Use of the tna operon as a new molecular target for Escherichia coli detection

Activity- and gene-based quantification of enteric viruses, F- specific RNA phage genogroups, pepper mild mottle virus, and Escherichia coli in surface water

Polymerase chain reaction (PCR) is widely applied for the monitoring of pathogenic viruses in water environments. To date, several pretreatments to selectively detect genes from infectious viruses via PCR have been developed. This study was aimed to characterize and validate methods for quantifying active viruses and indicators and to evaluate the proportion of their active fractions in surface water (n = 42). Active E. coli and F-specific RNA phage (FRNAPH) genogroups were quantified using culture assays. In addition to these microbes, norovirus genogroups I (GI) and II, Aichi virus 1, and pepper mild mottle virus (PMMoV) were quantified by (reverse transcription)-quantitative PCR (RT-qPCR) with and without cis-dichlorodiammineplatinum (CDDP) treatment to exclude genes in inactive viruses. CDDP-RT-qPCR showed concentrations and detection frequencies comparable to or higher than culture assays. Consequently, although CDDP-RT-qPCR can suggest the presence of an inactive virus, it can also overestimate the activity of the virus in the environment. Differences between culture and CDDP-RT-qPCR and between CDDP-RT-qPCR and RT-qPCR varied among the viruses. CDDP-RT-qPCR showed a concentration comparable to the culture assay (within 1 log10 difference) in 93 % of positive samples for GI-FRNAPH but in <63 % of positive samples for GII- and GIII-FRNAPHs. GII-NoV was detected from 5 and 30 out of 42 samples via CDDP-RT-qPCR and RT-qPCR, respectively, and was suggested as inactivated by 2.0 log10 or higher in most of the samples. By contrast, concentrations of PMMoV determined by these two assays were not notably different. It is suggested that the operational conditions of wastewater treatment plants around the sites, rather than environmental stresses, affected the microbial inactivation. To better understand the infectivity of viruses in the environment, it is important to investigate them using sensitive detection methods at various sites, including the source of contamination.

Theoretical assessment data for the binding of sepsis causing pathogens to ApoH beads

The data presented in this paper supports the research article “A rapid, highly sensitive and culture-free detection of pathogens from blood by positive enrichment” ( Vutukuru et al., 2016) [1]. We compared a list of sepsis causing pathogens to the ApoH binding data given to us by ApoH technologies. The data highlights the binding of ApoH beads to sepsis causing pathogens.

Comparison of quantitative PCR assays for Escherichia coli targeting ribosomal RNA and single copy genes

AIMS

Compare specificity and sensitivity of quantitative PCR (qPCR) assays targeting single and multi-copy gene regions of Escherichia coli.

METHODS AND RESULTS

A previously reported assay targeting the uidA gene (uidA405) was used as the basis for comparing the taxonomic specificity and sensitivity of qPCR assays targeting the rodA gene (rodA984) and two regions of the multi-copy 23S ribosomal RNA gene (EC23S and EC23S857). Experimental analyses of 28 culture collection strains representing E. coli and 21 related non-target species indicated that the uidA405 and rodA984 assays were both 100% specific for E. coli while the EC23S assay was only 29% specific. The EC23S857 assay was only 95% specific due to detection of E. fergusonii. The uidA405, rodA984, EC23S and EC23S857 assays were 85%, 85%, 100% and 86% sensitive, respectively, in detecting 175 presumptive E. coli culture isolates from fresh, marine and waste water samples. In analyses of DNA extracts from 32 fresh, marine and waste water samples, the rodA984, EC23S and EC23S857 assays detected mean densities of target sequences at ratios of approximately 1:1, 243:1 and 6:1 compared with the mean densities detected by the uidA405 assay.

CONCLUSIONS

The EC23S assay was less specific for E. coli, whereas the rodA984 and EC23S857 assay taxonomic specificities and sensitivities were similar to those of the uidA405 gene assay.

SIGNIFICANCE AND IMPACT

The EC23S857 assay has a lower limit of detection for E. coli cells than the uidA405 and rodA984 assays due to its multi-copy gene target and therefore provides greater analytical sensitivity in monitoring for these faecal pollution indicators in environmental waters by qPCR methods.