A nonfunctional sequence converted to a signal for glycophosphatidylinositol membrane anchor attachment

The COOH terminus of decay-accelerating factor (DAF) contains a signal that directs glycophosphatidylinositol (GPI) membrane anchor attachment in a process involving concerted proteolytic removal of 28 COOH-terminal residues. At least two elements are required for anchor addition: a COOH-terminal hydrophobic domain and a cleavage/attachment site located NH2-terminal to it, requiring a small amino acid as the acceptor for GPI addition. We previously showed that the last 29-37 residues of DAF, making up the COOH-terminal hydrophobic domain plus 20 residues of the adjacent serine/threonine-rich domain (including the anchor addition site), when fused to the COOH terminus of human growth hormone (hGH) will target the fusion protein to the plasma membrane via a GPI anchor. In contrast, a similar fusion protein (hGH-LDLR-DAF17, abbreviated HLD) containing a fragment of the serine/threonine-rich domain of the LDL receptor (LDLR) in place of the DAF-derived serine/threonine-rich sequences, does not become GPI anchored. We now show that this null sequence for GPI attachment can be converted to a strong GPI signal by mutating a pair of residues (valine-glutamate) in the LDLR sequence at a position corresponding to the normal cleavage/attachment site, to serine-glycine, as found in the DAF sequence. A single mutation (converting valine at the anchor addition site to serine, the normal acceptor for GPI addition in DAF) was insufficient to produce GPI anchoring, as was mutation of the valine-glutamate pair to serine-phenylalanine (a bulky residue). These results suggest that a pair of small residues (presumably flanking the cleavage point) is required for GPI attachment. By introducing the sequence serine-glycine (comprising a cleavage-attachment site for GPI addition) at different positions in the LDLR sequence of the fusion protein, HLD, we show that optimal GPI attachment requires a processing site positioned 10-12 residues NH2-terminal to the hydrophobic domain, the efficiency anchor attachment dropping off sharply as the cleavage site is moved beyond these limits. These data suggest that the GPI signal consists solely of a hydrophobic domain combined with a processing site composed of a pair of small residues, positioned 10-12 residues NH2-terminal to the hydrophobic domain. No other structural motifs appear necessary.     

Glycophospholipid membrane anchor attachment. Molecular analysis of the cleavage/attachment site.

The COOH terminus of decay accelerating factor (DAF) contains a signal that directs attachment of a glycophosphatidylinositol (GPI) membrane anchor in a process involving proteolytic removal of 17-31 COOH-terminal residues. Previous work suggested that two elements are required for anchor addition, a COOH-terminal hydrophobic domain (the GPI signal) and an element located NH2-terminal to it, postulated to be the cleavage/attachment site. Using [3H]ethanolamine (a component of the anchor) to tag the COOH terminus, we isolated and sequenced a COOH-terminal tryptic peptide, thereby identifying Ser-319 as the COOH-terminal residue attached to the GPI anchor. This indicates that a 28-residue peptide is removed during processing and localizes the cleavage/attachment site precisely to the region previously shown to be required for anchor attachment (between 10 and 20 residues NH2-terminal to the hydrophobic domain). Since DAF contains multiple cryptic cleavage/attachment sites, we used a GPI-linked human growth hormone-DAF fusion to study the structural requirements for cleavage/attachment. Our results show that while sequences immediately NH2-terminal to the attachment site are not required for anchor addition, deletion of Ser-319 abolishes both anchor attachment and transport to the cell surface. Systematic replacement of the attachment site serine with all possible amino acids indicated that alanine, aspartate, asparagine, glycine, or serine efficiently support GPI anchor attachment while valine and glutamate are partially effective. All other substitutions including cysteine (permitted at the attachment site in other GPI-anchored proteins) abolish both GPI anchor attachment and transport to the cell surface, resulting in accumulation of uncleaved fusion protein in internal compartments (endoplasmic reticulum and Golgi). These results support the general rule that the residue at the cleavage/attachment site must be small. Further, addition of a GPI anchor appears to be necessary for transport to the cell surface in transfected COS cells.     

