posted on 2024-04-17, 12:38authored byZachary
R. Cohen, Zoe R. Todd, Lutz Maibaum, David C. Catling, Roy A. Black
Cells require oligonucleotides and polypeptides with
specific,
homochiral sequences to perform essential functions, but it is unclear
how such oligomers were selected from random sequences at the origin
of life. Cells were probably preceded by simple compartments such
as fatty acid vesicles, and oligomers that increased the stability,
growth, or division of vesicles could have thereby increased in frequency.
We therefore tested whether prebiotic peptides alter the stability
or growth of vesicles composed of a prebiotic fatty acid. We find
that three of 15 dipeptides tested reduce salt-induced flocculation
of vesicles. All three contain leucine, and increasing their length
increases the efficacy. Also, leucine–leucine but not alanine–alanine
increases the size of vesicles grown by multiple additions of micelles.
In a molecular simulation, leucine–leucine docks to the membrane,
with the side chains inserted into the hydrophobic core of the bilayer,
while alanine–alanine fails to dock. Finally, the heterochiral
forms of leucine–leucine, at a high concentration, rapidly
shrink the vesicles and make them leakier and less stable to high
pH than the homochiral forms do. Thus, prebiotic peptide-membrane
interactions influence the flocculation, growth, size, leakiness,
and pH stability of prebiotic vesicles, with differential effects
due to sequence, length, and chirality. These differences could lead
to a population of vesicles enriched for peptides with beneficial
sequence and chirality, beginning selection for the functional oligomers
that underpin life.