Influence de la densité de peptides RGD greffés en surface de polyéthylène téréphtalate sur l’attachement des MC3T3

The aim of this study was to evaluate the impact of different densities on MC3T3 cells attachment onto polyethylene terephthalate (PET) film surfaces. Biomimetic modifications were performed by means of a three-step reaction procedure: creation of COOH functions onto PET surface, coupling agent grafting and finally immobilization of peptides. The originality of this work consist, in one hand on quantifying RGD peptides densities grafted onto PET, and on the other hand on studying MC3T3 cells responses after seeding on such biomimetic surfaces. After each functionnalization step, modifications were validated by several physicochemical techniques: X-Ray Photoelectron Spectroscopy permitted to prove the grafting and high-resolution β-imager coupled with use of radiolabelled amino acids served in evaluation of peptides densities. Moreover, this last technique permit us to ensure stability of binding between peptides and polymer. The efficiency of this new route for biomimetic modification of PET surface was demonstrated by measuring the adhesion at 15 hours of osteoblast like cells. Study of cellular comportment was realized by means of focal contact proteins (vinculin, actin) immunostaining.     

RGD peptides micro-patterning on poly(ethylene terephthalate) surfaces

The aim of this study was to evaluate the impact of RGD micro-patterned poly(ethylene terephthalate) (PET) on human osteoblast progenitor (HOP) cells attachment. Biomimetic modifications were performed by means of a four-step reaction: surface hydrolysis, oxidation in order to create COOH functions, coupling agent grafting (EDC, NHS) and finally immobilization of peptides. In addition to homogeneous or statistically distribution of peptides, micro-patterns of RGD were generated by: optical photolithography and UV excimer laser ablation. Modification steps were validated by physico-chemical techniques: XPS was used to prove covalent grafting at each stage of the surface functionalization, toluidine blue assay and high resolution µ-imager (using [3H]-Lys) to evaluate peptide densities and validate micro-patterns formation. Finally, the efficiency of this biomodification of PET was demonstrated onto homogeneous surfaces by measuring the adhesion between 1 and 24 h of osteoprogenitor cells isolated from HBMSC.     

Multifunctional poly(ethylene glycol) semi-interpenetrating polymer networks as highly selective adhesive substrates for bioadhesive peptide grafting

Novel artificial extracellular matrices were synthesized in the form of semi-interpenetrating polymer networks containing copolymers of poly(ethylene glycol) and acrylic acid (PEG-co-AA) grafted with synthetic bioadhesive peptides onto exposed carboxylic acid moieties. These substrates were very resistant to cell adhesion, but when they were grafted with adhesive peptides they were highly biospecific in their ability to support cell adhesion. Extensive preadsorption of adhesive proteins or peptides did not render these materials cell adhesive; yet covalent grafting of adhesive peptides did render these materials highly cell adhesive even in the absence of serum proteins. Polymer networks containing immobilized PEG-co-AA were grafted with peptides at densities of 475 +/- 40 pmol/cm(2). Polymer networks containing immobilized PEG-co-AA N-terminally grafted with GRGDS supported cell adhesion efficiencies of 42 +/- 4% 4 h after seeding and became confluent after 12 h. These cells displayed cell spreading and cytoskeletal grafted with inactive control peptides (GRDGS, GRGES, or no peptide) supported cell adhesion efficiencies of 0 +/- 0%, even when challenged with high seeding densities (to 100,000 cell/cm(2)) over 14 days. These polymer networks are suitable substrates to investigate in vitro cell-surface interactions in the presence of serum proteins without nonspecific protein adsorption adhesion signals other than those immobilized for study.     

Effect of receptor-ligand affinity on the strength of endothelial cell adhesion.

