The refined structure of the epsilon-aminocaproic acid complex of human plasminogen kringle 4.

The crystallographic structure of the plasminogen kringle 4-epsilon-aminocaproic acid (ACA) complex (K4-ACA) has been solved by molecular replacement rotation-translation methods utilizing the refined apo-K4 structure as a search model (Mulichak et al., 1991), and it has been refined to an R value of 0.148 at 2.25-A resolution. The K4-ACA structure consists of two interkringle residues, the kringle along with the ACA ligand, and 106 water molecules. The lysine-binding site has been confirmed to be a relatively open and shallow depression, lined by aromatic rings of Trp62, Phe64, and Trp72, which provide a highly nonpolar environment between doubly charged anionic and cationic centers formed by Asp55/Asp57 and Lys35/Arg71. A zwitterionic ACA ligand molecule is held by hydrogen-bonded ion pair interactions and van der Waals contacts between the charged centers. The lysine-binding site of apo-K4 and K4-ACA have been compared: the rms differences in main-chain and side-chain positions are 0.25 and 0.69 A, respectively, both practically within error of the determinations. The largest deviations in the binding site are due to different crystal packing interactions. Thus, the lysine-binding site appears to be preformed, and lysine binding does not require conformational changes of the host. The results of NMR studies of lysine binding with K4 are correlated with the structure of K4-ACA and agree well.     

Structure and binding determinants of the recombinant kringle-2 domain of human plasminogen to an internal peptide from a group A Streptococcal surface protein

The X-ray crystal structure of a complex of a modified recombinant kringle-2 domain of human plasminogen, K2Pg[C4G/E56D/L72Y] (mK2Pg), containing an upregulated lysine-binding site, bound to a functional 30 residue internal peptide (VEK-30) from an M-type protein of a group A Streptococcus surface protein, has been determined by molecular replacement methods using K4Pg as a model, and refined at 2.7 A resolution to a R-factor of 19.5 %. The X-ray crystal structure shows that VEK-30 exists as a nearly end-to-end alpha-helix in the complex with mK2Pg. The final structure also revealed that Arg17 and His18 of VEK-30 served as cationic loci for Asp54 and Asp56 of the consensus lysine-binding site of mK2Pg, while Glu20 of VEK-30 coordinates with Arg69 of the cationic binding site of mK2Pg. The hydrophobic ligand-binding pocket in mK2Pg, consisting primarily of Trp60 and Trp70, situated between the positive and negative centers of the lysine-binding site, is utilized in a novel manner in stabilizing the interaction with VEK-30 by forming a cation-pi-electron-mediated association with the positive side-chain of Arg17 of this peptide. Additional lysine-binding sites, as well as exosite electrostatic and hydrogen bonding interactions involving Glu9 and Lys14 of VEK-30, were observed in the structural model. The importance of these interactions were tested in solution by investigating the binding constants of synthetic variants of VEK-30 to mK2Pg, and it was found that, Lys14, Arg17, His18, and Glu20 of VEK-30 were the most critical amino acid binding determinants. With regard to the solution studies, circular dichroism analysis of the titration of VEK-30 with mK2Pg demonstrated that the peptidic alpha-helical structure increased substantially when bound to the kringle module, in agreement with the X-ray results.This investigation is the first to delineate structurally the mode of interaction of the lysine-binding site of a kringle with an internal pseudo-lysine residue of a peptide or protein that functionally interacts with a kringle module, and serves as a paradigm for this important class of interactions.     

Solution structure of the complex of VEK-30 and plasminogen kringle 2

The solution structure of the complex containing the isolated kringle 2 domain of human plasminogen (K2_Pg) and VEK-30, a 30-amino acid residue internal peptide from a streptococcal M-like plasminogen (Pg) binding protein (PAM), has been determined by multinuclear high-resolution NMR. Complete backbone and side-chain assignments were obtained from triple-resonance experiments, after which structure calculations were performed and ultimately refined by restrained molecular simulation in water. We find that, in contrast with the dimer of complexes observed in the asymmetric unit of the crystal, global correlation times and buoyant molecular weight determinations of the complex and its individual components showed the monomeric nature of all species in solution. The NMR-derived structure of K2_Pg in complex with VEK-30 presents a folding pattern typical of other kringle domains, while bound VEK-30 forms an end-to-end α-helix (residues 6–27) in the complex. Most of the VEK-30/K2_Pg interactions in solution occur between a single face of the α-helix of VEK-30 and the lysine binding site (LBS) of K2_Pg. The canonical LBS of K2_Pg, consisting of Asp54, Asp56, Trp60, Arg69, and Trp70 (kringle numbering), interacts with an internal pseudo-lysine of VEK-30, comprising side-chains of Arg17, His18, and Glu20. Site-specific mutagenesis analysis confirmed that the electrostatic field formed by the N-terminal anionic residues of the VEK-30 α-helix, viz., Asp7, and the non-conserved cationic residues of K2_Pg, viz., Lys43 and Arg55, play additional important roles in the docking of VEK-30 to K2_Pg. Structural analysis and kringle sequence alignments revealed several important features related to exosite binding that provide a structural rationale for the high specificity and affinity of VEK-30 for K2_Pg.     

