Solid-State 13 C NMR Chemical Shift Anisotropy Tensors of Polypeptides

A solid state NMR technique for the determination of peptide backbone conformations at specific sites in unoriented samples under magic angle spinning (MAS) is described and demonstrated on a doubly labeled polycrystalline sample of the tripeptide AlaGlyGly and a sextuply labeled lyophilized sample

This work explores the utility of simple rotary resonance experiments for the determination of the magnitude and orientation of 13 C chemical shift tensors relative to one or more 13 C-14 N internuclear axes from 13 C magic-angle-spinning NMR experiments. The experiment relies on simultaneous recoup

The inÑuence of hydrogen bonding (HB) on the 13C chemical shift tensors in four solid amino acids was studied by the ab initio gauge-included atomic orbital (GIAO) approach. The results of the present calculations were compared with those predicted previously and with the experimentally observed shi

The alkynyl carbon chemical shift (CS) tensors for 2-butyne-1,4-diol are reported, based on analyses of the carbon-13 NMR spectra of stationary-powder and slow magic-angle spinning (MAS) samples for which the alkynyl carbon nuclei are enriched in 13C. NMR spectra of slow MAS samples exhibit spinning

## Abstract ^13^C‐nmr chemical shifts of backbone carbonyl and side‐chain β‐carbons in polypeptides provide structural information. Recent utilization of substituent effects on ^13^C‐nmr chemical shifts (principally γ‐effects) has permitted the rationalization of their sequence and conformation dep