receptor autophosphorylated in vitro in the presence of insulin. This multisite regulatory tyrosine phosphorylation is the initial intracellular event in insulin action.