On the basis of a previously discovered anti-αβ integrin peptidomimetic (c(AmpRGD)) and the clinically approved antiangiogenic kinase inhibitor sunitinib, three novel dual conjugates were synthesized (compounds 1-3), featuring the covalent and robust linkage between these two active modules. In all conjugates, the ligand binding competence toward αβ (using both isolated receptors and αβ-overexpressing endothelial progenitor EP cells) and the kinase inhibitory activity (toward both isolated kinases and EPCs) remained almost untouched and comparable to the activity of the single active units. Compounds 1-3 showed interesting antiangiogenesis properties in an in vitro tubulogenic assay; furthermore, dimeric-RGD conjugate 3 strongly inhibited in vivo angiogenesis in Matrigel plug assays in FVB mice. These results offer proof-of-concept of how the covalent conjugation of two angiogenesis-related small modules may result in novel and stable molecules, which impair tumor-related angiogenesis with equal or even superior ability as compared to the single modules or their simple combinations.
The
principle of vinylogy states that the electronic effects of
a functional group in a molecule are possibly transmitted to a distal
position through interposed conjugated multiple bonds. As an emblematic
case, the nucleophilic character of a π-extended enolate-type
chain system may be relayed from the legitimate α-site to the
vinylogous γ, ε, ..., ω remote carbon sites along
the chain, provided that suitable HOMO-raising strategies are adopted
to transform the unsaturated pronucleophilic precursors into the reactive
polyenolate species. On the other hand, when “unnatural”
carbonyl
ipso
-sites are activated as nucleophiles
(umpolung), vinylogation extends the nucleophilic character to “unnatural”
β, δ, ... remote sites. Merging the principle of vinylogy
with activation modalities and concepts such as iminium ion/enamine
organocatalysis, NHC-organocatalysis, cooperative organo/metal catalysis,
bifunctional organocatalysis, dicyanoalkylidene activation, and organocascade
reactions represents an impressive step forward for all vinylogous
transformations. This review article celebrates this evolutionary
progress, by collecting, comparing, and critically describing the
achievements made over the nine year period 2010–2018, in the
generation of vinylogous enolate-type donor substrates and their use
in chemical synthesis.
The outstanding physio-pathological role played by integrin receptors in living subjects motivates the enormous interest shown by scientists worldwide for this topic. More than twenty years of research has spanned across the structural and functional elucidation of these proteins and over their antagonism-based biomedical applications. The proof-of concept stage, aimed at identifying potent inhibitors, covered a decade of studies, and paved the way for a more advanced era of research where these antagonist molecules were thrown into the deep end of applicative studies. This review intends to summarize the major efforts conducted thus far and focuses on the design, synthesis and biomedical applications of cyclic RGD-containing alpha(v)beta(3) integrin antagonists, in both their small and macromolecular formats. In particular, Chapters 1 and 2 offer a comprehensive outlook on the rational basis for the design of integrin inhibitors, Chapter 3 chronicles the biological and medical applications of monofunctional RGD integrin ligands both in their monomeric and multimeric asset, and Chapter 4 illustrates the potential of RGD-based multifunctional systems in molecular medicine.
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