A Novel Hyperthermostable Recombinant Protein Nanocage

Q2 Biochemistry, Genetics and Molecular Biology

Iranian Biomedical Journal Pub Date : 2022-11-01 DOI:10.52547/ibj.3839

Yaghoub Ahmadyousefi, Massoud Saidijam, Bagher Amirheidari, Fatehmeh Rahbarizadeh, Meysam Soleimani

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Abstract

Background: Background: Ferritin has an important role in iron storage in the cells, and due to its nanocage structure and self-assembly properties, it has wide application prospects in nanobiotechnology.

Methods: Methods: The maize (Zea mays) ferritin gene ZmFer1 was cloned and expressed in Escherichia coli BL21 (DE3) for the first time. Change in macromolecular structure of ZmFer1 ferritin due to heat treatment was investigated using native PAGE electrophoresis, dynamic light scattering (DLS), and transmission electron microscopy (TEM). Change in the secondary structures of the protein was evaluated using circular dichroism spectroscopy. Moreover, alteration in the conformation of the protein was evaluated using UV-absorption spectra and intrinsic fluorescence spectra. The melting temperature (Tm) of ZmFer1 was obtained using differential scanning calorimetry (DSC). Finally, the effect of heat on the function of ZmFer1 was assessed by iron loading ability.

Results: Results: The purified ZmFer1 protein showed a homopolymer nanocage structure. The results of native PAGE electrophoresis, DLS, and TEM techniques showed that ZmFer1 protein nanocage is stable to heat treatment up to 90 °C, and some of the protein nanocages retain their macromolecular structures even at 100 °C in liquid aqueous solution. Based on the DSC results, ZmFer1 protein nanocage had a Tm of 81.9 °C. After treatment at 100 °C, stable ZmFer1 protein nanocages were able to store iron atoms.

Conclusion: Conclusion: Recombinant ZmFer1 ferritin with a Tm > 80°C is a hyperthermostable protein nanocage. The results of this study are beneficial for the development of protein nanocages that are stable under extreme temperature conditions, as well as application of ZmFer1 in nanobiotechnology, biomaterials, and biomedical fields.

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一种新型超热稳定重组蛋白纳米笼

背景:铁蛋白在细胞内的铁储存中起着重要作用，由于其纳米笼结构和自组装特性，在纳米生物技术中具有广泛的应用前景。方法:方法:首次克隆玉米(Zea mays)铁蛋白基因ZmFer1，并在大肠杆菌BL21 (DE3)中表达。采用原生PAGE电泳、动态光散射(DLS)和透射电镜(TEM)研究热处理后ZmFer1铁蛋白大分子结构的变化。利用圆二色光谱法对蛋白质二级结构的变化进行了评价。此外，利用紫外吸收光谱和本征荧光光谱对蛋白质构象的改变进行了评价。采用差示扫描量热法(DSC)测定了ZmFer1的熔化温度(Tm)。最后，通过载铁能力评价热对ZmFer1功能的影响。结果:纯化后的ZmFer1蛋白呈均聚纳米笼结构。原生PAGE电泳、DLS和TEM技术的结果表明，ZmFer1蛋白纳米笼在90°C的高温下仍保持稳定，部分蛋白纳米笼在100°C的水溶液中仍保持其大分子结构。DSC结果显示，ZmFer1蛋白纳米笼的温度为81.9°C。经过100°C处理后，稳定的ZmFer1蛋白纳米笼能够储存铁原子。结论:Tm > 80°C的重组ZmFer1铁蛋白是一种超耐热蛋白纳米笼。本研究结果有利于开发在极端温度条件下稳定的蛋白质纳米笼，以及ZmFer1在纳米生物技术、生物材料和生物医学领域的应用。

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