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.     

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.     

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.     

The aromatic 1H-NMR spectrum of plasminogen kringle 4. A comparative study of human, porcine and bovine homologs

The isolated kringle 4 domain of human plasminogen has been compared with homologous structures from bovine and porcine sources, both free and in the presence of the ligand 6-aminohexanoic acid, by two-dimensional 1H-NMR spectroscopies at 300 MHz and 600 MHz. The chemical-shift-correlated, spin-echo-correlated, and double-quantum-correlated aromatic spectra of the three proteins reveal that the globular conformation of the fourth kringle is closely maintained throughout the set of homologs. Direct comparison shows that the three conserved Trp residues (at sites 25, 62 and 72) which exhibit highly non-degenerate subspectra, find themselves in similar intramolecular environments. In particular, proton Overhauser experiments reveal that the close steric interaction between the Trp-II (Trp62 or Trp25) indole group and the aromatic ring at site 74 (Tyr74 or Phe74) is strictly preserved. This feature forces the kringle inner loop, closed by the Cys51-Cys75 link, to fold back onto itself so as to place the site 74 residue proximal to the Cys22-Cys63 bridge. Single-residue substitutions enable unambiguous assignments of His-I to His3, Tyr-III to Tyr41 and Tyr-IV to Tyr74. From this direct evidence, comparison with the kringle 1 spectrum, and the previously reported chemical modification of Tyr-II (Tyr50) [Trexler M., Bányai L., Patthy L., Pluck N. D. & Williams R. J. P. (1985) Eur. J. Biochem. 152, 439-446], Tyr-I and Tyr-V (the latter, an immobile ring on the 600-MHz time scale) could be assigned to Tyr2 and Tyr9, respectively. Since Trp-III has previously been assigned to Trp72 at the lysine-binding site, the present study completes the assignment of 10 out of 12 aromatic spin systems in the kringle 4 1H-NMR spectrum; the only ambiguity which remains concerns the Trp-I and Trp-II indole spin systems, which are totally identified but as yet only tentatively assigned to Trp25 and Trp62, respectively.     

Analysis of the aromatic 1H NMR spectrum of chicken plasminogen kringle 4

The intact kringle 4 domain of chicken plasminogen has been characterized by 1H NMR spectroscopy at 300 and 620 MHz in both the presence and absence of epsilon-aminocaproic acid, an antifibrinolytic drug. The study focuses on the aromatic resonances. Comparisons with spectra from human, porcine and bovine kringle 4 homologs indicates a strict conservancy of conformation, reflecting the underlying primary sequence homology, and leads to an unambiguous assignment of all the aromatic resonances, including those of Phe15 and His40 which are unique to the chicken domain. Conclusive evidence is found that the Tyr9 ring fluctuates between two states, one in which it flips fast and other in which it is severely hindered. Similarly, the Tyr64 side chain finds itself in a structurally constrained locus. The Trp62, Tyr64, and Trp72 aromatic resonances are most sensitive to ligand presence, supporting a previously reported model of the kringle 4 lysine-binding site. His40, Phe41, and Tyr74 are also perturbed by ligand indicating proximity to the site. In contrast, the Phe15 aromatic spectrum indicates a rather mobile phenyl ring which is insensitive to ligand presence, thus confirming the lesser importance of the corresponding segment within the first kringle loop in determining kringle structure and/or function.     

Role of tryptophan-74 of the recombinant kringle 2 domain of tissue-type plasminogen activator in its omega-amino acid binding properties.

