壳聚糖反离子影响基于壳聚糖的 siRNA 载体与 siRNA 缔合的热力学。

Counterion of Chitosan Influences Thermodynamics of Association of siRNA with a Chitosan-Based siRNA Carrier.

机构信息

Institut Galien Paris-Sud, CNRS UMR 8612, Univ Paris-Sud, Faculté de Pharmacie, 5 rue J.B. Clément, 92296, Châtenay-Malabry Cedex, France.

出版信息

Pharm Res. 2020 Jan 2;37(2):22. doi: 10.1007/s11095-019-2751-z.

DOI:10.1007/s11095-019-2751-z

PMID:31897766

Abstract

PURPOSE

The work aimed to compare quality of a siRNA carrier prepared with chitosan of two different sources having similar degree of deacetylation and molecular weights. Differences were analyzed from thermodynamic characteristics of interactions with siRNA.

METHODS

The siRNA carrier (chitosan-coated poly(isobutylcyanoacrylate) nanoparticles) was prepared with home-prepared, CS, and commercial, CS, chitosans. Chitosan counterion was identified and chitosans CSmod1 and CSmod2 were obtained from CS exchanging counterion with that found on CS. Carrier quality was checked considering the size, zeta potential and siRNA association capacity by gel electrophoresis. Thermodynamic parameters of interactions between siRNA and chitosans in solution or immobilized at the carrier surface were determined by isothermal titration calorimetry (ITC).

RESULTS

CS and CSmod2 having a high content of acetate counterion associated better siRNA than CS and CSmod1 which counterion included mainly chloride. ITC measurements indicated that siRNA interactions with chitosan and the siRNA carrier were driven by entropic phenomena including dehydration, but thermodynamic parameters of interactions clearly differed according to the nature of the counterion of chitosan. The influence of chitosan counterions was interpreted considering their different lyotropic character.

CONCLUSION

Association of siRNA with our siRNA carrier was influenced by the nature of counterions associated with chitosan. Driven by entropic phenomena including dehydration, interactions were favored by acetate counterion. Although more work would be needed to decipher the influence of the counterion of chitosan during association with siRNA, it was pointed out as a new critical attribute of chitosan to consider while formulating siRNA carrier with this polysaccharide.

摘要

目的

本工作旨在比较两种脱乙酰度和分子量相似的壳聚糖制备的 siRNA 载体的质量。从与 siRNA 相互作用的热力学特性分析差异。

方法

采用自制 CS、商品 CS 壳聚糖制备 siRNA 载体（壳聚糖包覆聚异丁基氰基丙烯酸酯纳米粒）。通过用与 CS 上发现的相反电荷交换 CS 的反离子，鉴定壳聚糖反离子，并获得 CSmod1 和 CSmod2 壳聚糖。通过凝胶电泳检查载体的大小、zeta 电位和 siRNA 结合能力，检查载体质量。通过等温滴定微量热法（ITC）确定溶液中 siRNA 与壳聚糖之间以及固定在载体表面的 siRNA 与壳聚糖之间相互作用的热力学参数。

结果

带高含量醋酸盐反离子的 CS 和 CSmod2 比带主要含氯的 CS 和 CSmod1 更好地结合 siRNA。ITC 测量表明，siRNA 与壳聚糖和 siRNA 载体的相互作用是由包括脱水在内的熵驱动的，但根据壳聚糖反离子的性质，相互作用的热力学参数明显不同。根据壳聚糖反离子的不同溶致特性解释了壳聚糖反离子的影响。

结论

siRNA 与我们的 siRNA 载体的结合受与壳聚糖结合的反离子的性质影响。包括脱水在内的熵驱动的相互作用有利于醋酸盐反离子。尽管需要进一步研究以阐明壳聚糖反离子在与 siRNA 结合过程中的影响，但指出这是在使用该多糖制备 siRNA 载体时需要考虑的壳聚糖的一个新的关键属性。

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壳聚糖反离子影响基于壳聚糖的 siRNA 载体与 siRNA 缔合的热力学。

Counterion of Chitosan Influences Thermodynamics of Association of siRNA with a Chitosan-Based siRNA Carrier.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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