The objective of this study was to determine the effect of receptor-ligand affinity on the strength of endothelial cell adhesion. Linear and cyclic forms of the fibronectin (Fn) cell-binding domain peptide Arg-Gly-Asp (RGD) were covalently immobilized to glass, and Fn was adsorbed onto glass slides. Bovine aortic endothelial cells attached to the surfaces for 15 min. The critical wall shear stress at which 50% of the cells detached increased nonlinearly with ligand density and was greater with immobilized cyclic RGD than with immobilized linear RGD or adsorbed Fn. To directly compare results for the different ligand densities, the receptor-ligand dissociation constant and force per bond were estimated from data for the critical shear stress and contact area. Total internal reflection fluorescence microscopy was used to measure the contact area as a function of separation distance. Contact area increased with increasing ligand density. Contact areas were similar for the immobilized peptides but were greater on surfaces with adsorbed Fn. The dissociation constant was determined by nonlinear regression of the net force on the cells to models that assumed that bonds were either uniformly stressed or that only bonds on the periphery of the contact region were stressed (peeling model). Both models provided equally good fits for cells attached to immobilized peptides whereas the peeling model produced a better fit of data for cells attached to adsorbed Fn. Cyclic RGD and linear RGD both bind to the integrin alpha v beta 3, but immobilized cyclic RGD exhibited a greater affinity than did linear RGD. Receptor affinities of Fn adsorbed to glycophase glass and Fn adsorbed to glass were similar. The number of bonds was calculated assuming binding equilibrium. The peeling model produced good linear fits between bond force and number of bonds. Results of this study indicate that 1) bovine aortic endothelial cells are more adherent on immobilized cyclic RGD peptide than linear RGD or adsorbed Fn, 2) increased adhesion is due to a greater affinity between cyclic RGD and its receptor, and 3) the affinity of RGD peptides and adsorbed Fn for their receptors is increased after immobilization.     

Gene delivery into mesenchymal stem cells: a biomimetic approach using RGD nanoclusters based on poly(amidoamine) dendrimers

Poly(amidoamine) dendrimers (generations 5 and 6) with amine termini were conjugated with peptides containing the arginine-glycine-aspartic acid (RGD) sequence having in view their application as gene delivery vectors. The idea behind the work was to take advantage of the cationic nature of dendrimers and of the integrin targeting capabilities of the RGD motif to improve gene delivery. Dendrimers were used as scaffolds for RGD clustering and, by controlling the number of peptides (4, 8, and 16) linked to each dendrimer, it was possible to evaluate the effect of RGD density on the gene delivery process. The new vectors were characterized in respect to their ability to neutralize and compact plasmid DNA (pDNA). The complexes formed by the vectors and pDNA were studied concerning their size, zeta potential, capacity of being internalized by cells and ability of transferring genes. Transfection efficiency was analyzed, first, by using a pDNA encoding for Enhanced Green Fluorescent Protein and Firefly Luciferase and, second, by using a pDNA encoding for Bone Morphogenetic Protein-2. Gene expression in mesenchymal stem cells was enhanced using the new vectors in comparison to native dendrimers and was shown to be dependent on the electrostatic interaction established between the dendrimer moiety and the cell surface, as well as on the RGD density of nanoclusters. The use of dendrimer scaffolds for RGD cluster formation is a new approach that can be extended beyond gene delivery applications, whenever RGD clustering is important for modulating cellular responses.     

RGD-conjugated copolymer incorporated into composite of poly(lactide-co-glycotide) and poly(L-lactide)-grafted nanohydroxyapatite for bone tissue engineering

Various surface modification methods of RGD (Arg-Gly-Asp) peptides on biomaterials have been developed to improve cell adhesion. This study aimed to examine a RGD-conjugated copolymer RGD/MPEG-PLA-PBLG (RGD-copolymer) for its ability to promote bone regeneration by mixing it with the composite of poly(lactide-co-glycotide) (PLGA) and hydroxyapatite nanoparticles surface-grafted with poly(L-lactide) (g-HAP). The porous scaffolds were prepared using solvent casting/particulate leaching method and grafted to repair the rabbit radius defects after seeding with autologous bone marrow mesenchymal cells (MSCs) of rabbits. After incorporation of RGD-copolymer, there were no significant influences on scaffold's porosity and pore size. Nitrogen of RGD peptide, and calcium and phosphor of g-HAP could be exposed on the surface of the scaffold simultaneously. Although the cell viability of its leaching liquid was 92% that was lower than g-HAP/PLGA, its cell adhesion and growth of 3T3 and osteoblasts were promoted significantly. The greatest increment in cell adhesion ratios (131.2-157.1% higher than g-HAP/PLGA) was observed when its contents were 0.1-1 wt % but only at 0.5 h after cell seeding. All the defects repaired with the implants were bridged after 24 weeks postsurgery, but the RGD-copolymer contained composite had larger new bone formation and better fusion interface. The composites containing RGD-copolymer enhanced bone ingrowth but presented more woven bones than others. The combined application of RGD-copolymer and bone morphological protein 2 (BMP-2) exhibited the best bone healing quality and was recommended as an optimal strategy for the use of RGD peptides.     