The role of W74 in stabilization of the binding of omega-amino acids to the recombinant (r) kringle 2 domain (residues 180-261) of tissue-type plasminogen activator ([K2tPA]) has been assessed by examination of the binding (dissociation) constants (Kd) of epsilon-aminocaproic acid (EACA) and one of its structural analogues, 7-aminoheptanoic acid (7-AHpA), to variants of r-[K2tPA] generated by site-directed mutagenesis of the wild-type kringle domain. Two nonconservative mutations at W74 of r-[K2tPA] have been constructed, expressed, and purified, resulting in one variant molecule containing a W74L mutation (r-[K2tPA/W74L]) and another containing a W74S mutation (r-[K2tPA/W74S]). In both cases, binding of EACA and 7-AHpA was virtually eliminated in the mutated kringles. Two additional conservative mutations at W74 of r-[K2tPA] have been similarly generated, resulting in r-[K2tPA/W74F] and r-[K2tPA/W74Y]. For these mutants, binding of the same ligands to the variant recombinant kringle domain is retained, although it is significantly weaker in nature. The 1H-NMR spectra of each of the variant kringles demonstrates that all retain the general gross conformations of their wild-type counterpart but that some environmental changes of proton resonances occur at particular aromatic amino acid residues that may be involved in omega-amino acid binding. Differential scanning calorimetric analyses of each of the variant kringles suggest that none of the mutations led to substantial destabilization of their structures, again suggestive of gross conformational similarities in all r-[K2tPA] molecules constructed. We conclude that the aromatic character present at position 74 of wild-type r-[K2tPA] is of great importance to its ability to interact with omega-amino acid ligands, with tryptophan being the most effective amino acid at that position.     

Direct identification of lysine-33 as the principal cationic center of the omega-amino acid binding site of the recombinant kringle 2 domain of tissue-type plasminogen activator.

We have generated site-specific mutants of the kringle 2 domain of tissue-type plasminogen activator [( K2tPA]) in order to identify directly the cationic center of the protein that is responsible for its interaction with the carboxyl group of important omega-amino acid effector molecules, such as epsilon-amino caproic acid (EACA). Molecular modeling of [K2tPA], docked with EACA, based on crystal structures of the kringle 2 region of prothrombin and the kringle 4 domain of human plasminogen, clearly shows that Lys33 is the only positively charged amino acid in [K2tPA] that is sufficiently proximal to the carboxyl group of the ligand to stabilize this interaction. In order to examine directly the importance of this particular amino acid residue in this interaction, we have constructed, expressed, and purified three recombinant (r) mutants of [K2tPA], viz., Lys33Thr, Lys33Leu, and Lys33Arg, and found that only the last variant retained significant ability to interact with EACA and several of its structural analogues at neutral pH. In addition, another mutated r-[K2tPA], i.e., Lys33His, interacts very weakly with omega-amino acids at neutral pH and much more strongly at lower pH values where His33 would be expected to undergo protonation. This demonstrates that any positively charged amino acid at position 33 satisfies the requirement for mediation of significant bindings to this class of molecules. Since, in other kringles, positively charged residues at amino acid sequence positions homologous to Lys68, Arg70, and Arg71 of [K2tPA] have been found to participate in kringle interactions with EACA-like compounds, we have also examined the binding of EACA, and some of its analogues, to three additional r-[K2tPA] variants, i.e., Lys68Ala, Arg70Ala, and Arg71Ala. In each case, binding of these omega-amino acids to the variant kringles was observed, with only the Lys68Ala variant showing a slightly diminished capacity for this interaction. These investigations provide clear and direct evidence that Lys33 is the principal cationic site in wild-type r-[K2tPA] that directly interacts with the carboxyl group of omega-amino acid effector molecules.     

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)     

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.     

Importance of the conserved aromatic residues in the scorpion alpha-like toxin BmK M1: the hydrophobic surface region revisited

