Cleavage by signal peptide peptidase is required for the degradation of selected tail-anchored proteins

The regulated turnover of endoplasmic reticulum (ER)–resident membrane proteins requires their extraction from the membrane lipid bilayer and subsequent proteasome-mediated degradation. Cleavage within the transmembrane domain provides an attractive mechanism to facilitate protein dislocation but has never been shown for endogenous substrates. To determine whether intramembrane proteolysis, specifically cleavage by the intramembrane-cleaving aspartyl protease signal peptide peptidase (SPP), is involved in this pathway, we generated an SPP-specific somatic cell knockout. In a stable isotope labeling by amino acids in cell culture–based proteomics screen, we identified HO-1 (heme oxygenase-1), the rate-limiting enzyme in the degradation of heme to biliverdin, as a novel SPP substrate. Intramembrane cleavage by catalytically active SPP provided the primary proteolytic step required for the extraction and subsequent proteasome-dependent degradation of HO-1, an ER-resident tail-anchored protein. SPP-mediated proteolysis was not limited to HO-1 but was required for the dislocation and degradation of additional tail-anchored ER-resident proteins. Our study identifies tail-anchored proteins as novel SPP substrates and a specific requirement for SPP-mediated intramembrane cleavage in protein turnover.     

Structural features in the NH2-terminal region of a model eukaryotic signal peptide influence the site of its cleavage by signal peptidase

The 20-amino acid signal peptide of human pre (delta pro)apolipoprotein A-II contains the tripartite domain structure typical of eukaryotic prepeptides, i.e. a positively charged NH2-terminal (n) region, a hydrophobic core (h) region, and a COOH-terminal polar domain (c region). This signal sequence has multiple potential sites for cotranslational processing making it an attractive model for assessing the consequences of systematic structural alterations on the site selected for signal peptidase cleavage. We previously analyzed 40 mutant derivatives of this model preprotein using an in vitro translation/canine microsome processing assay. The results showed that the position of the boundary between the h and c regions and properties of the -1 residue are critical in defining the site of cotranslational cleavage. To investigate whether structural features in the NH2-terminal region of signal peptides play a role in cleavage specificity, we have now inserted various amino acids between the positively charged n region (NH2-Met-Lys) and the h region of a "parental" pre(delta pro)apoA-II mutant that has roughly equal cleavage between Gly18 decreases and Gly20 decreases. Movement of the n/h boundary toward the NH2 terminus results in a dramatic shift in cleavage to Gly18 decreases. Replacement of the Lys2 residue with hydrophilic, negatively charged residues preserves the original sites of cleavage. Replacement with a hydrophobic residue causes cleavage to shift "upstream." Simultaneous alteration of the position of n/h and h/c boundaries has an additive effect on the site of signal peptidase cleavage. None of these mutations produced a marked decrease in the efficiency of in vitro cotranslational translocation or cleavage. However, in sequence contexts having poor signal function, introduction of hydrophobic residues between the n and h regions markedly improved the efficiency of translocation/processing. We conclude that the position of the n/h boundary as well as positioning of the h/c boundary affects the site of cleavage chosen by signal peptidase.     

Kinetic constants of signal peptidase I using cytochrome b5 as a precursor substrate.

A procedure is described for measuring Escherichia coli signal peptidase I activity which exploits an intact precursor protein composed of the alkaline phosphatase signal peptide fused to the full length mammalian cytochrome b5. This cytochrome b5 precursor protein has been extensively characterised and shown to be processed accurately by purified signal peptidase I [Protein Expr. Purif. 7 (1996) 237]. The amphipathic, chimaeric cytochrome b5 precursor was isolated in mg quantities in a highly homogeneous state under non-denaturing conditions. The processing of the cytochrome b5 precursor by signal peptidase displayed Michaelis-Menten kinetics with K(m)=50 microM and k(cat)=11 s(-1). The K(m) was 20-fold lower than that obtained with signal peptide substrates and 3-fold higher than that reported for pro-OmpA-nuclease A precursor fusion. The corresponding turnover number, k(cat), was four orders of magnitude greater than the peptide substrates but was 2-fold lower than pro-OmpA-nuclease A precursor fusion. These results confirm that both the affinities and the catalytic power of the signal peptidase are significantly higher for macromolecular precursor substrates than for the shorter signal peptide substrates.     

