Chen Ying-Ja, Huang Xiaohua
Department of Bioengineering, University of California, San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0412, USA.
Anal Biochem. 2009 Jan 1;384(1):170-9. doi: 10.1016/j.ab.2008.09.048. Epub 2008 Oct 7.
We describe a new DNA sequencing method called sequencing by denaturation (SBD). A Sanger dideoxy sequencing reaction is performed on the templates on a solid surface to generate a ladder of DNA fragments randomly terminated by fluorescently labeled dideoxyribonucleotides. The labeled DNA fragments are sequentially denatured from the templates and the process is monitored by measuring the change in fluorescence intensities from the surface. By analyzing the denaturation profiles, the base sequence of the template can be determined. Using thermodynamic principles, we simulated the denaturation profiles of a series of oligonucleotides ranging from 12 to 32 bases and developed a base-calling algorithm to decode the sequences. These simulations demonstrate that DNA molecules up to 20 bases can be sequenced by SBD. Experimental measurements of the melting profiles of DNA fragments in solution confirm that DNA sequences can be determined by SBD. The potential limitations and advantages of SBD are discussed. With SBD, millions of sequencing reactions can be performed on a small area on a surface in parallel with a very small amount of sequencing reagents. Therefore, DNA sequencing by SBD could potentially result in a significant increase in speed and reduction in cost in large-scale genome resequencing.
我们描述了一种名为变性测序(SBD)的新DNA测序方法。在固体表面的模板上进行桑格双脱氧测序反应,以生成由荧光标记的双脱氧核糖核苷酸随机终止的DNA片段阶梯。标记的DNA片段依次从模板上变性,通过测量表面荧光强度的变化来监测该过程。通过分析变性图谱,可以确定模板的碱基序列。利用热力学原理,我们模拟了一系列长度从12到32个碱基的寡核苷酸的变性图谱,并开发了一种碱基识别算法来解码序列。这些模拟表明,长度达20个碱基的DNA分子可以通过SBD进行测序。对溶液中DNA片段解链图谱的实验测量证实,DNA序列可以通过SBD确定。讨论了SBD的潜在局限性和优点。使用SBD,可以在表面的小面积上并行进行数百万次测序反应,且所需测序试剂极少。因此,通过SBD进行DNA测序可能会显著提高大规模基因组重测序的速度并降低成本。