Fusion of sequence elements from non-anchored proteins to generate a fully functional signal for glycophosphatidylinositol membrane anchor attachment

Glycophosphatidylinositol (GPI) membrane anchor attachment is directed by a cleavable signal at the COOH terminus of the protein. The complete lack of homology among different GPI-anchored proteins suggests that this signal is of a general nature. Previous analysis of the GPI signal of decay accelerating factor (DAF) suggests that the minimal requirements for GPI attachment are (a) a hydrophobic domain and (b) a cleavage/attachment site consisting of a pair of small residues positioned 10-12 residues NH2-terminal to a hydrophobic domain. As an ultimate test of these rules we constructed four synthetic GPI signals, meeting these requirements but assembled entirely from sequence elements not normally involved in GPI attachment. We show that these synthetic signals are able to direct human growth hormone (hGH), a secreted protein, to the plasma membrane via a GPI anchor. Our results indicate that different hydrophobic sequences, derived from either the prolactin or hGH NH2-terminal signal peptide, can be linked to different cleavage sites via different hydrophilic spacers to produce a functional GPI signal. These data confirm that the only requirements for GPI-anchoring are a pair of small residues positioned 10-12 residues NH2 terminal to a hydrophobic domain, no other structural motifs being necessary.     

Analysis of the signal for attachment of a glycophospholipid membrane anchor

The COOH terminus of decay accelerating factor (DAF) contains a signal that directs attachment of a glycophospholipid (GPI) membrane anchor. To define this signal we deleted portions of the DAF COOH terminus and expressed the mutant cDNAs it CV1 origin-deficient SV-40 cells. Our results show that the COOH-terminal hydrophobic domain (17 residues) is absolutely required for GPI anchor attachment. However, when fused to the COOH terminus of a secreted protein this hydrophobic domain is insufficient to direct attachment of a GPI anchor. Additional specific information located within the adjacent 20 residues appears to be necessary. We speculate that by analogy with signal sequences for membrane translocation, GPI anchor attachment requires both a COOH-terminal hydrophobic domain (the GPI signal) as well as a suitable cleavage/attachment site located NH2 terminal to the signal.     

Recognition of the carboxyl-terminal signal for GPI modification requires translocation of its hydrophobic domain across the ER membrane

A carboxyl-terminal hydrophobic domain is an essential component of the processed signal for attachment of the glycosyl-phosphatidylinositol (GPI) membrane anchor to proteins and it is linked to the site (omega) of GPI modification by a spacer domain. This study was designed to test the hypothesis that the hydrophobic domain interacts with the lipid bilayer of the endoplasmic reticulum (ER) membrane to optimally position the omega site for GPI modification. The hydrophobic domain of the GPI signal in the human folate receptor (FR) type alpha was substituted with the carboxyl-terminal segment of the low-density lipoprotein receptor (LDLR), including its membrane spanning region, without altering either the spacer or the omega site. The FR-alpha/LDLR chimera was not GPI modified but was attached to the plasma membrane by a polypeptide anchor. When the carboxyl-terminal half of the hydrophobic transmembrane polypeptide in the FR-alpha/LDLR chimera was altered by introduction of negatively charged (Asp) residues, or when the cytosolic domain in the chimera was deleted, the mutated proteins became GPI-anchored. On the other hand, attachment of a carboxyl-terminal segment of LDLR including the entire cytosolic domain to FR-alpha converted it into a transmembrane protein. The results indicate that in the FR-alpha/LDLR chimera the inability of the cellular machinery for GPI modification to recognize the hydrophobic domain is not due to the intrinsic nature of the peptide, but is rather due to the retention of the peptide within the lipid bilayer. It follows that the hydrophobic domain in the signal for GPI modification must traverse the ER membrane prior to recognition of the omega site by the GPI-protein transamidase. The results thus establish a critical topographical requirement for recognition of the GPI signal in the ER.     