Cleavage of a tail-anchored protein by signal peptidase

Tail-anchored proteins are post-translationally targeted and inserted into the endoplasmic reticulum membrane. They do not use the co-translational signal-recognition particle (SRP)-dependent pathway, but rather utilize an ill-defined, ATP-dependent mechanism. Here, we show that a tail-anchored protein can be cleaved by signal peptidase and that the sequence requirements for efficient cleavage seem to be the same as for cleavage of co-translationally targeted SRP-dependent proteins.     

A chemically synthesized radiolabeled signal peptide: design, preparation, and biological evaluation of an iodinated analog of preproparathyroid hormone

The chemically synthesized signal peptide (native-sequence signal peptide) of preproparathyroid hormone exhibits signal sequence-like activity by inhibiting the translocation/processing of precursor proteins to their mature forms in an in vitro translation system. In order to prepare a biologically functional radiolabeled form of this peptide, we undertook structure-function studies of the native-sequence signal peptide. Since conventional iodination of peptides is performed under oxidizing conditions, chemical design efforts were focused on the oxidation-labile residues, methionine and cysteine, present in the native sequence. Substitution of the three methionines with norleucine and the single cysteine with alanine yielded a surfur-free analog, [Nle-(-25), Nle-(-21),Nle-(-18),Ala-(-14),D-Tyr-(+1)]pre-proPTH-(-29-+1)amide, which is resistant to oxidation and active in the inhibition of processing assay. An interaction between the signal region and one of the components of the intracellular secretory apparatus, signal recognition particle (SRP), was demonstrated: iodinated sulfur-free analog was cross-linked (using the homo-bifunctional reagent disuccinimidyl suberate) to the 54 kilodalton (kDa) subunit of SRP. The 68 kDa and 72 kDa subunits of SRP were also labeled, but to a lesser extent, by the iodinated peptide.     

A C-terminal region of signal peptide peptidase defines a functional domain for intramembrane aspartic protease catalysis

Intramembrane proteolysis is now firmly established as a prominent biological process, and structure elucidation is emerging as the new frontier in the understanding of these novel membrane-embedded enzymes. Reproducing this unusual hydrolysis within otherwise water-excluding transmembrane regions with purified proteins is a challenging prerequisite for such structural studies. Here we show the bacterial expression, purification, and reconstitution of proteolytically active signal peptide peptidase (SPP), a membrane-embedded enzyme in the presenilin family of aspartyl proteases. This finding formally proves that, unlike presenilin, SPP does not require any additional proteins for proteolysis. Surprisingly, the conserved C-terminal half of SPP is sufficient for proteolytic activity; purification and reconstitution of this engineered fragment of several SPP orthologues revealed that this region defines a functional domain for an intramembrane aspartyl protease. The discovery of minimal requirements for intramembrane proteolysis should facilitate mechanistic and structural analysis and help define general biochemical principles of hydrolysis in a hydrophobic environment.     

Mutations in the NH2-terminal domain of the signal peptide of preproparathyroid hormone inhibit translocation without affecting interaction with signal recognition particle

The amino-terminal domain of a eukaryotic signal peptide, from bovine parathyroid hormone, was altered by in vitro mutagenesis of the cDNA. The function of "internalized" signal sequence mutants and of deletion mutants was assayed using an in vitro translation-translocation system. The addition of 11 amino acids to the NH2 terminus of the signal peptide did not prevent normal processing of the precursor protein, whereas a 23-amino acid extension blocked processing. These data suggest that the NH2-terminal sequences of internal signal peptides must be permissive of the signal function. Deletion of 6 NH2-terminal amino acids from the signal peptide had no effect on its cleavage by microsomal membranes, but removal of 10 or 13 amino acids, including all charged residues prior to the hydrophobic core, prevented processing. For both the extension and deletion mutations, processed proteins were protected from proteolytic digestion, whereas unprocessed forms were not, which indicated that the unprocessed mutant proteins were not translocated across the microsomal membrane. Translation of both the extension and deletion translocation-deficient mutants was arrested by signal recognition particle, and salt-washed microsomal membranes reversed the translational arrest. These data demonstrate that the NH2-terminal domain is not required for the interaction of signal recognition particle with the signal peptide or with signal recognition particle receptor, but is required for formation of a maximally translocation-competent complex with the microsomal membrane.     

