Novel synthesis and characterization of a collagen-based biopolymer initiated by hydroxyapatite nanoparticles.

In this study, we developed a novel synthesis method to create a complex collagen-based biopolymer that promises to possess the necessary material properties for a bone graft substitute. The synthesis was carried out in several steps. In the first step, a ring-opening polymerization reaction initiated by hydroxyapatite nanoparticles was used to polymerize d,l-lactide and glycolide monomers to form poly(lactide-co-glycolide) co-polymer. In the second step, the polymerization product was coupled with succinic anhydride, and subsequently was reacted with N-hydroxysuccinimide in the presence of dicyclohexylcarbodiimide as the cross-linking agent, in order to activate the co-polymer for collagen attachment. In the third and final step, the activated co-polymer was attached to calf skin collagen type I, in hydrochloric acid/phosphate buffer solution and the precipitated co-polymer with attached collagen was isolated. The synthesis was monitored by proton nuclear magnetic resonance, infrared and Raman spectroscopies, and the products after each step were characterized by thermal and mechanical analysis. Calculations of the relative amounts of the various components, coupled with initial dynamic mechanical analysis testing of the resulting biopolymer, afforded a preliminary assessment of the structure of the complex biomaterial formed by this novel polymerization process.

Solution structure of an insect-specific neurotoxin from the New World scorpion Centruroides sculpturatus Ewing.

We report the high-resolution solution structure of the 6.3 kDa neurotoxic protein CsE-v5 from the scorpion Centruroides sculpturatus Ewing (CsE, range southwestern U.S.). This protein is the second example of an Old World-like neurotoxin isolated from the venom of this New World scorpion. However, unlike CsE-V, which is the first Old World-like toxin isolated and shows both anti-insect and anti-mammal activity, CsE-v5 shows high specificity for insect sodium channels. Sequence-specific proton NMR assignments and distance and angle constraints were obtained from 600 MHz 2D-NMR data. Distance geometry and dynamical simulated annealing refinements were performed to produce a final family of 20 structures without constraint violations, along with an energy-minimized average structure. The protein structure is well-defined (0.66 and 0.97 D rmsd for backbone and all heavy atoms, respectively) with a compact hydrophobic core and several extending loops. A large hydrophobic patch, containing four aromatic rings and other aliphatic residues, makes up a large area of one side of the protein. CsE-v5 shows secondary structural features characteristic of long-chain scorpion toxins: a two and a half-turn alpha-helix, a three-strand antiparallel beta-sheet, and four beta-turns. Among the proteins studied to date from the CsE venom, CsE-v5 is the most compact protein with nearly 50% of the amide protons having long exchange lifetimes, but CsE-v5 is unusual in that it has loop structures similar to both Old and New World toxins. Further, it also lacks prolines in its C-terminal 14 residues. It shows some important differences with respect to CsE-V not only in its primary sequence, but also in its electrostatic potential surface, especially around areas in register with residues 8, 9, 17, 18, 32, 43, and 57. The loss of anti-mammal activity in CsE-v5 and the differences in its anti-insect activity compared to that of other proteins such as CsE-V, v1, and v3 from this New World scorpion may be related to residue variations at these locations.

NMR conformational analysis of cis and trans proline isomers in the neutrophil chemoattractant, N-acetyl-proline-glycine-proline.

Alkaline hydrolysis of corneal proteins in the alkali-injured eye releases N-acetyl-proline-glycine-proline (Ac-Pro-Gly-Pro-OH) among other peptides. It has been shown that this tripeptide is a neutrophil chemoattractant. Existing data suggest that the release of this peptide is the catalytic event for early neutrophil invasion of the cornea leading to corneal ulcers. In order to design inhibitors of this tripeptide chemoattractant that would block neutrophil invasion and diminish corneal ulcers, we studied the solution properties of this tripeptide by NMR spectroscopy and compared this peptide to Ac-Pro-Gly-OH (a weaker chemoattractant), and to Ac-Pro-OH (inactive). The NMR data were consistent with Ac-Pro-Gly-Pro-OH existing in solution as a mixture of four isomers with different cis and trans conformations about the two X-proline amide bonds. The isomer with two trans conformations (trans-trans) was the most dominant (41%) in aqueous solution. This was followed by the isomers with mixed cis and trans conformations (trans-cis, 26% and cis-trans, 20%). The isomer with two cis conformations (cis-cis) was the least favored (13%). The populations of these isomers were investigated in DMSO and they were similar to those reported in aqueous solutions except that the ordering of the trans-cis and cis-trans isomers were reversed. NMR NH temperature coefficients and nuclear Overhauser effect (NOE) measurements as well as CD spectroscopy were used to demonstrate that the four isomers exist primarily in an extended conformation with little hydrogen bonding. The available (NOE) information was used with molecular dynamics calculations to construct a dominant solution conformation for each isomer of the tripeptide. This information will serve as a model for the design of peptide and nonpeptide inhibitors of the chemoattractant.

