Soni Gautam V, Meller Amit
Department of Biomedical Engineering, Boston University, Boston, MA 02215, USA.
Clin Chem. 2007 Nov;53(11):1996-2001. doi: 10.1373/clinchem.2007.091231. Epub 2007 Sep 21.
Measurements of the ionic current flowing through nanometer-scale pores (nanopores) have been used to analyze single DNA and RNA molecules, with the ultimate goal of achieving ultrafast DNA sequencing. However, attempts at purely electronic measurements have not achieved the signal contrast required for single nucleotide differentiation. In this report we propose a novel method of optical detection of DNA sequence translocating through a nanopore.
Each base of the target DNA sequence is 1st mapped onto a 2-unit code, 2 10-bp nucleotide sequence, by biochemical conversion into Designed DNA Polymers. These 2-unit codes are then hybridized to complementary, fluorescently labeled, and self-quenching molecular beacons. As the molecular beacons are sequentially unzipped during translocation through a <2-nm-wide nanopore, their fluorescent tags are unquenched and are detected by a custom-built dual-color total internal reflection fluorescence (TIRF) microscope. The 2-color optical signal is then correlated to the target DNA sequence.
A dual-color TIRFM microscope with single-molecule resolution was constructed, and controlled fabrication of 1-dimensional and 2-dimensional arrays of solid-state nanopores was performed. A nanofluidic cell assembly was constructed for TIRF-based optical detection of voltage-driven DNA translocation through a nanopore.
We present a novel nanopore-based DNA sequencing technique that uses an optical readout of DNA translocating unzipping through a nanopore. Our technique offers better single nucleotide differentiation in sequence readout, as well as the possibility of large-scale parallelism using nanopore arrays.
测量流经纳米级孔隙(纳米孔)的离子电流已被用于分析单个DNA和RNA分子,其最终目标是实现超快速DNA测序。然而,单纯的电子测量尝试尚未达到单核苷酸区分所需的信号对比度。在本报告中,我们提出了一种通过纳米孔对DNA序列进行光学检测的新方法。
通过生化转化为设计好的DNA聚合物,将目标DNA序列的每个碱基首先映射到一个2单元编码,即一个10碱基对的核苷酸序列。然后将这些2单元编码与互补的、荧光标记的、自猝灭的分子信标杂交。当分子信标在通过一个宽度小于2纳米的纳米孔时依次解链,它们的荧光标签被解除猝灭,并由一台定制的双色全内反射荧光(TIRF)显微镜进行检测。然后将双色光学信号与目标DNA序列相关联。
构建了具有单分子分辨率的双色TIRFM显微镜,并进行了固态纳米孔一维和二维阵列的可控制造。构建了一个纳米流体池组件,用于基于TIRF的光学检测电压驱动的DNA通过纳米孔的转运。
我们提出了一种基于纳米孔的新型DNA测序技术,该技术利用光学读出通过纳米孔解链转运的DNA。我们的技术在序列读出中提供了更好的单核苷酸区分能力,以及使用纳米孔阵列进行大规模并行操作的可能性。
