Interactive NMR and computer simulation studies of lanthionine-ring structures

We report progress in elucidating the structure of nisin, a naturally occurring peptide antibiotic. Nisin contains five rings constrained by lanthionine or methyllanthionine bridges, as well as alpha, beta-unsaturated amino acids. We have determined conformations for two model compounds of ring A and a derivative of ring B through interactive nmr and computer simulation studies. High-resolution nmr techniques provides structural information, which was further refined through molecular dynamics simulations. These methods are being applied to the remaining constrained fragments of the molecule. This conformational information will be employed in an aufbau approach to determining the structure of the entire molecule.     

Conformations of bombolitins I and III in aqueous solutions: circular dichroism, 1H NMR, and computer simulation studies

The heptadecapeptides bombolitin I and bombolitin III are two of a series of peptides postulated to be biologically active within a membrane environment. In the preceding paper [Bairaktari, E., Mierke, D.F., Mammi, S., & Peggion, E. (1990) Biochemistry (preceding paper in this issue)] the conformational preferences of these peptides in the presence of SDS surfactant micelles, a mimetic for biological membranes, were examined. During these studies the conformations of these peptides were investigated in aqueous solutions by circular dichroism and nuclear magnetic resonance. A large difference was observed for the two peptides. Bombolitin I lacks any observable secondary structure in aqueous solution, independent of temperature, pH, and concentration. In striking contrast, bombolitin III adopts a well-defined alpha-helix at concentrations greater than 1.3 mM. This is indeed surprising given the great similarity of the two peptides. The alpha-helix of bombolitin III is pH dependent, with a great decrease in the observed secondary structure at pH values below 3.5. This observation could only be due to the protonation of the Asp residue at the fifth position. These findings suggest that the secondary structure arises from molecular aggregation of bombolitin III through the formation of a salt bridge involving the Asp side chain. The alpha-helix observed at "high" concentration (greater than 2.5 mM) has been characterized by CD and by the NOE's measured throughout a majority of the peptide. The experimentally determined structure has been energy refined with restrained molecular dynamics. The conformational results from this study are then compared with the conformations found in the presence of surfactant micelles.     

Mechano-coupling and regulation of contractility by the vinculin tail domain

Vinculin binds to multiple focal adhesion and cytoskeletal proteins and has been implicated in transmitting mechanical forces between the actin cytoskeleton and integrins or cadherins. It remains unclear to what extent the mechano-coupling function of vinculin also involves signaling mechanisms. We report the effect of vinculin and its head and tail domains on force transfer across cell adhesions and the generation of contractile forces. The creep modulus and the adhesion forces of F9 mouse embryonic carcinoma cells (wild-type), vinculin knock-out cells (vinculin −/−), and vinculin −/− cells expressing either the vinculin head domain, tail domain, or full-length vinculin (rescue) were measured using magnetic tweezers on fibronectin-coated super-paramagnetic beads. Forces of up to 10 nN were applied to the beads. Vinculin −/− cells and tail cells showed a slightly higher incidence of bead detachment at large forces. Compared to wild-type, cell stiffness was reduced in vinculin −/− and head cells and was restored in tail and rescue cells. In all cell lines, the cell stiffness increased by a factor of 1.3 for each doubling in force. The power-law exponent of the creep modulus was force-independent and did not differ between cell lines. Importantly, cell tractions due to contractile forces were suppressed markedly in vinculin −/− and head cells, whereas tail cells generated tractions similar to the wild-type and rescue cells. These data demonstrate that vinculin contributes to the mechanical stability under large external forces by regulating contractile stress generation. Furthermore, the regulatory function resides in the tail domain of vinculin containing the paxillin-binding site.     

膝关节挫伤的磁共振影像表现

目的 :探讨磁共振短时的反转恢复序列 (STIR)在膝关节骨挫伤中的临床应用。方法 :通过 32例膝关节外伤病例在常规SE序列、FSE序列和STIR序列中的影像表现 ,分析STIR序列的优越性。结果 :32例共 45个骨挫伤病灶 ,T1W发现 38个 (占 84% ) ,T2W发现 37个 (占 82 % ) ,STIR序列病灶全部显示( 1 0 0 % )。结论 :STIR序列对骨挫伤的敏感性较高 ,能显示微小的骨髓水肿 ,充血及骨小梁的微骨折及其周围的骨软骨、关节囊的细微变化 ,对膝关节外伤具有较高价值。     