Importance of the propeptide sequence of human preproparathyroid hormone for signal sequence function

The function of amino-terminal pro-specific peptides (propeptides), sequences often found on intermediate precursor forms of secreted proteins, is poorly understood. Human preproparathyroid hormone (prepro-PTH), a precursor protein containing such a propeptide, is initially synthesized as a precursor containing a 25-amino acid signal sequence, a 6-amino acid propeptide, and the 84-amino acid mature secreted peptide. Cloned cDNA encoding prepro-PTH and synthetic oligonucleotides were used to generate a mutant missing precisely the pro-specific sequences. The effects of this deletion on signal sequence function and on secretion per se were assessed after expression of the mutant cDNA in intact cells and in a cell-free translation system using synthetic mRNA in the presence of microsomal membranes. The mutant precursor protein was inefficiently translocated and cleaved, and cleavage occurred both at the normal site and within the signal sequence. Thus, for the eukaryotic protein prepro-PTH, sequences immediately downstream and separate from the classically defined signal sequence facilitate accurate and efficient signal function.     

Three-dimensional structure of the signal peptide peptidase

Signal peptide peptidase (SPP) is an atypical aspartic protease that hydrolyzes peptide bonds within the transmembrane domain of substrates and is implicated in several biological and pathological functions. Here, we analyzed the structure of human SPP by electron microscopy and reconstructed the three-dimensional structure at a resolution of 22 Å. Enzymatically active SPP forms a slender, bullet-shaped homotetramer with dimensions of 85 × 85 × 130 Å. The SPP complex has four concaves on the rhombus-like sides, connected to a large chamber inside the molecule. Intriguingly, the N-terminal region of SPP is sufficient for the tetrameric assembly. Moreover, overexpression of the N-terminal region inhibited the formation of the endogenous SPP tetramer and the proteolytic activity within cells. These data suggest that the homotetramer is the functional unit of SPP and that its N-terminal region, which works as the structural scaffold, has a novel modulatory function for the intramembrane-cleaving activity of SPP.     

Structure of the human signal peptidase complex reveals the determinants for signal peptide cleavage

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Minimum substrate sequence for signal peptidase I of Escherichia coli

The minimum substrate sequence recognized by signal peptidase I (SPase I or leader peptidase) was defined by measuring the kinetic parameters for a set of chemically synthesized peptides corresponding to the cleavage site of the precursor maltose binding protein (pro-MBP). The minimum sequence of a substrate hydrolyzed by SPase I at a measurable rate was the pentapeptide Ala-Leu-Ala decreases Lys-Ile. The rates of hydrolysis of this substrate, however, were several hundred-fold lower than those observed for the maturation of MBP in Escherichia coli, suggesting that in addition to these minimal sites involved in recognition, other features of pro-MBP are also needed for the optimal rate of signal peptide cleavage by SPase I. One parameter may be the length of the polypeptide chain. Studies of the synthetic peptides showed that decreasing the length of the polypeptide chain of substrates decreased the substrate efficiency measured as kcat/Km. However, in one case a decrease in the length of a peptide corresponding to -7 to +3 positions of pro-MBP to a nonapeptide (-7 to +2) increased the substrate efficiency by about 900-fold. The nonapeptide is the most efficient substrate for the enzyme in vitro so far reported. It is speculated that better peptide substrates are the ones which are able to adopt folded structures.     

Purification and properties of a peptidase acting on a synthetic substrate for collagenase from monkey kidney.

