Controlled intracellular processing of fusion proteins by TEV protease

Here we describe a method for controlled intracellular processing (CIP) of fusion proteins by tobacco etch virus (TEV) protease. A fusion protein containing a TEV protease recognition site is expressed in Escherichia coli cells that also contain a TEV protease expression vector. The fusion protein vector is an IPTG-inducible ColE1-type plasmid, such as a T7 or tac promoter vector. In contrast, the TEV protease is produced by a compatible p15A-type vector that is induced by tetracyclines. Not only is the TEV protease regulated independently of the fusion protein, but its expression is highly repressed in the absence of inducer. Certain fusion partners have been shown to enhance the yield and solubility of their passenger proteins. When CIP is used as a purification step, it is possible to take advantage of these characteristics while both eliminating the need for large amounts of pure protease at a later stage and possibly simplifying the purification process. Additionally, we have observed that in some cases the timing of intracellular proteolysis can affect the solubility of the cleaved passenger protein, allowing it to be directed to either the soluble or the insoluble fraction of the crude cell lysate. This method also makes it possible to quickly gauge the efficiency of proteolysis in vivo, before protein purification has begun and in vitro processing is attempted.     

Efficient site-specific processing of fusion proteins by tobacco vein mottling virus protease in vivo and in vitro

Affinity tags are widely used as vehicles for the production of recombinant proteins. Yet, because of concerns about their potential to interfere with the activity or structure of proteins, it is almost always desirable to remove them from the target protein. The proteases that are most often used to cleave fusion proteins are factor Xa, enterokinase, and thrombin, yet the literature is replete with reports of fusion proteins that were cleaved by these proteases at locations other than the designed site. It is becoming increasingly evident that certain viral proteases have more stringent sequence specificity. These proteases adopt a trypsin-like fold but possess an unconventional catalytic triad in which Cys replaces Ser. The tobacco etch virus (TEV) protease is the best-characterized enzyme of this type. TEV protease cleaves the sequence ENLYFQG/S between QG or QS with high specificity. The tobacco vein mottling virus (TVMV) protease is a close relative of TEV protease with a distinct sequence specificity (ETVRFQG/S). We show that, like TEV protease, TVMV protease can be used to cleave fusion proteins with high specificity in vitro and in vivo. We compared the catalytic activity of the two enzymes as a function of temperature and ionic strength, using an MBP-NusG fusion protein as a model substrate. The behavior of TVMV protease was very similar to that of TEV protease. Its catalytic activity was greatest in the absence of NaCl, but diminished only threefold with increasing salt up to 200 mM. We found that the optimum temperatures of the two enzymes are nearly the same and that they differ only two-fold in catalytic efficiency, both at room temperature and 4 degrees C. Hence, TVMV protease may be a useful alternative to TEV protease when a recombinant protein happens to contain a sequence that is similar to a TEV protease recognition site or for protein expression strategies that involve the use of more than one protease.     

Specificity of the hepatitis C virus NS3 serine protease: effects of substitutions at the 3/4A, 4A/4B, 4B/5A, and 5A/5B cleavage sites on polyprotein processing.

