Preclinical evaluation of senescence-based strategies to improve cancer therapy

  1. ESTEPA FERNÁNDEZ, ALEJANDRA
Dirixida por:
  1. Ramón Martínez Máñez Director
  2. Félix Sancenón Galarza Director
  3. M. Mar Orzáez Calatayud Director

Universidade de defensa: Universitat Politècnica de València

Fecha de defensa: 16 de setembro de 2022

Tribunal:
  1. Ignacio Palmero Rodríguez Presidente/a
  2. Salvador Macip Secretario/a
  3. María de la Fuente Freire Vogal

Tipo: Tese

Resumo

This PhD thesis entitled "Preclinical evaluation of senescence-based strategies to improve cancer therapy" focuses on exploiting senescence as a therapeutic option in cancer treatments through design, synthesis and in vitro and in vivo evaluation. of several nanodevices and prodrugs, as well as the identification of a new senolytic drug. In the first experimental chapter we evaluated the negative effect of endothelial senescence in the tumor context and the consequence of its elimination through the use of the senolytic navitoclax. We found that systemic treatment with palbociclib in an orthotopic model of breast cancer in mice induces senescence in vascular endothelial cells, generating a altered endothelium that favors the migration of cancer cells. Recovery of endothelial functionality was achieved, after palbociclib-senescence induction, by removal of senescent cells (senolysis) with navitoclax-loaded nanoparticles (NP(nav)-Gal). In a preclinical model, the combined treatment of palbociclib with NP(nav)-Gal decreased endothelial senescence in veins as well as in metastatic nodules in the lungs. Taking into account the results obtained, chapter two describes a similar therapeutic strategy for triple-negative breast cancer. In this case, a human xenograft mice model was employed to evaluate the effect of combined therapy of palbociclib plus navitoclax. To overcome the side effects of navitoclax treatment (mainly thrombocytopenia), we evaluated the effect of the prodrug nav-Gal. Palbociclib therapy-induced senescence, followed by adjuvant navitoclax or nav-Gal therapy, resulted in synergistic clearance of senescent tumor cells and reduction of tumor growth and lung metastasis in the xenograft mice model of aggressive human TNBC. Chapter three focuses on the design and development of a new stigmergy nanoparticle communication system to improve tumor therapy in breast cancer. The communication of nanoparticles by stigmergy consists of a sequential system of two nanoparticles in which the first modifies the environment allowing the second nanoparticle to act. To do this, we again rely on a two-step therapy, the first step being the induction of senescence with palbociclib in tumor cells and the second its subsequent elimination with navitoclax. To this end, two nanodevices were prepared: the first nanodevice (NP(palbo)PEG-MUC1) was loaded with palbociclib and functionalized with an aptamer targeting the surface protein MUC1, frequently overexpressed in breast tumor cells; for the second nanodevice, the senolytic nanoparticle NP(nav)-Gal was used. When both nanoparticles were administered sequentially, an increased effect was achieved, delaying tumor growth and reducing lung metastases in the previously described model of hTNBC xenograft mice. In the last chapter we identified a new senolytic agent (H14) that can kill senescent melanoma tumor cells with optimal efficacy and safety in vivo. For this, a combinatorial library of D-amino acid hexapeptides was screened in senescent SK-Mel-103 melanoma cells, in which senescence induction had occurred by treatment with palbociclib. The combined treatment of palbociclib and H14 hexapeptide achieved an improvement in the elimination of senescent tumor cells in vivo, as well as in the reduction of tumor growth, reaching similar effects to the combined treatment of palbociclib and navitoclax. Future breakthroughs in the field of cellular senescence treatment are expected. We hope that the results achieved in this PhD thesis will open new research opportunities and inspire the development of advanced strategies with smart nanodevices and prodrugs for their application in the field of cellular senescence and other different biomedical areas and in sensing and communication technologies to solve patient needs.