Secondary Binding Site of Trypsin: Revealed by Crystal Structure of Trypsin-Peptide Complex

Abstract

Designed synthetic heterochiral peptides, when added to porcine trypsin, resulted in reduction of enzyme activity. The crystal structure of a complex formed between porcine trypsin and a heterochiral hepta peptide Boc-Pro-DAsp-Aib-Leu-Aib-Leu-Ala-NHMe has been determined at 1.9 Å resolution. The hepta peptide does not bind at the active site, but is located in the interstitial region, and interacts with the calcium-binding loop (residues 60–80). The bound peptide interacts with the active site residue Ser195 through an acetate ion, and with Lys 60 mediated by water molecules. The structure, when compared with the other trypsin-peptide complexes, suggests that the flexibility of surface loops, concerted movement of the loops towards the active site, and the interaction of the bound peptide with Lys 60, may be responsible for the reduction in enzyme activity. This study provides a structural evidence for the earlier biochemical observation regarding the role of surface loops in the catalysis of the enzyme.     

Trypsin activity reduced by an autocatalytically produced nonapeptide

Trypsin, a serine protease enzyme plays a pivotal role in digestion and is autocatalytic. The crystal structure of a complex formed between porcine trypsin and an auto catalytically produced peptide is reported here. This complex shows a reduction in enzyme activity as compared to native beta-trypsin. The nonapeptide has a lysine, which is recognized by Asp 189 at the specificity pocket. The auto catalytically produced native nonapeptide is bound at the active site cleft like other trypsin inhibitors but the important interactions with the oxyanion hole are absent. The peptide covers only a part of the active site cleft and hence the enzyme activity is reduced rather than being inhibited.     

Trypsin Activity Reduced by an Autocatalytically Produced Nonapeptide

Abstract

Trypsin, a serine protease enzyme plays a pivotal role in digestion and is autocatalytic. The crystal structure of a complex formed between porcine trypsin and an auto catalytically produced peptide is reported here. This complex shows a reduction in enzyme activity as compared to native β-trypsin. The nonapeptide has a lysine, which is recognized by Asp 189 at the specificity pocket. The auto catalytically produced native nonapeptide is bound at the active site cleft like other trypsin inhibitors but the important interactions with the oxyanion hole are absent. The peptide covers only a part of the active site cleft and hence the enzyme activity is reduced rather than being inhibited.     

Structural Insights into the Role of the Cyclic Backbone in a Squash Trypsin Inhibitor

MCoTI-II is a head-to-tail cyclic peptide with potent trypsin inhibitory activity and, on the basis of its exceptional proteolytic stability, is a valuable template for the design of novel drug leads. Insights into inhibitor dynamics and interactions with biological targets are critical for drug design studies, particularly for protease targets. Here, we show that the cyclization and active site loops of MCoTI-II are flexible in solution, but when bound to trypsin, the active site loop converges to a single well defined conformation. This finding of reduced flexibility on binding is in contrast to a recent study on the homologous peptide MCoTI-I, which suggested that regions of the peptide are more flexible upon binding to trypsin. We provide a possible explanation for this discrepancy based on degradation of the complex over time. Our study also unexpectedly shows that the cyclization loop, not present in acyclic homologues, facilitates potent trypsin inhibitory activity by engaging in direct binding interactions with trypsin.     

Regulation of trypsin activity by peptide fraction of an aqueous extract of human placenta used as wound healer

An aqueous extract of human placenta, used as wound healer, shows stabilization of trypsin against autodigestion as one of the peptides of the extract binds very strongly with the protease. Trypsin retains 40% of activity at constant level between 20 and 26 days in presence of the extract against complete inactivation in its absence. Inhibition of esterolytic activity and inability to react with p-nitrophenyl-p'-guanidinobenzoate, HCl, an active site directed reagent, by trypsin in presence of a peptide fraction of the extract indicated blocking of the catalytic site of the enzyme. Rayleigh scattering, size-exclusion HPLC, fluorescence resonance energy transfer, and surface plasmon resonance show that fibronectin type III-like peptide present in the extract interacts with trypsin. The peptide-trypsin complex is dissociated in presence of high concentration of substrates. Thus, regulation of trypsin activity by the placental extract is evident.     