Expression and function of the gonadotropin-releasing hormone receptor are dependent on a conserved apolar amino acid in the third intracellular loop

The coupling of agonist-activated heptahelical receptors to their cognate G proteins is often dependent on the amino-terminal region of the third intracellular loop. Like many G protein-coupled receptors, the gonadotropin-releasing hormone (GnRH) receptor contains an apolar amino acid in this region at a constant distance from conserved Pro and Tyr/Asn residues in the fifth transmembrane domain (TM V). An analysis of the role of this conserved residue (Leu(237)) in GnRH receptor function revealed that the binding affinities of the L237I and L237V mutant receptors were unchanged, but their abilities to mediate GnRH-induced inositol phosphate signaling, G protein coupling, and agonist-induced internalization were significantly impaired. Receptor expression at the cell surface was reduced by replacement of Leu(237) with Val, and abolished by replacement with Ala, Arg, or Asp residues. These results are consistent with molecular modeling of the TM V and VI regions of the GnRH receptor, which predicts that Leu(237) is caged by several apolar amino acids (Ile(233), Ile(234), and Val(240) in TM V, and Leu(262), Leu(265), and Val(269) in TM VI) to form a tight hydrophobic cluster. These findings indicate that the conserved apolar residue (Leu(237)) in the third intracellular loop is an important determinant of GnRH receptor expression and activation, and possibly that of other G protein-coupled receptors.     

Structure of murine complement component C3. II. Nucleotide sequence of cloned complementary DNA coding for the alpha chain

From the inserts of two recombinant plasmids isolated from a murine liver cDNA library, the nucleotide sequence coding for the C3 alpha chain was obtained and the corresponding amino acid sequence was derived. The alpha chain portion of the mRNA is 2979 nucleotides long, specifying a polypeptide of 993 amino acids. The molecular weight of the alpha chain, in the absence of carbohydrate, was calculated from the sequence data to be 112,933. Two possible carbohydrate attachment sites were predicted at residues 269 (Asn) and 947 (Asn). In addition, the positions for two putative factor I cleavage sites were predicted from a comparison with the cleavage sites in the human C3 alpha chain. The C3 alpha chain contains 24 cysteine residues, 10 of these clustered in the C-terminal 175 amino acids of the alpha chain. Together with the accompanying report (Lundwall, A, Wetsel, R.A., Domdey, H., Tack, B.F., and Fey, G.H. (1984) J. Biol. Chem. 259, 13851-13856), this study completes the nucleotide and amino acid structure of the murine precursor prepro-C3 molecule.     

Molecular cloning and localization of a cDNA encoding a crustacean hyperglycemic hormone from the South African spiny lobster,Jasus lalandii

A cDNA, encoding a crustacean hyperglycemic hormone (cHH) of the South African spiny lobster, Jasus lalandii has been cloned. The cDNA consists of 1773 bp with an open reading frame of 399 bp that encodes a preprohormone of 133 amino acid residues. The preprohormone consists of a 25 amino acid hydrophobic signal peptide, a 32 amino acid cHH precursor-related peptide (CPRP) and the cHH sequence of 72 amino acid residues. The cHH sequence is flanked N-terminally by a Lys-Arg cleavage site and C-terminally by Gly-Lys, where Gly serves as an amidation site. The deduced amino acid sequence of the CPRP is in complete agreement with a peptide previously elucidated from sinus glands of J. lalandii, code-named CPRP 2 and the sequence of the cHH peptide matches that of the minor cHH isoform of J. lalandii, i.e. crustacean hyperglycemic hormone-II (cHH-II), which was also previously obtained by peptide sequencing. In situ hybridization on eyestalks revealed strong cHH-II mRNA expression in a subset of neurosecretory cells of the X-organ.     

