STRONG BINDING OF ALKYLGUANIDINIUM IONS BY MOLECULAR TWEEZERS - AN ARTIFICIAL SELECTIVE ARGININE RECEPTOR MOLECULE WITH A BIOMIMETIC RECOGNITION PATTERN
T. Schrader, STRONG BINDING OF ALKYLGUANIDINIUM IONS BY MOLECULAR TWEEZERS - AN ARTIFICIAL SELECTIVE ARGININE RECEPTOR MOLECULE WITH A BIOMIMETIC RECOGNITION PATTERN, Chemistry, 3(9), 1997, pp. 1537-1541
Bisphosphonates 2 and 3 represent the first artificial receptor molecu
les for alkylguanidinium ions. They bind to the guanidinium moiety by
forming a 1:1 chelate complex, stabilized by a planar network of elect
rostatic interactions and hydrogen bonds. This hydrogen bonding config
uration is identical to the ''arginine fork'' postulated by Frankel as
a key element in RNA-protein recognition of the AIDS virus. Our guani
dinium-bisphosphonate complexes thus constitute the first synthetic mo
del for this important biological interaction and demonstrate that the
high binding energy can be a driving force for a conformational chang
e in the receptor (induced fit, e.g., in the RNA). Although binding of
monosubstituted alkylguanidines is generally strong (K-a approximate
to 10 000 in DMSO), molecular tweeter 3 recognizes N- and C-amide-prot
ected arginine derivatives especially well (K-a approximate to 300 000
in DMSO), because an additional hydrogen bond is formed between the a
mide and the phosphonate. Since 3 does not bind amines effectively, it
is highly selective for arginine, even in the presence of lysine or o
ther amino acids. For di-, tri-, and tetrasubstituted guanidines the a
ssociation constant remains low (K-a less than or equal to 1000 in DMS
O) reflecting the increase in the steric bulk of the guest.