Affinity purification of DNA and RNA from environmental samples with peptide nucleic acid clamps.

Bispeptide nucleic acids (bis-PNAs; PNA clamps), PNA oligomers, and DNA oligonucleotides were evaluated as affinity purification reagents for subfemtomolar 16S ribosomal DNA (rDNA) and rRNA targets in soil, sediment, and industrial air filter nucleic acid extracts. Under low-salt hybridization conditions (10 mM NaPO(4), 5 mM disodium EDTA, and 0.025% sodium dodecyl sulfate [SDS]) a PNA clamp recovered significantly more target DNA than either PNA or DNA oligomers. The efficacy of PNA clamps and oligomers was generally enhanced in the presence of excess nontarget DNA and in a low-salt extraction-hybridization buffer. Under high-salt conditions (200 mM NaPO(4), 100 mM disodium EDTA, and 0.5% SDS), however, capture efficiencies with the DNA oligomer were significantly greater than with the PNA clamp and PNA oligomer. Recovery and detection efficiencies for target DNA concentrations of > or =100 pg were generally >20% but depended upon the specific probe, solution background, and salt condition. The DNA probe had a lower absolute detection limit of 100 fg of target (830 zM [1 zM = 10(-21) M]) in high-salt buffer. In the absence of exogenous DNA (e.g., soil background), neither the bis-PNA nor the PNA oligomer achieved the same absolute detection limit even under a more favorable low-salt hybridization condition. In the presence of a soil background, however, both PNA probes provided more sensitive absolute purification and detection (830 zM) than the DNA oligomer. In varied environmental samples, the rank order for capture probe performance in high-salt buffer was DNA > PNA > clamp. Recovery of 16S rRNA from environmental samples mirrored quantitative results for DNA target recovery, with the DNA oligomer generating more positive results than either the bis-PNA or PNA oligomer, but PNA probes provided a greater incidence of detection from environmental samples that also contained a higher concentration of nontarget DNA and RNA. Significant interactions between probe type and environmental sample indicate that the most efficacious capture system depends upon the particular sample type (and background nucleic acid concentration), target (DNA or RNA), and detection objective.

Affinity capture and recovery of DNA at femtomolar concentrations with peptide nucleic acid probes.

The efficacy of PNA vs DNA oligomers for the recovery of femtomolar concentrations of 16S rDNA targets was determined with solution- and mixed-phase hybridization formats and limiting dilution quantitative PCR. Several results contradict existing perceptions of expected PNA behavior deduced from hybridization studies with oligonucleotide targets at high concentration. For example, DNA probes in the solution hybridization format performed as well as or better than PNA probes under high- or low-salt conditions, regardless of hybridization time or target size. In the mixed-phase hybridization format, however, PNA probes showed certain advantages, with more rapid and efficient binding/recovery of target nucleic acids regardless of target size. Recovery of target DNA with PNA probes was always more efficient in low-salt (20 mM in Na(+)) than high-salt (400 mM in Na(+-)) phosphate buffer. Recovery of target DNA by PNA probes was enhanced in the presence of excess, nontarget DNA, and differences in PNA efficacy under low- or high-salt conditions vanquished. In contrast, DNA probe performance was unaffected by the presence or absence of exogenous DNA in both solution- and mixed-phase hybridization formats. The absolute recovery and detection limit of the affinity purification method with either DNA or PNA probes was approximately 10(2) input target molecules at zeptamolar concentrations.

An algorithm for automated bacterial identification using matrix-assisted laser desorption/ionization mass spectrometry.

An algorithm for bacterial identification using matrix-assisted laser desorption/ionization (MALDI) mass spectrometry is being developed. This mass spectral fingerprint comparison algorithm is fully automated and statistically based, providing objective analysis of samples to be identified. Based on extraction of reference fingerprint ions from test spectra, this approach should lend itself well to real-world applications where samples are likely to be impure. This algorithm is illustrated using a blind study. In the study, MALDI-MS fingerprints for Bacillus atrophaeus ATCC 49337, Bacillus cereus ATCC 14579T, Escherichia coli ATCC 33694, Pantoea agglomerans ATCC 33243, and Pseudomonas putida F1 are collected and form a reference library. The identification of test samples containing one or more reference bacteria, potentially mixed with one species not in the library (Shewanella alga BrY), is performed by comparison to the reference library with a calculated degree of association. Out of 60 samples, no false positives are present, and the correct identification rate is 75%. Missed identifications are largely due to a weak B. cereus signal in the bacterial mixtures. Potential modifications to the algorithm are presented and result in a higher than 90% correct identification rate for the blind study data, suggesting that this approach has the potential for reliable and accurate automated data analysis of MALDI-MS.