Automatic assignment of NOESY cross peaks and determination of the protein structure of a new world scorpion neurotoxin using NOAH/DIAMOD.

The 3D NMR structures of the scorpion neurotoxin, CsE-v5, were determined from the same NOESY spectra with NOAH/DIAMOD, an automated assignment and 3D structure calculation software package, and with a conventional manual assignment combined with a distance geometry/simulated annealing (X-PLOR) refinement method. The NOESY assignments and the 3D structures obtained from the two independent methods were compared in detail. The NOAH/DIAMOD program suite uses feedback filtering and self-correcting distance geometry methods to automatically assign NOESY spectra and to calculate the 3D structure of a protein. NOESY cross peaks were automatically picked using a standard software package and combined with 74 manually assigned NOESY peaks to start the NOAH/DIAMOD calculations. After 63 NOAH/DIAMOD cycles, using REDAC procedures in the last 8 cycles, and final FANTOM constrained energy minimization, a bundle of 20 structures with the smallest target functions has a RMSD of 0.81 A for backbone atoms and 1.11 A for all heavy atoms to the mean structure. Despite some missing chemical shifts of side chain protons, 776 (including 74 manually assigned) of 1130 NOE peaks were unambiguously assigned, 150 peaks have more than one possible assignment compatible with the bundle structures, and only 30 peaks could not be assigned within the given chemical shift tolerance ranges in either the D1 or the D2 dimension. The remaining 174, mainly weak NOE peaks were not compatible with the final 20 best bundle structures at the last NOAH/DIAMOD cycle. The automatically determined structures agree well with the structures determined independently using the conventional method and the same NMR spectra, with the mean RMSD in well-defined regions of 0.84 A for bb and 1.48 A for all heavy atoms from residues 2-5, 18-26, 32-36, and 39-45. This study demonstrates the potential of the NOAH/DIAMOD program suite to automatically assign NMR data for proteins and determine their structure.

Nitration of unsaturated fatty acids by nitric oxide-derived reactive nitrogen species peroxynitrite, nitrous acid, nitrogen dioxide, and nitronium ion.

Reactive nitrogen species derived from nitric oxide are potent oxidants formed during inflammation that can oxidize membrane and lipoprotein lipids in vivo. Herein, it is demonstrated that several of these species react with unsaturated fatty acid to yield nitrated oxidation products. Using HPLC coupled with both UV detection and electrospray ionization mass spectrometry, products of reaction of ONOO- with linoleic acid displayed mass/charge (m/z) characteristics of LNO2 (at least three products at m/z 324, negative ion mode). Further analysis by MS/MS gave a major fragment at m/z 46. Addition of a NO2 group was confirmed using [15N]ONOO- which gave a product at m/z 325, fragmenting to form a daughter ion at m/z 47. Formation of nitrated lipids was inhibited by bicarbonate, superoxide dismutase (SOD), and Fe3+-EDTA, while the yield of oxidation products was decreased by bicarbonate and SOD, but not by Fe3+-EDTA. Reaction of linoleic acid with both nitrogen dioxide (*NO2) or nitronium tetrafluoroborate (NO2BF4) also yielded nitrated lipid products (m/z 324), with HPLC retention times and MS/MS fragmentation patterns identical to the m/z 324 species formed by reaction of ONOO- with linoleic acid. Finally, reaction of HPODE, but not linoleate, with nitrous acid (HONO) or isobutyl nitrite (BuiONO) yielded a product at m/z 340, or 341 upon reacting with [15N]HONO. MS/MS analysis gave an NO2- fragment, and 15N NMR indicated that the product contained a nitro (RNO2) functional group, suggesting that the product was nitroepoxylinoleic acid [L(O)NO2]. This species could form via homolytic dissociation of LOONO to LO* and *NO2 and rearrangement of LO* to an epoxyallylic radical L(O)* followed by recombination of L(O)* with *NO2. Since unsaturated lipids of membranes and lipoproteins are critical targets of reactive oxygen and nitrogen species, these pathways lend insight into mechanisms for the formation of novel nitrogen-containing lipid products in vivo and provide synthetic strategies for further structural and functional studies.

Solution structure of a beta-neurotoxin from the New World scorpion Centruroides sculpturatus Ewing.