Breakdown of the endothelial barrier function in tumor cell transmigration

The ability of tumor cells to metastasize is associated with a poor prognosis for cancer. During the process of metastasis, tumor cells circulating in the blood or lymph vessels can adhere to, and potentially transmigrate through, the endothelium and invade the connective tissue. We studied the effectiveness of the endothelium as a barrier against the invasion of 51 tumor cell lines into a three-dimensional collagen matrix. Only nine tumor cell lines showed attenuated invasion in the presence of an endothelial cell monolayer, whereas 17 cell lines became invasive or showed a significantly increased invasion. Endothelial cells cocultured with invasive tumor cells increased chemokine gene expression of IL-8 and Gro-β. Expression of the IL-8 and Gro-β receptor, CXCR2, was upregulated in invasive tumor cells. Addition of IL-8 or Gro-β increased tumor cell invasiveness by more than twofold. Tumor cell variants selected for high CXCR2 expression were fourfold more invasive in the presence of an endothelial cell layer, whereas CXCR2 siRNA knock-down cells were fivefold less invasive. We demonstrate that Gro-β and IL-8 secreted by endothelial cells, together with CXCR2 receptor expression on invasive tumor cells, contribute to the breakdown of the endothelial barrier by enhancing tumor cell force generation and cytoskeletal remodeling dynamics.     

Structural insight into the role of the second intracellular loop of the bradykinin 2 receptor in signaling and internalization.

The second cytoplasmic loop (IC2) of the bradykinin B2 receptor plays a vital role in its dynamic life cycle including the activation, internalization, desensitization, and resensitization of this receptor. Here, we probe the structure and function of the IC2, with particular emphasis on threonine-137, which is crucial for signal transduction and internalization. Mutation of this threonine to proline (T137P) produces wild type (WT) signaling and complete inhibition of internalization. Incorporation of aspartate (T137D) leads to a marked reduction in receptor signaling but with WT receptor uptake. The T137D mutation coupled with serine to alanine substitution of S335 and S341 within the distal C-terminus recovers signaling, leading to an actually enhanced arachidonic acid release and phosphoinositide turnover compared to WT bradykinin B2 receptor (BKB2R). To provide a structural basis for the actions of this mutant, the conformational features of IC2 (both WT and mutant) were investigated by high-resolution NMR. The NMR analysis illustrated two prominent alpha-helices at the N- (L123-M138) and C-termini (A149-I156) of the IC2 receptor domain. Incorporating these structural characteristics into a model of BKB2R, we determined that the entire N-terminal helix of IC2 is incorporated as TM3, placing Y131 1.5 helical turns into TM3 and T137 at the membrane surface. The NMR data indicated no structural changes upon substitution of T137D. These results suggest that the altered signaling of the T137D mutant can be attributed to the introduction of a negative charge, indicating that phosphorylation of this residue takes place and participates in the life cycle of this receptor. Additionally, the return to WT signal capacity of the mutation T137D/S335A/S341A, to overcome the deleterious T137D substitution points to a functional interaction between the IC2 and the C-terminus.     

The PDZ1 domain of SAP90. Characterization of structure and binding.

The structural features of the PDZ1 domain of the synapse-associated protein SAP90 have been characterized by NMR. A comparison with the structures of the PDZ2 and PDZ3 domains of SAP90 illustrates significant differences, which may account for the unique binding properties of these homologous domains. Within the postsynaptic density, SAP90 functions as a molecular scaffold with a number of the protein-protein interactions mediated through the PDZ1 domain. Here, using fluorescence anisotropy and NMR chemical shift analysis, we have characterized the association of PDZ1 to the C-terminal peptides of the GluR6 subunit of the kainate receptor, voltage-gated K(+) channel Kv1.4, and microtubule-associate protein CRIPT, all of which are known to associate with SAP90. The latter two, which possess the consensus sequence for binding to PDZ domains (T/S-X-V-oh), have low micromolar binding affinities (1.5-15 microm). The C terminus of GluR6, RLPGKETMA-oh, lacking the consensus sequence, binds to PDZ1 of SAP90 with an affinity of 160 microm. The NMR data illustrate that although all three peptides occupy the binding groove capped by the GLGF loop of PDZ1, specific differences are present, consistent with the variation in binding affinities.     

Identification of a contact domain between echistatin and the integrin alpha(v)beta(3) by photoaffinity cross-linking.

