Homochirality

Homochirality is a uniformity of chirality, or handedness. Objects are chiral when they cannot be superposed on their mirror images. For example, the left and right hands of a human are approximately mirror images of each other but are not their own mirror images, so they are chiral. In chemistry, chirality is a geometric property of some compounds and ions. These compounds exist in two different chiral conformations, enantiomers, often described as the left-handed and right-handed isomers of a compound (denoted by L- (levorotatory to the left) and D- (dextrorotatory to the right), respectively, from how chiral molecules rotate plane-polarized light). The term homochiral is used to describe enantiopure samples of substances in which all the constituents are the same enantiomer.

Enantiomers have the same chemical properties in an achiral environment, so abiotic chemical processes typically produce racemic mixtures of chiral compounds, i.e., mixtures containing equal amounts of L- and D-isomers. However, many biologically-synthesized compounds are homochiral. For example, 19 of the 20 genetically-coded proteinogenic amino acids are left-handed, with exception of the achiral glycine, and biological sugars are right-handed.

Many theories have been proposed for the "function" of homochirality in nature: it may be a form of information storage and may reduce entropy barriers in the formation of large organized molecules. It has been experimentally verified that amino acids form large aggregates in larger abundance from enantiopure samples than from racemic ones. Enantiomeric impurities also impede RNA replication and chain elongation, processes central to both modern cellular processes like transcription and the RNA world hypothesis.

As homochirality is ubiquitous in extant biology, a key question in origins of life and prebiotic chemistry research is how biological homochirality could have arisen from racemic mixtures of the simple chemical building blocks of life. Many mechanisms for the origin of homochirality have been proposed. Some of these models propose three distinct steps: a mirror-symmetry breaking mechanism to create a minute enantiomeric imbalance (enantiomeric excess or ee) from a racemic mixture, subsequent chiral amplification to achieve a larger ee or full homochirality (i.e., ee=100%), and finally chiral transmission/propagation to transfer chirality from one set of molecules to another. In addition, another important consideration is the environmental plausibility of proposed mechanisms — whether a symmetry breaking, amplification, or propagation process could occur over relevant timescales and using only materials that could feasibly be available prebiotically under early Earth conditions.