About one-third of the amino acid residues conserved in all scorpion long chain Na+ channel toxins are aromatic residues, some of which constitute the so-called "conserved hydrophobic surface." At present, in-depth structure-function studies of these aromatic residues using site-directed mutagenesis are still rare. In this study, an effective yeast expression system was used to study the role of seven conserved aromatic residues (Tyr5, Tyr14, Tyr21, Tyr35, Trp38, Tyr42, and Trp47) from the scorpion toxin BmK M1. Using site-directed mutagenesis, all of these aromatic residues were individually substituted with Gly in association with a more conservative substitution of Phe for Tyr5, Tyr14, Tyr35, or Trp47. The mutants, which were expressed in Saccharomyces cerevisiae S-78 cells, were then subjected to a bioassay in mice, electrophysiological characterization on cloned Na+ channels (Nav1.5), and CD analysis. Our results show an eye-catching correlation between the LD50 values in mice and the EC50 values on Nav1.5 channels in oocytes, indicating large mutant-dependent differences that emphasize important specific roles for the conserved aromatic residues in BmK M1. The aromatic side chains of the Tyr5, Tyr35, and Trp47 cluster protruding from the three-stranded beta-sheet seem to be essential for the structure and function of the toxin. Trp38 and Tyr42 (located in the beta2-sheet and in the loop between the beta2- and beta3-sheets, respectively) are most likely involved in the pharmacological function of the toxin.     

Structural/functional characterization of the alpha 2-plasmin inhibitor C-terminal peptide

The alpha(2)-plasmin inhibitor (A2PI) is a main physiological regulator of the trypsin-like serine proteinase plasmin. It is composed of an N-terminal 15 amino acid fibrin cross-linking polypeptide, a 382-residue serpin domain, and a flexible C-terminal segment. The latter, peptide Asn(398)-Lys(452), and its Lys452Ala mutant were expressed as recombinant proteins in Escherichia coli (r-A2PIC and r-A2PICmut, respectively). CD and NMR analyses indicate that r-A2PIC is flexible, loosely folded, and with low content of regular secondary structure. Functional characterization via intrinsic fluorescence ligand titrations shows that r-A2PIC interacts with the isolated plasminogen kringle 1 (r-K1) (K(a) approximately 69.9 mM(-)(1)), K4 (K(a) approximately 45.7 mM(-)(1)), K5 (K(a) approximately 4.3 mM(-)(1)), and r-K2 (K(a) approximately 3.2 mM(-)(1)), all of which are known to exhibit lysine-binding capability. The affinities of these kringles for r-A2PIC are consistently larger than those reported for the ligand N(alpha)-acetyllysine, a mimic of a C-terminal Lys residue. The r-A2PICmut, with a C-terminal Ala residue, also interacts with r-K1 and K4, although with approximately 5-fold lesser affinities relative to r-A2PIC, demonstrating that while Lys(452) plays a major role in the binding, internal residues in r-A2PIC tether the kringles. (1)H NMR spectroscopy shows that key aromatic residues within the K4 lysine-binding site (LBS), namely, Trp(25), Trp(62), Phe(64), Trp(72), and Tyr(74), selectively respond to the addition of r-A2PIC and r-A2PICmut, indicating that these interactions proceed via the kringles' canonical LBS. We conclude that r-A2PIC docks to kringles primarily through lysine side chains and that Lys(452) most definitely enhances the binding. This suggests that multiple Lys residues within A2PI could contribute, perhaps in a zipper-like fashion, to its binding to the in-tandem, multikringle array that configures the plasmin heavy chain.     

Two-dimensional 1H-NMR studies of phospholipase-A2-inhibitor complexes bound to a micellar lipid-water interface