Recombinant kringle IV-10 modules of human apolipoprotein(a): structure, ligand binding modes, and biological relevance

The kringle modules of apolipoprotein(a) [apo(a)] of lipoprotein(a) [Lp(a)] are highly homologous with kringle 4 of plasminogen (75-94%) and like the latter are autonomous structural and functional units. Apo(a) contains 14-37 kringle 4 (KIV) repeats distributed into 10 classes (1-10). Lp(a) binds lysine-Sepharose via a lysine binding site (LBS) located in KIV-10 (88% homology with plasminogen K4). However, the W72R substitution that occurs in rhesus monkeys and occasionally in humans leads to impaired lysine binding capacity of KIV-10 and Lp(a). The foregoing has been investigated by determining the structures of KIV-10/M66 (M66 variant) in its unliganded and ligand [epsilon-aminocaproic acid (EACA)] bound modes and the structure of recombinant KIV-10/M66R72 (the W72R mutant). In addition, the EACA liganded structure of a sequence polymorph (M66T in about 42-50% of the human population) was reexamined (KIV-10/T66/EACA). The KIV-10/M66, KIV-10/M66/EACA, and KIV-10/T66/EACA molecular structures are highly isostructural, indicating that the LBS of the kringles is preformed anticipating ligand binding. A displacement of three water molecules from the EACA binding groove and a movement of R35 bringing the guanidinium group close to the carboxylate of EACA to assist R71 in stabilizing the anionic group of the ligand are the only changes accompanying ligand binding. Both EACA structures were in the embedded binding mode utilizing all three binding centers (anionic, hydrophobic, cationic) like plasminogen kringles 1 and 4. The KIV-10/T66/EACA structure determined in this work differs from one previously reported [Mikol, V., Lo Grasso, P. V. and, Boettcher, B. R. (1996) J. Mol. Biol. 256, 751-761], which crystallized in a different crystal system and displayed an unbound binding mode, where only the amino group of EACA interacted with the anionic center of the LBS. The remainder of the ligand extended into solvent perpendicular to the kringle surface, leaving the hydrophobic pocket and the cationic center of the LBS unoccupied. The structure of recombinant KIV-10/M66R72 shows that R72 extends along the ligand binding groove parallel to the expected position of EACA toward the anionic center (D55/D57) and makes a salt bridge with D57. Thus, the R72 side chain mimics ligand binding, and loss of binding ability is the result of steric blockage of the LBS by R72 physically occupying part of the site. The rhesus monkey lysine binding impairment is compared with that of chimpanzee where KIV-10 has been shown to have a D57N mutation instead.     

Solution structure of the tissue-type plasminogen activator kringle 2 domain complexed to 6-aminohexanoic acid an antifibrinolytic drug.

The solution structure of a recombinant tissue-type plasminogen activator kringle 2 domain, complexed with the antifibrinolytic drug 6-aminohexanoic acid (6-AHA) was determined via 1H nuclear magnetic resonance spectroscopy and dynamical simulated annealing calculations. The structure determination is based on 610 intramolecular kringle 2 and 14 intermolecular kringle 2-6-AHA interproton distance restraints, as well as on 82 torsion angle restraints. Three sets of simulated annealing structures were computed from three different classes of starting structures: (1) random conformations devoid of disulfide bridges; (2) random conformations that contain correct disulfide bonds; and (3) a folded conformation modeled after the homologous prothrombin kringle 1 X-ray crystallographic structure. All three sets of structures are well defined, with averaged atomic root-mean-square deviations between individual structures and mean set structures of 0.77, 0.99 and 0.70 A for backbone atoms, and 1.36, 1.55 and 1.41 A for all atoms, respectively. Kringle 2 is an oblate ellipsoid with overall dimensions of approximately 34 A x 30 A x 17 A. It exhibits a compact globular conformation characterized by a number of turns and loop elements as well as by one right-handed alpha-helix and five (1 extended and 4 rudimentary) antiparallel beta-sheets. The extended beta-sheet exhibits a right-handed twist. Close van der Waals' contacts between the Cys22-Cys63 and Cys51-Cys75 disulfide bridges and the central hydrophobic core composed of the Trp25, Leu46, His48a and Trp62 side-chains are among the distinguishing features of the kringle 2 fold. The binding site for 6-AHA appears as a rather exposed cleft with a negatively charged locus defined by the Asp55 and Asp57 side-chains, and with an aromatic pocket structured by the Tyr36, Trp62, His64 and Trp72 side-chains. The Trp62 and His64 rings line the back surface of the pocket, while the Tyr36 and Trp72 rings confine it from two sides. The Trp62 and Trp72 indole rings conform a V-shaped groove. The methyl groups of Val35 also contribute lipophilic character to the ligand-interacting surface. It is suggested that the positively charged side-chains of Lys34 and, potentially, Arg69 may favor interactions with the carboxylate group of the ligand. The Trp25 and Tyr74 aromatic rings, although conserved elements of the binding site structure, seem not to undergo direct contacts with the ligand.     

