Vaccination with DKK1-derived peptides promotes bone formation and bone mass in an aged mouse osteoporosis model.

The investigation of agents for the treatment of osteoporosis has been a long-standing effort. The Wnt pathway plays an important role in bone formation and regeneration, and expression of Wnt pathway inhibitors, Dickkopf-1 (DKK1), appears to be associated with changes in bone mass. Inactivation of DKK1 leads to substantially increased bone mass in genetically manipulated animals. DKK1-derived peptides (DDPs) were added to BMP2-stimulated MC3T3-E1 preosteoblastic cells in vitro to evaluate inhibitory activity of DDPs in MC3T3-E1 cell differentiation. Study was extended in vivo on old female mice to show whether or not inhibition of endogenous DKK1 biological activity using DDPs vaccination approach leads to increase of bone formation, bone density, and improvement of bone microstructure. We reported that synthetic DDPs were able to reduce alkaline phosphatase activity, prevent mineralization and inhibit the differentiation of MC3T3-E1 cells in vitro. Furthermore, vaccination with these DDPs in aged female mice 4 times for a total period of 22 weeks promoted bone mass and bone microstructure. 3D microCT and histomorphometric analysis showed that there were significant increase in bone mineral densities, improvement of bone microstructure and promotion of bone formation in the vaccinated mice, especially in the mice vaccinated with DDP-A and DDP-C. Histological and scanning electron microscopy image analysis also indicated that vaccination increased trabecular bone mass and significantly decreased fragmentation of bone fibers. Taken together, these preclinical results suggest that vaccination with DDPs represents a promising new therapeutic approach for the treatment of bone-related disorders, such as osteoporosis.

Chemical conjugation of urokinase to magnetic nanoparticles for targeted thrombolysis.

Thrombolytic therapy is an important treatment for thrombosis, a life-threatening condition in cardiovascular diseases. However, the traditional thrombolytic therapies have often been associated with the risk of severe bleeding. By conjugating urokinase with magnetic nanoparticles (MNPs), we have presented a strategy to control thrombolysis within a specific site. The covalent bioconjugate of urokinase and dextran-coated MNPs was synthesized and isolated. Thrombolysis by the conjugate was studied under a magnetic field in a rat arteriovenous shunt thrombosis model. The magnetic field was generated by two AlNiCo permanent magnets around the site of thrombus. The magnetic field enhanced the thrombolytic efficacy of the conjugate by 5-fold over urokinase with no reduction in plasma fibrinogen and little prolonged bleeding time. It suggested that thrombolysis had been specifically directed to the desired site by the magnetic carrier under the magnetic field. Additionally, the conjugate had a longer half-life than urokinase in circulation.

Gel-pad microarrays templated by patterned porous silicon for dual-mode detection of proteins.

A proof-of-concept study demonstrated the feasibility of a novel gel-pad microarray on porous silicon chips, by initiation of an atom transfer radical propagation (ATRP) polymerisation of (polyethylene glycol) methacrylate (PEGMA) with surface Si-H species, stepwise chemical conversions of the gel membrane to an NTA-Ni2+/histidine-tagged protein system, and matrix-assisted laser desorption/ionisation mass spectroscopy (MALDI MS) and fluorescence detections.

Click-chemistry-conjugated oligo-angiomax in the two-dimensional DNA lattice and its interaction with thrombin.

The recently arising antithrombin drug, angiomax, was successfully conjugated with a 5'-amino oligonucleotide through click chemistry. This oligo-angiomax conjugate was assembled into a two-dimensional DNA lattice with other oligonucleotides together. Besides the plane sheet of DNA lattices, an interesting angiomax-involved DNA tubing structure, constructed by 40 to 50 angiomax stripes which are parallel to the longitudinal axis of the tube, was also imaged. After incubation of thrombins with the angiomax-involved DNA lattice, the binding of thrombins to arrayed angiomax peptides was observed. Finally a chromogenic substrate bioassay was employed to estimate the antithrombin activities as assembled oligo-angiomax DNA lattice approximately 1.1, oligo-angiomax approximately 2.7 angiomax. The functionalized DNA lattices have the potential to be used as a powerful platform for investigation of biomolecular interactions such as drug-protein, protein-protein, DNA-RNA, and DNA-protein interactions in the nano- and subnanoscales.

Aqueous solubility and membrane interactions of hydrophobic peptides with peptoid tags.

