Anticancer lipopeptides (ACLPs) are considered promising alternatives to combat resistant cancer cells, but the influence of peptide conformational propensity alone on their selectivity and mechanism remains obscure. In this study, we developed N-palmitoylated MK5E (P1MK5E) and MEK5 (P1MEK5) that have the same composition of 23 residues undergoing the pH-dependent structural alterations but differ in the conformational tendency of their amino acid composites. Nonlipidated peptides were readily accumulated in the A549 cell nucleus by the direct membrane translocation and the heparan sulfate-mediated endocytosis than the lipid-raftdependent pathway. The increased hydrophobicity favored the amino acid-positiondependent folding of P1MK5E and P1MEK5, respectively, toward the α-helical coiledcoil nanofibrils and amyloidlike β-protofibrils. At the close concentrations (∼7.5 μM) to the toxic effects of doxorubicin (DOX), P1MK5E exhibited (i) an increased anticancer toxicity through a time-dependent S-phase arrest, (ii) enhanced plasma membrane permeability, and (iii) dose-dependent changes in the cell death characteristic features in the A549 cells relative to P1MEK5 that was almost inactive at ∼75 μM. These observations were in accordance with the TNF-α-mediated necroptotic signaling in the c-MYC/PARP1-overexpressed A549 cells exposed to P1MK5E and accompanied by the ultrastructure of plasma membrane protrusions, extensive endoplasmic reticulum (ER) membrane expansion, mitochondrial swelling, and the formation of distinct cytoplasmic vacuolation. The structural results and the bioactivity behaviors, herein, declared the significance of α-helical propensity in the peptide sequence and the nanostructure morphologies of self-assembling ACLPs upon the selectivity and enhanced anticancer effectiveness, which notably holds promise in the design and development of efficient therapeutics for cancer.
The
influence of side chain residue and phospholipid characteristics
of the cytoplasmic membrane upon the fibrillation and bacterial aggregation
of arginine (Arg) and tryptophan (Trp) rich antimicrobial peptides
(AMPs) has not been well described to date. Here, we utilized the
structural advantages of HHC-10 and 4HarHHC-10 (Har, l-homoarginine) that are highly active Trp-rich AMPs and investigated
their fibril formation and activity behavior against bacteria. The
peptides revealed time-dependent self-assembly of polyproline II (PPII)
α-helices, but by comparison, 4HarHHC-10 tended to
form higher ordered fibrils due to relatively strong cation−π
stacking of Trp with Har residue. Both peptides rapidly killed S. aureus and E. coli at their MICs and
caused aggregation of bacteria at higher concentrations. This bacterial
aggregation was accompanied by the formation of morphologically distinct
electron-dense nanostructures, likely including but not limited to
peptides alone. Both HHC-10-derived peptides caused blebs and buds
in the E. coli membrane that are rich in POPE phospholipid
that promotes negative curvature. However, the main population of S. aureus cells retained their cocci structure upon treatment
with HHC peptides even at concentration higher than the MICs. In contrast,
the cell aggregation was not induced by HHC fibrils that were most
likely stabilized through intra-/intermolecular cation−π
stacking. It is proposed that masking of these interactions might
have resulted in diminished membrane association/insertion of the
HHC nanostructures. The peptides caused aggregation of POPC/POPG (1/3)
and POPE/POPG (3/1) liposomes. Nonetheless, disaggregation of the
former vesicles was observed at ratios of lipid to peptide of greater
than 6 and 24 for HHC-10 and 4HarHHC-10, respectively.
Collectively, our results revealed dose-dependent bacterial aggregation
mediated by Trp-rich AMPs that was profoundly influenced by the degree
of peptide’s self-association and the composition and intrinsic
curvature of the cytoplasmic membrane lipids.
Owing
to their self-aggregation propensity and selective interaction
with the anionic membranes, the peptides rich in tryptophan (Trp)
and arginine (Arg) are considered for the development of novel anticancer
therapeutics. However, the structural insights from the perspective
of backbone chirality and spatial orientation of side chains into
the selective toxicity of peptides are limited. Here, we investigated
the selectivity and cellular uptake of HHC36, a Trp/Arg-rich nonapeptide,
and its d-enantiomer (allDHHC36) and a retroinverso
analogue in the lung A549 and breast MDA-MB-231 cancer cells. We realized
that the d-peptides can specifically induce autophagy at
nontoxic concentrations only in the A549 cells supported from the
LC 3-II immunostaining expression in the vicinity of the nucleus and
the ultrastructural analysis revealing the autophagosome formation.
The autophagic flux was also remarkable in the cells exposed to d-peptides at a far lower concentration in synergism with doxorubicin
(DOX). In marked contrast, nonselective cell death was observed only
if a high amount of HHC36 was applied. HHC36 tended to irregular collagen-like
fibrils relative to allDHHC36 that distinctly formed higher-order
coiled nanostructures. Interestingly, the short d-peptide
fragments were generated in a harsh oxidative condition. Compared
with the direct membrane transduction of HHC36, the entry of d-peptides into the lung cancer cells was controlled by endocytosis
through the contribution of heparan sulfate proteoglycans (HSPGs)
and cholesterol (CHO). However, both l- and d-peptides
feasibly crossed the membrane and localized inside the S-phase-arrested
cell nucleus. This suggested the likelihood of peptide intercalation
with DNA that might differently appear in selective and/or nonselective
deaths. These results unraveled the d-handedness-selective
toxicity of a self-assembling Trp/Arg-rich sequence that is dependent
on the cell type from the aspects of the density of anionic charges
and CHO in the outer leaflet of the plasma membrane, as well as the
intracellular redox imbalance that may drive the formation of toxic
peptide nanostructure fragments.
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