The level of endothelial glycocalyx maturity modulates interactions with charged nano-materials

Claire Bridges, Lu Fu, Jonathan Yeow, Xiaojing Huang, Miriam Jackson, Rhiannon Kuchel, James Sterling, Shenda Baker, Megan Lord
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Abstract

Nanomaterials have been extensively investigated for their potential in delivering therapeutics to target tissues, but few have advanced to clinical application. The luminal surface of endothelial cells that line blood vessels are covered by a glycocalyx, a complex extracellular matrix rich in anionic glycans. However, the role of this glycocalyx in governing nanomaterial- cell interactions is often overlooked. In this study, we demonstrate that gold nanoparticles functionalized with branched polyethyleneimine (AuNP+) bind to primary human endothelial cells expressing either a developing or mature glycocalyx, with the interaction involving hyaluronan and heparan sulfate. Notably, the mature glycocalyx decreases the toxicity of AuNP+. In contrast, lipoic acid-functionalized gold nanoparticles (AuNP-) bind to endothelial cells with a developing glycocalyx, but not a mature glycocalyx. To further investigate this phenomenon, we studied charged polymers, including poly(arginine) (polyR) and poly(glutamic acid) (polyE). PolyE does not associate with endothelial cells regardless of glycocalyx maturity, but when glycans are enzymatically degraded, it can bind to the cells. Conversely, polyR associates with endothelial cells irrespective of glycocalyx maturity or glycan degradation. These findings highlight the intricate relationship between nanomaterial charge and presentation in interactions with endothelial cells, offering insights for modulating nanomaterial interactions with the blood vessel wall.
内皮糖萼成熟度调节与带电纳米材料的相互作用
人们对纳米材料向目标组织输送治疗药物的潜力进行了广泛研究,但很少有纳米材料进入临床应用。血管内皮细胞的管腔表面覆盖着一层糖萼,这是一种富含阴离子聚糖的复杂细胞外基质。然而,这种糖萼在管理纳米材料与细胞相互作用方面的作用往往被忽视。在这项研究中,我们证明了用支化聚乙烯亚胺(AuNP+)功能化的金纳米粒子能与表达发育中或成熟糖萼的原代人类内皮细胞结合,其相互作用涉及透明质酸和硫酸肝素。值得注意的是,成熟的糖萼能降低 AuNP+ 的毒性。相比之下,硫辛酸功能化金纳米粒子(AuNP-)能与糖萼正在发育的内皮细胞结合,但不能与成熟的糖萼结合。为了进一步研究这一现象,我们研究了带电聚合物,包括聚(精氨酸)(polyR)和聚(谷氨酸)(polyE)。无论糖萼成熟与否,PolyE 都不会与内皮细胞结合,但当聚糖被酶降解时,它就能与细胞结合。相反,无论糖萼成熟与否或聚糖降解与否,polyR 都能与内皮细胞结合。这些发现凸显了纳米材料在与内皮细胞相互作用时电荷和呈现之间错综复杂的关系,为调节纳米材料与血管壁的相互作用提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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