Cleavage at four sites (3/4A, 4A/4B, 4B/5A, and 5A/5B) in the hepatitis C virus polyprotein requires a viral serine protease activity residing in the N-terminal one-third of the NS3 protein. Sequence comparison of the residues flanking these cleavage sites reveals conserved features including an acidic residue (Asp or Glu) at the P6 position, a Cys or Thr residue at the P1 position, and a Ser or Ala residue at the P1' position. In this study, we used site-directed mutagenesis to assess the importance of these and other residues for NS3 protease-dependent cleavages. Substitutions at the P7 to P2' positions of the 4A/4B site had varied effects on cleavage efficiency. Only Arg at the P1 position or Pro at P1' substantially blocked processing at this site. Leu was tolerated at the P1 position, whereas five other substitutions allowed various degrees of cleavage. Substitutions with positively charged or other hydrophilic residues at the P7, P3, P2, and P2' positions did not reduce cleavage efficiency. Five substitutions examined at the P6 position allowed complete cleavage, demonstrating that an acidic residue at this position is not essential. Parallel results were obtained with substrates containing an active NS3 protease domain in cis or when the protease domain was supplied in trans. Selected substitutions blocking or inhibiting cleavage at the 4A/4B site were also examined at the 3/4A, 4B/5A, and 5A/5B sites. For a given substitution, a site-dependent gradient in the degree of inhibition was observed, with a 3/4A site being least sensitive to mutagenesis, followed by the 4A/4B, 4B/5A, and 5A/5B sites. In most cases, mutations abolishing cleavage at one site did not affect processing at the other serine protease-dependent sites. However, mutations at the 3/4A site which inhibited cleavage also interfered with processing at the 4B/5A site. Finally, during the course of these studies an additional NS3 protease-dependent cleavage site has been identified in the NS4B region.     

Polypeptide substrate specificity of PsLSMT. A set domain protein methyltransferase

Rubisco large subunit methyltransferase (PsLSMT) is a SET domain protein responsible for the trimethylation of Lys-14 in the large subunit of Rubisco. The polypeptide substrate specificity determinants for pea Rubisco large subunit methyltransferase were investigated using a fusion protein construct between the first 23 amino acids from the large subunit of Rubisco and human carbonic anhydrase II. A total of 40 conservative and non-conservative amino acid substitutions flanking the target Lys-14 methylation site (positions P(-3) to P(+3)) were engineered in the fusion protein. The catalytic efficiency (k(cat)/K(m)) of PsLSMT was determined using each of the substitutions and a polypeptide consensus recognition sequence deduced from the results. The consensus sequence, represented by X-(Gly/Ser)-(Phe/Tyr)-Lys-(Ala/Lys/Arg)-(Gly/Ser)-pi, where X is any residue, Lys is the methylation site, and pi is any aromatic or hydrophobic residue, was used to predict potential alternative substrates for PsLSMT. Four chloroplast-localized proteins were identified including gamma-tocopherol methyltransferase (gamma-TMT). In vitro methylation assays using PsLSMT and a bacterially expressed form of gamma-TMT from Perilla frutescens confirmed recognition and methylation of gamma-TMT by PsLSMT in vitro. RNA interference-mediated knockdown of the PsLSMT homologue (NtLSMT) in transgenic tobacco plants resulted in a 2-fold decrease of alpha-tocopherol, the product of gamma-TMT. The results demonstrate the efficacy of consensus sequence-driven identification of alternative substrates for PsLSMT as well as identification of functional attributes of protein methylation catalyzed by LSMT.     

Tobacco etch virus protease: mechanism of autolysis and rational design of stable mutants with wild-type catalytic proficiency.

Because of its stringent sequence specificity, the catalytic domain of the nuclear inclusion protease from tobacco etch virus (TEV) is a useful reagent for cleaving genetically engineered fusion proteins. However, a serious drawback of TEV protease is that it readily cleaves itself at a specific site to generate a truncated enzyme with greatly diminished activity. The rate of autoinactivation is proportional to the concentration of TEV protease, implying a bimolecular reaction mechanism. Yet, a catalytically active protease was unable to convert a catalytically inactive protease into the truncated form. Adding increasing concentrations of the catalytically inactive protease to a fixed amount of the wild-type enzyme accelerated its rate of autoinactivation. Taken together, these results suggest that autoinactivation of TEV protease may be an intramolecular reaction that is facilitated by an allosteric interaction between protease molecules. In an effort to create a more stable protease, we made amino acid substitutions in the P2 and P1' positions of the internal cleavage site and assessed their impact on the enzyme's stability and catalytic activity. One of the P1' mutants, S219V, was not only far more stable than the wild-type protease (approximately 100-fold), but also a more efficient catalyst.     

