posted on 2013-02-28, 00:00authored byXiaojun Li, Kathrin H. Hopmann, Jana Hudecová, Johan Isaksson, Jana Novotná, Wenche Stensen, Valery Andrushchenko, Marie Urbanová, John-Sigurd Svendsen, Petr Bouř, Kenneth Ruud
Increasing precision of contemporary computational methods
makes
spectroscopies such as vibrational (VCD) and electronic (ECD) circular
dichroism attractive for determination of absolute configurations
(AC) of organic compounds. This is, however, difficult for polar,
flexible molecules with multiple chiral centers. Typically, a combination
of several methods provides the best picture of molecular behavior.
As a test case, all possible stereoisomers with known AC (RS, SR, SS, and RR) of the cyclic dipeptide cyclo(Arg-Trp) (CAT) were synthesized,
and the performances of the ECD, infrared (IR), VCD, Raman, Raman
optical activity (ROA), and nuclear magnetic resonance (NMR) techniques
for AC determination were investigated. The spectra were interpreted
with the aid of density functional theory (DFT) calculations. Folded
geometries stabilized by van der Waals and electrostatic interactions
between the diketopiperazine (DKP) ring and the indole group are predicted
to be preferred for CAT, with more pronounced folding due to Arg-Trp
stacking in the case of SS/RR-CAT. The RS/SR isomers prefer a twist-boat puckering of the DKP ring, which is
relatively independent of the orientation of the side chains. Calculated
conformer-averaged VCD and ECD spectra explain most of the experimentally
observed bands and allow for AC determination of the tryptophan side-chain,
whereas the stereochemical configuration of the arginine side-chain
is visible only in VCD. NMR studies provide characteristic long-range 2J(C,H) and 3J(C,H) coupling constants, and nuclear Overhauser effect (NOE) correlations,
which in combination with either ECD or VCD also allow for complete
AC determination of CAT.