One- and two-dimensional NMR studies were performed on the complexes of porcine pancreatic phospholipase A2 with substrate analogs bound to a micellar lipid-water interface of fully deuterated dodecylphosphocholine. The interactions between the inhibitor and the enzyme were localized by comparison of the two-dimensional NOE spectra recorded for the enzyme-inhibitor complex using both protonated and selectively deuterated inhibitors. These experiments led us to the following conclusions for the phospholipase-A2-micelle complex: (i) the 38-kDa phospholipase A2 complex gives NMR spectra with relatively narrow lines, which is indicative of high mobility of the enzyme; (ii) the residues Ala1, Trp3, Phe63 and Tyr69 located in the interface recognition site, as well as Phe22, Tyr75, Phe106 and Tyr111 are involved in the micelle-binding process; (iii) when present on the micelle, phospholipase A2 is stereospecific for the inhibitor binding; (iv) the inhibitor, (R)-dodecyl-2-aminohexanol-1-phosphoglycol, binds stoichiometrically to phospholipase A2 with high affinity (Kd less than or equal to 10 microM); (v) the inhibitor binds in the active site of the enzyme, which is evidenced by large chemical-shift differences for Phe5, Ile9, Phe22, His48, Tyr52 and Phe106; (vi) the acyl chain of the inhibitor makes hydrophobic contacts (less than 0.4 nm) near Phe5, Ile9, Phe22 and Phe106. Comparison of our results on the enzyme-inhibitor-micelle ternary complex with the crystal structure of the enzyme-inhibitor complex [Thunnissen, M. M. G. M., AB, E., Kalk, K. H., Drenth, J., Dijkstra, B. W., Kuipers, O. P., Dijkman, R., de Haas, G. H. & Verheij, H. M. (1990) Nature 347, 689-691] shows that the mode of inhibitor binding is similar.     

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.     

Identification of tyrosine residues involved in ligand recognition by the phosphatidylinositol 3-kinase Src homology 3 domain: circular dichroism and UV resonance Raman studies.

Src homology 3 (SH3) domains are small noncatalytic protein modules capable of mediating protein-protein interactions. We previously demonstrated that the association of a ligand peptide RLP1 (RKLPPRPSK) causes environmental and structural changes of Trp55 and some of seven Tyr residues in the phosphatidylinositol 3-kinase (PI3K) SH3 domain by circular dichroism (CD) and 235-nm excited UV resonance Raman (UVRR) spectroscopies [Okishio, N., et al. (2000) Biopolymers 57, 208-217]. In this work, the affected Tyr residues were identified as Tyr12, Tyr14, and Tyr73 by the CD analysis of a series of mutants, in which every single Tyr residue was replaced by a Phe residue. Among these three residues, Tyr14 was found to be a main contributor to the UVRR spectral change upon the RLP1 binding. Interestingly, CD and UVRR analyses revealed that RLP1 associates with the Y14F and Y14H mutants in different ways. These results suggest that Tyr14 plays a crucial role in the ligand recognition, and the amino acid substitution at Tyr14 affects the mode of PI3K SH3-ligand interaction. Our findings give an insight into how SH3 domains can produce diversity and specificity to transduce signaling within cells.     

Molecular modelling and site-directed mutagenesis of human GALR1 galanin receptor defines determinants of receptor subtype specificity

Human galanin is a 30 amino acid neuropeptide that elicits a range of biological activities by interaction with G protein-coupled receptors. We have generated a model of the human GALR1 galanin receptor subtype (hGALR1) based on the alpha carbon maps of frog rhodopsin and investigated the significance of potential contact residues suggested by the model using site-directed mutagenesis. Mutation of Phe186 within the second extracellular loop to Ala resulted in a 6-fold decrease in affinity for galanin, representing a change in free energy consistent with hydrophobic interaction. Our model suggests interaction between Phe186 of hGALR1 and Ala7 or Leu11 of galanin. Receptor subtype specificity was investigated by replacement of residues in hGALR1 with the corresponding residues in hGALR2 and use of the hGALR2-specific ligands hGalanin(2-30) and [D-Trp2]hGalanin(1-30). The His267Ile mutant receptor exhibited a pharmacological profile corresponding to that of hGALR1, suggesting that His267 is not involved in a receptor-ligand interaction. The mutation Phe115Ala resulted in a decreased binding affinity for hGalanin and for hGALR2-specific analogues, indicating Phe115 to be of structural importance to the ligand binding pocket of hGALR1 but not involved in direct ligand interaction. Analysis of Glu271Trp suggested that Glu271 of hGALR1 interacts with the N-terminus of galanin and that the Trp residue in the corresponding position in hGALR2 is involved in receptor subtype specificity of binding. Our model supports previous reports of Phe282 of hGALR1 interacting with Trp2 of galanin and His264 of hGALR1 interacting with Tyr9 of galanin.     