Antigenic activity of porcine muscle lactate dehydrogenase fragment 180-214 containing the histidine residue of the isoenzyme active center

Solid phase immunoenzymatic analysis was used to study the antigenic activity of proteolytic degradation products of the porcine muscle lactate dehydrogenase isoform M4. The presence in the enzyme structure of topographic (linear) antigenic determinants was demonstrated. Peptide 180-214 containing histidine-195 in the active center of lactate dehydrogenase was isolated from the tryptic hydrolysate of the carboxymethylated enzyme. This peptide interacts with antibodies against the native enzyme, i.e., antibodies bound to the immunoadsorbent, and causes a 20-25% inhibition of the antigen-antibody complex formation. Protein modification by fluorescein mercuriacetate at Cys-165 essential for the enzyme activity does not result in the synthesis of antibodies that would stimulate the inhibition of the lactate dehydrogenase catalytic activity as compared to antibodies to the native isoenzyme. The putative role of some amino acid residues in the structure of antigenic determinants of porcine muscle lactate dehydrogenase is discussed.     

New general approach for determining the solution structure of a ligand bound weakly to a receptor: structure of a fibrinogen Aalpha-like peptide bound to thrombin (S195A) obtained using NOE distance constraints and an ECEPP/3 flexible docking program.

A new approach incorporating flexible docking simulations and NMR data is presented for calculating the bound conformation of a ligand that interacts weakly with an enzyme. This approach consists of sampling directly the conformation of a flexible ligand inside a receptor active site containing surrounding flexible loops. To make this sampling efficient, a ligand-growing procedure has been adopted. Optimization of the ECEPP/3-plus-NOE constraint function is carried out by using a collective variable Monte Carlo minimization technique. Numerous energy minimizations are made possible for such a large system by using a Bezier splines energy grid technique. This new flexible docking approach was applied to determine the structure of a fibrinogen Aalpha-like peptide (7DFLAEGGGVRGPRV20) bound to an active site mutant of thrombin [thrombin(S195A)]. Structure calculations of the bound ligand, using 2D-transferred NOESY distance constraints in the DIANA program, showed that the N-terminal portion of the peptide (D7-R16) involves a chain reversal, whereas the C-terminal portion (G17-V20) adopts a fold that exists in several different orientations. In addition, the ECEPP/3 flexible docking package was used to assess the conformational variability of the ligand and surrounding 60D-insertion loop of thrombin. Amino acid residues (17-20) of the peptide interact with a region of the enzyme that exhibits broad specificity, with a preferred direction between the 60D-insertion loop and Pro37 of thrombin.     

The 80s loop of the catalytic chain of Escherichia coli aspartate transcarbamoylase is critical for catalysis and homotropic cooperativity.

The X-ray structure of the Escherichia coli aspartate transcarbamoylase with the bisubstrate analog phosphonacetyl-L-aspartate (PALA) bound shows that PALA interacts with Lys84 from an adjacent catalytic chain. To probe the function of Lys84, site-specific mutagenesis was used to convert Lys84 to alanine, threonine, and asparagine. The K84N and K84T enzymes exhibited 0.08 and 0.29% of the activity of the wild-type enzyme, respectively. However, the K84A enzyme retained 12% of the activity of the wild-type enzyme. For each of these enzymes, the affinity for aspartate was reduced 5- to 10-fold, and the affinity for carbamoyl phosphate was reduced 10- to 30-fold. The enzymes K84N and K84T exhibited no appreciable cooperativity, whereas the K84A enzyme exhibited a Hill coefficient of 1.8. The residual cooperativity and enhanced activity of the K84A enzyme suggest that in this enzyme another mechanism functions to restore catalytic activity. Modeling studies as well as molecular dynamics simulations suggest that in the case of only the K84A enzyme, the lysine residue at position 83 can reorient into the active site and complement for the loss of Lys84. This hypothesis was tested by the creation and analysis of the K83A enzyme and a double mutant enzyme (DM) that has both Lys83 and Lys84 replaced by alanine. The DM enzyme has no cooperativity and exhibited 0.18% of wild-type activity, while the K83A enzyme exhibited 61% of wild-type activity. These data suggest that Lys84 is not only catalytically important, but is also essential for binding both substrates and creation of the high-activity, high-affinity active site. Since low-angle X-ray scattering demonstrated that the mutant enzymes can be converted to the R-structural state, the loss of cooperativity must be related to the inability of these mutant enzymes to form the high-activity, high-affinity active site characteristic of the R-functional state of the enzyme.     

