Differential Tumor Cell Targeting of Anti-HER2 (Herceptin) and Anti-CD20 (Mabthera) Coupled Nanoparticles
Overview
Affiliations
Two types of antibody-labeled nanoparticles (mAb-NPs) were prepared with the aim to achieve specific tumor targeting. Anti-HER2 and anti-CD20 monoclonal antibodies (mAb) were used as model ligands. Small poly(dl-lactic acid) nanoparticles (PLA NPs) with a mean size of about 170 nm were prepared by the salting out method. Thereafter, the coating of PLA NPs with mAbs was performed in two steps. First, thiol groups (-SH) were introduced on the surface of PLA-NPs by a two-step carbodiimide reaction. The number of -SH groups on the surface of NPs increased from 150 to 400 mmol-SH/mol PLA when cystamine concentrations of 25-1518 mol cystamine/mol PLA were used during the thiolation reaction. In the second step, covalent coupling of antibodies to thiolated NPs (NPs-SH) was obtained via a bifunctional cross-linker, m-maleimidobenzoyl-N-hydroxy-sulfosuccinimide ester (sulfo-MBS). For both mAbs anti-HER2 and anti-CD20, respectively, the number of -SH functions on the NPs had no influence on the amount of mAb coupled to the NPs. Approximately, 295 anti-HER2 and 557 anti-CD20 molecules, respectively, were covalently coupled per nanoparticle. The NPs size after the coupling reactions was about 250 nm. The specific interaction between tumor cells and mAb-NPs was determined by confocal microscopy using two cell lines: SKOV-3 human ovarian cancer cells (overexpressing HER2) and Daudi lymphoma cells (overexpressing CD20). The results showed the selective targeting of mAb-NPs to tumor cells overexpressing the specific antigen. While anti-CD20 labeled NPs (anti-CD20 NPs) bound to and remained at the cellular surface, anti-HER2 labeled NPs (anti-HER2 NPs) were efficiently internalized. The mAb-NPs represent a promising approach to improve the efficacy of NPs in active targeting for cancer therapy while the choice of the antibody-target system defines the fate of the mAb-NPs after their binding to the cells.
Effect of the Protein Corona Formation on Antibody Functionalized Liquid Lipid Nanocarriers.
Navarro-Marchal S, Martin-Contreras M, Castro-Santiago D, Del Castillo-Santaella T, Gravan P, Jodar-Reyes A Int J Mol Sci. 2023; 24(23).
PMID: 38069079 PMC: 10706289. DOI: 10.3390/ijms242316759.
Ekinci M, Rebelo Alencar L, Lopes A, Santos-Oliveira R, Ilem-Ozdemir D J Funct Biomater. 2023; 14(9).
PMID: 37754891 PMC: 10532481. DOI: 10.3390/jfb14090477.
Cell surface GRP78: a potential mechanism of therapeutic resistant tumors.
Amaresan R, Gopal U Cancer Cell Int. 2023; 23(1):100.
PMID: 37221596 PMC: 10204160. DOI: 10.1186/s12935-023-02931-9.
PLGA Particles in Immunotherapy.
Horvath D, Basler M Pharmaceutics. 2023; 15(2).
PMID: 36839937 PMC: 9965784. DOI: 10.3390/pharmaceutics15020615.
Brown S, Snyder J, Ali M Nov Approaches Cancer Study. 2022; 6(3):609-614.
PMID: 35237758 PMC: 8886688. DOI: 10.31031/nacs.2021.06.000639.