posted on 2020-12-09, 19:41authored byDavid A. Nicholson, Abhigyan Sengupta, David J. Nesbitt
The preponderance of a specific d- or l-chirality in fats, sugars, amino acids, nucleic
acids, and so on is ubiquitous in nature, yet the biological origin
of such chiral dominance (i.e., with one enantiomer overwhelmingly
present) remains an open question. One plausible proposal for the
predominance of l-chirality in amino acids could be through
evolutionary templating of chiral RNA-folding via chaperone activity.
To help evaluate this possibility, single molecule fluorescence experiments
have been performed that measure the chiral dependence of chaperone
folding dynamics for the simple tetraloop–tetraloop receptor
(TL-TLR) tertiary binding motif in the presence of a series of chiral
amino acids. Specifically, d- vs l-arginine is found
to accelerate the unfolding of this RNA motif in a chirally selective
fashion, with temperature-dependent studies of the kinetics performed
to extract free energy, enthalpy, and entropy landscapes for the underlying
thermodynamics. Furthermore, all-atom molecular dynamics (MD) simulations
are pursued to provide additional physical insight into this chiral
sensitivity, which reveal enantiomer-specific sampling of nucleic
acid surfaces by d- vs l-arginine and support a
putative mechanism for chirally specific denaturation of RNA tertiary
structure by arginine but not other amino acids.