Solution structure and dynamics of the plasminogen kringle 2-AMCHA complex: 3(1)-helix in homologous domains

The kringle 2 (K2) module of human plasminogen (Pgn) binds L-lysine and analogous zwitterionic compounds, such as the antifibronolytic agent trans-(aminomethyl)cyclohexanecarboxylic acid (AMCHA). Far-UV CD and NMR spectra reveal little conformational change in K2 upon ligand binding. However, retarded (1)H-(2)H isotope exchange kinetics induced by AMCHA indicate stabilization of the K2 conformation by the ligand. Assessment of secondary structure content from CD spectra yields approximately 26% beta-STRAND, approximately 13% beta-TURN, approximately 15% 3(1)-HELIX, and approximately 6% 3(10)-HELIX. The NMR solution conformation of the K2 domain complexed to AMCHA has been determined [heavy atom rmsd = 0.49 +/- 0.09A (BACKBONE) AND 1.02+/- 0.08 (ALL)]. The K2 molecule has overall dimensions of approximately 34.5A times approximately 33.4A times approximately 22.7A . Analogous with the polypeptide outline of homologous domains, K2 contains three short antiparallel beta-sheets (paired strands 15-16/20-21, 24-25/48-49, and 62-64/72-74) and four defined beta-turns (residues 6-9, 16-19, 53-56, AND 67-70). Consistent with the CD analysis, albeit novel in the context of kringle folding, the NMR structure reveals an unpaired beta-strand structured by residues 30-32, a turn of 3(10)-helix compromising residues 38-41, and a 3(1)-helix for residues 21-24 and 74-79. We also identify alignable 3(1)-helices in previously reported homologous kringle structures. Rather high order parameter S(2) values (= approximately 0.85 +/- 0.04) characterize the K2 backbone dynamics. The lowest flexibility is observed for the two inner loop segments of residues 51-63 AND 63-75 (= approximately 0.86-0.87 +/- 0.03). Overhauser connectivities reveal close hydrophobic contacts of the ligand ring with side chains of Tyr(36), Trp(62), Phe(64), Trp(72), AND Leu(74). In most K2 structures, the N atom of AMCHA places itself approximately 3.9 and 4.4A from the anionic groups of Glu(57) and Asp(55), respectively, while its carboxylate group, H-bonded to the Tyr(36) side chain OH(eta), ion-pairs the Arg(71) guanidinium group. Consistent with the preference of K2 for binding 5-aminopentanoic acid over 6-aminohexanoic acid, the positions of the ionic centers within the K2 binding site approach each other approximately 1A closer relative to what is observed in lysine binding sites of homologous Pgn modules.     

Proton Overhauser experiments on kringle 4 from human plasminogen. Implications for the structure of the kringles' hydrophobic core

1H-NMR Overhauser experiments at 300 and 600 MHz have been implemented on the isolated kringle 4 fragment of human plasminogen. This study shows that Leu46 and Leu77 CH3 delta,delta' groups, as well as two threonine CH3 gamma and a methionine S-CH epsilon (probably Met48) groups, are in efficient dipolar contact with histidine and aromatic side-chains. In particular, the experiments reveal that of the two Leu46 CH3 delta,delta' groups, one is in efficient contact with tryptophan (Trp25 and Trp62) indole rings while the other interacts with a tyrosine (probably Tyr41) phenol. Leu46 appears also to be close to an Ala CH3 beta group. Such a hydrophobic cluster appears to be contiguous to Trp72, hence to Arg71, residues that are through to be part of the lysine-binding site. Acid-base titration experiments show that the buried methionine S-CH3 epsilon group senses a neighboring ionizable group of pK*1 = 3.76, suggesting presence of a carboxyl anionic group (probably an aspartic acid side-chain) in the vicinity of the hydrophobic core. A preliminary model is proposed for the overall folding of the kringle polypeptide chain.     

