Synthesis and biological evaluation of a new triazole-oxotechnetium complex.

A new triazole oxotechnetium chelating agent was synthesized via a 'Click-to-Chelate' strategy. In vivo evaluation of the corresponding (99m)Tc complex shows that the tracer exhibits very interesting properties for molecular imaging.

Synthesis, in vitro screening and in vivo evaluation of cyclic RGD analogs cyclized through oxorhenium and oxotechnetium coordination.

A library of RGD tripeptide analogs cyclized through oxorhenium coordination by an NS2/S chelation motif was synthesized. Screening towards integrins αVß3, αIIbß3 and αVß5 led to the identification of 6 oxorhenium complexes that bind to integrin αVß3 in the submicromolar range. In vivo evaluation of five of the corresponding oxotechnetium complexes using nude mice bearing a U87MG human tumor xenograft showed a significant and specific accumulation of radioactivity inside the tumor. The best results in vivo were obtained with complexes Tc-16 and Tc-50 that displayed a higher tumor accumulation and a lower distribution in other tissues relative to a reference cyclopentapeptide tracer.

Oxorhenium-mediated assembly of noncyclic selective integrin antagonists: a combinatorial approach.

The parallel oxorhenium-mediated assembly of 288 noncyclic RGD analogues is reported. All complexes contain a NS(2) +S chelating motif that enables the unambiguous coordination of the oxorhenium and oxotechnetium cores. In this study, "modules S" contain a variety of pending guanidinium groups whereas the "NS(2) modules" are made of a series of N-acylated amino acids. Combination of sets of "NS(2) " and "S modules" together with tetrabutylammonium tetrachlorooxorhenate gave the corresponding oxorhenium complexes in good yields and satisfactory purities. Evaluation of these metalloconstructs towards integrins α(V) ß(3) , α(IIb) ß(3) , and α(V) ß(5) led to the identification of micromolar and submicromolar antagonists of theses integrins. These compounds exhibit interesting selectivities and promise attractive applications for the molecular imaging of integrin-dependent pathologies.

Synthesis and biochemical evaluation of a cyclic RGD oxorhenium complex as new ligand of alphaVbeta3 integrin.

We report the design of a new ligand of integrins that might be used for the molecular imaging of tumor neoangiogenesis. For this purpose, we designed a modified RGD tripeptide bearing a N-terminal N-bis(thioethyl)glycinate (NS(2)) motif and a thioethyl moiety at the C-terminus. Simultaneous coordination of an oxorhenium core by the NS(2) and thioethyl moieties led to peptide cyclization and gave the corresponding monomers 13a and b (major isomer) resulting from the syn/anti-isomerism, along with dimers' species 16a and b. Cyclometallated peptide 13b showed the most promising activity with an IC(50) of 86 nM for integrin alpha(V)beta(3) whereas it binds integrin alpha(IIb)beta(3) with an affinity lower by an order of magnitude. Labeling with [(99m)Tc]oxotechnetium gluconate led exclusively to complex 17, the equivalent of compound 13b, which displayed satisfactory stabilities in mice plasma and towards glutathione.

Metal-binding stoichiometry and selectivity of the copper chaperone CopZ from Enterococcus hirae.

We studied the interaction of several metal ions with the copper chaperone from Enterococcus hirae (EhCopZ). We show that the stoichiometry of the protein-metal complex varies with the experimental conditions used. At high concentration of the protein in a noncoordinating buffer, a dimer, (EhCopZ)2-metal, was formed. The presence of a potentially coordinating molecule L in the solution leads to the formation of a monomeric ternary complex, EhCopZ-Cu-L, where L can be a buffer or a coordinating molecule (glutathione, tris(2-carboxyethyl)phosphine). This was demonstrated in the presence of glutathione by electrospray ionization MS. The presence of a tyrosine close to the metal-binding site allowed us to follow the binding of cadmium to EhCopZ by fluorescence spectroscopy and to determine the corresponding dissociation constant (Kd = 30 nm). Competition experiments were performed with mercury, copper and cobalt, and the corresponding dissociation constants were calculated. A high preference for copper was found, with an upper limit for the dissociation constant of 10-12 m. These results confirm the capacity of EhCopZ to bind copper at very low concentrations in living cells and may provide new clues in the determination of the mechanism of the uptake and transport of copper by the chaperone EhCopZ.

Analysis of the metal-binding selectivity of the metallochaperone CopZ from Enterococcus hirae by electrospray ionization mass spectrometry.

Metallochaperones are soluble proteins involved in metal transport and regulation in vivo. Copper metallochaperones belong to a structural family of metal binding domains displaying a ferredoxin-like fold (betaalphabetabetaalphabeta) and a consensus metal-binding motif MXCXXC. The metal-binding selectivities for this class of proteins are poorly documented so far. The present study focuses on the measurement of the selectivity of the copper metallochaperone CopZ from Enterococcus hirae for different metal ions using an experimental approach based on electrospray ionization mass spectrometry (ESI-MS). All the metal cations tested, i.e. Cu(I), Cu(II), Hg(II), Cd(II) and Co(II), form specific metal complexes with CopZ. The study of a chemically modified CopZ as well as variants of CopZ in the active site demonstrated that the complexes observed by ESI-MS, i.e. in the gas phase, corresponded to the complexes previously observed by other analytical methods in solution. Competition experiments allowed the classification of the metal ions by increasing affinities for CopZ as follows: Co << Cd < Hg < Cu. A dissociation constant in the range of 20 microM was determined for cobalt. The affinity of CopZ for the other metals tested was found to be higher, with dissociation constants smaller than micromolar.

Engineering new metal specificity in EF-hand peptides.

Peptides (33-34 amino acids long) corresponding to the helix-turn-helix (EF-hand) motif of the calcium binding site I of Paramecium tetraurelia calmodulin have been synthesized. The linear sequence was unable to acquire a native-like conformation and calcium binding. However, incorporation of a well-positioned disulfide bond bridging the two putative helical regions greatly improved the ordered structure and binding properties. Analyzed by electrospray mass spectrometry, circular dichroism and time-resolved laser-induced fluorescence, such a disulfide-stabilized peptide is shown to acquire a calcium-dependent helical conformation and exhibits native-like affinity for calcium, terbium and europium ions with 30+/-1, 3.5+/-0.6 and 0.6+/-0.1 microM dissociation constants, respectively. Comparable affinities were calculated within the biological construct comprising the entire domain I of Arabidopsis taliana calmodulin. Single sequence mutation (Glu25Asp) in the binding loop of the peptide abolishes calcium affinity, but preserves lanthanide affinity, showing that metal selectivity can be modulated by specific mutations. Such disulfide-stabilized peptides represent useful models to engineer metal specificity in new calmodulin proteins, facilitating the development of new systems to monitor metal pollution in biosensors and to increase metal binding capability of bacterial and plant cells in bioremediation techniques.

Calixarene-Based Copper(I) Complexes as Models for Monocopper Sites in Enzymes.

A cavity that acts as a molecular funnel is formed from calix[6]arene 1 and [CuI (NCCH3 )4 ]PF6 [Eq. (a)]. An exchange of the well-protected acetonitrile ligand for other nitriles RCN is only possible with small R groups. The protection of the copper ions precludes oxidative dimerization; thus, the complexes mimic the mononuclear site of copper enzymes.