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Chemical shifts and structure

Chemical shifts and structure. chemical shifts depend upon local electron distributions, bond hybridization states, proximity to polar groups, nearby aromatic rings, local magnetic anisotropies.

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Chemical shifts and structure

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  1. Chemical shifts and structure • chemical shifts depend upon local electron distributions, bond hybridization states, proximity to polar groups, nearby aromatic rings, local magnetic anisotropies. • in other words, chemical shifts depend upon the structural environment and thus can provide information about structure • observation of relationships between chemical shifts and protein secondary structure has led to the development of some useful empirical rules

  2. Ha chemical shifts and secondary structure • Hachemical shifts are generally lower for a-helices than for b-sheets • the figure at right shows distributions of Ha chemical shifts observed in sheets (lighter bars) and helices (darker bars). The black bar in each distribution is the median. • Hachemical shifts in a-helices are on average 0.39 ppmbelow“random coil” values, while b-sheet values are 0.37 ppm above random coil values. Wishart, Sykes & Richards J Mol Biol (1991) 222, 311.

  3. Chemical shift index (CSI) • trends like these led to the development of the concept of the chemical shift index* as a tool for assigning secondary structure using chemical shift values. • one starts with a table of reference values for each amino-acid type, which is essentially a table of “random coil” Havalues • CSI’s are then assigned as follows: exp’tl Ha shift rel. to referenceassignedCSI within ± 0.1 ppm 0 >0.1 ppm lower -1 >0.1 ppm higher +1 *Wishart, Sykes & Richards Biochemistry (1992) 31, 1647-51.

  4. Chemical shift indices • one can then plot CSI vs. sequence and assign 2ndary str. as follows: • any “dense” grouping of four or more “-1’s”, uninterrupted by “1’s” is assigned as a helix, while any “dense” grouping of three or more “1’s”, uninterrupted by “-1’s”, is assigned as a sheet. • a “dense” grouping means at least 70% nonzero CSI’s. • other regions are assigned as “coil” • this simple technique assigns 2ndary structure w/90-95% accuracy • similar useful relationships exist for 13Ca, 13Cb13CC=O shifts CSI residue #

  5. here’s a figure showing deviations of Ca and Cb chemical shifts from random coil values when in either a-helix or b-sheet conformation for a-helices, Ca shifts are higher than normal, whereas Cb shifts are lower than normal. Note in your reading of the apo-calmodulin paper that Ca shifts are used in characterizing the structure of the interdomain linker

  6. Chemical shifts and structural restraints • so CSI is a useful technique for identifying secondary structures from chemical shift data • explicit restraints on structureare also derivable from chemical shifts, analogous to our nOe-derived distance restraints, our coupling-constant-derived dihedral angle restraints and our hydrogen-exchange derived hydrogen bond restraints. However, these are not in very wide use yet.

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