Control of conformational equilibria in the human B2 bradykinin receptor. Modeling of nonpeptidic ligand action and comparison to the rhodopsin structure

A prototypic study of the molecular mechanisms of activation or inactivation of peptide hormone G protein-coupled receptors was carried out on the human B2 bradykinin receptor. A detailed pharmacological analysis of receptor mutants possessing either increased constitutive activity or impaired activation or ligand recognition allowed us to propose key residues participating in intramolecular interaction networks stabilizing receptor inactive or active conformations: Asn(113) and Tyr(115) (TM III), Trp(256) and Phe(259) (TM VI), Tyr(295) (TM VII) which are homologous of the rhodopsin residues Gly(120), Glu(122), Trp(265), Tyr(268), and Lys(296), respectively. An essential experimental finding was the spatial proximity between Asn(113), which is the cornerstone of inactive conformations, and Trp(256) which plays a subtle role in controlling the balance between active and inactive conformations. Molecular modeling and mutagenesis data showed that Trp(256) and Tyr(295) constitute, together with Gln(288), receptor contact points with original nonpeptidic ligands. It provided an explanation for the ligand inverse agonist behavior on the WT receptor, with underlying restricted motions of TMs III, VI, and VII, and its agonist behavior on the Ala(113) and Phe(256) constitutively activated mutants. These data on the B2 receptor emphasize that conformational equilibria are controlled in a coordinated fashion by key residues which are located at strategic positions for several G protein-coupled receptors. They are discussed in comparison with the recently determined rhodopsin crystallographic structure.     

Crystal and molecular structure of human plasminogen kringle 4 refined at 1.9-A resolution.

The crystal structure of human plasminogen kringle 4 (PGK4) has been solved by molecular replacement using the bovine prothrombin kringle 1 (PTK1) structure as a model and refined by restrained least-squares methods to an R factor of 14.2% at 1.9-A resolution. The K4 structure is similar to that of PTK1, and an insertion of one residue at position 59 of the latter has minimal effect on the protein folding. The PGK4 structure is highly stabilized by an internal hydrophobic core and an extensive hydrogen-bonding network. Features new to this kringle include a cis peptide bond at Pro30 and the presence of two alternate, perpendicular, and equally occupied orientations for the Cys75 side chain. The K4 lysine-binding site consists of a hydrophobic trough formed by the Trp62 and Trp72 indole rings, with anionic (Asp55/Asp57) and cationic (Lys35/Arg71) charge pairs at either end. With the adjacent Asp5 and Arg32 residues, these result in triply charged anionic and cationic clusters (pH of crystals at 6.0), which, in addition to the unusually high accessibility of the Trp72 side chain, serve as an obvious marker of the binding site on the K4 surface. A complex intermolecular interaction occurs between the binding sites of symmetry-related molecules involving a highly ordered sulfate anion of solvation in which the Arg32 side chain of a neighboring kringle occupies the binding site.     

Effect of water coordination on competition between π and non-π cation binding sites in aromatic amino acids: l-phenylalanine, l-tyrosine, and l-tryptophan Li+, Na+, and K+ complexes

Quantum chemistry methods have been applied to charged complexes of the alkali metals Li(+), Na(+), and K(+) with the aromatic amino acids (AAAs) phenylalanine (Phe), tyrosine (Tyr), and tryptophan (Trp). The geometries of 72 different complexes (Phe·M, Tyr·M, Trp·M, M is Li(+), Na(+), or K(+)) were completely optimized at the B3LYP/6-311+G(d,p) level of density functional theory. The solvent effect on the geometry and stability of individual complexes was studied by making use of a microsolvation model. The interaction enthalpies, entropies, and Gibbs energies of nine different complexes of the systems Phe·M, Tyr·M, and Trp·M (M is Li(+), Na(+), or K(+)) were also determined at the B3LYP density functional level of theory. The calculated Gibbs binding energies of the M(+)-AAA complexes follow the order Phe < Tyr < Trp for all three metal cations studied. Among the three AAAs studied, the indole ring of Trp is the best π donor for alkali metal cations. Our calculations demonstrated the existence of strong cation-π interactions between the alkali metals and the aromatic side chains of the three AAAs. These AAAs comprise about 8% of all known protein sequences. Thus, besides the potential for hydrogen-bond interaction, aromatic residues of Phe, Tyr, and Trp show great potential for π-donor interactions. The existence of cation-π interaction in proteins has also been demonstrated experimentally. However, more complex experimental studies of metal cation-π interaction in diverse biological systems will no doubt lead to more exact validation of these investigations.     

