Abstract

Driving nanomaterials to specific cell populations is still a major challenge for different biomedical applications. Several strategies to improve cell binding and uptake have been tried thus far by intrinsic material modifications or decoration with active molecules onto their surface. In the present work, we covalently bound the chemokine CXCL5 on fluorescently labeled amino-functionalized SiO2 nanoparticles to precisely targeting CXCR2+ immune cells. We synthesized and precisely characterized the physicochemical features of the modified particles. The presence of CXCL5 on the surface was detected by z-potential variation and CXCL5-specific electron microscopy immunogold labeling. CXCL5-amino SiO2 nanoparticle cell binding and internalization performances were analyzed in CXCR2+ THP-1 cells by flow cytometry and confocal microscopy. We showed improved internalization of the chemokine modified particles in the absence or the presence of serum. This internalization was reduced by cell pre-treatment with free CXCL5. Furthermore, we demonstrated CXCR2+ cell preferential targeting by comparing particle uptake in THP-1 vs. low-CXCR2 expressing HeLa cells. Our results provide the proof of principle that chemokine decorated nanomaterials enhance uptake and allow precise cell subset localization. The possibility to aim at selective chemokine receptor-expressing cells can be beneficial for the diverse pathological conditions involving immune reactions.

Highlights

  • The search for nanomaterials (NMs) with the ability to travel to specific biological tissues is constantly increasing

  • We focused on NP surface functionalization with stable biomolecules that usually interact with all the different immune cells in a selective manner

  • We described a novel functionalization of potential nano-delivery systems using chemokines

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Summary

Introduction

The search for nanomaterials (NMs) with the ability to travel to specific biological tissues is constantly increasing. The major physiological protection towards the invasion of external bodies is provided by the immune system (IS), the first line of which involves the so called “innate” IS. This is formed by a huge number of molecules with binding and enzymatic activity that opsonize and modify the alien threat, allowing its quick removal by phagocytes. A safe delivery is even more intricate if the targets are other immune cells, which share many tissue environments with phagocytes

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