new approach to artificial receptors as mimics for

Institute for Organic Chemistry, University of Duisburg-Essen, Universitätsstraße 5, D-45117 Essen Here, we present the conceptual design of artificial receptors 13 by combining the tweezer 10 with the guanidiniocarbonyl pyrrole 6 via suitable linkers to bind RGD sequences selectively. Synthesis of first prototypes and the evaluation of their binding properties are in progress. By varying the spacer we expect selective recognition of RGD containing proteins. Drugs against integrin depended diseases can be considered as a potential application. [1] Kessler H. et al., Angew. Chem., 1997, 109, 1440–1456. [2] Zanardi F. et al., J. Med. Chem., 2008, 51 (6), 1771-1782. [3] Klärner F. et al., J. Am. Chem. Soc., 2005, 127, 14415–14421. [4] Schmuck C. et al., Synthesis, 2006, 1, 89–96. HO O NH 2 m n O O HN O CO 2 Me HN O NH 2 H 2 N O 13 N H O 3 P 2 m n Different receptors 13 will be obtained by varying the linker. In future research binding studies with different RGD- containing substrates will be carried out with the obtained receptors. Receptor for the negatively charged aspartate residue (D) of the RGD-sequence. 4 A versatile receptor for arginine (R). 3 Scheme 1. Guanidiniocarbonyl pyrrole cation. Scheme 2. Molecular tweezer. The scope of our research is the connection of the binding motifs (Scheme 1-2) by a suitable linker. Molecular modelling (Fig. 4)* has shown that sterically unhindered but rigid spacers should be used. Aromatic linkers are potential candidates. As can be seen from Figures 3 and 4 the ditopic binding motif provides a binding pocket for glycoproteins with a solvent exposed RDG-sequence. A variety of receptors can be synthesized via coupling reactions between the linker molecules. * Monte Carlo conformational search, Macro-Model Ver. 8.0, force field Amber*, GB/SA water solvation. New Approach to Artificial Receptors as Mimics for Integrin-Receptors n = 1-2, m = 0-1 Integrins play a pivotal role in cell processes such as cell-adhesion, cell-differentiation, and cell-signaling and play a crucial effect in diseases like acute renal failure, osteoporosis, apoplectic stroke, and human tumor metastasis. 1 Fig. 3. Binding pocket with the substrate Fig. 4 Fig. 2 RGD-containing substrate Fig. 1. RGD-sequence. Artificial receptor Linker The interior cleft of the integrin vitronectin (Fig. 2) shows binding constants to the Arginine-Glycine-Aspar- tate (RGD) sequence in a nanomolar range (Fig. 1). 2 Inhibition of signal transduction by Johannes Hofmann and Carsten Schmuck capturing the RGD- containing trans- mitter with an artificial receptor. R = alkyl

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Page 1: New Approach to Artificial Receptors as Mimics for

Institute for Organic Chemistry, University of Duisburg-Essen, Universitätsstraße 5, D-45117 Essen

Here, we present the conceptual design of artificial receptors 13 bycombining the tweezer 10 with the guanidiniocarbonyl pyrrole 6 viasuitable linkers to bind RGD sequences selectively. Synthesis of firstprototypes and the evaluation of their binding properties are inprogress.By varying the spacer we expect selective recognition of RGDcontaining proteins. Drugs against integrin depended diseases can beconsidered as a potential application.

[1] Kessler H. et al., Angew. Chem., 1997, 109, 1440–1456.[2] Zanardi F. et al., J. Med. Chem., 2008, 51 (6), 1771-1782.[3] Klärner F. et al., J. Am. Chem. Soc., 2005, 127, 14415–14421.[4] Schmuck C. et al., Synthesis, 2006, 1, 89–96.

HO O

NH2

CO2Me

NH2

H2N

O3P

Different receptors 13 will beobtained by varying thelinker.In future research bindingstudies with different RGD-containing substrates will becarried out with the obtainedreceptors.

Receptor for the negativelycharged aspartate residue (D) ofthe RGD-sequence.4

A versatile receptor for arginine(R).3

Scheme 1. Guanidiniocarbonylpyrrole cation. Scheme 2. Molecular tweezer.

The scope of our research is theconnection of the binding motifs(Scheme 1-2) by a suitable linker.

Molecular modelling (Fig. 4)* hasshown that sterically unhinderedbut rigid spacers should be used.

Aromatic linkers are potentialcandidates. As can be seen fromFigures 3 and 4 the ditopic binding

motif provides a binding pocket forglycoproteins with a solventexposed RDG-sequence.

A variety of receptors can besynthesized via coupling reactionsbetween the linker molecules.

* Monte Carlo conformational search,Macro-Model Ver. 8.0, force field Amber*,GB/SA water solvation.

New Approach to Artificial Receptors as Mimics for Integrin-Receptors

n = 1-2, m = 0-1

Integrins play a pivotal role in cell processes such as cell-adhesion,cell-differentiation, and cell-signaling and play a crucial effect indiseases like acute renal failure, osteoporosis, apoplectic stroke,and human tumor metastasis.1

Fig. 3. Binding pocket with the substrate

Fig. 4Fig. 2

RGD-containing substrate

Fig. 1. RGD-sequence.

Artificial receptor

LinkerThe interior cleft of theintegrin vitronectin (Fig. 2)shows binding constants tothe Arginine-Glycine-Aspar-tate (RGD) sequence in ananomolar range (Fig. 1).2

Inhibition of signal transduction

Johannes Hofmann and Carsten Schmuck

capturing the RGD-containing trans-mitter with an arti-ficial receptor.

R = alkyl

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