A peptidase cleaving a synthetic substrate for collagenase, 4-phenylazobenzyloxycarbonyl-L-Pro-L-Leu-Gly-L-Pro-D-Arg (designated as PZ-peptide) has been purified extensively (about 5200-fold) from a soluble extract of monkey kidney with a view of carrying out studies on its possible physiological role. The purified PZ-peptidase appeared essentially free of collagenase, nonspecific protease and di- and tri-peptidase activities. The properties of the purified PZ-peptidase resemble very much the granuloma enzyme. It is optimally active around pH 7.0. Its apparent Km value for PZ-peptide is 0.72 mM and V is 10.1 mumol/mg protein/min. It is reversibly inhibited by p-hydroxymercuribenzoate and HgCl2, whereas iodoactetamide does not affect the enzyme activity. N-Ethylmaleimide inhibited the enzyme partially (50%). Heavy metals like Cu-2+, Cd-2+, Ag+, Pb-2+, Ni-2+, and Zn-2+ completely inhibited the enzyme activity, while the inhibition by Co-2+ was only partial. Fe-2+ did not exert any effect on the activity. The enzyme activity was completely inhibited by EDTA and was restored almost to the original value by metal ions like Mn-2+, Mg-2+, Ca-2+ and Ba-2+. The approximate molecular weight of the purified enzyme was estimated to be 56 000.     

Discovery of substrate for type I signal peptidase SpsB from Staphylococcus aureus.

Based on the kinetic model of substrate phage proteolysis, we have formulated a strategy for best manipulating the conditions in screening phage display libraries for protease substrates (Sharkov, N. A., Davis, R. M., Reidhaar-Olson, J. F., Navre, M., and Cai, D. (2001) J. Biol. Chem. 276, 10788-10793). This strategy is exploited in the present study with signal peptidase SpsB from Staphylococcus aureus. We demonstrate that highly active substrate phage clones can be isolated from a phage display library by systematically tuning the selection stringency in screening. Several of the selected clones exhibit superior reactivity over a control, the best clone, SIIIRIII-8, showing >100-fold improvement. Because no conserved sequence features were readily revealed that could allow delineation of the active and unreactive clones, the sequences identified in five of the active clones were tested as synthetic dodecamers, Ac-AGX(8)GA-NH(2). Using electrospray ionization mass spectrometry, we show that four of these peptides can be cleaved by SpsB and that Ala is the P1 residue exclusively and Ala or Leu the P3 residue, in keeping with the (-3, -1) rule for substrate recognition by signal peptidase. Our successful screening with SpsB demonstrated the general applicability of the screening strategy and allowed us to isolate the first peptide substrates for the enzyme.     

Crystal structure of a bacterial signal peptidase apoenzyme: implications for signal peptide binding and the Ser-Lys dyad mechanism.

We report here the x-ray crystal structure of a soluble catalytically active fragment of the Escherichia coli type I signal peptidase (SPase-(Delta2-75)) in the absence of inhibitor or substrate (apoenzyme). The structure was solved by molecular replacement and refined to 2.4 A resolution in a different space group (P4(1)2(1)2) from that of the previously published acyl-enzyme inhibitor-bound structure (P2(1)2(1)2) (Paetzel, M., Dalbey, R.E., and Strynadka, N.C.J. (1998) Nature 396, 186-190). A comparison with the acyl-enzyme structure shows significant side-chain and main-chain differences in the binding site and active site regions, which result in a smaller S1 binding pocket in the apoenzyme. The apoenzyme structure is consistent with SPase utilizing an unusual oxyanion hole containing one side-chain hydroxyl hydrogen (Ser-88 OgammaH) and one main-chain amide hydrogen (Ser-90 NH). Analysis of the apoenzyme active site reveals a potential deacylating water that was displaced by the inhibitor. It has been proposed that SPase utilizes a Ser-Lys dyad mechanism in the cleavage reaction. A similar mechanism has been proposed for the LexA family of proteases. A structural comparison of SPase and members of the LexA family of proteases reveals a difference in the side-chain orientation for the general base lysine, both of which are stabilized by an adjacent hydroxyl group. To gain insight into how signal peptidase recognizes its substrates, we have modeled a signal peptide into the binding site of SPase. The model is built based on the recently solved crystal structure of the analogous enzyme LexA (Luo, Y., Pfuetzner, R. A., Mosimann, S., Paetzel, M., Frey, E. A., Cherney, M., Kim, B., Little, J. W., and Strynadka, N. C. J. (2001) Cell 106, 1-10) with its bound cleavage site region.     

