AI Article Synopsis
- L-amino acids dominate in proteins due to their selection during chemical evolution, but D-aspartyl residues, especially D-β-Asp, are present in various tissues and are believed to accumulate in abnormal proteins.
- D-β-Asp is thought to be more stable and resistant to biochemical reactions, showing less reactivity during bond cleavage compared to its L-amino acid counterpart.
- The study utilizes real-time NMR to compare the peptide bond cleavage rates of different Asp isomers, revealing that D-β-Asp is tougher against cleavage due to differences in pKa and conformation.
Article Abstract
Although L-amino acids were selected as main constituents of peptides and proteins during chemical evolution, D-aspartyl (Asp) residue is found in a variety of living tissues. In particular, D-β-Asp is thought to be stable than any other Asp isomers, and this could be a reason for gradual accumulation in abnormal proteins and peptides to modify their structures and functions. It is predicted that D-β-Asp shows high resistance to biomolecular reactions. For instance, less reactivity of D-β-Asp is expected to bond cleavage, although such information has not been provided yet. In this work, the spontaneous peptide bond cleavage was compared between Asp isomers, by applying real-time solution-state NMR to eye lens αΑ-crystallin 51-60 fragment, S(51)LFRTVLD(58)SG(60) and αΒ-crystallin 61-67 analog, F(61)D(62)TGLSG(67) consisting of L-α- and D-β-Asp 58 and 62, respectively. Kinetic analysis showed how tough the uncommon D-β-Asp residue was against the peptide bond cleavage as compared to natural L-α-Asp. Differences in pKa and conformation between L-α- and D-β-Asp side chains were plausible factors to determine reactivity of Asp isomers. The present study, for the first time, provides a rationale to explain less reactivity of D-β-Asp to allow abnormal accumulation.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4753488 | PMC |
| http://dx.doi.org/10.1038/srep21594 | DOI Listing |
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