Kringle-kringle interactions in multimer kringle structures.

The crystal structure of a monoclinic form of human plasminogen kringle 4 (PGK4) has been solved by molecular replacement using the orthorthombic structure as a model and it has been refined by restrained least-squares methods to an R factor of 16.4% at 2.25 A resolution. The X-PLOR structure of kringle 2 of tissue plasminogen activator (t-PAK2) has been refined further using PROFFT (R = 14.5% at 2.38 A resolution). The PGK4 structure has 2 and t-PAK2 has 3 independent molecules in the asymmetric unit. There are 5 different noncrystallographic symmetry "dimers" in PGK4. Three make extensive kringle-kringle interactions related by noncrystallographic 2(1) screw axes without blocking the lysine binding site. Such associations may occur in multikringle structures such as prothrombin, hepatocyte growth factor, plasminogen (PG), and apolipoprotein [a]. The t-PAK2 structure also has noncrystallographic screw symmetry (3(1)) and mimics fibrin binding mode by having lysine of one molecule interacting electrostatically with the lysine binding site of another kringle. This ligand-like binding interaction may be important in kringle-kringle interactions involving non-lysine binding kringles with lysine or pseudo-lysine binding sites. Electrostatic intermolecular interactions involving the lysine binding site are also found in the crystal structures of PGK1 and orthorhombic PGK4. Anions associate with the cationic centers of these and t-PAK2 that appear to be more than occasional components of lysine binding site regions.     

1H NMR structural characterization of a recombinant kringle 2 domain from human tissue-type plasminogen activator

The kringle 2 domain of human tissue-type plasminogen activator (t-PA) has been characterized via 1H NMR spectroscopy at 300 and 620 MHz. The experiments were performed on the isolated domain obtained by expression of the 174-263 portion of t-PA in Escherichia coli [Cleary et al. (1989) Biochemistry 28, 1884-1891]. The spectrum of t-PA kringle 2 is characteristic of a globular structure and shows overall similarity to that of the plasminogen (PGN) kringle 4. Spectral comparison with human and bovine PGN kringle 4 identifies side-chain resonances from Leu46, which afford a fingerprint of kringle folding, and from most of the aromatic ring spin systems. Assignment of signals arising from the His13, His48a, and His64 side chains, which are unique to t-PA kringle 2, was assisted by the availability of a His64----Tyr mutant. Ligand-binding studies confirm that t-PA kringle 2 binds L-lysine with an association constant Ka approximately 11.9 mM-1. The data indicate that homologous or conserved residues relative to those that compose the lysine-binding sites of PGN kringles 1 and 4 are involved in the binding of L-lysine to t-PA kringle 2. These include Tyr36 and, within the kringle inner loop, Trp62, His64, Trp72, and Tyr74. Acid/base titration of aromatic singlets in the presence of L-lysine yields pKa* approximately 6.25 and approximately 4.41 for His13 and His64, respectively, and shows that the His48a imidazole group does not protonate down to pH* approximately 4.3. Thus, the His48a and His64 side chains are in solvent-shielded locations. As observed for the PGN kringles, the Trp62 indole group titrates with pKa* approximately 4.60, which indicates proximity of the side chain to a titratable carboxyl group, most likely that of Asp57 at the binding site. Several labile NH protons of t-PA kringle 2 exhibit retarded H-exchange kinetics, requiring more than a week in 2H2O for full deuteration in the presence of L-lysine at 37 degrees C. This reveals that kringle 2 is endowed with a compact, dynamically stable conformation. Proton Overhauser experiments in 1H2O, centered on well-resolved NH resonances between 9.8 and 12 ppm, identify signals arising from the His48a imidazole NH3 proton and the three Trp indole NH1 protons. A strong dipolar interaction was observed among the Trp25 indole NH1, the Tyr50 amide NH, and the His48a imidazole CH2 protons, which affords evidence for an aromatic cluster in t-PA kringle 2 similar to that found at the hydrophobic kernel of PGN kringles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Apolipoprotein(a): structure-function relationship at the lysine-binding site and plasminogen activator cleavage site