A synthetic signal peptide blocks import of precursor proteins destined for the mitochondrial inner membrane or matrix

A peptide corresponding to amino acids 1-27 of preornithine carbamyltransferase (pOCT) has been chemically synthesized. When added to energized mitochondria in vitro, 20 microM of the peptide, designated pO(1-27), resulted in a collapse of the electrochemical potential across the mitochondrial inner membrane. This effect on transmembrane potential was not observed, however, when pO(1-27) was added to energized mitochondria under conditions that support in vitro import of precursor proteins (i.e. in the presence of reticulocyte lysate). The latter finding, therefore, made possible an examination of the ability of pO(1-27) to block import of homologous and heterologous proteins into the organelle. At 5-10 microM, pO(1-27) prevented import of pOCT in vitro; inhibition was overcome by increasing the concentration of pOCT. In contrast, pO(16-27), a peptide corresponding to amino acids 16-27 of pOCT and exhibiting a charge:mass ratio similar to pO(1-27) had no such inhibitory effect. pO(1-27) blocked import of other unrelated precursor proteins destined either for the mitochondrial matrix (pre-malate dehydrogenase and a hybrid protein containing the signal sequence of pre-carbamyl phosphate synthetase) or for the mitochondrial inner membrane (pre-thermogenin).     

A microassay for the peptidase activity of enzymes utilizing ribonuclease S peptide as a substrate

A microassay for the peptidase activity of proteins obtained in minute amounts was devised. The method uses ribonuclease S peptide as a substrate. The substrate when cleaved is unable to reconstitute an active ribonuclease S complex. Therefore the loss in activity of the reconstituted complex is a measure of the peptidase activity. The method was previously tested with known peptidases such as clastase (9), chymotrypsin (8), and trypsin. In this work the peptidase activity of a protein related to a sperm-decapitating factor (1) is evidenced.     

Characterization of the sppA gene coding for protease IV, a signal peptide peptidase of Escherichia coli.

The sppA gene codes for protease IV, a signal peptide peptidase of Escherichia coli. Using the gene cloned on a plasmid, we constructed an E. coli strain carrying the ampicillin resistance gene near the chromosomal sppA gene and an sppA deletion strain in which the deleted portion was replaced by the kanamycin resistance gene. Using these strains, we mapped the sppA gene at 38.5 min on the chromosome, the gene order being katE-xthA-sppA-pncA. Although digestion of the signal peptide that accumulated in the cell envelope fraction was considerably slower in the deletion mutant than in the sppA+ strain, it was still significant, suggesting the participation of another envelope protease(s) in signal peptide digestion.     

Structural analysis of hepatitis C virus core-E1 signal peptide and requirements for cleavage of the genotype 3a signal sequence by signal peptide peptidase

The maturation of the hepatitis C virus (HCV) core protein requires proteolytic processing by two host proteases: signal peptidase (SP) and the intramembrane-cleaving protease signal peptide peptidase (SPP). Previous work on HCV genotype 1a (GT1a) and GT2a has identified crucial residues required for efficient signal peptide processing by SPP, which in turn has an effect on the production of infectious virus particles. Here we demonstrate that the JFH1 GT2a core-E1 signal peptide can be adapted to the GT3a sequence without affecting the production of infectious HCV. Through mutagenesis studies, we identified crucial residues required for core-E1 signal peptide processing, including a GT3a sequence-specific histidine (His) at position 187. In addition, the stable knockdown of intracellular SPP levels in HuH-7 cells significantly affects HCV virus titers, further demonstrating the requirement for SPP for the maturation of core and the production of infectious HCV particles. Finally, our nuclear magnetic resonance (NMR) structural analysis of a synthetic HCV JFH1 GT2a core-E1 signal peptide provides an essential structural template for a further understanding of core processing as well as the first model for an SPP substrate within its membrane environment. Our findings give deeper insights into the mechanisms of intramembrane-cleaving proteases and the impact on viral infections.