Unusual gold nanoparticle-antibody interactions

Q3 Materials Science JCIS open Pub Date : 2023-10-01 DOI:10.1016/j.jciso.2023.100089
Helena Mateos , Antonia Mallardi , Esther Serrano-Pertierra , María Carmen Blanco-López , Margherita Izzi , Nicola Cioffi , Gerardo Palazzo
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Abstract

The formation of an antibody (Ab) protein corona surrounding gold nanoparticles (AuNPs) is a crucial step in the design of immunological assays. The Ab corona stabilizes AuNPs, preventing their aggregation even at high ionic strength, and can be achieved by simply mixing Abs and AuNPs. In this paper, we report the unusual interactions between AuNPs and the antibody against L1 Cell Adhesion Molecule (L1CAM) purified from rabbits.

We have observed that at low ionic strength, the addition of a wide range of concentrations of rabbit monoclonal Abs against L1CAM protein immediately causes the coagulation of citrate-capped gold nanoparticles. This finding is surprising since the addition of proteins to colloidal gold usually forms a stable protein corona. The combination of extinction spectra, dynamic light scattering (DLS), and transmission electron microscopy (TEM) measurements reveals the presence of small clusters of AuNPs coated by the antibodies, as well as micron-sized antibody aggregates. Furthermore, static light scattering measurements demonstrate that Ab self-interactions are attractive (with a negative second virial coefficient, B2) and induce very slow Ab self-aggregation over several months. Overall, these results indicate that, at low ionic strength, the presence of AuNPs enhances Ab-Ab interactions, leading to their rapid aggregation. Simultaneously, the self-aggregation of the antibodies coating the AuNPs results in the formation of nanoparticle clusters.

The addition of NaCl to increase the ionic strength fully reverses the coagulation of AuNPs (the Ab-coated AuNPs repel each other) and dissolves the Ab aggregates (the Ab interactions become repulsive, with a positive B2). The AuNPs-induced enhancement of the aggregation process can be explained by considering that the highly favorable binding of Abs on the gold surface compensates for the entropic penalty associated with Ab-Ab aggregation.

The phenomenon we observed is specific to anti-L1CAM purified from rabbits and aligns with very old reports on AuNP coagulation induced specifically by the immunoglobulins present in the cerebrospinal fluid of patients suffering from neurosyphilis or multiple sclerosis (C. Lange Zeitschr. Chemotherap., 1912, 1, 44). It is reasonable to hypothesize that other antibodies exhibit this unusual behavior, so this work may aid in the interpretation of “anomalous” results that might otherwise be attributed to errors in fine-tuning AuNPs-Abs conjugation protocols.

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不同寻常的金纳米粒子-抗体相互作用
在金纳米颗粒(AuNPs)周围形成抗体(Ab)蛋白冠是设计免疫检测的关键步骤。Ab电晕稳定了AuNPs,即使在高离子强度下也能阻止它们聚集,这可以通过简单地混合Abs和AuNPs来实现。在本文中,我们报道了从兔中纯化的抗L1细胞粘附分子抗体(L1 Cell Adhesion Molecule, L1CAM)与AuNPs之间不寻常的相互作用。我们观察到,在低离子强度下,加入大范围浓度的抗L1CAM蛋白的兔单克隆抗体会立即引起柠檬酸盐覆盖的金纳米颗粒凝固。这一发现令人惊讶,因为在胶体金中加入蛋白质通常会形成稳定的蛋白质冕。消光光谱、动态光散射(DLS)和透射电子显微镜(TEM)测量的结合揭示了抗体包被的小簇AuNPs的存在,以及微米大小的抗体聚集体。此外,静态光散射测量表明,Ab自相互作用具有吸引力(具有负的第二维里系数B2),并且在几个月内诱导非常缓慢的Ab自聚集。总的来说,这些结果表明,在低离子强度下,AuNPs的存在增强了Ab-Ab相互作用,导致它们快速聚集。同时,包裹在AuNPs表面的抗体的自聚集导致纳米粒子簇的形成。NaCl的加入增加了离子强度,完全逆转了AuNPs的凝聚(Ab包覆的AuNPs相互排斥),并溶解了Ab聚集体(Ab相互作用成为排斥性,带正电荷B2)。aunps诱导的聚集过程的增强可以通过考虑Abs在金表面的高度有利结合来补偿与Ab-Ab聚集相关的熵损失来解释。我们观察到的现象是针对从兔子中纯化的抗l1cam特异性的,并且与非常古老的关于神经梅毒或多发性硬化症患者脑脊液中存在的免疫球蛋白特异性诱导AuNP凝固的报道一致(C. Lange Zeitschr)。Chemotherap。, 1912, 1, 44)。假设其他抗体也表现出这种不寻常的行为是合理的,因此这项工作可能有助于解释“异常”结果,否则可能归因于微调AuNPs-Abs偶联方案的错误。
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来源期刊
JCIS open
JCIS open Physical and Theoretical Chemistry, Colloid and Surface Chemistry, Surfaces, Coatings and Films
CiteScore
4.10
自引率
0.00%
发文量
0
审稿时长
36 days
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