The relative importance of topography and RGD ligand density for endothelial cell adhesion

The morphology and function of endothelial cells depends on the physical and chemical characteristics of the extracellular environment. Here, we designed silicon surfaces on which topographical features and surface densities of the integrin binding peptide arginine-glycine-aspartic acid (RGD) could be independently controlled. We used these surfaces to investigate the relative importance of the surface chemistry of ligand presentation versus surface topography in endothelial cell adhesion. We compared cell adhesion, spreading and migration on surfaces with nano- to micro-scaled pyramids and average densities of 6×10(2)-6×10(11) RGD/mm(2). We found that fewer cells adhered onto rough than flat surfaces and that the optimal average RGD density for cell adhesion was 6×10(5) RGD/mm(2) on flat surfaces and substrata with nano-scaled roughness. Only on surfaces with micro-scaled pyramids did the topography hinder cell migration and a lower average RGD density was optimal for adhesion. In contrast, cell spreading was greatest on surfaces with 6×10(8) RGD/mm(2) irrespectively of presence of feature and their size. In summary, our data suggest that the size of pyramids predominately control the number of endothelial cells that adhere to the substratum but the average RGD density governs the degree of cell spreading and length of focal adhesion within adherent cells. The data points towards a two-step model of cell adhesion: the initial contact of cells with a substratum may be guided by the topography while the engagement of cell surface receptors is predominately controlled by the surface chemistry.     

Antibacterial surfaces based on polymer brushes: investigation on the influence of brush properties on antimicrobial peptide immobilization and antimicrobial activity

Primary amine containing copolymer, poly(N,N-dimethylacrylamide-co-N-(3-aminopropyl)methacrylamide hydrochloride) (poly(DMA-co-APMA)), brushes were synthesized on Ti surface by surface-initiated atom transfer radical polymerization (SI-ATRP) in aqueous conditions. A series of poly(DMA-co-APMA) copolymer brushes on titanium (Ti) surface with different molecular weights, thicknesses, compositions, and graft densities were synthesized by changing the SI-ATRP reaction conditions. Cysteine-functionalized cationic antimicrobial peptide Tet213 (KRWWKWWRRC) was conjugated to the copolymers brushes using a maleimide-thiol addition reaction after initial modification of the grafted chains using 3-maleimidopropionic acid N-hydroxysuccinimide ester. The modified surfaces were characterized by X-ray photoelectron spectroscopy (XPS), water contact angle measurements, attenuated total reflectance Fourier transform infrared (ATR-FTIR) spectroscopy, atomic force microscopy (AFM), and ellipsometry analysis. The conjugation of the Tet213 onto brushes strongly depended on graft density of the brushes at different copolymer brush compositions. The peptide density (peptides/nm(2)) on the surface varied with the initial composition of the copolymer brushes. Higher graft density of the brushes generated high peptide density (pepetide/nm(2)) and lower number of peptides/polymer chain and vice versa. The peptide density and graft density of the chains on surface greatly influenced the antimicrobial activity of peptide grafted polymer brushes against Pseudomonas aeruginosa.     

Three-dimensional migration of neurites is mediated by adhesion site density and affinity

Three-dimensional neurite outgrowth rates within fibrin matrices that contained variable amounts of RGD peptides were shown to depend on adhesion site density and affinity. Bi-domain peptides with a factor XIIIa substrate in one domain and a RGD sequence in the other domain were covalently incorporated into fibrin gels during coagulation through the action of the transglutaminase factor XIIIa, and the RGD-dependent effect on neurite outgrowth was quantified, employing chick dorsal root ganglia cultured two- and three-dimensionally within the modified fibrin. Two separate bi-domain peptides were synthesized, one with a lower binding affinity linear RGD domain and another with a higher binding affinity cyclic RGD domain. Both peptides were cross-linked into fibrin gels at concentrations up to 8.2 mol of peptide/mol of fibrinogen, and their effect on neurite outgrowth was measured. Both two- and three-dimensional neurite outgrowth demonstrated a bi-phasic dependence on RGD concentration for both the linear and cyclic peptide, with intermediate adhesion site densities yielding maximal neurite extension and higher densities inhibiting outgrowth. The adhesion site density that yielded maximal outgrowth depended strongly on adhesion site affinity in both two and three dimensions, with lower densities of the higher affinity ligand being required (0.8-1.7 mol/mol for the linear peptide versus 0.2 mol/mol for the cyclic peptide yielding maximum neurite outgrowth rates in three-dimensional cultures).     

