Ma Yaohong, Xue Yunlong, Wang Xingbao, Shao Yue, Huang Xiaozhen, Zhang Zhenyu, Zhu Sirong, Gong Weili
Shandong Provincial Key Laboratory of Biosensors, Biology Institute, Qilu University of Technology (Shandong Academy of Sciences), No. 28789, Jingshi East Road, Licheng District, Jinan, 250103, Shandong, China.
Appl Biochem Biotechnol. 2025 Mar;197(3):1590-1609. doi: 10.1007/s12010-024-05087-y. Epub 2024 Nov 26.
The development of an efficient lactose biosensor employing cellobiose dehydrogenases (CDHs) for monitoring and precise control of the lactose levels in dairy-based products is extremely important for the health of lactose-intolerant population. In this study, the mesophilic (Nc_CDH) and thermophilic (Ct_CDH-A, Ct_CDH-B) CDHs were successfully obtained by heterologous expression and treated with α-1,2-mannosidase and endoglycosidase H to prepare the deglycosylated forms (Nc_dCDH, Ct_dCDH-A, and Ct_dCDH-B); then, the effects of deglycosylation on the catalytic activity in solution and electrochemical performance on electrodes for lactose detection were systematically investigated. In solution, Nc_dCDH was more stable and had a higher V value and lower K value than Nc_CDH at different temperatures and pH values. In contrast, deglycosylation had adverse effects on the stability of Ct_CDH-A and Ct_CDH-B. When the CDHs mixed with multi-walled carbon nanotubes were dropped and immobilized on electrodes, with regard to Nc_CDH, in the presence of the same concentration of lactose, the detection current of the electrode modified with Nc_dCDH was higher than that of the electrode modified with Nc_CDH, and it had a lower detection limit (2.006 mM) and higher sensitivity (39.37 μA.mmol.L.cm). However, with respect to the thermophilic CDHs, the sensitivity was lowered and the detection limit was increased after deglycosylation. The discrepancy may result from two reasons: N-glycosylation may play a more crucial role in thermostability and structural stability of thermophilic CDHs, and the distribution sites of glycosylated residues may affect the electron transfer kinetics. This study is a step toward using CDH as an electron transfer-based lactose biosensor.
开发一种利用纤维二糖脱氢酶(CDHs)的高效乳糖生物传感器,用于监测和精确控制乳制品中的乳糖水平,对乳糖不耐受人群的健康极为重要。在本研究中,通过异源表达成功获得了嗜温(Nc_CDH)和嗜热(Ct_CDH-A、Ct_CDH-B)CDHs,并用α-1,2-甘露糖苷酶和内切糖苷酶H处理以制备去糖基化形式(Nc_dCDH、Ct_dCDH-A和Ct_dCDH-B);然后,系统研究了去糖基化对溶液中催化活性以及用于乳糖检测的电极上电化学性能的影响。在溶液中,在不同温度和pH值下,Nc_dCDH比Nc_CDH更稳定,具有更高的V值和更低的K值。相比之下,去糖基化对Ct_CDH-A和Ct_CDH-B的稳定性有不利影响。当将与多壁碳纳米管混合的CDHs滴涂并固定在电极上时,对于Nc_CDH,在相同浓度的乳糖存在下,用Nc_dCDH修饰的电极的检测电流高于用Nc_CDH修饰的电极,并且其检测限更低(2.006 mM),灵敏度更高(39.37 μA·mmol⁻¹·L⁻¹·cm⁻²)。然而,对于嗜热CDHs,去糖基化后灵敏度降低,检测限增加。这种差异可能源于两个原因:N-糖基化可能在嗜热CDHs的热稳定性和结构稳定性中起更关键的作用,并且糖基化残基的分布位点可能影响电子转移动力学。本研究朝着将CDH用作基于电子转移的乳糖生物传感器迈出了一步。