A tale of two tails: The importance of unstructured termini in the aggregation pathway of β2‐microglobulin

The identification of intermediate states for folding and aggregation is important from a fundamental standpoint and for the design of novel therapeutic strategies targeted at conformational disorders. Protein human β2‐microglobulin (HB2m) is classically associated with dialysis‐related amyloidosis, but the single point mutant D76N was recently identified as the causative agent of a hereditary systemic amyloidosis affecting visceral organs. Here, we use D76N as a model system to explore the early stage of the aggregation mechanism of HB2m by means of an integrative approach framed on molecular simulations. Discrete molecular dynamics simulations of a structured‐based model predict the existence of two intermediate states populating the folding landscape. The intermediate I₁ features an unstructured C‐terminus, while I₂, which is exclusively populated by the mutant, exhibits two unstructured termini. Docking simulations indicate that I₂ is the key species for aggregation at acidic and physiological pH contributing to rationalize the higher amyloidogenic potential of D76N relative to the wild‐type protein and the ΔN6 variant. The analysis carried out here recapitulates the importance of the DE‐loop in HB2m self‐association at a neutral pH and predicts a leading role of the C‐terminus and the adjacent G‐strand in the dimerization process under acidic conditions. The identification of aggregation hot‐spots is in line with experimental results that support the importance of Phe56, Asp59, Trp60, Phe62, Tyr63, and Tyr66 in HB2m amyloidogenesis. We further predict the involvement of new residues such as Lys94 and Trp95 in the aggregation process.     

The cationic locus on the recombinant kringle 2 domain of tissue-type plasminogen activator that stabilizes its interaction with omega-amino acids.

The properties of the cationic locus within the recombinant (r) kringle 2 domain (residues 180-261) of tissue-type plasminogen activator ([K2tPA]) that are responsible for stabilization of its interaction with the carboxylate moiety of omega-amino acid ligands have been assessed by determination of the binding constants of several such ligands to a variety of r-[K2tPA] mutants obtained by oligonucleotide-directed mutagenesis. We have generated, expressed in Escherichia coli, and purified alanyl mutants of individual histidyl,lysyl, and arginyl residues of r-[K2tPA] and determined the dissociation constants of several omega-amino acids, viz., 6-aminohexanoic acid (6-AHxA), 7-aminoheptanoic acid (7-AHpA), L-lysine (L-Lys), and trans-(aminomethyl)cyclohexane-1-carboxylic acid (AMCHA), to each of the r-[K2tPA] variants. We find that K33 plays the most significant role as a cationic partner of the complementary carboxylate group of these ligands. When K33 is altered to a variety of other amino acids, the K33R mutant best stabilizes binding of all of these ligands. However, the r-K33L and r-K33F variants selectively interact with 7-AHpA almost as strongly (ca. 2-fold reduction in binding strength) as wild-type r-[K2tPA]. Increased polarity (K33Q) or a negative charge (K33E) at this sequence position significantly destabilizes binding of omega-amino acids to the muteins. We also found that the r-K33E mutant and, to a lesser extent, the r-K33Q variant selectively interact with a new ligand, 1,6-diaminohexane. These observations show that the omega-amino acid binding site of wtr-[K2tPA] could be redesigned to provide a new binding specificity.(ABSTRACT TRUNCATED AT 250 WORDS)