Crystal structure of tobacco etch virus protease shows the protein C terminus bound within the active site

Tobacco etch virus (TEV) protease is a cysteine protease exhibiting stringent sequence specificity. The enzyme is widely used in biotechnology for the removal of the affinity tags from recombinant fusion proteins. Crystal structures of two TEV protease mutants as complexes with a substrate and a product peptide provided the first insight into the mechanism of substrate specificity of this enzyme. We now report a 2.7A crystal structure of a full-length inactive C151A mutant protein crystallised in the absence of peptide. The structure reveals the C terminus of the protease bound to the active site. In addition, we determined dissociation constants of TEV protease substrate and product peptides using isothermal titration calorimetry for various forms of this enzyme. Data suggest that TEV protease could be inhibited by the peptide product of autolysis. Separate modes of recognition for native substrates and the site of TEV protease self-cleavage are proposed.     

Substrate requirements of human rhinovirus 3C protease for peptide cleavage in vitro

A series of synthetic peptides representing authentic proteolytic cleavage sites of human rhinovirus type 14 were assayed as substrates for purified 3C protease. Competition cleavage assays were employed to determine the relative specificity constants (Kcat/Km) for substrates with sequences related to the viral 2C-3A cleavage site. Variable length peptides representing the 2C-3A cleavage site were cleaved with comparable efficiency. These studies defined a minimum substrate of 6 amino acids (TLFQ/GP), although retention of the residue at position P5 (ETLFQ/GP) resulted in a better substrate by an order of magnitude. Amino acid substitutions at position P5, P4, P1', or P2' indicated that the identity of the residue at position P5 was not critical, whereas substitutions at position P4, P1' or P2' resulted in substrates with Kcat/Km values varying over 2 orders of magnitude. In contrast to the 2C-3A cleavage site, small peptide derivatives representative of the 3A-3B cleavage site were relatively poor substrates, which suggested that residues flanking the minimum core sequence may influence susceptibility to cleavage. The 3C protease of rhinovirus type 14 was also capable of cleaving peptides representing comparable cleavage sites predicted for coxsackie B virus and poliovirus.     

Actin, troponin C, Alzheimer amyloid precursor protein and pro-interleukin 1 beta as substrates of the protease from human immunodeficiency virus

We show here for the first time that actin, troponin C, Alzheimer amyloid precursor protein (AAP), and pro-interleukin 1 beta (pro-IL-1 beta), are substrates of the protease encoded by the human immunodeficiency virus (HIV) type-1. As has been seen in other non-viral protein substrates of the HIV protease, the presence of Glu residues in the P2' position appears to play an important role in substrate recognition. Three of the four bonds cleaved in actin, two of the three in troponin C, and all of the bonds hydrolyzed in AAP and pro-IL-1 beta have a P2' Glu residue. In fact, Glu residues are accommodated in all positions from P4 to P4' surrounding the scissile bond in substrates of the HIV proteases, and as many as 4 adjacent Glu residues were seen in one of the bonds cleaved in AAP. This study of non-viral protein substrates has also revealed unexpected amino acids such as Gly, Arg, and Glu in the scissile bond itself rather than the more conventional hydrophobic amino acids. The HIV-2 protease hydrolyzed actin in a manner similar to that of the HIV-1 enzyme, but its cleavage of troponin C was distinct in that it split a bond adjacent to a triplet of Glu residues in P2, P3, and P4 that was refractory to the HIV-1 enzyme. Documentation of cleavage sites in the several important cellular proteins noted above has extended our understanding of the features in a substrate that are recognized by these multi sub-site proteases of retroviral maturation. Moreover, the present work adds to an accumulating body of evidence which demonstrates that these enzymes can damage crucial structural and regulatory cellular proteins if ever their activity is expressed outside the viral particle itself.     