Study of the complex between porcine plasmin and alpha2-macroglobulin (author's transl)]

Porcine plasmin (EC 3.4.21.7) is obtained from plasminogen activated by human urokinase. This enzyme can bind, in an equimolecular ratio, to an alpha2-macroglobulin isolated from porcine serum. The number of active sites of plasmin has been determined through a burst titration of nitroaniline during the presteady-state hydrolysis of an amide substrate (N-alpha-carbobenzoxy-L-arginine-p-nitroanilide). The kinetic constants relative to a very sensitive ester substrate (N-alpha-carbobenzoxy-L-lysine nitrophenylester) hydrolysis have been measured. The binding of plasmin to alpha2-macroglobulin results in a complete inhibition of proteolytic activity, a reduction of active sites number and a decrease of esterolytic activity towards this substrate. In the complex, the residual activity (about 60%) is protected from protein inhibitors. Absorbance difference spectra show that 1 mol of alpha2-macroglobulin binds 1 mol of plasmin and 2 mol of trypsin. When plasmin is first bound to alpha2-macroglobulin, only 1 mol of trypsin can gain access tothe second site without removing the plasmin, showing that a steric hindrance is implicated in the inhibition performed by alpha2-macroglobulin binding.     

Tryptic cleavage as a probe of conformational differences between active and inactive forms of ornithine aminotransferase

Treatment of ornithine aminotransferase with trypsin resulted in rapid and complete loss of enzyme activity in a process that coincided with a reduction in subunit Mr of about 3000. However, electrophoresis showed that a substantial proportion of the enzyme had not been digested. The component of the preparation of ornithine aminotransferase that was insusceptible to trypsin contained a naturally occurring but enzymically inactive form of the enzyme, and when this had been removed, the remaining fully active enzyme was completely digested. Irreversible inactivation with a substrate analogue made all of the enzyme insusceptible to trypsin. The hydrolyzed enzyme still underwent a very slow half-reaction with ornithine. Sequence analysis of the truncated protein, prepared by blotting from electrophoretic gels, showed that hydrolysis had occurred at peptide bond Lys26-Tyr27.     

Electrostatic contributions to site specific DNA cleavage by EcoRV endonuclease

Mutational analysis of amino acids at the periphery of the EcoRV endonuclease active site suggests that moderate-range electrostatic effects play a significant role in modulating the efficiency of phosphoryl transfer. Asp36 and Lys38 located on minor-groove binding surface loops approach within 7-9 A of the scissile phosphates of the DNA. While the rates of single-site mutations removing the carboxylate or amine moieties at these positions are decreased 10(3)-10(5)-fold compared to that of wild-type EcoRV, we find that double mutants which rebalance the charge improve catalysis by up to 500-fold. Mutational analysis also suggests that catalytic efficiency is influenced by Lys173, which is buried at the base of a deep depression penetrating from a distal surface of the enzyme. The Lys173 amine group lies just 6 A from the amine group of the conserved essential Lys92 side chain in the active site. Kinetic and crystallographic analyses of the EcoRV E45A mutant enzyme further show that the Glu45 carboxylate group facilitates an extensive set of conformational transitions which occur upon DNA binding. The crystal structure of E45A bound to DNA and Mn2+ ions reveals significant conformational alterations in a small alpha-helical portion of the dimer interface located adjacent to the DNA minor groove. This leads to a tertiary reorientation of the two monomers as well as shifting of the key major-groove binding recognition loops. Because the Glu45 side chain does not appear to play a direct structural role in maintaining the active site, these rearrangements may instead originate in an altered electrostatic potential caused by removal of the negative charge. A Mn2+ binding site on the scissile phosphate is also disrupted in the E45A structure such that inner-sphere metal interactions made by the scissile DNA phosphate and conserved Asp90 carboxylate are each replaced with water molecules in the mutant. These findings argue against a proposed role for Asp36 as the general base in EcoRV catalysis, and reveal that the induced-fit conformational changes necessary for active site assembly and metal binding are significantly modulated by the electrostatic potential in this region.     

Evaluation of indole esters as inhibitors of p60(c-Src) receptor tyrosine kinase and investigation of the inhibition using receptor docking studies

Several indole esters were tested as inhibitors of tyrosine kinase p60(c-Src). Compound (4) was found fairly active against the enzyme with IC50 = 1.34 microM. DOCK methodology was used to asses our inhibitors for their inhibitory potency against tyrosine kinase. The docking results showed that compounds (4), (25) and (26) were bound to the active site of the enzyme Lys 295 of p60(c-Src) tyrosine kinase. Both activity and docking studies showed a parallel result, with compound (4) having a better interaction with the enzyme active site and also greater activity than the other compounds, indicating a potential role as new lead inhibitor.     