We report the detailed solution structure of the 7.2 kDa protein CsE-I, a beta-neurotoxin from the New World scorpion Centruroides sculpturatus Ewing. This toxin binds to sodium channels, but unlike the alpha-neurotoxins, shifts the voltage of activation toward more negative potentials causing the membrane to fire spontaneously. Sequence-specific proton NMR assignments were made using 600 MHz 2D-NMR data. Distance geometry and dynamical simulated annealing refinements were performed using experimental distance and torsion angle constraints from NOESY and pH-COSY data. A family of 40 structures without constraint violations was generated, and an energy-minimized average structure was computed. The backbone conformation of the CsE-I toxin shows similar secondary structural features as the prototypical alpha-neurotoxin, CsE-v3, and is characterized by a short 2(1/2)-turn alpha-helix and a 3-strand antiparallel beta-sheet, both held together by disulfide bridges. The RMSD for the backbone atoms between CsE-I and CsE-v3 is 1.48 A. Despite this similarity in the overall backbone folding, the these two proteins show some important differences in the primary structure (sequence) and electrostatic potential surfaces. Our studies provide a basis for unravelling the role of these differences in relation to the known differences in the receptor sites on the voltage sensitive sodium channel for the alpha- and beta-neurotoxins.

The solution structure of a class II major histocompatibility complex superantigen binding domain.

We have used 600 MHz 1H NMR spectroscopy data to determine the solution structure of a 31-residue domain of a murine class II major histocompatibility (MHC) protein. This domain, I-Ab(beta)-(60-90), binds to the superantigen staphylococcal enterotoxin A. Distance geometry and dynamical simulated annealing calculations were performed using NOESY- and COSY-deduced constraints. I-Ab(beta)-(60-90), which is mostly alpha-helical, is more similar to the corresponding region of the class II MHC protein HLA-DR1 than to the class I MHC protein HLA-A2. Arg-72 and Arg-80 lie on the same side of the helix and face away from the antigenic peptide binding groove. His-81, implicated in both superantigen and peptide binding, is located midway between the surface defined by Arg-72/Arg-80 and residues that define the inside of the peptide binding groove, allowing for its participation in both types of binding.

Structural requirements for agonist activity of a murine interferon-gamma peptide.

We have demonstrated previously that murine interferon-gamma (MuIFN-gamma) binds to the extracellular domain of the receptor alpha chain through its N-terminus and subsequently to the cytoplasmic domain of the receptor via its C-terminus. Binding of the C-terminus to the cytoplasmic domain of the receptor is thought to occur following endocytosis of the IFN-gamma-receptor complex. In fact, the MuIFN-gamma C-terminus peptide, MuIFN-gamma (95-133), has full agonist activity on macrophages where it is internalized through pinocytosis. Here we examine the structural elements required for the agonist activity of MuIFN-gamma (95-133). Disruption of the alpha helical structure of the peptide by proline substitutions or truncation of the helix resulted in significant loss of binding or loss of antiviral activity or both and induction of MHC class II molecules. Further, removal of the polycationic sequence RKRKR in the tail beyond the helical structure also resulted in loss of agonist activity. Thus, we have isolated the functional site on MuIFN-gamma to the C-terminus and have shown that its helical structure and polycationic tail are required for binding to the cytoplasmic domain of the receptor and induction of biologic activity.

Complete 1H NMR assignments of synthetic glycopeptides from the carbohydrate-protein linkage region of serglycins.

We present complete 1H NMR assignments for two synthetic glycopeptides representative of the carbohydrate-protein linkage region of serglycin proteoglycans. The peptides are: Ser(Galp-Xylp)-Gly-Ser-Gly-Ser(Galp-Xylp)-Gly and, Ser(Galp-Xylp)-Gly-Ser(Galp-Xylp)-Gly-Ser(Galp-Xylp)-G ly. A number of 2D NMR spectra together with a 3D NOESY-TOCSY spectrum were acquired at 600 MHz to complete the assignments of the glycopeptides dissolved in water with 40% trifluoroethanol. Preliminary analysis of the NMR data suggests folded structures for the glycopeptides.

Solution structure of an Old World-like neurotoxin from the venom of the New World scorpion Centruroides sculpturatus Ewing.

We have determined the solution structure of an alpha-toxin, CsE-V, isolated from the venom of the New World scorpion Centruroides sculpturatus Ewing (CsE). This toxin causes spontaneous rhythmic contractions in muscle. Unlike other New World toxins from CsE, this protein exhibits amino acid insertions and deletions at locations similar to Old World toxins and may thus represent a transition protein between the New World and Old World scorpion alpha-toxins. Sequence-specific assignments were made using 600 MHz 1H two-dimensional NMR data. NOESY, PH-COSY and amide-exchange data were used to deduce constraints for molecular modeling calculations. Distance geometry and dynamical simulated annealing calculations were performed to generate a family of 70 structures free of constraint violations. With respect to this family of structures, the energy-minimized average structure had root-mean-square deviations of 0.74 and 1.32 A for backbone and all atoms, respectively (excluding the C-terminal dipeptide, which is disordered). As with other scorpion toxins, the secondary structure of CsE-V consists of an alpha-helix, a three-strand anti-parallel beta-sheet, four beta-turns, and a hydrophobic patch that includes tyrosine residues in herringbone configuration. Unlike the CsE-v3 and -v1 proteins from C. sculpturatus, all of the proline residues were found to be in the trans configuration. The alpha-helix is slightly longer in CsE-V. The overall structure is more similar to the Old World alpha-toxin AaH-II from Androctonus australis Hector (r.m.s.d 1.59 A for backbone atoms of matching residues) than to the New World alpha-toxin CsE-v3 (r.m.s.d. 1.91 A). These structural data on CsE-V add further to our knowledge of the conformational repertoire exhibited by these sodium channel-binding neurotoxins.

