Heparin-Promoted Cellular Uptake of the Cell-Penetrating Glycosaminoglycan Binding Peptide, GBPECP, Depends on a Single Tryptophan.

A 10-residue, glycosaminoglycan-binding peptide, GBPECP, derived from human eosinophil cationic protein has been recently designated as a potent cell-penetrating peptide. A model system containing peptide, glycan, and lipid was monitored by nuclear magnetic resonance (NMR) spectroscopy to determine the cell-penetrating mechanism. Heparin octasaccharide with dodecylphosphocholine (DPC) lipid micelle was titrated into the GBPECP solution. Our data revealed substantial roles for the charged residues Arg5 and Lys7 in recognizing heparin, whereas Arg3 had less effect. The aromatic residue Trp4 acted as an irreplaceable moiety for membrane insertion, as the replacement of Trp4 with Arg4 abolished cell penetration, although it significantly improved the heparin-binding ability. GBPECP bound either heparin or lipid in the presence or absence of the other ligand indicating that the peptide has two alternative binding sites: Trp4 is responsible for lipid insertion, and Arg5 and Lys7 are for GAG binding. We developed a molecular model showing that the two effects synergistically promote the penetration. The loss of either effect would abolish the penetration. GBPECP has been proven to enter cells through macropinocytosis. The GBPECP treatment inhibited A549 lung cancer cell migration and invasion, implying that the cellular microenvironment would be modulated by GBPECP internalization. The intracellular penetration of GBPECP leading to inhibition of epithelial cell migration and invasion depends on the presence of the tryptophan residue in its sequence compared with similar derivative peptides. Therefore, GBPECP shows substantial potential as a novel delivery therapeutic through rapid and effective internalization and interference with cell mobility.

Autophagy promotes radiation-induced senescence but inhibits bystander effects in human breast cancer cells.

Ionizing radiation induces cellular senescence to suppress cancer cell proliferation. However, it also induces deleterious bystander effects in the unirradiated neighboring cells through the release of senescence-associated secretory phenotypes (SASPs) that promote tumor progression. Although autophagy has been reported to promote senescence, its role is still unclear. We previously showed that radiation induces senescence in PTTG1-depleted cancer cells. In this study, we found that autophagy was required for the radiation-induced senescence in PTTG1-depleted breast cancer cells. Inhibition of autophagy caused the cells to switch from radiation-induced senescence to apoptosis. Senescent cancer cells exerted bystander effects by promoting the invasion and migration of unirradiated cells through the release of CSF2 and the subsequently activation of the JAK2-STAT3 and AKT pathways. However, the radiation-induced bystander effects were correlated with the inhibition of endogenous autophagy in bystander cells, which also resulted from the activation of the CSF2-JAK2 pathway. The induction of autophagy by rapamycin reduced the radiation-induced bystander effects. This study reveals, for the first time, the dual role of autophagy in radiation-induced senescence and bystander effects.