Apolipoprotein(a) [apo(a)] is the distinctive glycoprotein of lipoprotein Lp(a), which is disulfide linked to the apo B100 of a low density lipoprotein particle. Apo(a) possesses a high degree of sequence homology with plasminogen, the precursor of plasmin, a fibrinolytic and pericellular proteolytic enzyme. Apo(a) exists in several isoforms defined by a variable number of copies of plasminogen-like kringle 4 and single copies of kringle 5, and the protease region including the backbone positions for the catalytic triad (Ser, His, Asp). A lysine-binding site that is similar to that of plasminogen kringle 4 is present in apo(a) kringle IV type 10. These kringle motifs share some amino acid residues (Asp55, Asp57, Phe64, Tyr62, Trp72, Arg71) that are key components of their lysine-binding site. The spatial conformation and the function of this site in plasminogen kringle 4 and in apo(a) kringle IV-10 seem to be identical as indicated by (i) the ability of apo(a) to compete with plasminogen for binding to fibrin, and (ii) the neutralisation of the lysine-binding function of these kringles by a monoclonal antibody that recognises key components of the lysine-binding site. In contrast, the lysine-binding site of plasminogen kringle 1 contains a Tyr residue at positions 64 and 72 and is not recognised by this antibody. Plasminogen bound to fibrin is specifically recognised and cleaved by the tissue-type plasminogen activator at Arg561-Val562, and is thereby transformed into plasmin. A Ser-Ile substitution at the activation cleavage site is present in apo(a). Reinstallation of the Arg-Val peptide bond does not ensure cleavage of apo(a) by plasminogen activators. These data suggest that the stringent specificity of tissue-type plasminogen activator for plasminogen requires molecular interactions with structures located remotely from the activation disulfide loop. These structures ensure second site interactions that are most probably absent in apo(a).     

An internal histidine residue from the bacterial surface protein, PAM, mediates its binding to the kringle-2 domain of human plasminogen.

The determinants of binding of a peptide lacking C-termini-exposed lysine residues to a kringle domain were investigated using an up-regulated lysine binding kringle (K2Pg[C4G/E56D/K72Y]) of plasminogen and a peptide (a1-PAM) with a sequence derived from a surface-exposed M-like streptococcal protein. Significant kringle-induced chemical shifts in a His side-chain of a1-PAM were revealed by two-dimensional NMR. Further studies using isothermal titration calorimetry (ITC) provided support for the involvement of His12 in the peptide/ protein complex. In an effort to screen a1-PAM-derived truncation peptides, a combinatorial mixture, a1deltaa2-PAM[H12X] (where X=Pro, Arg, His, Trp, Lys, Ala, Phe, Asp and Gly), was analyzed using the surface-enhanced laser desorption ionization time-of-flight mass spectrometry (SELDI) platform. The major peptide that remained bound to the surface of the K2Pg[C4G/ E56D/K72Y]-containing chip was that containing His12, corresponding to the wild-type sequence. Minor peaks, representing binding, were obtained for Lys12-, Arg12- and Trp12-containing peptides. Individual peptides containing these amino acids were then examined using ITC and the binding constants obtained correlated with the relative strengths of binding estimated from the SELDI-based screen.     

1H NMR studies of aliphatic ligand binding to human plasminogen kringle 4

A detailed 1H NMR analysis of ligand binding to the human plasminogen kringle 4 domain has been carried out at 300 MHz. The ligands that were investigated are N alpha-acetyl-L-lysine, L-lysine methyl ester, N alpha-acetyl-L-lysine methyl ester, L-lysine hydroxamic acid, trans-(aminomethyl)cyclohexanecarboxylic acid (AMCHA), and 4-(aminomethyl)bicyclo[2.2.2]octane-1-carboxylic acid (AMBOC). Specific ligand-binding effects were detected via two-dimensional COSY experiments. The side chains that are the most perturbed by ligand presence are those from Trp62, Phe64, and Trp72. Ligand-kringle saturation transfer (Overhauser) experiments show that the aromatic rings from these three residues, especially Trp72, are in direct contact with the ligand. These results add support to a previously reported model of the kringle 4 lysine-binding site [Ramesh, V., Petros, A. M., Llinás, M., Tulinsky, A., & Park, C. H. (1987) J. Mol. Biol. 198, 481-498] by which these aromatic groups are assigned a key role in establishing hydrophobic interactions with the ligand molecule. Equilibrium association constants (Ka) and kinetic rate constants (kon, koff) were determined for the binding of the various linear and cyclic ligands to kringle 4. We find that those ligands whose carboxylate function is blocked bind significantly weaker (Ka approximately less than 2 mM-1) than the corresponding analogues where the anionic center is present (Ka approximately greater than 20 mM-1), which underscores the relevance of the polar group in stabilizing the interaction with the kringle 4 binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

1H-NMR spectroscopic manifestations of ligand binding to the kringle 4 domain of human plasminogen

