posted on 2024-07-16, 19:37authored byJaehui Park, Eiki Yamashita, Jaehoon Yu, Soo Jae Lee, Soonsil Hyun
Recent attention
has focused on the de novo design
of proteins, paralleling advancements in biopharmaceuticals. Achieving
protein designs with both structure and function poses a significant
challenge, particularly considering the importance of quaternary structures,
such as oligomers, in protein function. The cell penetration properties
of peptides are of particular interest as they involve the penetration
of large molecules into cells. We previously suggested a link between
the oligomerization propensity of amphipathic peptides and their cell
penetration abilities, yet concrete evidence at cellular-relevant
concentrations was lacking due to oligomers’ instability. In
this study, we sought to characterize oligomerization states using
various techniques, including X-ray crystallography, acceptor photobleaching
Förster resonance energy transfer (FRET), native mass spectrometry
(MS), and differential scanning calorimetry (DSC), while exploring
the function related to oligomer status. X-ray crystallography revealed
the atomic structures of oligomers formed by LK-3, a bis-disulfide
bridged dimer with amino acid sequence LKKLCLKLKKLCKLAG, and its derivatives,
highlighting the formation of hexamers, specifically the trimer of
dimers, which exhibited a stable hydrophobic core. FRET experiments
showed that LK-3 oligomer formation was associated with cell penetration.
Native MS confirmed higher-order oligomers of LK-3, while an intriguing
finding was the enhanced cell-penetrating capability of a 1:1 mixture
of l/d-peptide dimers compared to pure enantiomers.
DSC analysis supported the notion that this enantiomeric mixture promotes
the formation of functional oligomers, crucial for cell penetration.
In conclusion, our study provides direct evidence that amphipathic
peptide LK-3 forms oligomers at low nanomolar concentrations, underscoring
their significance in cell penetration behavior.