Function of fibrinogen gamma-chain dodecapeptide-conjugated latex beads under flow

In order to perform a fundamental study of platelet substitutes, novel particles that bound to activated platelets were prepared using two oligopeptides conjugated to latex beads. The oligopeptides were CHHLGGAKQAGDV (H12), which is a fibrinogen gamma-chain carboxy-terminal sequence (gamma 400-411), and CGGRGDF (RGD), which contains a fibrinogen alpha-chain sequence (alpha 95-98 RGDF). Both peptides contained an additional amino-terminal cysteine to enable conjugation. Human serum albumin was adsorbed onto the surface of latex beads (average diameter 1microm) and pyridyldisulfide groups were chemically introduced into the adsorbed protein. H12 or RGD peptides were then chemically linked to the modified surface protein via disulfide linkages. H12- or RGD-conjugated latex beads prepared in this way enhanced the in vitro thrombus formation of activated platelets on collagen-immobilized plates under flowing thrombocytopenic-imitation blood. Based on the result of flow cytometric analyses of agglutination, PAC-1 binding, antiP-selectin antibody binding, and annexin V binding, the H12-conjugated latex beads showed minimal interaction with non-activated platelets. These results indicate the excellent potential of H12-conjugated particles as a candidate for a platelet substitute.     

How do immobilised cell-adhesive Arg–Gly–Asp-containing peptides behave at the PAA brush surface?

Bio-engineered surfaces that aim to induce normal cell behaviour in vitro need to ‘mimic’ the extracellular matrix in a way that allows cell adhesion. In this computational work, several model cell-binding peptides with a minimal cell-adhesive Arg–Gly–Asp sequence are investigated in the bulk as well as immobilised on a soft surface. For this reason, a combination of density functional theory and all-atom MD simulations is applied. The major goal of the modelling is to characterise the accessibility of the cell-recognition motif on the functionalised soft polymer surface. As a reference system, the behaviour of three peptide sequences is preliminarily studied in explicit water simulations. From the analysis of the MD trajectories, the solvent accessible surface area, the distribution of water molecules around peptide groups, the secondary structure and the thermodynamics of hydration are evaluated. Furthermore, each peptide is immobilised on the surface of a homopolymer poly(acrylic acid) brush. During MD simulations, all three peptides approach closely toward PAA brush, and their surface accessibility is characterised. Although the peptides are adsorbed onto the brush, they are not hidden by the polymer strands, with RGD unit accessible on the surface and available for guided cell adhesion.     

肝癌细胞-胞外基质粘附性与粘附识别序列的相关性

以微管吸吮技术研究了人肝癌细胞在ＩＶ型胶原／层粘连蛋白（ＬＮ）／纤维连结蛋白（ＦＮ）裱衬表面的粘附性。进一步,用四种人工合成肽精－甘－天冬－丝（ＲＧＤＳ）、甘－精－甘－天冬－苏－脯ＧＲＧＤＴＰ）、酪－异亮－甘－丝－精（ＹＩＧＳＲ０和半胱－天冬－脯－甘－酪－异亮－甘－丝－精（ＣＤＰＧＹＩＧＳＲ）研究了肝癌细胞粘附性对两种粘附识别序列ＲＧＤ和ＹＩＧＳＲ的依赖性。为了归纳和整理实验结果,根据竞争性抑制的     

Peptide-based immunoadsorbents: Molecular grafting of IgG–Fc-binding epitopes of Protein A onto a de novo-designed helix-loop-helix peptide

The development of immunoadsorbents that have high specificity for immunoglobulin and no immunogenicity is essential for immunoadsorption treatment of autoimmune diseases. In this study, we designed peptide immunoadsorbents by molecular grafting of the IgG–Fc binding epitopes of Protein A onto a de novo-designed helix-loop-helix peptide. Linear (linG7A5) and cyclic (cyG7A5) grafted peptides were synthesized to test their binding affinity and specificity. Peptide cyG7A5 demonstrated high specificity for human IgG–Fc, with a K_D of 19 μM, and demonstrated no affinity to other plasma proteins, human serum albumin, or fibrinogen. To evaluate their immunoadsorbance efficiency, the grafted peptides and Protein A were conjugated to polyvinyl acetate resin and tested in a batch-wise process for adsorption removal of IgG from human plasma. The IgG capture capacities of the peptides correlated well with their binding affinities. Interestingly, cyG7A5 showed a higher binding specificity for IgG than did Protein A.     

