Zhou Wenhu, Vazin Mahsa, Yu Tianmeng, Ding Jinsong, Liu Juewen
School of Pharmaceutical Sciences, Central South University, Changsha, Hunan, 410013, P.R. China.
Department of Chemistry, Waterloo Institute for Nanotechnology, University of Waterloo, Waterloo, Ontario, N2L 3G1, Canada.
Chemistry. 2016 Jul 4;22(28):9835-40. doi: 10.1002/chem.201601426. Epub 2016 Jun 1.
Chromium is a very important analyte for environmental monitoring, and developing biosensors for chromium is a long-standing analytical challenge. In this work, in vitro selection of RNA-cleaving DNAzymes was carried out in the presence of Cr(3+) . The most active DNAzyme turned out to be the previously reported lanthanide-dependent Ce13d DNAzyme. Although the Ce13d activity was about 150-fold lower with Cr(3+) than that with lanthanides, the activity of lanthanides and other competing metals was masked by using a phosphate buffer; this left Cr(3+) as the only metal that could activate Ce13d. With 100 μm Cr(3+) , the cleavage rate is 1.6 h(-1) at pH 6. By using a molecular beacon design, Cr(3+) was measured with a detection limit of 70 nm, which was significantly lower than the United States Environmental Protection Agency (EPA) limit (11 μm). Cr(4+) was measured after reduction by NaBH4 to Cr(3+) , and it could be sensed with a similar detection limit of 140 nm Cr(4+) ; this value was lower than the EPA limit of 300 nm. This sensor was tested for chromium speciation analysis in a real sample, and the results supported its application for environmental monitoring. At the same time, it has enhanced our understanding of the interactions between chromium and DNA.
铬是环境监测中一种非常重要的分析物,开发用于检测铬的生物传感器一直是一项长期的分析挑战。在这项工作中,在Cr(3+)存在的情况下进行了切割RNA的脱氧核酶的体外筛选。结果发现最具活性的脱氧核酶是先前报道的依赖镧系元素的Ce13d脱氧核酶。尽管Ce13d对Cr(3+)的活性比对镧系元素的活性低约150倍,但通过使用磷酸盐缓冲液,镧系元素和其他竞争性金属的活性被掩盖了;这使得Cr(3+)成为唯一能够激活Ce13d的金属。在含有100μm Cr(3+)的情况下,在pH 6时切割速率为1.6 h(-1)。通过使用分子信标设计,对Cr(3+)的检测限为70nm,这明显低于美国环境保护局(EPA)的限值(11μm)。Cr(4+)在被NaBH4还原为Cr(3+)后进行检测,其检测限为140nm Cr(4+),与Cr(3+)的检测限相似;该值低于EPA的300nm限值。该传感器在实际样品中进行了铬形态分析测试,结果支持其在环境监测中的应用。同时,它增强了我们对铬与DNA之间相互作用的理解。