<p>Paclitaxel has been a cornerstone of ovarian cancer chemotherapy for over two decades. However, its clinical application is constrained by poor solubility and non-specific delivery, resulting in systemic toxicity and inconsistent therapeutic outcomes. Nanotechnology-based drug delivery systems have emerged as a promising strategy to address these limitations. In this study, we employed elastin-like polypeptide (ELP) nanocarriers, precisely modified with the tumor-targeting AP1 peptide, to deliver paclitaxel in ovarian cancer. ELPs are biologically inspired, genetically engineered polymers that can form nano-sized structures with controlled physicochemical properties, facilitating passive tumor targeting. The integration of the AP1 peptide, which specifically binds to the IL-4 receptor overexpressed in numerous cancers, enables active targeting of these nanocarriers, complementing the passive delivery approach. This investigation focused on the synthesis and characterization of paclitaxel delivery vehicles based on modified (A60) and unmodified (E60) ELPs. Paclitaxel (PTX) was conjugated to ELPs via a thiol–maleimide Michael-addition strategy. Both ELP-PTX formulations formed stable, monodisperse micelles, with A60-PTX nanoparticles measuring 28 ± 2.8&#xa0;nm and E60-PTX nanoparticles measuring 46.8 ± 6.6&#xa0;nm, as determined by TEM. DLS analysis further confirmed the narrow size distribution, evidenced by a single, narrow peak in the size distribution profile, indicating near homogeneity of the micellar population. In vitro binding analysis in SKOV-3 and OVCAR-3 ovarian cancer cells demonstrated significantly enhanced targeting capability with A60, exhibiting ~ 8.6-fold and ~ 2.7-fold higher cell binding than E60, respectively. Consistently, A60-PTX demonstrated superior cytotoxicity, with ~ 2.6-fold and ~ 1.4-fold lower IC50 values than E60-PTX in SKOV-3 (47 nM vs. 120 nM) and OVCAR-3 (45 nM vs. 62 nM), respectively. The relevance of the active targeting was further validated in agarose-based 3D spheroid models of the two cell lines with A60-PTX demonstrating approximately ~ 3-fold (SKOV-3) and ~ 2.5-fold (OVCAR-3) higher cytotoxicity compared to E60-PTX. Overall, this study highlights the potential of AP1-functionalized ELP nanocarriers to enhance the precision and therapeutic efficacy of paclitaxel delivery, offering a promising strategy for targeted ovarian cancer therapy.</p> Graphical Abstract <p></p>

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Targeted paclitaxel delivery in ovarian cancer via AP1-functionalized elastin-like polypeptide nanocarriers: development and characterization

  • Ridhima Goel,
  • Shakeel Alvi,
  • Rashid Ali,
  • Pradeep Sharma,
  • Jayanta Bhattacharyya,
  • Vijaya Sarangthem,
  • Thoudam Debraj Singh

摘要

Paclitaxel has been a cornerstone of ovarian cancer chemotherapy for over two decades. However, its clinical application is constrained by poor solubility and non-specific delivery, resulting in systemic toxicity and inconsistent therapeutic outcomes. Nanotechnology-based drug delivery systems have emerged as a promising strategy to address these limitations. In this study, we employed elastin-like polypeptide (ELP) nanocarriers, precisely modified with the tumor-targeting AP1 peptide, to deliver paclitaxel in ovarian cancer. ELPs are biologically inspired, genetically engineered polymers that can form nano-sized structures with controlled physicochemical properties, facilitating passive tumor targeting. The integration of the AP1 peptide, which specifically binds to the IL-4 receptor overexpressed in numerous cancers, enables active targeting of these nanocarriers, complementing the passive delivery approach. This investigation focused on the synthesis and characterization of paclitaxel delivery vehicles based on modified (A60) and unmodified (E60) ELPs. Paclitaxel (PTX) was conjugated to ELPs via a thiol–maleimide Michael-addition strategy. Both ELP-PTX formulations formed stable, monodisperse micelles, with A60-PTX nanoparticles measuring 28 ± 2.8 nm and E60-PTX nanoparticles measuring 46.8 ± 6.6 nm, as determined by TEM. DLS analysis further confirmed the narrow size distribution, evidenced by a single, narrow peak in the size distribution profile, indicating near homogeneity of the micellar population. In vitro binding analysis in SKOV-3 and OVCAR-3 ovarian cancer cells demonstrated significantly enhanced targeting capability with A60, exhibiting ~ 8.6-fold and ~ 2.7-fold higher cell binding than E60, respectively. Consistently, A60-PTX demonstrated superior cytotoxicity, with ~ 2.6-fold and ~ 1.4-fold lower IC50 values than E60-PTX in SKOV-3 (47 nM vs. 120 nM) and OVCAR-3 (45 nM vs. 62 nM), respectively. The relevance of the active targeting was further validated in agarose-based 3D spheroid models of the two cell lines with A60-PTX demonstrating approximately ~ 3-fold (SKOV-3) and ~ 2.5-fold (OVCAR-3) higher cytotoxicity compared to E60-PTX. Overall, this study highlights the potential of AP1-functionalized ELP nanocarriers to enhance the precision and therapeutic efficacy of paclitaxel delivery, offering a promising strategy for targeted ovarian cancer therapy.

Graphical Abstract