Enhancement of star vector-based gene delivery to endothelial cells by addition of RGD-peptide

This study aimed to investigate the feasibility of using a cationic nonviral gene carrier in endothelial cells for enhancing gene expression by the addition of an integrin-binding RGD peptide. A 4-branched cationic polymer of poly( N,N-dimethylaminopropylacrylamide) (star vector), developed as a gene carrier, could complex with the luciferase-encoding plasmid DNA under a charge ratio of 5 (vector/pDNA) to form polymer/DNA complexes (polyplexes). The addition of the RGD-containing peptide (GRGDNP) to the polyplex solution led to a decrease in the zeta-potential from ca. +30 to +20 mV along with the reduction in the particle size from ca. 300 to 200 nm. Additionally, a marked inhibition of polyplex aggregation was observed, indicating the coating of the polyplex surface with RGD peptides. A transfection study on endothelial cells showed that the luciferase activity increased with the amount of RGD peptides added to the polyplexes and exhibited minimal cellular cytotoxicity. The transfection activity further increased when cyclic RGD peptides (RGDFV) were used; the activity with RGD peptide addition was approximately 8-fold compared to that without RGD peptide addition. Gene delivery to endothelial cells was significantly enhanced by only the addition of RGD peptides to star vector-based polyplexes.     

Chemical conjugate TMV-peptide bivalent fusion vaccines improve cellular immunity and tumor protection

Chemical conjugation of CTL peptides to tobacco mosaic virus (TMV) has shown promise as a molecular adjuvant scaffold for augmentation of cellular immune responses to peptide vaccines. This study demonstrates the ease of generating complex multipeptide vaccine formulations using chemical conjugation to TMV for improved vaccine efficacy. We have tested a model foreign antigen target-the chicken ovalbumin-derived CTL peptide (Ova peptide), as well as mouse melanoma-associated CTL epitopes p15e and tyrosinase-related protein 2 (Trp2) peptides that are self-antigen targets. Ova peptide fusions to TMV, as bivalent formulations with peptides encoding additional T-help or cellular uptake via the integrin-receptor binding RGD peptide, showed improved vaccine potency evidenced by significantly enhanced numbers of antigen-reactive T cells measured by in vitro IFNgamma cellular analysis. We measured the biologically relevant outcome of vaccination in protection of mice from EG.7-Ova tumor challenge, which was achieved with only two doses of vaccine ( approximately 600 ng peptide) given without adjuvant. The p15e peptide alone or Trp2 peptide alone, or as a bivalent formulation with T-help or RGD uptake epitopes, was unable to stimulate effective tumor protection. However, a vaccine with both CTL peptides fused together onto TMV generated significantly improved survival. Interestingly, different bivalent vaccine formulations were required to improve vaccine efficacy for Ova or melanoma tumor model systems.     

RGD and YIGSR synthetic peptides facilitate cellular adhesion identical to that of laminin and fibronectin but alter the physiology of neonatal cardiac myocytes

In the mammalian heart, the extracellular matrix plays an important role in regulating cell behavior and adaptation to mechanical stress. In cell culture, a significant number of cells detach in response to mechanical stimulation, limiting the scope of such studies. We describe a method to adhere the synthetic peptides RGD (fibronectin) and YIGSR (laminin) onto silicone for culturing primary cardiac cells and studying responses to mechanical stimulation. We first examined cardiac cells on stationary surfaces and observed the same degree of cellular adhesion to the synthetic peptides as their respective native proteins. However, the number of striated myocytes on the peptide surfaces was significantly reduced. Focal adhesion kinase (FAK) protein was reduced by 50% in cardiac cells cultured on YIGSR peptide compared with laminin, even though ₁-integrin was unchanged. Connexin43 phosphorylation increased in cells adhered to RGD and YIGSR peptides. We then subjected the cardiac cells to cyclic strain at 20% maximum strain (1 Hz) for 48 h. After this period, cell attachment on laminin was reduced to 50% compared with the unstretched condition. However, in cells cultured on the synthetic peptides, there was no significant difference in cell adherence after stretch. On YIGSR peptide, myosin protein was decreased by 50% after mechanical stimulation. However, total myosin was unchanged in cells stretched on laminin. These results suggest that RGD and YIGSR peptides promote the same degree of cellular adhesion as their native proteins; however, they are unable to promote the signaling required for normal FAK expression and complete sarcomere formation in cardiac myocytes. cell adhesion; connexin43; focal adhesion kinase; surface chemistry     

