Origin of Biological Homochirality by Crystallization of an RNA Precursor on a Magnetic Surface

Abstract: Homochirality is a signature of life on Earth yet its origins remain an unsolved puzzle. Achieving homochirality is essential for a high-yielding prebiotic network capable of producing functional polymers like ribonucleic acid (RNA) and peptides. However, a prebiotically plausible and robust mechanism to reach homochirality has not been shown to this date. The chiral-induced spin selectivity (CISS) effect has established a strong coupling between electron spin and molecular chirality and this coupling paves th… Show more

“…Likewise, electrons with a well-deőned spin alignment to the molecular frame interact with chiral molecules based on their molecular handedness [15,16,17,18,19]. In our latest work, we reached homochirality utilizing this phenomenon and showed the importance of magnetic surfaces to induce enantioselective processes in a prebiotic network [20].…”

“…This natural net magnetization is not uniform albeit statistically significant and can allow for spin-selective asymmetric processes due to the CISS effect. In our previous work, we have shown that an essential RNA precursor, ribose-aminooxazoline (RAO), can selectively crystallize from a racemic mixture of pentose aminooxazolines on a magnetized magnetite (Fe3O4) surface[20]. Although, with a subsequent re-crystallization, we obtained nearly enantiopure crystals of RAO; in a natural environment, on a surface with non-uniform magnetization, this process will inevitably be less selective.…”

“…Moreover, we have shown that, conglomerate crystallization can accompany the chiral symmetry breaking by the magnetic surface as a simultaneous and well-matched ampliőcation mechanism. By combining these two necessary features to reach homochirality, we obtained enantiopure crystals of ribose-aminooxazoline (RAO) on magnetite surfaces, from a fully racemic solution of RAO [20]. RAO is a ribonucleotide precursor that can be synthesized by the reaction of glyceraldehyde and 2-aminooxazole with high-yields under prebiotically plausible conditions [22,23].…”

“…It is a poorly water-soluble compound that is stable against racemization and forming homochiral crystals in the non-centrosymmetric P2 1 2 1 2 1 space group [24,22,25]. Last but not least, the emergence of homochirality at the stage of RAO allows for the propagation of homochirality through RNA to peptides and therefore to the entire prebiotic network [26,27,20]. With these features, RAO is an important prebiotic compound which can play a central role in the origin of homochirality.…”

“…Our previous results on spin-selective crystallization of RAO on Fe 3 O 4 surfaces demonstrate that it is possible to obtain enantiopure RAO from a racemic mixture by a process controlled only by the environ-ment [20]. However, the interaction behind this process is not one-sided: just as magnetic surfaces induce enantioselective processes among chiral molecules, chiral molecules as well can induce spin polarization on magnetic surfaces.…”

Chirality-Induced Magnetization of Magnetite by an RNA Precursor

“…Likewise, electrons with a well-deőned spin alignment to the molecular frame interact with chiral molecules based on their molecular handedness [15,16,17,18,19]. In our latest work, we reached homochirality utilizing this phenomenon and showed the importance of magnetic surfaces to induce enantioselective processes in a prebiotic network [20].…”

“…This natural net magnetization is not uniform albeit statistically significant and can allow for spin-selective asymmetric processes due to the CISS effect. In our previous work, we have shown that an essential RNA precursor, ribose-aminooxazoline (RAO), can selectively crystallize from a racemic mixture of pentose aminooxazolines on a magnetized magnetite (Fe3O4) surface[20]. Although, with a subsequent re-crystallization, we obtained nearly enantiopure crystals of RAO; in a natural environment, on a surface with non-uniform magnetization, this process will inevitably be less selective.…”

“…Moreover, we have shown that, conglomerate crystallization can accompany the chiral symmetry breaking by the magnetic surface as a simultaneous and well-matched ampliőcation mechanism. By combining these two necessary features to reach homochirality, we obtained enantiopure crystals of ribose-aminooxazoline (RAO) on magnetite surfaces, from a fully racemic solution of RAO [20]. RAO is a ribonucleotide precursor that can be synthesized by the reaction of glyceraldehyde and 2-aminooxazole with high-yields under prebiotically plausible conditions [22,23].…”

“…It is a poorly water-soluble compound that is stable against racemization and forming homochiral crystals in the non-centrosymmetric P2 1 2 1 2 1 space group [24,22,25]. Last but not least, the emergence of homochirality at the stage of RAO allows for the propagation of homochirality through RNA to peptides and therefore to the entire prebiotic network [26,27,20]. With these features, RAO is an important prebiotic compound which can play a central role in the origin of homochirality.…”

“…Our previous results on spin-selective crystallization of RAO on Fe 3 O 4 surfaces demonstrate that it is possible to obtain enantiopure RAO from a racemic mixture by a process controlled only by the environ-ment [20]. However, the interaction behind this process is not one-sided: just as magnetic surfaces induce enantioselective processes among chiral molecules, chiral molecules as well can induce spin polarization on magnetic surfaces.…”

Chirality-Induced Magnetization of Magnetite by an RNA Precursor

Constraints on the Emergence of RNA through Non-Templated Primer Extension with Mixtures of Potentially Prebiotic Nucleotides

Nonenzymatic, prebiotic aminoacylation couples chirality of RNA and protein