PCR is effective in detecting bacterial DNA in samples, but it is unable to differentiate viable bacteria from inactivated cells or free DNA fragments. New PCR-based analytical strategies have been developed to address this limitation. Molecular viability testing (MVT) correlates bacterial viability with the ability to rapidly synthesize species-specific rRNA precursors (pre-rRNA) in response to brief nutritional stimulation. Previous studies demonstrated that MVT can assess bacterial inactivation by chlorine, serum, and low-temperature pasteurization. Here, we demonstrate that MVT can detect inactivation of Escherichia coli, Aeromonas hydrophila, and Enterococcus faecalis cells by UV irradiation. Some UV-inactivated E. coli cells transiently retained the ability to synthesize pre-rRNA postirradiation (generating false-positive MVT results), but this activity ceased within 1 h following UV exposure. Viable but transiently undetectable (by culture) E. coli cells were consistently detected by MVT. An alternative viability testing method, viability PCR (vPCR), correlates viability with cell envelope integrity. This method did not distinguish viable bacteria from UVinactivated bacteria under some conditions, indicating that the inactivated cells retained intact cell envelopes. MVT holds promise as a means to rapidly assess microbial inactivation by UV treatment.IMPORTANCE UV irradiation is increasingly being used to disinfect water, food, and other materials for human use. Confirming the effectiveness of UV disinfection remains a challenging task. In particular, microbiological methods that rely on rapid detection of microbial DNA can yield misleading results, due to the detection of remnant DNA associated with dead microbial cells. This report describes a novel method that rapidly distinguishes living microbial cells from dead microbial cells after UV disinfection. KEYWORDS molecular viability testing (MVT), disinfection, viability PCR (vPCR), propidium monoazide (PMA), drinking water, viable but nonculturable (VBNC), ratiometric pre-rRNA analysis, UV irradiation, bacterial inactivation A ssessing the viability of microbial cells (defined as the capacity to form progeny) in samples is critically important but challenging for microbiologists (1, 2). Microbiological cultures require viability but underestimate microbial diversity because only a fraction of species can be cultured (3). Furthermore, culturing can be time-consuming (1 to 30 days, depending on species). PCR is a fast, sensitive, and specific alternative to culturing methods. However, traditional PCR cannot distinguish viable cells from nonviable cells or from free nucleic acids in the samples.Viability PCR (vPCR) is a PCR-based strategy that selectively detects viable microbial cells. In vPCR, a membrane-impermeant DNA-binding compound, propidium monoazide (PMA), selectively associates with free DNA and DNA in cells with compromised cell membranes. Upon photoactivation, PMA covalently binds DNA and prevents amplification by PCR (4). Viable cells...