The integrin alpha(v)beta(3) is the major receptor mediating the attachment of osteoclasts to the extracellular matrix in bone and plays a critical role in bone resorption and bone remodeling. Most of the ligands interacting with the alpha(v)beta(3) receptor contain an Arg-Gly-Asp (RGD) motif. Recently, we have identified two small RGD peptides, containing a benzophenone moiety at either the carboxyl or amino terminus, that photo-cross-linked within the beta(3)[99-118] [Bitan, G., et al. (1999) Biochemistry 38, 3414-3420] or the beta(3)[167-171] [Bitan, G., et al. (2000) Biochemistry 39, 11014-11023] sequence, respectively, of the alpha(v)beta(3) receptor in a selective fashion. Here, we report the synthesis of a photoreactive analogue of echistatin (a 49-amino acid peptide), a potent RGD-containing antagonist of the alpha(v)beta(3) receptor both in vitro and in vivo. This bioactive analogue is substituted at position 45 with a p-benzoyl moiety (pBz(2)), located within the flexible C-terminal domain and removed 20 amino acid residues from the R(24)GD(26) triad. This C-terminal domain was reported to contribute to receptor binding affinity by acting as an auxiliary binding site. The radiolabeled (125)I-[Arg(35),Lys(45)(N(epsilon)-pBz(2))]-echistatin photo-cross-links effectively to a site within the beta(3)[209-220] sequence. Residues in this domain have been reported to be part of the metal ion-dependent adhesion site (MIDAS). Receptor fragments overlapping this domain were reported to bind to fibrinogen and block fibrinogen binding to alpha(IIb)beta(3), the platelet integrin receptor. Taken together, position 45 in echistatin, located within an auxiliary binding site in echistatin, cross-links to a site distinct from the two previously reported sites, beta(3)[99-118] and beta(3)[167-171], which cross-link to photophores flanking the RGD triad. These cross-linking data support the hypothesis that the ligand-bound conformation of the integrin beta(3) subunit differs from the known conformation of I domains.     

Structural characterization of the intermolecular interactions of synapse-associated protein-97 with the NR2B subunit of N-methyl-D-aspartate receptors

The synapse-associated protein-97 (SAP97) is important in the proper trafficking and cell surface maintenance of the N-methyl-D-aspartate ionotropic glutamate receptor. The molecular scaffold/receptor interaction is mediated by the association of the C terminus of the NR2B subunit of the N-methyl-D-aspartate receptor with the PDZ domains of SAP97. Here, we characterize the binding of the C terminus of NR2B with the PDZ domains of SAP97 and determine the structure of the PDZ1-NR2B complex employing high-resolution NMR. Based on fluorescence anisotropy, the NR2B subunit binds to the first and second PDZ domains of SAP97, with higher affinity for PDZ2; no appreciable binding to PDZ3 could be measured. The structural features of the NR2B bound to PDZ1 is consistent with the canonical PDZ-binding motif with the glutamic acid at the -3 position of the C terminus (i.e. -E-S-D-V) interacting with the beta2/beta3 loop. Two sites within the loop of PDZ1 were replaced with the corresponding residue from PDZ2, D243G and P245Q. The former mutation, designed to remove a possible Coulombic repulsion between E(-3)(NR2B) and Asp-243 (PDZ1) has only a minimal effect on binding. The P245Q mutation leads to a 2-fold increase in binding affinity of NR2B, approaching that observed for wild-type PDZ2. These results indicate that modification of the beta2/beta3 loop provides an avenue for regulating the ligand specificity of PDZ domains.     

Structural characterization of a cyclic dipeptidomimetic: the effect of ring size on a 1,2,5-trisubstituted-3-oxo-1,4-diazepine system

A series of dipeptidomimetics derived from C(alpha)(i)-to-N(i-1) side chain-to-backbone amide cyclization of adjacent amino acids are structurally characterized. The resulting ring systems are either 1,2,5-trisubstituted-3-oxo-1,4-diazepine (DAP) structurally related to benzodiazepines, commonly used in drug candidates and therapeutic agents, or higher homologs of it. Here, we examine the structural consequences of enlarging the ring size from seven members to eight-, nine-, and ten-membered rings. The structural features determined by high-resolution NMR methods, relying largely on homo- and heteronuclear coupling constants, indicate that variation of the ring leads to alternative conformations and topological orientations of the attached chemical moieties or functional groups. Controlling the topological display of the ring substituents required for biological action, using a molecular scaffold made up entirely of functional groups found in peptides, should facilitate the rational, stepwise transformation of peptide lead candidate into a nonpeptidic drug candidate.