Nonidentity

Conformational analysis (Section 3 1) Study of the conforma tions available to a molecule their relative stability and the role they play in defining the properties of the molecule Conformations (Section 3 1) Nonidentical representations of a molecule generated by rotation about single bonds Conformers (Section 3 1) Different conformations of a single molecule... 

Dynamic structural characteristics can also be interpreted in terms of resonance. There is a substantial barrier to rotation about the C—N single bonds in carboxamides. A frequently observed consequence is the nonidentity of NMR peaks due to the syn and anti... 

Compounds in which one or more carbon atoms have four nonidentical substituents are the largest class of chiral molecules. Carbon atoms with four nonidentical ligands are referred to as asymmetric carbon atoms because the molecular environment at such a carbon atom possesses no element of symmetry. Asymmetric carbons are a specific example of a stereogenic center. A stereogenic center is any structural feature that gives rise to chirality in a molecule. 2-Butanol is an example of a chiral molecule and exists as two nonsuperimposable mirror images. Carbon-2 is a stereogenic center. 

There are a number of important kinds of stereogenic centers besides asymmetric carbon atoms. One example is furnished by sulfoxides with nonidentical substituents on sulfur. Sulfoxides are pyramidal and maintain dieir configuration at room temperature. Unsymmetrical sulfoxides are therefore chiral and exist as enantiomers. Sulfonium salts with three nonidentical ligands are also chiral as a result of their pyramidal shape. Some examples of chiral derivatives of sulfur are given in Scheme 2.1. 

Separation of enantiomers by physical or chemical methods requires the use of a chiral material, reagent, or catalyst. Both natural materials, such as polysaccharides and proteins, and solids that have been synthetically modified to incorporate chiral structures have been developed for use in separation of enantiomers by HPLC. The use of a chiral stationary phase makes the interactions between the two enantiomers with the adsorbent nonidentical and thus establishes a different rate of elution through the column. The interactions typically include hydrogen bonding, dipolar interactions, and n-n interactions. These attractive interactions may be disturbed by steric repulsions, and frequently the basis of enantioselectivity is a better steric fit for one of the two enantiomers. ... 

Alkyl derivatives of 1,3-butadiene usually undergo photosensitized Z-E isomerism when photosensitizers that can supply at least 60 kcal/mol are used. Two conformers of the diene, the s-Z and s-E, exist in equilibrium, so there are two nonidentical ground states from which excitation can occur. Two triplet excited states that do not readily interconvert are derived from the s-E and s-Z conformers. Theoretical calculations suggest that at their energy minimum the excited states of conjugated dienes can be described as an alkyl radical and an orthogonal allyl system called an allylmethylene diradical ... 

Conformations (Section 3.1) Nonidentical representations of a molecule generated by rotation about single bonds. 

The maturation of the precursor protein involves their proteolytic cleavage. There are two proteins important in this cleavage, so-called processing protease and protease enhancing peptide. These are now believed to be nonidentical subunits of the same enzyme. The structural requirements for recognition of the cleavage site are not fully understood and except for a positively charged residue at position (-2) there is no consensus sequence around this site. 

Tropomyosin is a long thin rodlike protein (42x2 nm) of about 30 kDa, composed of two nonidentical subunits. It associates with actin in a ratio of about... 

Fibrinogen (factor I, 340 kDa see Figures 51-1 and 51-4 and Tables 51-1 and 51-2) is a soluble plasma glycoprotein that consists of three nonidentical pairs of polypeptide chains (Aa,Bpy)2 covalently linked by disulfide bonds. The B(3 and y chains contain asparagine-linked complex oligosaccharides. All three... 

The alkylation of an enolate creates a new stereogenic center when the a-substituents are nonidentical. In enantioselective synthesis, it is necessary to control the direction of approach and thus the configuration of the new stereocenter. 

In the discussion of the stereochemistry of aldol and Mukaiyama reactions, the most important factors in determining the syn or anti diastereoselectivity were identified as the nature of the TS (cyclic, open, or chelated) and the configuration (E or Z) of the enolate. If either the aldehyde or enolate is chiral, an additional factor enters the picture. The aldehyde or enolate then has two nonidentical faces and the stereochemical outcome will depend on facial selectivity. In principle, this applies to any stereocenter in the molecule, but the strongest and most studied effects are those of a- and (3-substituents. If the aldehyde is chiral, particularly when the stereogenic center is adjacent to the carbonyl group, the competition between the two diastereotopic faces of the carbonyl group determines the stereochemical outcome of the reaction. 

L gene was identified in PK Kowloon, Nepalese nonidentical twin girls who have been transfusion dependent (K9). The +1 position of intron 7 was replaced from QT to XT, resulting in retention of intron 7 in the R-PK mRNA. Consequently, the... 

Figure 5.6 Biphasic concentration-response plot for an enzyme displaying a high- and low-affinity binding interaction with an inhibitor. In panel A, the data are fit to Equation (5.4) and the best fit suggests a Hill coefficient of about 0.46. In panel B, the data are fitted to an equation that accounts for two, nonidentical binding interactions Vj/v0 = (a/(l + ([/]/ICs0))) + ((1 - a)/(l+([t]/IC(o)))> where a is an amplitude term for the population with high binding affinity, reflected by IC , and IC 0 is the IC50 for the lower affinity interaction. (See Copeland, 2000, for further details.)...

The agonist binding sites on the receptor are some distance from the ion channel and outside the membrane. They are in pockets formed within each a-subunit (Unwin, 1996). The environment of the two binding sites cannot, in principle, be identical because of the nonidentical adjacent subunits and the fact that the receptor is a pentamer. However, functional evidence demonstrating nonequiv-alance of the two binding sites has not been consistent between species. 

S. V., Evidence for two nonidentical drug-interaction sites in the human P-glycoprotein, Proc. Natl. Acad. Sci. USA 1997, 94, 10594-10599. 

Other less definite yet important effects such as profile changes due to nonlinear refractive index alteration in spatially nonuniform high power beams must be carefully considered. As example, the use of nonidentical liquids and optical paths prior to and in, say, EFISH cells and the usual quartz calibration cells could cause potentially inaccurate x determinations. Obviously these types of considerations are important when precise experimentation to test fine models of molecular behavior are intended, but have not stood as obstacle to uncovering the important general trends in molecular nonlinearity enhancement. 

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