Purified NS2B/NS3 serine protease of dengue virus type 2 exhibits cofactor NS2B dependence for cleavage of substrates with dibasic amino acids in vitro

Dengue virus type 2 NS3, a multifunctional protein, has a serine protease domain (NS3pro) that requires the conserved hydrophilic domain of NS2B for protease activity in cleavage of the polyprotein precursor at sites following two basic amino acids. In this study, we report the expression of the NS2B-NS3pro precursor in Escherichia coli as a fusion protein with a histidine tag at the N terminus. The precursor was purified from insoluble inclusion bodies by Ni(2+) affinity and gel filtration chromatography under denaturing conditions. The denatured precursor was refolded to yield a purified active protease complex. Biochemical analysis of the protease revealed that its activity toward either a natural substrate, NS4B-NS5 precursor, or the fluorogenic peptide substrates containing two basic residues at P1 and P2, was dependent on the presence of the NS2B domain. The peptide with a highly conserved Gly residue at P3 position was 3-fold more active as a substrate than a Gln residue at this position. The cleavage of a chromogenic substrate with a single Arg residue at P1 was NS2B-independent. These results suggest that heterodimerization of the NS3pro domain with NS2B generates additional specific interactions with the P2 and P3 residues of the substrates.     

Cleavage preference distinguishes the two-component NS2B-NS3 serine proteinases of Dengue and West Nile viruses

Regulated proteolysis of the polyprotein precursor by the NS2B-NS3 protease is required for the propagation of infectious virions. Unless the structural and functional parameters of NS2B-NS3 are precisely determined, an understanding of its functional role and the design of flaviviral inhibitors will be exceedingly difficult. Our objectives were to define the substrate recognition pattern of the NS2B-NS3 protease of West Nile and Dengue virises (WNV and DV respectively). To accomplish our goals, we used an efficient, 96-well plate format, method for the synthesis of 9-mer peptide substrates with the general P4-P3-P2-P1-P1'-P2'-P3'-P4'-Gly structure. The N-terminus and the constant C-terminal Gly of the peptides were tagged with a fluorescent tag and with a biotin tag respectively. The synthesis was followed by the proteolytic cleavage of the synthesized, tagged peptides. Because of the strict requirement for the presence of basic amino acid residues at the P1 and the P2 substrate positions, the analysis of approx. 300 peptide sequences was sufficient for an adequate representation of the cleavage preferences of the WNV and DV proteinases. Our results disclosed the strict substrate specificity of the WNV protease for which the (K/R)(K/R)R/GG amino acid motifs was optimal. The DV protease was less selective and it tolerated well the presence of a number of amino acid residue types at either the P1' or the P2' site, as long as the other position was occupied by a glycine residue. We believe that our data represent a valuable biochemical resource and a solid foundation to support the design of selective substrates and synthetic inhibitors of flaviviral proteinases.     

Molecular determinants of substrate specificity for Semliki Forest virus nonstructural protease

The C-terminal cysteine protease domain of Semliki Forest virus nonstructural protein 2 (nsP2) regulates the virus life cycle by sequentially cleaving at three specific sites within the virus-encoded replicase polyprotein P1234. The site between nsP3 and nsP4 (the 3/4 site) is cleaved most efficiently. Analysis of Semliki Forest virus-specific cleavage sites with shuffled N-terminal and C-terminal half-sites showed that the main determinants of cleavage efficiency are located in the region preceding the cleavage site. Random mutagenesis analysis revealed that amino acid residues in positions P4, P3, P2, and P1 of the 3/4 cleavage site cannot tolerate much variation, whereas in the P5 position most residues were permitted. When mutations affecting cleavage efficiency were introduced into the 2/3 and 3/4 cleavage sites, the resulting viruses remained viable but had similar defects in P1234 processing as observed in the in vitro assay. Complete blockage of the 3/4 cleavage was found to be lethal. The amino acid in position P1' had a significant effect on cleavage efficiency, and in this regard the protease markedly preferred a glycine residue over the tyrosine natively present in the 3/4 site. Therefore, the cleavage sites represent a compromise between protease recognition and other requirements of the virus life cycle. The protease recognizes at least residues P4 to P1', and the P4 arginine residue plays an important role in the fast cleavage of the 3/4 site.     

