Optimal DNA Isolation Method for Detection of Bacteria in Clinical Specimens by Broad-Range PCR

Abstract

Broad-range amplification of bacterial DNA from clinical specimens has proved useful for the diagnosis of various bacterial infections, especially during antimicrobial treatment of the patient. Optimal sample processing protocols for diagnostic broad-range bacterial PCR should release DNA from an array of target organisms with equal efficiencies and wash out inhibitory factors from various sample types without introducing bacterial DNA contamination to the amplification reaction. In the present study, two physical cell wall disintegration methods, bead beating and sonication, for enhanced detection of organisms with difficult-to-lyse cell walls were studied. The analytical sensitivities of several commercially available DNA purification kits, which were used with and without additional cell disintegration steps, were compared by using dilution series of model bacteria. Selected purification methods were used to process routine clinical specimens in parallel with the standard phenol-ether DNA extraction, and the results obtained by bacterial PCR and sequencing with the two template preparations were compared. The method with the DNA isolation kit with the lowest detection limits from the bacterial suspensions (Masterpure) did not prove to be superior to the standard method when the two methods were applied to 69 clinical specimens. For another set of 68 clinical specimens, DNA purified with a glass fiber filter column (High Pure) with an additional sonication step yielded results well in accord with those obtained by the standard method. Furthermore, bacterial DNA was detected in four samples that remained PCR negative by the standard method, and three of these contained DNA from gram-positive pathogens. Three samples were positive by the standard method only, indicating the limitations of applying any single method to all samples.