Purification and characterization of a putative proenkephalin cleaving enzyme.

A putative proenkephalin-cleaving enzyme (PCE) extracted from bovine adrenal chromaffin granules was purified with soybean trypsin inhibitor high-performance affinity chromatography. The 12,600-fold purified enzyme was maximally active at pH 8.0. The enzyme was completely inhibited with lima bean trypsin inhibitor (0.1 mg/ml), soybean trypsin inhibitor (0.1 mg/ml), and p-(chloromercuri)benzenesulfonic acid (1.0 mM), indicating PCE is a serine protease with cysteine residues likely to be involved in its structure or activity. It exhibited significant autoproteolysis without specific substrates present. The substrate specificity and kinetic constants with the enkephalin-containing (EC) peptides Leu-9 and proenkephalin Peptides B, E, and F as substrates were studied. The cleavage patterns were substantially different than with trypsin digestion. PCE specifically recognized the paired basic amino acid residues and predominantly cleaved the peptide bonds between Lys and Arg sites and peptide bonds after Lys-Lys and Arg-Arg sites. Different Km and Vmax values for the different Lys-Arg sites indicate sequences in addition to the paired basic residues can affect enzyme activity. Also, the lower Km and Vmax of Peptide E suggest a higher affinity for this peptide but much slower cleavage. The C-terminally located Lys-Arg site appears responsible for this high affinity. Based on these observations, we propose the following: (a) the primary structure of these peptides contains enough information to be processed correctly by PCE and (b) PCE may be regulated by pH and Peptide E to prevent extensive processing of the intermediate EC peptides which are the major opioid peptides found in the adrenal chromaffin granules.     

Template-assisted rational design of peptide inhibitors of furin using the lysine fragment of the mung bean trypsin inhibitor

Highly active, small-molecule furin inhibitors are attractive drug candidates to fend off bacterial exotoxins and viral infection. Based on the 22-residue, active Lys fragment of the mung bean trypsin inhibitor, a series of furin inhibitors were designed and synthesized, and their inhibitory activity towards furin and kexin was evaluated using enzyme kinetic analysis. The most potent inhibitor, containing 16 amino acid residues with a Ki value of 2.45x10(-9) m for furin and of 5.60x10(-7) m for kexin, was designed with three incremental approaches. First, two nonessential Cys residues in the Lys fragment were deleted via a Cys-to-Ser mutation to minimize peptide misfolding. Second, residues in the reactive site of the inhibitor were replaced by the consensus substrate recognition sequence of furin, namely, Arg at P1, Lys at P2, Arg at P4 and Arg at P6. In addition, the P7 residue Asp was substituted with Ala to avoid possible electrostatic interference with furin inhibition. Finally, the extra N-terminal and C-terminal residues beyond the doubly conjugated disulfide loops were further truncated. However, all resultant synthetic peptides were found to be temporary inhibitors of furin and kexin during a prolonged incubation, with the scissile peptide bond between P1 and P1' being cleaved to different extents by the enzymes. To enhance proteolytic resistance, the P1' residue Ser was mutated to D-Ser or N-methyl-Ser. The N-methyl-Ser mutant gave rise to a Ki value of 4.70x10(-8) m for furin, and retained over 80% inhibitory activity even after a 3 h incubation with the enzyme. By contrast, the d-Ser mutant was resistant to cleavage, although its inhibitory activity against furin drastically decreased. Our findings identify a useful template for the design of potent, specific and stable peptide inhibitors of furin, shedding light on the molecular determinants that dictate the inhibition of furin and kexin.     

Sepharose-bound trypsin and activated sepharose-bound trypsinogen. Studies with small and large substrates

Several enzymic and physical properties of Sepharose-bound trypsin and activated Sepharose-bound trypsinogen have been compared to those of the soluble enzyme. Sepharose-bound trypsinogen could be activated to the same extent as soluble trypsinogen; the release of the activation peptide and formation of the active site occurred as expected in the presence of catalytic amounts of trypsin. With synthetic substrates, the relative activity and pH dependence of both immobilized trypsin preparations were essentially identical and nearly the same as the soluble enzyme. Sepharose-trypsin also formed an inactive complex with soybean trypsin inhibitor, with 85% of the active sites participating. In contrast, the activity of Sepharose-trypsin with chymotrypsinogen and with trypsinogen as substrates was only 40% that of soluble trypsin. There is evidence for some catalytic heterogeneity of active sites of bound trypsin; probably those sites buried within the gel have a limited catalytic efficiency with macromolecular substrates. The immobilized enzyme is more stable than the soluble enzyme at elevated temperatures and to concentrated urea, and denaturation by urea at pH 8 is fully reversible since the loss of molecules by autolysis is eliminated.     