An improved strategy for high-level production of TEV protease in Escherichia coli and its purification and characterization

Because of its stringent sequence specificity, tobacco etch virus (TEV) protease emerges as a useful reagent with wide application in the cleavage of recombinant fusion proteins. However, the solubility of TEV protease expressed in Escherichia coli is extremely low. In the present study, we introduced a more efficient system to improve and facilitate the soluble production of TEV protease in E. coli. Optimal expression of soluble His6-TEV was achieved by examining the contribution of chaperone co-expression and lower temperature fermentation. When further purified by Ni(2+) affinity chromatography, 65mg of His6-TEV was isolated with purity over 95% from 1L of culture. The enzyme activity of His6-TEV was generally characterized by using GST-EGFP and His6-L-TNF fusion protein as substrates, which contained a TEV cleavage site between two moieties.     

Human mesotrypsin exhibits restricted S1' subsite specificity with a strong preference for small polar side chains

Mesotrypsin, an inhibitor-resistant human trypsin isoform, does not activate or degrade pancreatic protease zymogens at a significant rate. These observations led to the proposal that mesotrypsin is a defective digestive protease on protein substrates. Surprisingly, the studies reported here with alpha1-antitrypsin (alpha1AT) revealed that, even though mesotrypsin was completely resistant to this serpin-type inhibitor, it selectively cleaved the Lys10-Thr11 peptide bond at the N-terminus. Analyzing a library of alpha1AT mutants in which Thr11 was mutated to various amino acids, we found that mesotrypsin hydrolyzed lysyl peptide bonds containing Thr or Ser at the P1' position with relatively high specificity (kcat/KM approximately 10(5) m(-1) x s(-1)). Compared with Thr or Ser, P1' Gly or Met inhibited cleavage 13- and 25-fold, respectively, whereas P1' Asn, Asp, Ile, Phe or Tyr resulted in 100-200-fold diminished rates of proteolysis, and Pro abolished cleavage completely. Consistent with the Ser/Thr P1' preference, mesotrypsin cleaved the Arg358-Ser359 reactive-site peptide bond of alpha1AT Pittsburgh and was rapidly inactivated by the serpin mechanism (ka approximately 10(6) m(-1) s(-1)). Taken together, the results indicate that mesotrypsin is not a defective protease on polypeptide substrates in general, but exhibits a relatively high specificity for Lys/Arg-Ser/Thr peptide bonds. This restricted, thrombin-like subsite specificity explains why mesotrypsin cannot activate pancreatic zymogens, but might activate certain proteinase-activated receptors. The observations also identify alpha1AT Pittsburgh as an effective mesotrypsin inhibitor and the serpin mechanism as a viable stratagem to overcome the inhibitor-resistance of mesotrypsin.     

Mechanism of inhibition of the retroviral protease by a Rous sarcoma virus peptide substrate representing the cleavage site between the gag p2 and p10 proteins.

The activity of the avian myeloblastosis virus (AMV) or the human immunodeficiency virus type 1 (HIV-1) protease on peptide substrates which represent cleavage sites found in the gag and gag-pol polyproteins of Rous sarcoma virus (RSV) and HIV-1 has been analyzed. Each protease efficiently processed cleavage site substrates found in their cognate polyprotein precursors. Additionally, in some instances heterologous activity was detected. The catalytic efficiency of the RSV protease on cognate substrates varied by as much as 30-fold. The least efficiently processed substrate, p2-p10, represents the cleavage site between the RSV p2 and p10 proteins. This peptide was inhibitory to the AMV as well as the HIV-1 and HIV-2 protease cleavage of other substrate peptides with Ki values in the 5-20 microM range. Molecular modeling of the RSV protease with the p2-p10 peptide docked in the substrate binding pocket and analysis of a series of single-amino acid-substituted p2-p10 peptide analogues suggested that this peptide is inhibitory because of the potential of a serine residue in the P1' position to interact with one of the catalytic aspartic acid residues. To open the binding pocket and allow rotational freedom for the serine in P1', there is a further requirement for either a glycine or a polar residue in P2' and/or a large amino acid residue in P3'. The amino acid residues in P1-P4 provide interactions for tight binding of the peptide in the substrate binding pocket.     

