Re-engineering lysozyme solubility and activity through surfactant complexation†

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Advances Pub Date : 2024-10-01 DOI:10.1039/D4MA00720D
Jiaming Mu, Leran Mao, Gavin P. Andrews and Sheiliza Carmali
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Abstract

Hydrophobic ion-pairing is an established solubility engineering technique that uses amphiphilic surfactants to modulate drug lipophilicity and facilitate encapsulation in polymeric and lipid-based drug delivery systems. For proteins, surfactant complexation can also lead to unfolding processes and loss in bioactivity. In this study, we investigated the impact of two surfactants, sodium dodecyl sulphate (SDS) and dioctyl sulfosuccinate (DOSS) on lysozyme's solubility, activity, and structure. SDS and DOSS were combined with lysozyme at increasing charge ratios (4 : 1, 2 : 1, 1 : 1, 1 : 2 and 1 : 4) via hydrophobic ion pairing at pH 4.5. Maximum complexation efficiency at the 1 : 1 charge ratio was confirmed by protein quantitation assays and zeta potential measurements, showing a near neutral surface charge. Lysozyme lipophilicity was successfully increased, with log D n-octanol/PBS values up to 2.5 with SDS and 1.8 with DOSS. Bioactivity assays assessing lysis of M. lysodeikticus cell walls showed up to a 2-fold increase in lysozyme's catalytic ability upon complexation with SDS at ratios less than stoichiometric, suggesting favourable mechanisms of stabilisation. Secondary structural analysis using Fourier-transform infrared spectroscopy indicated that lysozyme underwent a partial unfolding process upon complexation with low SDS concentrations. Molecular dynamic simulations further confirmed that at these low concentrations, a positive conformation was obtained with the active site residue Glu 35 more solvent-exposed. Combined, this suggested that sub-stoichiometric SDS altered the active site's secondary structure through increased backbone flexibility, leading to higher substrate accessibility. For DOSS, low surfactant concentrations retained lysozyme's native function and structure while still increasing the protein's lipophilic character. Our research findings demonstrate that modulation of protein activity can be related to surfactant chemistry and that controlled ion-pairing can lead to re-engineering of lysozyme solubility, activity, and structure. This has significant implications for advanced protein applications in healthcare, particularly towards the development of formulation strategies for oral biotherapeutics.

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通过表面活性剂复合重新设计溶菌酶的溶解性和活性†。
疏水离子配对是一种成熟的溶解度工程技术,它使用两亲性表面活性剂来调节药物的亲油性,并促进聚合物和脂质给药系统的封装。对于蛋白质来说,表面活性剂复合物也会导致蛋白质的折叠过程和生物活性的丧失。在本研究中,我们研究了十二烷基硫酸钠(SDS)和磺基琥珀酸二辛酯(DOSS)这两种表面活性剂对溶菌酶的溶解度、活性和结构的影响。在 pH 值为 4.5 的条件下,通过疏水离子配对,溶菌酶与 SDS 和 DOSS 的电荷比(4:1、2:1、1:1、1:2 和 1:4)依次增加。电荷比为 1 :蛋白质定量检测和 zeta 电位测量证实了 1 : 1 电荷比时的最高复合效率,显示出接近中性的表面电荷。溶菌酶的亲脂性成功得到了提高,SDS 和 DOSS 的正辛醇/PBS 对数值分别达到了 2.5 和 1.8。评估溶菌酶细胞壁裂解情况的生物活性测定显示,溶菌酶与 SDS 复配后,其催化能力最多可提高 2 倍,而复配比例却小于化学计量比,这表明溶菌酶具有有利的稳定机制。利用傅立叶变换红外光谱进行的二级结构分析表明,溶菌酶在与低浓度 SDS 复配时经历了部分解折过程。分子动力学模拟进一步证实,在这些低浓度条件下,活性位点残基 Glu 35 的溶剂暴露程度较高,从而获得了正构象。综合来看,这表明亚计量 SDS 通过增加骨架的灵活性改变了活性位点的二级结构,从而提高了底物的可及性。就 DOSS 而言,低浓度表面活性剂保留了溶菌酶的原生功能和结构,同时仍增加了蛋白质的亲脂性。我们的研究结果表明,蛋白质活性的调节与表面活性剂的化学性质有关,受控的离子配对可以重新设计溶菌酶的溶解性、活性和结构。这对高级蛋白质在医疗保健领域的应用,尤其是口服生物治疗剂配方策略的开发具有重要意义。
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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来源期刊
Materials Advances
Materials Advances MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
7.60
自引率
2.00%
发文量
665
审稿时长
5 weeks
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