Three forms of crystalline aspartame have been observed: two hemihydrate polymorphs and a
dihemihydrate. The 13C CP/MAS NMR spectra of two of the forms of aspartame showed that certain carbons
have up to three resonances due to different conformations/arrangements of molecules in the asymmetric unit
cell. Techniques for assigning resonances based upon the number of attached protons or J couplings were not
effective because the multiple resonances arise from the same carbon in the molecule. We used two-dimensional
exchange experiments on uniformly 13C-labeled aspartame to assign the spectra of aspartame. Experiments
performed with typical MAS rates (7 kHz) and 1H decoupling powers (63 kHz) of uniformly 13C-labeled
aspartame were uninformative because 1H−13C and 13C−13C dipolar couplings significantly broadened these
resonances. Increasing the spinning rate to 28 kHz and the 1H decoupling power to 263 kHz increased the
resolution sufficiently to observe crystallographically inequivalent sites. Two-dimensional radio frequency driven
dipolar recoupling (RFDR) and exchange experiments using very high spinning speed and decoupling power
gave complimentary assignment information for short (1−2 bond) and long (>3 bonds) range interactions in
the two polymorphic forms. For one form of aspartame, peaks were assigned to aspartame molecules in three
inequivalent crystalline environments.
Adducts formed between electrophiles and nucleic acid bases are believed to play a key role in chemically induced mutations and cancer. M(1)G-dR is an endogenous exocyclic DNA adduct formed by the reaction of the dicarbonyl compound malondialdehyde with a dG residue in DNA. It is an intermediate in the synthesis of a class of modified oligodeoxyribonucleotides that are used to study the mutagenicity and repair of M(1)G. This unit presents methods for synthesizing M(1)G-dR by enzymatic coupling.
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