Chemical replacement of P1' serine residue at the second reactive site of soybean protease inhibitor C-II

The P1' Ser(50) at the second reactive site of soybean protease inhibitor C-II was replaced with arginine to confirm the contribution of this residue to the inhibition. The Arg derivative had less trypsin inhibitory activity (Ki = 1 X 10(-7) M) than the Ser derivative (Ki = 2 X 10(-8) M), in contrast to the results obtained from studies on peanut protease inhibitor B-III reported in the previous paper (J. Biochem. 101, 723-728 (1987)). These results suggest that each Bowman-Birk type inhibitor has an amino acid at the P1' position inherently best suited to maintaining its inhibitory activity, and that serine is not unique for the P1' amino acid in Bowman-Birk type inhibitors.     

In silico mutations and molecular dynamics studies on a winged bean chymotrypsin inhibitor protein

Winged bean chymotrypsin inhibitor (WCI) has an intruding residue Asn14 that plays a crucial role in stabilizing the reactive site loop conformation. This residue is found to be conserved in the Kunitz (STI) family of serine protease inhibitors. To understand the contribution of this scaffolding residue on the stability of the reactive site loop, it was mutated in silico to Gly, Ala, Ser, Thr, Leu and Val and molecular dynamics (MD) simulations were carried out on the mutants. The results of MD simulations reveal the conformational variability and range of motions possible for the reactive site loop of different mutants. The N-terminus side of the scissile bond, which is close to a beta-barrel, is conformationally less variable, while the C-terminus side, which is relatively far from any such secondary structural element, is more variable and needs stability through hydrogen-bonding interactions. The simulated structures of WCI and the mutants were docked in the peptide-binding groove of the cognate enzyme chymotrypsin and the ability to form standard hydrogen-bonding interactions at P3, P1 and P2' residues were compared. The results of the MD simulations coupled with docking studies indicate that hydrophobic residues like Leu and Val at the 14th position are disruptive for the integrity of the reactive site loop, whereas a residue like Thr, which can stabilize the C-terminus side of the scissile bond, can be predicted at this position. However, the size and charge of the Asn residue made it most suitable for the best maintenance of the integrity of the reactive site loop, explaining its conserved nature in the family.     

3C-like protease of rabbit hemorrhagic disease virus: identification of cleavage sites in the ORF1 polyprotein and analysis of cleavage specificity.

Rabbit hemorrhagic disease virus, a positive-stranded RNA virus of the family Caliciviridae, encodes a trypsin-like cysteine protease as part of a large polyprotein. Upon expression in Escherichia coli, the protease releases itself from larger precursors by proteolytic cleavages at its N and C termini. Both cleavage sites were determined by N-terminal sequence analysis of the cleavage products. Cleavage at the N terminus of the protease occurred with high efficiency at an EG dipeptide at positions 1108 and 1109. Cleavage at the C terminus of the protease occurred with low efficiency at an ET dipeptide at positions 1251 and 1252. To study the cleavage specificity of the protease, amino acid substitutions were introduced at the P2, P1, and P1' positions at the cleavage site at the N-terminal boundary of the protease. This analysis showed that the amino acid at the P1 position is the most important determinant for substrate recognition. Only glutamic acid, glutamine, and aspartic acid were tolerated at this position. At the P1' position, glycine, serine, and alanine were the preferred substrates of the protease, but a number of amino acids with larger side chains were also tolerated. Substitutions at the P2 position had only little effect on the cleavage efficiency. Cell-free expression of the C-terminal half of the ORF1 polyprotein showed that the protease catalyzes cleavage at the junction of the RNA polymerase and the capsid protein. An EG dipeptide at positions 1767 and 1768 was identified as the putative cleavage site. Our data show that rabbit hemorrhagic disease virus encodes a trypsin-like cysteine protease that is similar to 3C proteases with regard to function and specificity but is more similar to 2A proteases with regard to size.     

