Amino acid conformational analysis

Initial applications of Jqq couplings to amino acid conformation analysis were based on the theoretical finite perturbation theory self consistent field molecular orbital theory at the INDO level of approximation for butanoic acid 25) (Table I). Ptak, et al.(29) noted In their studies of enriched threonine and aspartic acid that application of the butanoic acid couplings did not give agreement with the rotamer populations based on analysis and suggested different values (Table I). We have obtained theoretical results for aspartic... 

R. Chandrasekaran and G. N. Ramachandran, Studies on the conformation of amino acids, xi. Analysis of the observed side group conformations in proteins. Int. J. Protein Res. 2, 223 (1970). 

Analysis and prediction of side-chain conformation have long been predicated on statistical analysis of data from protein structures. Early rotamer libraries [91-93] ignored backbone conformation and instead gave the proportions of side-chain rotamers for each of the 18 amino acids with side-chain dihedral degrees of freedom. In recent years, it has become possible to take account of the effect of the backbone conformation on the distribution of side-chain rotamers [28,94-96]. McGregor et al. [94] and Schrauber et al. [97] produced rotamer libraries based on secondary structure. Dunbrack and Karplus [95] instead examined the variation in rotamer distributions as a function of the backbone dihedrals ( ) and V /, later providing conformational analysis to justify this choice [96]. Dunbrack and Cohen [28] extended the analysis of protein side-chain conformation by using Bayesian statistics to derive the full backbone-dependent rotamer libraries at all... 

FIGURE 5.2 The peptide bond is shown in its usnal trans conformation of carbonyl O and amide H. The atoms are the oi-carbons of two adjacent amino acids joined in peptide linkage. The dimensions and angles are the average valnes observed by crystallographic analysis of amino acids and small peptides. The peptide bond is the light gray bond between C and N. (Adapted from Ramachandran, G. A., ct ai, 1974. Biochimica Biophysica Acta 359 298-302.)... 

The recognition that short chain / -peptides can form regular secondary structures initially came from detailed conformational analysis of y9 -peptides 1 and 66 (which incorporates a central (2S,3S)-3-amino-2-methylbutanoic acid residue) by NMR in pyridine-d5 and CD3OH [10, 103, 164] and homooUgomers (as short as four residues) of trons-2-amino-cyclohexanecarboxyhc acid (trans-ACHC) (e.g. hex-amer 2 for the (S,S) series) by NMR and X-ray diffraction [6, 126, 159]. 

Figure 39-15. The leucine zipper motif. A shows a helical wheel analysis of a carboxyl terminal portion of the DNA binding protein C/EBP. The amino acid sequence is displayed end-to-end down the axis of a schematic a-helix. The helical wheel consists of seven spokes that correspond to the seven amino acids that comprise every two turns of the a-helix. Note that leucine residues (L) occur at every seventh position. Other proteins with "leucine zippers" have a similar helical wheel pattern. B is a schematic model of the DNA binding domain of C/EBP. Two identical C/EBP polypeptide chains are held in dimer formation by the leucine zipper domain of each polypeptide (denoted by the rectangles and attached ovals). This association is apparently required to hold the DNA binding domains of each polypeptide (the shaded rectangles) in the proper conformation for DNA binding. (Courtesy ofS McKnight)...

While the ddNs and ANPs must be converted intracellularly to their 5 -triphosphates (ddNTPs) or diphosphate derivatives before they can interact as competitive inhibitors/alternate substrates with regard to the natural substrates (dNTPs), the NNRTIs do not need any metabolic conversion to interact, noncompetitively with respect to the dNTPs, at an allosteric, non-substrate binding site of the HIV-1 RT. Through the analysis of NNRTI-resistant mutants, combined with site-directed mutagenesis studies, it has become increasingly clear which amino acid residues are involved in the interaction of the NNRTIs with HIV-1 RT, and, since the conformation of the HIV-1 RT has been resolved at 3.0 A resolution [73], it is now possible to visualize the binding site of the NNRTIs [74],... 

Masamura.M. 1988a. Reliability of AMI in Conformational Analysis of Unionized Amino Acids. J. Mol. Struct. (Theochem) 168, 227-234. 

Lewis, P. N., F. A. Momany, and H. A. Scheraga. 1973a. Energy Parameters For Polypeptides Conformational Energy Analysis Of The N-Acetyl N -Methyl Amides of The Twenty Naturally Occurring Amino Acids. Isr. J. Chem. 11, 121-152. 

---