Structural aspects of the binding of the linear ligands N alpha-acetyl-L-lysine (AcLys) and epsilon-aminocaproic acid (epsilon ACA) and of the cyclic analogs trans-(aminomethyl)-cyclohexanecarboxylic acid (AMCHA) and p-benzylaminesulfonic acid (BASA) to the intact plasminogen kringle 4 domain have been investigated by 1H-NMR spectroscopy at 300 and 600 MHz. Ligand binding results in consistent shifts of the His-II (His31), Trp-I (Trp25?), Trp-II (Trp62?), Trp-III (Trp72), Tyr-II (Tyr50), and Phe64 ring signals. BASA tends to induce larger shifts than elicited by the aliphatic ligands, most noticeably on Trp-II and on Trp72, suggesting that the ligand aromatic ring interacts with the two indole groups. Trp-II and, to lesser extent, Trp-I interact with an acidic side chain group, in a manner that is blocked by BASA. BASA binding also perturbs Tyr-II (Tyr50), Tyr-III (Tyr41), and Tyr-IV (Tyr74) over a wide pH range and lowers the pKa* of His31 from approximately 4.8 to approximately 4.6. His-III (His33) responds to BASA and AMCHA but is relatively insensitive to the linear ligands. His33 carries a sterically shielded side chain which, in conjunction with Leu46, Trp-I, Tyr50, and Tyr74, participates in structuring the kringle hydrophobic core, contiguous to the binding site. Pronounced shifts are observed for aliphatic resonances stemming from the kringle-bound molecules of AMCHA, AcLys, and epsilon ACA. It is proposed that the lysine-binding site is mostly supported by the loop that extends from Cys51 through Cys71 and that aromatic residues, which include Trp-II, Trp72, and Phe64, play a major role in interacting with the nonpolar segment of the ligand molecule. The binding site also encompasses Tyr50, Tyr74, His31, and His33 although it is not clear the extent to which these residues interact directly with the ligand.     

Mutational replacements in subtilisin 309. Val104 has a modulating effect on the P4 substrate preference.

The previous notion that the amino acid side chain at position 104 of subtilisins is involved in the binding of the side chain at position P4 of the substrate has been investigated. The amino acid residue Val104 in subtilisin 309 has been replaced by Ala, Arg, Asp, Phe, Ser, Trp and Tyr by site-directed mutagenesis. It is shown that the P4 specificity of this enzyme is not determined solely by the amino acid residue occupying position 104, as the enzyme exhibits a marked preference for aromatic groups in P4, regardless of the nature of the position-104 residue. With hydrophilic amino acid residues at this position, no involvement is seen in binding of either hydrophobic or hydrophilic amino acid residues at position P4 of the substrates. The substrate with Asp in P4 is an exception, as the preference for this substrate is increased dramatically by introduction of an arginine residue at position 104 in the enzyme, presumably due to a substrate-induced conformational change. However, when position 104 is occupied by hydrophobic residues, it is highly involved in binding of hydrophobic amino acid residues, either by increasing the hydrophobicity of S4 or by determining the size of the pocket. The results suggest that the amino acid residue at position 104 is mobile such that it is positioned in the S4 binding site only when it can interact favourably with the substrate's side chain at position P4.     

A 1H-NMR study of isolated domains from human plasminogen. Structural homology between kringles 1 and 4

Kringles 1 and 4 from human plasminogen are polypeptide domains of Mr approximately equal to 10000 each of which can be isolated by proteolysis of the zymogen. They have been studied by 1H-NMR spectroscopy at 300 MHz and 600 MHz. The spectra, characteristic of globular structures, show striking analogies that point to a close conformational relatedness among the two kringles, consistent with their high degree of amino acid conservancy and homology. The interaction of both kringles with p-benzylaminesulfonic acid (BASA), an antifibrinolytic drug that binds to a lysine-binding site, results in better resolved, narrower lines for both spectra. Aromatic and methyl-region spectra of BASA complexes of kringles 1 and 4 were compared and the latter was studied by two-dimensional NMR spectroscopy. Analysis of the CH3 multiplets in terms of their resonance patterns, and the amino acid compositions and sequences of the two kringles, leads to the identification of most signals and to some assignments. In particular, a doublet at -1 ppm, exhibited by both kringles and also found in reported proton spectra of homologous bovine prothrombin fragments, has been assigned to Leu46, a residue that is conserved in all of the kringles studied to date by 1H-NMR. Since this resonance is somewhat more sensitive to BASA than other methyl signals, it is likely that Leu46 is proximal to the lysine-binding site. Nuclear Overhauser experiments reveal that Leu46 is surrounded by a cluster of closely interacting hydrophobic and aromatic side chains. Kringle 4 was also compared with a derivative chemically modified at Trp72 with dimethyl(2-hydroxy-5-nitrobenzyl)sulfonium bromide. As judged from the proton spectra, the modified kringle 4 retains globularity and is perturbed mainly in the aromatic region, in analogy to that which is observed for the unmodified kringle upon BASA binding. Furthermore, although previous studies have indicated no retention of the modified kringle by lysine-Sepharose, the NMR studies point to a definite interaction between BASA and the kringle derivative. The spectroscopic data also suggest that the His31 imidazole is not significantly affected by the ligand and that the lysine-binding site is structured mostly by hydrophobic side chains, including Trp72 in the case of kringle 4, and probably Tyr72 in kringle 1.     

