Cupples Alison M, Shaffer Elizabeth A, Chee-Sanford Joanne C, Sims Gerald K
United States Department of Agriculture-Agricultural Research Service, University of Illinois at Urbana-Champaign, S-306 Turner Hall, 1102 S. Goodwin Ave., Urbana, IL 61801, USA.
Microbiol Res. 2007;162(4):328-34. doi: 10.1016/j.micres.2006.01.016. Epub 2006 Mar 24.
DNA-based stable isotope probing (SIP) is a novel technique for the identification of organisms actively assimilating isotopically labeled compounds. Herein, we define the limitations to using 15N-labeled substrates for SIP and propose modifications to compensate for these shortcomings. Changes in DNA buoyant density (BD) resulting from 15N incorporation were determined using cultures of disparate GC content (Escherichia coli and Micrococcus luteus). Incorporation of 15N into DNA increased BD by 0.015+/-0.002 g mL(-1) for E. coli and 0.013+/-0.002 g mL(-1) for M. luteus. The DNA BD shift was greatly increased (0.045 g mL(-1)) when dual isotope (13C plus 15N) labeling was employed. Despite the limited DNA BD shift following 15N enrichment, we found the use of gradient fractionation, followed by a comparison of T-RFLP profiles from fractions of labeled and control treatments, facilitated detection of enrichment in DNA samples from either cultures or soil.
基于DNA的稳定同位素探测(SIP)是一种用于鉴定积极同化同位素标记化合物的生物体的新技术。在此,我们定义了使用15N标记底物进行SIP的局限性,并提出了弥补这些缺点的改进方法。使用不同GC含量的培养物(大肠杆菌和藤黄微球菌)确定了15N掺入导致的DNA浮力密度(BD)变化。15N掺入DNA使大肠杆菌的BD增加0.015±0.002 g mL(-1),使藤黄微球菌的BD增加0.013±0.002 g mL(-1)。当采用双同位素(13C加15N)标记时,DNA BD偏移大大增加(0.045 g mL(-1))。尽管15N富集后DNA BD偏移有限,但我们发现使用梯度分级分离,然后比较标记处理和对照处理组分的T-RFLP图谱,有助于检测来自培养物或土壤的DNA样品中的富集情况。
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