Racemization

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In chemistry racemization refers to partial conversion of one enantiomer into another.

1 Stereochemistry
2 Physical properties
3 Biological importance
4 Formation of racemic mixtures
5 See also

[edit] Stereochemistry

Chiral molecules have two forms (at each point of asymmetry) which differ in their optical characteristics: the levorotatory form (the (−)-form) will rotate the plane of polarization of a beam of light to the left, while the dextrorotatory form (the (+)-form) will rotate the plane of polarization of a beam of light to the right. The two forms, which are non-superimposable when rotated in 3 dimensional space, are said to be diasteromers.

In order for a point of asymmetry to exist there must be four different groups attached to the central atom (the chiral center). When considering chemical stereochemistry it's important to recall that molecules exist in 3 dimensional space, and as such can have different arrangement of the atoms in that space.

[edit] Physical properties

Diastermers have similar chemical properties yet have differing physical properties. Via processes such as crystallization one diastermer can be isolated.

[edit] Biological importance

Generally only one form of a chiral molecule will participate in biochemical reactions while the other simply does not participiate or can cause sideffects in the form of side reactions. Of note, the L form is usually the biologically reactive form.

[edit] Formation of racemic mixtures

Substitution reactions that proceed through a carbocation intermediate (such as unimolecular substitution reactions) lead to the non-stereospecific addition of substituents. While unimolecular elimination reactions also proceed through a carbocation, they do not result in a chiral center, rather they result in a set of geometric isomers in which trans/cis or E/Z forms will result

The rate of racemization (from L-forms to a mixture of L-forms and D-forms) has been used as a way of dating biological specimens.

[edit] See also

Racemic

Protein primary structure and posttranslational modifications
General:	Protein biosynthesis \| Peptide bond \| Proteolysis \| Racemization \| N-O acyl shift
N-terminus:	Acetylation \| Formylation \| Myristoylation \| Pyroglutamate \| methylation \| glycation \| myristoylation (Gly) \| carbamylation
C-terminus:	Amidation \| Glycosyl phosphatidylinositol (GPI) \| O-methylation \| glypiation \| ubiquitination \| sumoylation
Lysine:	Methylation \| Acetylation \| Acylation \| Hydroxylation \| Ubiquitination \| SUMOylation \| Desmosine \| deamination and oxidation to aldehyde\| O-glycosylation \| imine formation \| glycation \| carbamylation
Cysteine:	Disulfide bond \| Prenylation \| Palmitoylation
Serine/Threonine:	Phosphorylation \| Glycosylation
Tyrosine:	Phosphorylation \| Sulfation \| porphyrin ring linkage \| flavin linkage \| GFP prosthetic group (Thr-Tyr-Gly sequence) formation \| Lysine tyrosine quinone (LTQ) formation \| Topaquinone (TPQ) formation
Asparagine:	Deamidation \| Glycosylation
Aspartate:	Succinimide formation
Glutamine:	Transglutamination
Glutamate:	Carboxylation \| polyglutamylation \| polyglycylation
Arginine:	Citrullination \| Methylation
Proline:	Hydroxylation
←Amino acids		Secondary structure→