Molecular characterization of KEX1, a kexin-like protease in mouse Pneumocystis carinii

Expression screening of a Pneumocystis carinii-infected mouse lung cDNA library with specific monoclonal antibodies (mAbs) led to the identification of a P. carinii cDNA with extensive homology to subtilisin-like proteases, particularly fungal kexins and mammalian prohormone convertases. The 3.1 kb cDNA contains a single open reading frame encoding 1011 amino acids. Structural similarities to fungal kexins in the deduced primary amino acid sequence include a putative proenzyme domain delineated by a consensus autocatalytic cleavage site (Arg-Glu-Lys-Arg), conserved Asp, His, Asn and Ser residues in the putative catalytic domain, a hydrophobic transmembrane spanning domain, and a carboxy-terminal cytoplasmic domain with a conserved tyrosine motif thought to be important for localization of the protease in the endoplasmic reticulum and/or Golgi apparatus. Based on these structural similarities and the classification of P. carinii as a fungus, the protease was named KEX1. Southern blotting of mouse P. carinii chromosomes localized kex1 to a single chromosome of approximately 610 kb. Southern blotting of restriction enzyme digests of genomic DNA from P. carinii-infected mouse lung demonstrated that kex1 is a single copy gene. The function of kexins in other fungi suggests that KEX1 may be involved in the post-translational processing and maturation of other P. carinii proteins.     

Requirements for glycosylphosphatidylinositol attachment are similar but not identical in mammalian cells and parasitic protozoa

The general features of the glycosylphosphatidylinositol (GPI) signal have been conserved in evolution. To test whether the requirements for GPI attachment are indeed the same in mammalian cells and parasitic protozoa, we expressed the prototype GPI-linked protein of Trypanosoma brucei, the variant surface glycoprotein (VSG), in COS cells. Although large amounts of VSG were produced, only a small fraction became GPI linked. This impaired processing is not caused by the VSG ectodomain, since replacement of the VSG GPI signal with that of decay accelerating factor (DAF) produced GPI-linked VSG. Furthermore, whereas fusion of the DAF GPI signal to the COOH terminus of human growth hormone (hGH) produces GPI-linked hGH, an analogous hGH fusion using the VSG GPI signal does not, indicating that the VSG GPI signal functions poorly in mammalian cells. By constructing chimeric VSG-DAF GPI signals and fusing them to the COOH terminus of hGH, we show that of the two critical elements that comprise the GPI-signal--the cleavage/attachment site and the COOH terminal hydrophobic domain--the former is responsible for the impaired activity of the VSG GPI signal in COS cells. To confirm this, we show that the VSG GPI signal can be converted to a viable signal for mammalian cells by altering the amino acid configuration at the cleavage/attachment site. We also show that when fused to the COOH terminus of hGH, the putative GPI signal from the malaria circumsporozoite (CS) protein produces low levels of GPI- anchored hGH, suggesting that the CS protein is indeed GPI linked, but that the CS protein GPI signal, like the VSG-signal, functions poorly in COS cells. The finding that the requirements for GPI attachment are similar but not identical in parasitic protozoa and mammalian cells may allow for the development of selective inhibitors of GPI-anchoring that might prove useful as antiparasite therapeutics.     

A putative signal peptidase recognition site and sequence in eukaryotic and prokaryotic signal peptides

Presecretory signal peptides of 39 proteins from diverse prokaryotic and eukaryotic sources have been compared. Although varying in length and amino acid composition, the labile peptides share a hydrophobic core of approximately 12 amino acids. A positively charged residue (Lys or Arg) usually precedes the hydrophobic core. Core termination is defined by the occurrence of a charged residue, a sequence of residues which may induce a beta-turn in a polypeptide, or an interruption in potential alpha-helix or beta-extended strand structure. The hydrophobic cores contain, by weight average, 37% Leu: 15% Ala: 10% Val: 10% Phe: 7% Ile plus 21% other hydrophobic amino acids arranged in a non-random sequence. Following the hydrophobic cores (aligned by their last residue) a highly non-random and localized distribution of Ala is apparent within the initial eight positions following the core: (formula; see text) Coincident with this observation, Ala-X-Ala is the most frequent sequence preceding signal peptidase cleavage. We propose the existence of a signal peptidase recognition sequence A-X-B with the preferred cleavage site located after the sixth amino acid following the core sequence. Twenty-two of the above 27 underlined Ala residues would participate as A or B in peptidase cleavage. Position A includes the larger aliphatic amino acids, Leu, Val and Ile, as well as the residues already found at B (principally Ala, Gly and Ser). Since a preferred cleavage site can be discerned from carboxyl and not amino terminal alignment of the hydrophobic cores it is proposed that the carboxyl ends are oriented inward toward the lumen of the endoplasmic reticulum where cleavage is thought to occur. This orientation coupled with the predicted beta-turn typically found between the core and the cleavage site implies reverse hairpin insertion of the signal sequence. The structural features which we describe should help identify signal peptides and cleavage sites in presumptive amino acid sequences derived from DNA sequences.     

