Covalent affixation of histidine-tagged proteins tethered onto Ni-nitrilotriacetic acid sensors for enhanced surface plasmon resonance detection of small molecule drugs and kinetic studies of antibody/antigen interactions
Analyst Pub Date: 2018-10-23 DOI: 10.1039/C8AN01794H
Abstract
The Ni2+-histidine (His) chelation yields a more uniform and predicable orientation of immobilized protein molecules than an amine-coupling reaction in surface plasmon resonance (SPR) analyses. However, the gradual dissociation of His-tagged proteins leads to a long and sloped baseline, which adversely affects kinetic studies. Furthermore, as shown in this work for the first time, the strong binding affinity between the histidine-rich Fc domain of immunoglobulin-type antibodies and Ni-nitrilotriacetic acid (NTA) interferes with the kinetic studies of these antibodies and their His-tagged antigens. By performing an amine-coupling reaction immediately after the Ni2+-His chelation, essentially all of the Ni2+-tethered protein molecules can be covalently linked to the carboxyl groups on the underlying carboxymethylated dextran surface. The sequential injections of pH 8.6 phosphate-buffered saline provided additional time to ensure a higher amine coupling efficiency and reverted NHS esters on the protein molecules to carboxyl groups. The application of our method to antibody/antigen interactions is demonstrated with the kinetic analysis of His-tagged t-DARPP protein/anti-t-DARPP interactions. In a separate experiment, the highly efficient immobilization method resulted in a higher immobilization density of His-tagged human carbonic anhydrase (HCA) II, affording accurate kinetic measurements for the binding of 4-carboxybenzenesulfonamide. In addition, the higher HCA II density enhanced the SPR sensitivity, allowing 4-carboxybenzenesulfonamide to be determined with a remarkable detection limit (14 nM).
Recommended Literature
- [1] An artificial enzyme cascade amplification strategy for highly sensitive and specific detection of breast cancer-derived exosomes? Huiying Xu,Lu Zheng,Yu Zhou,Bang-Ce YeAnalyst, 2021,146, 5542-5549 10.1039/D1AN01071A
- [2] An amino group functionalized metal–organic framework as a luminescent probe for highly selective sensing of Fe3+ ions? Zhonghua Xiang,Chuanqi Fang,Sanhua Leng,Dapeng CaoJ. Mater. Chem. A, 2014,2, 7662-7665 10.1039/C4TA00313F
- [3] An approach to the structure and vibrational analysis of cis- and trans-3-chlorostyrene through IR/Raman and INS spectroscopies and theoretical ab initio/DFT calculations? J. M. Granadino-Roldán,M. Fernández-Gómez,A. Navarro,T. Pe?a Ruiz,U. A. JayasooriyaPhys. Chem. Chem. Phys., 2004,6, 1133-1143 10.1039/B314243D
- [4] An integrated system for field analysis of Cd(ii) and Pb(ii) via preconcentration using nano-TiO2/cellulose paper composite and subsequent detection with a portable X-ray fluorescence spectrometer? Xiaofeng LinRSC Adv., 2016,6, 9002-9006 10.1039/C5RA25693C
- [5] An all-solid-state asymmetric device based on a polyaniline hydrogel for a high energy flexible supercapacitor? Hamid Heydari,Mohammad B. GholivandNew J. Chem., 2017,41, 237-244 10.1039/C6NJ02266A
- [6] Aluminium alkyl and aryloxide complexes of pyrazine and bipyridines: synthesis and structure? Doug Ogrin,Laura H. van Poppel,Simon G. Bott,Andrew R. BarronDalton Trans., 2004, 3689-3694 10.1039/B410662H
- [7] An amorphous lanthanum–iridium solid solution with an open structure for efficient water splitting? Wei Sun,Chenglong Ma,Xinlong Tian,Jianjun Liao,Ji Yang,Chengjun Ge,Weiwei HuangJ. Mater. Chem. A, 2020,8, 12518-12525 10.1039/D0TA03351K
- [8] An anti-ultrasonic-stripping effect in confined micro/nanoscale cavities and its applications for efficient multiscale metallic patterning? Quan Xiang,Yiqin Chen,Zhiqin Li,Kaixi Bi,Guanhua Zhang,Huigao DuanNanoscale, 2016,8, 19541-19550 10.1039/C6NR07585A
- [9] An Assessment of the Laminar Hypersonic Double-Cone Experiments in the LENS-XX Tunnel JaideepRay,PatrickBlonigan,EricT.Phipps,KathrynMaupin 10.2514/1.j062802
- [10] Alumina coating on 5 V lithium cobalt fluorophosphate cathode material for lithium secondary batteries – synthesis and electrochemical properties? S. Amaresh,K. Karthikeyan,K. J. Kim,Y. S. LeeRSC Adv., 2014,4, 23107-23115 10.1039/C4RA02318H
Journal Name:Analyst
research_products
-
CAS no.: 89640-58-4
![1,2,3,4,5,6-Hexahydro-[2,3]bipyridinyl-6-ol](https://ossimg.kuujia.com/scimg/1271000/1270529-38-8x500.png)
![N-(3-cyanothiolan-3-yl)-2-[(2,2,2-trifluoroethyl)sulfanyl]pyridine-4-carboxamide](https://ossimg.kuujia.com/scimg/1444500/1444113-98-7x500.png)
![2,2-Difluoro-3-[methyl(2-methylbutyl)amino]propanoic acid](https://ossimg.kuujia.com/scimg/2138500/2138166-62-6x500.png)
![2-(1H-indol-3-yl)-N-{[6-(thiophen-2-yl)-[1,2,4]triazolo[4,3-b]pyridazin-3-yl]methyl}acetamide](https://ossimg.kuujia.com/scimg/2034500/2034271-14-0x500.png)