Roles of catalytic domain residues in interfacial binding and activation of group IV cytosolic phospholipase A2

Group IV cytosolic phospholipase A(2) (cPLA(2)) has been shown to play a critical role in eicosanoid biosynthesis. cPLA(2) is composed of the C2 domain that mediates the Ca(2+)-dependent interfacial binding of protein and the catalytic domain. To elucidate the mechanism of interfacial activation of cPLA(2), we measured the effects of mutations of selected ionic and hydrophobic residues in the catalytic domain on the enzyme activity and the membrane binding of cPLA(2). Mutations of anionic residues located on (Glu(419) and Glu(420)) or near (Asp(436), Asp(438), Asp(439), and Asp(440)) the active site lid enhanced the affinity for cPLA(2) for anionic membranes, implying that the electrostatic repulsion between these residues and the anionic membrane surface might trigger the opening of the active site. This notion is further supported by a biphasic dependence of cPLA(2) activity on the anionic lipid composition of the vesicles. Mutations of a cluster of cationic residues (Lys(541), Lys(543), Lys(544), and Arg(488)), while significantly enhancing the activity of enzyme, abrogated the specific activation effect by phosphatidylinositol 4,5-bisphosphate (PtdIns(4,5)P(2)). These data, in conjunction with cell activity of cPLA(2) and mutants transfected into HEK293 cells, suggest that the cationic residues form a specific binding site for PtdIns(4,5)P(2) and that the specific PtdIns(4,5)P(2) binding is involved in cellular activation of cPLA(2). Also, three hydrophobic residues at the rim of the active site (Ile(399), Leu(400), and Leu(552)) were shown to partially penetrate the membrane, thereby promoting membrane binding and activation of cPLA(2). Based on these results, we propose an interfacial activation mechanism for cPLA(2) which involves the removal of the active site lid by nonspecific electrostatic repulsion, the interdomain hinge movement induced by specific PtdIns(4,5)P(2) binding, and the partial membrane penetration by catalytic domain hydrophobic residues.     

Proton magnetic resonance study of kringle 1 from human plasminogen. Insights into the domain structure

The aromatic H NMR spectrum of the kringle 1 domain from human plasminogen has been investigated by proton Overhauser experiments, acid-base titration, and two-dimensional chemical shift correlated spectroscopy. Spin-echo and pH response experiments lead to the identification of the N-terminal Tyr-3 phenol ring signals. The connectivities among the tryptophanyl aromatic protons have been established and sets of singlet-doublet-triplet resonances stemming from each of the two indole groups sorted according to their common side chain origin. Similarly, the four histidyl singlets have been identified and paired per imidazole group. From their pH responses, it is indicated that a histidyl (His31) and a tryptophanyl (Trp-II) residue are placed in the neighborhood of carboxyl groups. The high-field chemical shifts observed for proton resonances of the ligand epsilon-aminocaproic acid upon binding to kringle 1 indicate that the ligand-binding site is rich in aromatic components. Overhauser experiments reveal that Leu46 is surrounded by a cluster of interacting aromatic side chains, which includes Trp25, Phe36, His41, Trp62, and Tyr64, and define a hydrophobic region contiguous to the kringle lysine-binding site. Relative internuclear distances have been estimated for aromatic H-atoms in the vicinity of Leu46 by reference to one of the latter's CH3 sigma, sigma' groups. Some of the connectives have previously been found for Leu46 in kringle 4 which further supports the idea of a common structure for the homologous domains.     

Proton magnetic resonance study of lysine-binding to the kringle 4 domain of human plasminogen. The structure of the binding site