Identification of a critical basic residue on the ecotropic murine leukemia virus receptor

Susceptibility to ecotropic murine leukemia viruses (MLV) is restricted to mice and rats at the level of virus binding to the host cell receptor. Asparagine 232, valine 233, tyrosine 235, and glutamic acid 237 in the third extracellular domain (EL3) of the receptor are critical determinants of the host range difference between mice and humans. However, placing these residues in the human homolog confers only partial binding, indicating that other divergent sequences are involved. We sought to determine if the other sequences lie within or outside EL3. Here we report the identification of lysine 234 as another critical residue that influences virus binding and infection, as well as evidence that the unidentified sequences lie outside EL3. Each of the four basic residues in the third extracellular domain were changed to an acidic residue and initially examined in combination with a change at position 235 or position 237. Substitution of lysine 211, 215, or 222 combined with substitution of the critical tyrosine 235 or glutamic acid 237 did not affect virus infection. However, combined substitution of lysine 234, a conserved residue between mice and humans, and tyrosine 235 resulted in a marked decrease in virus infection and binding. A lysine 234 change alone reduced virus binding, contrary to previous observations that at least two of the other four residues must be changed before binding is reduced. Interestingly, there was no decrease in infection when lysine 234 was replaced in combination with glutamic acid 237. This result suggests that residue 234 may act by influencing the local structure of residues 233 to 235, whereas the presence of a glycine at position 236 may prevent this influence from extending to residue 237. With this report, the involvement of all the residues divergent between mice and humans in the third extracellular domain has been ruled out, suggesting that as yet unidentified determinants lie in other extracellular domains.     

The carboxyl terminus of Dictyostelium discoideum protein 1I encodes a functional glycosyl-phosphatidylinositol signal sequence

The 1I gene is expressed in the prespore cells of culminating Dictyostelium discoideum. The open reading frame of 1I cDNA encodes a protein of 155 amino acids with hydrophobic segments at both its NH(2)- and COOH-termini that are indicative of a glycosyl-phosphatidylinositol (GPI)-anchored protein. A hexaHis-tagged form of 1I expressed in D. discoideum cells appeared on Western blot analysis as a doublet of 27 and 24 kDa, with a minor polypeptide of 22 kDa. None of the polypeptides were released from the cell surface with bacterial phosphatidylinositol-specific phospholipase C, although all three were released upon nitrous acid treatment, indicating the presence of a phospholipase-resistant GPI anchor. Further evidence for the C-terminal sequence of 1I acting as a GPI attachment signal was obtained by replacing the GPI anchor signal sequence of porcine membrane dipeptidase with that from 1I. Two constructs of dipeptidase with the 1I GPI signal sequence were constructed, one of which included an additional six amino acids in the hydrophilic spacer. Both of the resultant constructs were targeted to the surface of COS cells and were GPI-anchored as shown by digestion with phospholipase C, indicating that the Dictyostelium GPI signal sequence is functional in mammalian cells. Site-specific antibodies recognising epitopes either side of the expected GPI anchor attachment site were used to determine the site of GPI anchor attachment in the constructs. These parallel approaches show that the C-terminal signal sequence of 1I can direct the addition of a GPI anchor.     

