Abstract

With the ability to exponentially amplify regions of DNA, two different PCR-based strategies have been developed for nonculture diagnosis of bacteremia. The first approach targets the species-specific genes for amplification (1), whereas the second approach involves universal PCR amplification of conserved bacterial DNA sequences, such as the 16S rRNA, the 23S rRNA, and the 16S-23S rRNA interspace regions (2)(3)(4). Although universal PCR is not able to distinguish bacteria to the species level, numerous studies have shown that this method provides valuable information complementary to the results of time-consuming and subjective phenotypic tests used in detection of bacterial infection (5) and can be used to differentiate bacterial from viral or other infections (6)(7). In clinical applications, real-time PCR for broad-range amplification of bacterial DNA sequences could offer additional benefits: it is less labor-intensive, less time-consuming, and reduces the risk of PCR carryover contamination. A major obstacle for broad-range PCR amplification is the presence of bacterial DNA in the Taq DNA polymerase and real-time PCR master mixture (8)(9)(10). The contaminating DNA is effectively amplified, giving rise to false-positive results. Efforts have been taken to eliminate contaminating DNA, including the use of Sau 3AI restriction endonuclease (11), DNase I (12)(13), and ultraviolet irradiation (7)(8). Although these strategies may be effective for conventional PCR, the study by Corless et al. (14) indicated that the contamination issue could not be avoided without affecting sensitivity when TaqMan probe-based real-time PCR is performed. Therefore, an appropriate method for removal of contaminating bacterial DNA and subsequent real-time amplification is required. In this study, we address this issue and report optimized conditions for broad-range amplification of the bacterial 16S rRNA gene by real-time PCR using SYBR Green I dye (15) as the fluorescent signal. Bacterial …

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