Characterization of the S1 binding site of the glutamic acid-specific protease from Streptomyces griseus.

The glutamic acid-specific protease from Streptomyces griseus (SGPE) is an 18.4-kDa serine protease with a distinct preference for Glu in the P1 position. Other enzymes characterized by a strong preference for negatively charged residues in the P1 position, e.g., interleukin-1 beta converting enzyme (ICE), use Arg or Lys residues as counterions within the S1 binding site. However, in SGPE, this function is contributed by a His residue (His 213) and two Ser residues (Ser 192 and S216). It is demonstrated that proSGPE is activated autocatalytically and dependent on the presence of a Glu residue in the -1 position. Based on this observation, the importance of the individual S1 residues is evaluated considering that enzymes unable to recognize a Glu in the P1 position will not be activated. Among the residues constituting the S1 binding site, it is demonstrated that His 213 and Ser 192 are essential for recognition of Glu in the P1 position, whereas Ser 216 is less important for catalysis out has an influence on stabilization of the ground state. From the three-dimensional structure, it appears that His 213 is linked to two other His residues (His 199 and His 228), forming a His triad extending from the S1 binding site to the back of the enzyme. This hypothesis has been tested by substitution of His 199 and His 228 with other amino acid residues. The catalytic parameters obtained with the mutant enzymes, as well as the pH dependence, do not support this theory; rather, it appears that His 199 is responsible for orienting His 213 and that His 228 has no function associated with the recognition of Glu in P1.     

Substrate specificity of ascidian sperm trypsin-like proteases,spermosin and acrosin

In order to investigate systematically the substrate or subsite specificity of two sperm proteases; acrosin and spermosin (a novel trypsin-like protease) of the ascidian, Halocynthia roretzi, the effects of peptidyl-argininals on the purified enzymes as well as on fertilization were examined. Among four benzyloxycarbonyl (Z)-Leu-X-argininals (X = Pro, Leu, Ser, and Gly), Z-Leu-Pro-argininal showed the strongest inhibition toward the spermosin activity. On the P3 site specificity, Val-Pro-argininal derivatives showed a stronger inhibition than a Leu-Pro-argininal derivative, suggesting the preference of Val rather than Leu residue at the P3 position. Similar results were obtained by analyzing the hydrolyzing activity of the fluorogenic peptide substrates: it hydrolyzed Boc-Val-Pro-Arg-4-methylcoumaryl-7-amide (MCA) most efficiently, and Boc-Asp(O-benzyl)-Pro-Arg-MCA was the next best substrate, but Gly-Pro-Arg (or Lys)-MCAs were hardly hydrolyzed. On the other hand, acrosin was found to prefer Leu or Pro residue rather than Gly or Ser residue at the P2 position as revealed by comparing the Ki values of peptidyl-argininals. Detailed kinetic analysis on the inhibitory abilities of peptidyl-argininals toward the purified enzymes and the ascidian fertilization suggested that both acrosin and spermosin are involved in ascidian fertilization. © 1996 Wiley Liss, Inc.     

Substrate specificity of the protease that processes human interleukin-1 beta

The substrate specificity of the protease which generates mature human interleukin-1 beta (IL-1 beta) from pro-interleukin-1 beta was investigated using synthetic peptide substrates and recombinant pro-IL-1 beta. The requirement of an L-aspartate in the P-1 position was confirmed together with the need for a small hydrophobic residue in the P-1' position (Gly or Ala). It was shown that the enzyme can tolerate conservative substitutions in the P-2 and P-2' positions. We found little difference in the enzyme's ability to cleave denatured and native pro-IL-1 beta, indicating that tertiary structure recognition is not involved in binding. The enzyme did, however, require a peptide of more than six amino acids for cleavage to occur. These results conclusively demonstrate the unusual specificity of this protease.