Site-directed mutagenesis, proteolytic cleavage, and activation of human proheparanase

Heparanase is an endo-beta-D-glucuronidase that degrades heparan sulfate in the extracellular matrix and cell surfaces. Human proheparanase is produced as a latent 65-kDa polypeptide undergoing processing at two potential proteolytic cleavage sites, located at Glu109-Ser110 (site 1) and Gln157-Lys158 (site 2). Cleavage of proheparanase yields 8- and 50-kDa subunits that heterodimerize to form the active enzyme. The fate of the linker segment (Ser110-Gln157) residing between the two subunits, the mode of processing, and the protease(s) engaged in proheparanase processing are currently unknown. We applied multiple site-directed mutagenesis and deletions to study the nature of the potential cleavage sites and amino acids essential for processing of proheparanase in transfected human choriocarcinoma cells devoid of endogenous heparanase but possessing the enzymatic machinery for proper processing and activation of the proenzyme. Although mutagenesis at site 1 and its flanking sequences failed to identify critical residues for proteolytic cleavage, processing at site 2 required a bulky hydrophobic amino acid at position 156 (i.e. P2 of the cleavage site). Substitution of Tyr156 by Ala or Glu, but not Val, resulted in cleavage at an upstream site in the linker segment, yielding an improperly processed inactive enzyme. Processing of the latent 65-kDa proheparanase in transfected Jar cells was inhibited by a cell-permeable inhibitor of cathepsin L. Moreover, recombinant 65-kDa proheparanase was processed and activated by cathepsin L in a cell-free system. Altogether, these results suggest that proheparanase processing at site 2 is brought about by cathepsin L-like proteases. The involvement of other members of the cathepsin family with specificity to bulky hydrophobic residues cannot be excluded. Our results and a three-dimensional model of the enzyme are expected to accelerate the design of inhibitory molecules capable of suppressing heparanase-mediated enhancement of tumor angiogenesis and metastasis.     

Optimising the signal peptide for glycosyl phosphatidylinositol modification of human acetylcholinesterase using mutational analysis and peptide-quantitative structure-activity relationships.

Glycosyl phosphatidylinositol (GPI)-modified proteins have a C-terminal signal peptide (GPIsp) that mediates the addition of a GPI-anchor to an amino acid residue at the cleavage and modification site (omega-site). Within the GPIsp, a stretch of hydrophilic amino acid residues are found which constitutes the spacer region that separates the omega-site residue from a hydrophobic C-terminus. Deletions and insertions into the spacer region of human acetylcholinesterase (AChE) show that the length of this spacer region is very important for efficient GPI-modification. Surprisingly, the natural length of the spacer region in human AChE was not optimal for the highest degree of GPI modification. The importance of the two adjacent residues downstream of the omega-site, the omega+1 and omega+2 residues, was investigated by peptide-quantitative structure-activity relationships (Peptide-QSAR). A model was made that predicts the efficiency of the GPI modification when these residues are substituted with others, and suggests important features for these residues. The most preferred omega+1 and omega+2 residues, predicted by the model, in combination with an ideal spacer length resulted in an optimised GPIsp. This mutant protein is more efficiently GPI-modified than any mutant AChE tested thus far.     

A novel trypsin-like serine protease (hepsin) with a putative transmembrane domain expressed by human liver and hepatoma cells

Recombinant clones with cDNA inserts coding for a new serine protease (hepsin) have been isolated from cDNA libraries prepared from human liver and hepatoma cell line mRNA. The total length of the cDNA is approximately 1.8 kilobases and includes a 5' untranslated region, 1251 nucleotides coding for a protein of 417 amino acids, a 3' untranslated region, and a poly(A) tail. The amino acid sequence coded by the cDNA for hepsin shows a high degree of identity to pancreatic trypsin and other serine proteases present in plasma. It also exhibits features characteristic of zymogens to serine proteases in that it contains a cleavage site for protease activation and the highly conserved regions surrounding the His, Asp, and Ser residues that participate in enzyme catalysis. In addition, hepsin lacks a typical amino-terminal signal peptide. Hydropathy analysis of the protein sequence, however, revealed a very hydrophobic region of 27 amino acids starting 18 residues downstream from the apparent initiator Met. This region may serve as an internal signal sequence and a transmembrane domain. This putative transmembrane domain could be involved in anchoring hepsin to the cell membrane and orienting it in such a manner that its carboxyl terminus, containing the catalytic domain, is extracellular.     