Grafting of material-binding function into antibodies Functionalization by peptide grafting

Quite recently, a few antibodies against bulk material surface have been selected from a human repertoire antibody library, and they are attracting immense interest in the bottom-up integration of nanomaterials. Here, we constructed antibody fragments with binding affinity and specificity for nonbiological inorganic material surfaces by grafting material-binding peptides into loops of the complementarity determining region (CDR) of antibodies. Loops were replaced by peptides with affinity for zinc oxide and silver material surfaces. Selection of CDR loop for replacement was critical to the functionalization of the grafted fragments; the grafting of material-binding peptide into the CDR2 loop functionalized the antibody fragments with the same affinity and selectivity as the peptides used. Structural insight on the scaffold fragment used implies that material-binding peptide should be grafted onto the most exposed CDR loop on scaffold fragment. We show that the CDR-grafting technique leads to a build-up creation of the antibody with affinity for nonbiological materials.     

The RGD containing site of the mouse laminin A chain is active for cell attachment, spreading, migration and neurite outgrowth

The laminin A chain has been sequenced by cDNA cloning and was found to contain an RGD sequence. Synthetic peptides containing the RGD sequence and flanking amino acids were active in mediating cell adhesion, spreading, migration, and neurite outgrowth. Furthermore, endothelial cell attachment to a laminin substrate was inhibited by an RGD-containing synthetic peptide. Antisera against the integrin (fibronectin) receptor, and monoclonal antibody to the integrin, VLA-6, inhibited cell interaction with laminin, as well as with peptides containing an RGD sequence. These results suggest that the RGD containing site of laminin is active and interacts with the integrin family of receptors in certain cells.     

Optimized conventional synthesis of “RGD” and “RGDS” peptides and their sarcosine mimics as integrin GP IIb/IIIa antagonists

Synthetic arginyl-glycyl- alpha-aspartyl "RGD" and arginyl-glycyl- alpha-aspartyl-serinyl "RGDS" peptide sequences, which are originally located in matrix proteins, are confirmed to be as versatile integrin GP IIb/IIIa antagonists. Since integrins, as cell surface glycoprotein receptors are implicated in several physiological mechanisms, these peptides are recently specially considered in the design of new therapeutics.Replacing glycine by sarcosine, as its more lipophilic isomer, in RGD peptides seemed, accordingly, interesting in revealing some structural/biological activity relationships.To render "RGD" peptides more conveniently available, an ameliorated quasi-gram yield conventional synthesis in solution of the parent "RGD" and "RGDS" [8, Scheme 1A & 15, Scheme 1B] and their sarcosine analogues, [8', Scheme 1A & 15', Scheme 1B] respectively, is herein described.A compilation of the mild hydrogenolysis removable Z and NO(2) groups and/or the acidiolytic removable Boc group were manipulated for the amino temporary protecting steps. Both the DCCI/HOBt and MA methodologies served well as peptide coupling methods.     

Preparation and evaluation of glycosylated arginine-glycine-aspartate (RGD) derivatives for integrin targeting

Arginine-glycine-aspartate (RGD) derivatives were prepared by a combination of solid-phase and solution-phase synthesis for selective targeting of alpha vbeta 3 integrin expressed in tumors. In order to evaluate the value of a triazole moiety as a proposed amide isostere, the side chain glycosylated cyclic RGD ( cRGD) peptides were synthesized with either a natural amide linkage or a triazole. Affinity of the cRGD constructs for the alpha vbeta 3 integrin was determined in a solid-phase competitive binding assay, showing strong similarity in binding affinity for each of the compounds under evaluation. Furthermore, the in vivo tumor targeting potential of glycosylated cRGD peptides, linked via amide or triazole, was investigated by determining the biodistribution of (125)I-labeled derivatives in mice with tumors expressing alpha vbeta 3. All of the cyclic RGD derivatives showed preferential uptake in the subcutaneous tumors, with the highest tumor-to-blood ratio measured for the triazole-linked glycosylated derivative. The results of the present study are a clear indication of the value of the triazole moiety as a suitable amide isostere in the development of glycosylated peptides as pharmaceuticals.