The binding of L-Lys, D-Lys and epsilon-aminocaproic acid (epsilon ACA) to the kringle 4 domain of human plasminogen has been investigated via one and two-dimensional 1H-nuclear magnetic resonance spectroscopy at 300 and 600 MHz. Ligand-kringle association constants (Ka) were determined assuming single site binding. At 295 K, pH 7.2, D-Lys binds to kringle 4 much more weakly (Ka = 1.2 mM-1) than does L-Lys (Ka = 24.4 mM-1). L-Lys binding to kringle 4 causes the appearance of ring current-shifted high-field resonances within the -1 approximately less than delta approximately less than 0 parts per million range. The ligand origin of these signals has been confirmed by examining the spectra of kringle 4 titrated with deuterated L-Lys. A systematic analysis of ligand-induced shifts on the aromatic resonances of kringle 4 has been carried out on the basis of 300 MHz two-dimensional chemical shift correlated (COSY) and double quantum correlated spectroscopies. Significant differences in the effect of L-Lys and D-Lys binding to kringle 4 have been observed in the aromatic COSY spectrum. In particular, the His31 H4 and Trp72 H2 singlets and the Phe64 multiplets appear to be the most sensitive to the particular enantiomers, indicating that these residues are in proximity to the ligand C alpha center. In contrast, the rest of the indole spectrum of Trp72 and the aromatic resonances of Trp62 and Tyr74, which are affected by ligand presence, are insensitive to the optical nature of the ligand isomer. These results, together with two-dimensional proton Overhauser studies and ligand-kringle saturation transfer experiments reported previously, enabled us to generate a model of the kringle 4 ligand-binding site from the crystallographic co-ordinates of the prothrombin kringle 1. The latter, although lacking recognizable lysine-binding capability, is otherwise structurally homologous to the plasminogen kringles.     

Ligand specificity of human plasminogen kringle 4.

The ligand specificity of the human plasminogen kringle 4 was characterized in terms of ligand size, aromatic/aliphatic character, and ionic charge distribution. The binding of the following ligands was investigated via 1H NMR spectroscopy, and their equilibrium association constants (Ka) were determined: (1) p-aminomethylbenzoic acid (Ka approximately 4.8 mM-1), (2) benzylamine (Ka approximately 0.2 mM-1), (3) l-aminohexane (Ka approximately 0.07 mM-1), (4) 7-aminoheptanoic acid (Ka approximately 6.6 mM-1), (5) 5-aminopentanoic acid (Ka approximately 16 mM-1), (6) N alpha-acetyl-L-arginine (Ka approximately 0.3 mM-1), and (7) N alpha-acetyl-L-arginine methyl ester (Ka approximately 0.08 mM-1). Benzamidine and L-arginine do not bind measurably to kringle 4. We have also established that 1-hexanoic acid and 4-methylbenzoic acid do not interact significantly with kringle 4 (Ka less than 0.05 mM-1). The Trp62 resonances were found to be quite sensitive to aromatic ligands as well as to aliphatic ligand length. Phe64 is similarly sensitive to the ligand aromatic/aliphatic character and chain length and to the identity of the ligand anionic group. His31 and His33 do not respond significantly to variations in ligand structure, although they are perturbed by aromatic and aliphatic effectors. The perturbations induced by the arginine derivatives on these residues show that these compounds interact with the lysine-binding site (LBS) of kringle 4. The LBS was further characterized using 2D NMR studies of a kringle 4/trans-(aminomethyl)cyclohexanecarboxylic acid (AMCHA) complex. A complete assignment of the AMCHA spectrum in the bound state was achieved. This enabled the unambiguous identification of intermolecular contact points between the central AMCHA protons and Trp62 and Trp72. A model based on the X-ray crystallographic structure of kringle 4, incorporating these constraints, has been derived.     

A multinuclear NMR study of the active site of an endoglucanase from a strain of Bacillus. Use of Trp residues as structural probes.

In the hydrolytic reaction catalyzed by an endoglucanase from a Bacillus strain (endoglucanase K), 2 of 12 Trp residues, Trp174 and Trp243, are responsible for binding of the substrate and/or for the catalysis (Kawaminami, S., Ozaki, K., Sumitomo, N., Hayashi, Y., Ito, S., Shimada, I., and Arata, Y. (1994) J. Biol. Chem. 269, 28752-28756). Here we report results of a stable isotope-aided NMR analysis of the active site of endoglucanase K, using Trp174 and Trp243 as structural probes. Hydrogen-deuterium exchange experiments performed for the NH protons of main and side chains of Trp residues revealed that Trp174 and Trp243 are located in the hydrophilic and hydrophobic microenvironments in the active site, respectively. We also carried out pH titration experiments for indole C2 proton resonances of Trp residues and measured the pH dependence of specific activities for wild-type endoglucanase K and its mutants in which Glu or Asp residues are replaced with their respective amide forms. On the basis of the results obtained from the present study, we conclude that (a) Glu130 and Asp191, which are in spatial proximity to Trp174 and Trp243 in the active site, play a crucial role in the enzymatic activity; (b) Glu130 and Asp191 interact with each other in the active site, leading to an increase in the pKa values to 5.5 for both amino acid residues; and (c) the pKa values of Glu130 and Asp191 would lead to an unusually narrow pH-activity profile of the endoglucanase K.