Identification of lysine 15 at the active site in Escherichia coli glycogen synthase. Conservation of Lys-X-Gly-Gly sequence in the bacterial and mammalian enzymes

Glycogen synthases from Escherichia coli and mammalian muscle differ in many respects including regulation, sugar nucleotide specificity, and primary sequence. To compare the structure of the active sites in these enzymes, the affinity-labeling study of the E. coli enzyme was carried out using adenosine diphosphopyridoxal as the reagent. The E. coli enzyme was inactivated in a time- and dose-dependent manner when incubated with the reagent followed by sodium borohydride reduction. The inactivation was markedly protected by ADP-glucose and ADP, suggesting that the reagent was bound to the substrate-binding site. The stoichiometry of the bound reagent to the enzyme was approximately 1:1. Sequence analysis of the labeled peptide isolated from a proteolytic digest of the modified protein revealed that Lys15 is labeled. Based on the geometry of the reagent, the epsilon-amino group of this residue might be located close to the pyrophosphate moiety of ADP-glucose bound to the E. coli enzyme, like that of Lys38 in the rabbit muscle enzyme, which is labeled by uridine diphosphopyridoxal (Tagaya, M., Nakano, K., and Fukui, T. (1986) J. Biol. Chem. 260, 6670-6676; Mahrenholz, A. M., Wang, Y., and Roach, P. J. (1988) J. Biol. Chem. 263, 10561-10567). The importance of the conserved sequence of Lys-X-Gly-Gly is discussed in connection with the glycine-rich region found in many nucleotide-binding proteins.     

Structural basis for the activation of phenylalanine in the non-ribosomal biosynthesis of gramicidin S.

The non-ribosomal synthesis of the cyclic peptide antibiotic gramicidin S is accomplished by two large multifunctional enzymes, the peptide synthetases 1 and 2. The enzyme complex contains five conserved subunits of approximately 60 kDa which carry out ATP-dependent activation of specific amino acids and share extensive regions of sequence similarity with adenylating enzymes such as firefly luciferases and acyl-CoA ligases. We have determined the crystal structure of the N-terminal adenylation subunit in a complex with AMP and L-phenylalanine to 1.9 A resolution. The 556 amino acid residue fragment is folded into two domains with the active site situated at their interface. Each domain of the enzyme has a similar topology to the corresponding domain of unliganded firefly luciferase, but a remarkable relative domain rotation of 94 degrees occurs. This conformation places the absolutely conserved Lys517 in a position to form electrostatic interactions with both ligands. The AMP is bound with the phosphate moiety interacting with Lys517 and the hydroxyl groups of the ribose forming hydrogen bonds with Asp413. The phenylalanine substrate binds in a hydrophobic pocket with the carboxylate group interacting with Lys517 and the alpha-amino group with Asp235. The structure reveals the role of the invariant residues within the superfamily of adenylate-forming enzymes and indicates a conserved mechanism of nucleotide binding and substrate activation.     

Studies on simultaneous inhibition of trypsin and chymotrypsin by horsegram Bowman-Birk inhibitor

Bowman-Birk inhibitors (BBI) isolated from plant seeds are small proteins active against trypsin and/or chymotrypsin. These inhibitors have been extensively studied in terms of their structure, interactions, function and evolution. Examination of the known three-dimensional structures of BBIs revealed similarities and subtle differences. The hydrophobic core, deduced from surface accessibility and hydrophobicity plots, corresponding to the two tandem structural domains of the double headed BBI are related by an almost exact two-fold, in contrast to the reactive site loops which depart appreciably from the two-fold symmetry. Also, the orientations of inhibitory loops in soybean and peanut inhibitors were different with respect to the rigid core. Based on the structure of Adzuki bean BBI-trypsin complex, models of trypsin and chymotryspin bound to the monomeric soybean BBI (SBI) were constructed. There were minor short contacts between the two enzymes bound to the inhibitor suggesting near independence of binding. Binding studies revealed that the inhibition of one enzyme in the presence of the other is associated with a minor negative cooperativity. In order to assess the functional significance of the reported oligomeric forms of BBI, binding of proteases to the crystallographic and non-crystallographic dimers as found in the crystal structure of peanut inhibitor were examined. It was found that all the active sites in these oligomers cannot simultaneously participate in inhibition.