Proton nuclear magnetic resonance and distance geometry/simulated annealing studies on the variant-1 neurotoxin from the New World scorpion Centruroides sculpturatus Ewing.

The sequence-specific proton resonance assignments for the variant-1 (CsE-v1) neurotoxin from the venom of the New World scorpion Centruroides sculpturatus Ewing (range Southwestern United States) have been performed by 2D 1H NMR spectroscopy at 600 MHz. The stereospecific assignments for the beta-methylene protons of 19 non-proline residues have been determined. A number of short-, medium-, and long-range NOESY contacts as well as the backbone and the side-chain vicinal coupling constants for several residues have been determined. Slowly exchanging amide hydrogens from a number of residues have been identified. On the basis of the NMR data, the solution structure of this protein has been determined by a hybrid procedure consisting of distance geometry and dynamical simulated annealing refinement calculations. Distance constraints from the NOESY data and torsion angle constraints from proton vicinal coupling constant data were used in the simulated annealing calculations. The three-dimensional structure of CsE-v1 is characterized by a three-stranded antiparallel beta-sheet, a short alpha-helix, a cis-proline, and intervening loops. A comparison with the solution NMR data of a homologous protein (CsE-v3) from the Centruroides venom, shows that the structures are essentially similar, except for some minor differences. Some of the NMR spectral perturbations are felt in regions far removed from sites of amino acid substitutions. The hydrophobic surface in CsE-v1 is slightly more extended than in CsE-v3.

13C and 15N nuclear magnetic resonance evidence that the active site carboxyl group of dihydrofolate reductase is not involved in the relay of a proton to substrate.

Nuclear magnetic resonance (NMR) spectra for [2-amino,3-15N2]folate and [2-13C]folate complexed with human dihydrofolate reductase, and for complexes of similarly labeled dihydrofolate, show that the N-3 proton of bound folate or dihydrofolate exchanges slowly with solvent and that the bound substrates are in the imino-keto tautomeric form. Previously proposed schemes for substrate protonation that require bound substrate to be in the enolic tautomer are therefore unlikely. The NMR spectra for bound folate are unchanged by raising the pH from 7 to 9.5, whereas those for free folate show marked changes due to ionization for the N-3 proton. The fraction of bound folate with the N-3 proton ionized at pH 9.5 is therefore very small, and the rate constant for the dissociation of the ionized species must be at least 320 times faster than for the protonated species. Comparison of NMR spectra over the pH range 5 to 7 gives no indication of a change in ionization state of the Glu30 carboxyl group over this pH range. This raises doubts about whether the apparent pKa of approximately 6 that describes pH dependence of hydride transfer is due to ionization of this carboxyl group.

Proton NMR sequence-specific assignments and secondary structure of a receptor binding domain of mouse gamma-interferon.

Previous studies using synthetic peptides and monoclonal antibodies have implicated the N-terminal 39-residue segment as a receptor binding region of mouse gamma-interferon (MuIFN gamma). In this work, we report the solution structure of this fragment (dissolved in water with 40% trifluoroethanol) as determined by proton NMR spectroscopy. The proton sequence-specific assignments were determined from TOCSY and NOESY spectra using established procedures. The secondary structure is characterized by two well-defined alpha-helical regions composed of residues 5-16 and 22-37. These two helices are joined by a loop. No NOESY contacts between the two helical regions were detected. Molecular models consistent with the NMR data were generated for MuIFN gamma (1-39) using distance geometry and restrained molecular dynamics/energy minimization calculations. Comparison with similar N-terminal domains in the published NMR and crystallographic studies on the dimeric human and rabbit IFN gamma suggests some similarities in the structures except that the helical regions in the fragment are longer, and considerable variation may exist in the relative orientation of the two helices in the solution phase. The presence of stronger alpha N sequential NOE's suggests that this peptide is flexible. The absence of NOESY contacts involving the N-terminal tripeptide suggests that this region undergoes rapid segmental motion. The data presented here on MuIFN gamma (1-39), combined with the studies on human and rabbit IFN gamma, suggest that the N-terminal receptor binding domain of the protein can undergo structural changes, the understanding of which may provide insight into the basis for receptor interaction by this lymphokine.