Lysine tagging of hydrophobic peptides of parent sequence KKAAALAAAAALAAWAALAAAKKKK-NH(2) has been shown to facilitate their synthesis and purification through water solubilization, yet not impact on the intrinsic properties of the hydrophobic core sequence with respect to its insertion into membranes in an alpha-helical conformation. However, due to their positively charged character, such peptides often become bound to phospholipid head groups in membrane surfaces, which inhibits their transbilayer insertion and/or prevents their transport across cellular bilayers. We sought to develop more neutral peptides of membrane-permeable character by replacing most Lys residues with uncharged peptoid [N-(R)glycyl] residues, which might similarly confer water solubility while retaining membrane-interactive properties of the hydrophobic core. Several "peptoid-tagged" derivatives of the parent peptide were prepared with varying peptoid content, with five of the six Lys residues replaced with peptoids Nala and/or Nval. Conformations of these peptides measured by circular dichroism spectroscopy demonstrated that these water-soluble peptides retain the alpha-helix structure in micelles (lysophosphatidylcholine and sodium dodecyl sulfate) notwithstanding the known helix-breaking capacity of the peptoid tags. Blue shifts in Trp fluorescence spectra and quenching experiments with acrylamide confirmed that peptoid-tagged peptides insert spontaneously into micellar membranes. Results suggest that upon introduction of uncharged tags, the interaction between the membrane and the peptides is dominated by the hydrophobicity of the peptide core rather than the electrostatic interactions between the Lys and the head groups of the lipids. The overall findings indicate that peptoid residues are effective surrogates for Lys as uncharged water-solubilizing tags and, as such, provide a potentially valuable feature of design of membrane-interactive peptides.

Hydrophobicity and helicity of membrane-interactive peptides containing peptoid residues.

Peptoid (N-alkylglycyl) residues in peptides have been studied in a variety of applications, but their behavior in membrane environments has not been systematically investigated. We have synthesized a series of membrane-interactive peptides of prototypic structure KKAAAXAAAAAXAAWAAXAAAKKKK-amide, where X corresponds to the peptoid residues Nala (= sarcosine), Nval, Nile, Nleu, Nphe, and Ntrp. Investigation of their relative hydrophobic character by high-performance liquid chromatography indicated an order of hydrophobicity Ntrp > Nphe > Nleu > Nile > Nval > Nala-largely parallel to the relative scale for these side-chains in natural amino acids, although all values were significantly more "hydrophilic" than their amino acid correspondents. Conformations of peptoid-containing peptides measured by circular dichroism spectroscopy were unordered in the presence of SDS micelles but helical for peptides with X = the corresponding amino acids, suggesting a general helix-breaking tendency for the peptoid residues. However, peptides were able to form helical structures in the solvent n-butanol, indicating that this conformation is possible if peptides became inserted into micellar phases. The latter notion was confirmed by increasing hydrophobic content of the peptides by embedding peptoid Nala residues in Leu-rich rather than Ala-rich sequences, which promoted peptide insertion and helical structure in micelles. The overall results suggest that judicious interspersing of amino acid and peptoid residues in peptide sequences can produce hydrophobic water-soluble materials with membrane-partitioning capacity.

Promotion of cyclization of linear pentapeptides and heptapeptide by different univalent metal ions.

Univalent metal ions such as Na+, K+ and Cs+ can enhance not only the cyclization yields of some linear pentapeptides and heptapeptide but also their cyclization rates while some bivalent and trivalent metal ions such as Mg2+, Ca2+, Zn2+, Fe2+, Ni2+ and Cr3+ elevate neither the cyclization yields nor the cyclization rates and some of them prevent the cyclization.

Synthesis of cyclopentapeptides and cycloheptapeptides by DEPBT and the influence of some factors on cyclization.

Three cyclic peptides - cyclo(GlyAlaTyrLeuAla), cyclo(GlyProTyrLeuAla) and cyclo(GlyTyrGlyGlyProPhePro) - isolated and identified from medicinal herbs were chosen as model cyclic peptides to study the influence of the linear precursors and coupling reagents on cyclization. The 17 linear precursors of these three cyclic peptides were synthesized and cyclized using 3-(diethoxyphosphoryloxy)-(1-3)-benzotriazin-4 (3H)-one (DEPBT) as the major coupling reagent. The present work shows that: (i) the effects of linear peptide precursors on the cyclization are complex but some guidelines for choosing suitable precursor for cyclization could be considered; and (ii) DEPBT results in a higher cyclization yield compared with other coupling reagents. In addition, it was confirmed that peptides containing alternating D and L residues favor cyclization.