Analysis of tryptophan‐rich region in Clostridium septicum alpha‐toxin involved with binding to glycosylphosphatidylinositol‐anchored proteins

Clostridium septicum alpha‐toxin has a unique tryptophan‐rich region (³⁰²NGYSEWDWKWV³¹²) that consists of 11 amino acid residues near the C‐terminus. Using mutant toxins, the contribution of individual amino acids in the tryptophan‐rich region to cytotoxicity and binding to glycosylphosphatidylinositol (GPI)‐anchored proteins was examined. For retention of maximum cytotoxic activity, W307 and W311 are essential residues and residue 309 has to be hydrophobic and possess an aromatic side chain, such as tryptophan or phenylalanine. When residue 308, which lies between tryptophans (W307 and W309) is changed from an acidic to a basic amino acid, the cytotoxic activity of the mutant is reduced to less than that of the wild type. It was shown by a toxin overlay assay that the cytotoxic activity of each mutant toxin correlates closely with affinity to GPI‐anchored proteins. These findings indicate that the WDW_W sequence in the tryptophan‐rich region plays an important role in the cytotoxic mechanism of alpha‐toxin, especially in the binding to GPI‐anchored proteins as cell receptors.     

Covalent structure of collagen: amino acid sequence of alpha 2-CB5 of chick skin collagen containing the animal collagenase cleavage site.

The amino acid sequence of the 112 residues from the amino terminus of alpha 2-CB5 from chick skin collagen was determined by automated sequential degradation of intact alpha 2-CB5 and several chymotryptic and tryptic peptides. This segment of the peptide includes the site of the action of animal collagenases. As compared to the sequence around the alpha 1 cleavage site, the alpha 2 sequence is notable for the remarkable constancy of the residues to the amino side and the relative abundance of hydrophobic residues to the carboxyl side of the cleavage site, suggesting that these features are important in the recognition by the enzyme. The sequence of this region of the alpha 2 chain is consistent with the Gly-X-Y triplet structure and the preference of certain residues for either the X or Y position in distribution. However, three of the six residues of leucine were found in the Y position rather than the X position. Leucine residues were found only once in the Y position in the alpha 1 (I) chain. This preference does not appear to hold in the alpha 2 chain.     

Activation of the SspA serine protease zymogen of Staphylococcus aureus proceeds through unique variations of a trypsinogen-like mechanism and is dependent on both autocatalytic and metalloprotease-specific processing

The serine and cysteine proteases SspA and SspB of Staphylococcus aureus are secreted as inactive zymogens, zSspA and zSspB. Mature SspA is a trypsin-like glutamyl endopeptidase and is required to activate zSspB. Although a metalloprotease Aureolysin (Aur) is in turn thought to contribute to activation of zSspA, a specific role has not been demonstrated. We found that pre-zSspA is processed by signal peptidase at ANA(29) downward arrow, releasing a Leu(30) isoform that is first processed exclusively through autocatalytic intramolecular cleavage within a glutamine-rich propeptide segment, (40)QQTQSSKQQTPKIQ(53). The preferred site is Gln(43) with secondary processing at Gln(47) and Gln(53). This initial processing is necessary for optimal and subsequent Aur-dependent processing at Leu(58) and then Val(69) to release mature SspA. Although processing by Aur is rate-limiting in zSspA activation, the first active molecules of Val(69)SspA promote rapid intermolecular processing of remaining zSspA at Glu(65), producing an N-terminal (66)HANVILP isoform that is inactive until removal of the HAN tripeptide by Aur. Modeling indicated that His(66) of this penultimate isoform blocks the active site by hydrogen bonding to Ser(237) and occlusion of substrate. Binding of glutamate within the active site of zSspA is energetically unfavorable, but glutamine fits into the primary specificity pocket and is predicted to hydrogen bond to Thr(232) proximal to Ser(237), permitting autocatalytic cleavage of the glutamine-rich propeptide segment. These and other observations suggest that zSspA is activated through a trypsinogen-like mechanism where supplementary features of the propeptide must be sequentially processed in the correct order to allow efficient activation.