Recent developments in the use of viability dyes and quantitative PCR in the food microbiology field

Elizaquível, Patricia; Aznar, Rosa; Sánchez, Glòria

doi:10.1111/jam.12365

Cited by 150 publications

(113 citation statements)

References 93 publications

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“…This highlights the importance of implementing new methodologies to assess infectivity in food samples. So far, viability PCR has successfully been applied for bacterial detection in several types of food (reviewed by Elizaquível et al, 2014) but not for enteric viruses. This study shows for the first time the potential of PMA to discriminate between thermally inactivated HAV and infectious HAV in food applications.…”

Section: Rt-qpcrmentioning

confidence: 99%

“…A promising new strategy to assess viral infectivity relies on the use of nucleic acid intercalating dyes, or viability dyes, such as ethidium monoazide (EMA) or propidium monoazide (PMA) as a sample pretreatment before applying molecular techniques (reviewed by Elizaquível et al, 2014). Theoretically, these compounds cannot penetrate intact capsids but are able to penetrate damaged or destroyed capsids.…”

Section: Introductionmentioning

confidence: 99%

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Application of viability PCR to discriminate the infectivity of hepatitis A virus in food samples

Moreno

Aznar

Sánchez

2015

International Journal of Food Microbiology

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Section: Rt-qpcrmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Application of viability PCR to discriminate the infectivity of hepatitis A virus in food samples

Moreno

Aznar

Sánchez

2015

International Journal of Food Microbiology

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“…Of the two methods discussed in this review, viability PCR is by far the more extensively evaluated and vetted. In one of several reviews (9, 30-33), Elizaquível et al (31) cataloged over 30 published studies that applied the method to food safety models alone. Viability PCR has also been extensively optimized.…”

mentioning

confidence: 99%

“…The extent of signal reduction or ⌬C T correlates with the Rapid physical inactivation of a narrow range of targets, resulting in rapid loss of viability followed by slower decay (over hours or days) of cellular components, including the cytoplasmic membrane UV, solar disinfection, low-temp pasteurization 4 Inactivation of a specific and essential target (e.g., DNA, RNA, and protein biosynthetic enzymes), resulting in rapid loss of viability followed by slower decay (over hours or days) of cellular components, including the cytoplasmic membrane Antibiotics such as rifamycins, macrolides, aminoglycosides, and quinolones portion of the target DNA in the sample that is associated with inactivated cells (34). The utility of viability PCR has been expanded by modifications to this basic strategy (31). Dithiothreitol cotreatment was reported to facilitate PMA penetration of inactivated Bacillus subtilis spores, thereby improving the ability to discern the viability of spores (35).…”

mentioning

confidence: 99%

Dead or Alive: Molecular Assessment of Microbial Viability

Cangelosi

Meschke

2014

Appl Environ Microbiol

240

198

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Nucleic acid-based analytical methods, ranging from species-targeted PCRs to metagenomics, have greatly expanded our understanding of microbiological diversity in natural samples. However, these methods provide only limited information on the activities and physiological states of microorganisms in samples. Even the most fundamental physiological state, viability, cannot be assessed cross-sectionally by standard DNA-targeted methods such as PCR. New PCR-based strategies, collectively called molecular viability analyses, have been developed that differentiate nucleic acids associated with viable cells from those associated with inactivated cells. In order to maximize the utility of these methods and to correctly interpret results, it is necessary to consider the physiological diversity of life and death in the microbial world. This article reviews molecular viability analysis in that context and discusses future opportunities for these strategies in genetic, metagenomic, and single-cell microbiology.Yet it hath happened that the veritable body without the spirit hath walked.-Ambrose Bierce, The Death of Halpin Frayser M icrobiologists, like characters in zombie fiction, quickly learn the critical importance of distinguishing the living from the dead. In addition to characterizing the numbers and species of microorganisms in samples, it is important to collect data on their physiological states. The most fundamental physiological state of microbial cells is their viability, defined here as the capacity to form progeny. For ecologists, pathobiologists, metagenomicists, food or water safety analysts, infectious-disease clinicians, and virtually every other stripe of microbiologist, the observation of a viable microorganism in a sample means something entirely different from the observation of a dead one. Despite its importance, this distinction remains extremely challenging by current microbiological methods.Microbiological culture meets this requirement, as it selectively detects viable organisms. However, because only a small percentage of species can be cultured, this strategy underestimates microbial diversity (1-6). In contrast, nucleic acid-based methods, ranging from species-specific PCR to metagenomic methods, have greatly advanced our ability to detect diverse microorganisms independently of microbiological culture (7,8). However, these methods provide only limited information on the physiology of microorganisms in samples. They can assess microbial viability retrospectively, by measuring quantitative changes over time, but they cannot discern viability cross-sectionally (in single measurements). Traditional PCR is notoriously poor at differentiating DNA associated with a viable bacterial cell from DNA associated with an inactivated one or from a free DNA fragment. All of these analytes register as "hits" in PCR, despite their very distinct meanings.In order to address this limitation, alternative PCR-based strategies have been developed. This article reviews two complementary strategies. One strategy, term...

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“…A possible explanation on the statistical significant difference between qPCR and plate count at 28 days is the presence of dead cells that could not be distinguished from viable cells by qPCR, since it amplifies DNA from both dead and viable bacteria as DNA remains stable after the death of bacteria (Li et al 2013). An alternative approach to detect only viable bacteria is viability qPCR using dyes that intercalate DNA of dead cells, such as ethidium monoazide and propidium monoazide (Barbau-Piednoir et al 2014;Elizaquivel et al 2014). Another strategy to detect viable bacteria is the analysis of 16S transcripts by RNAseq (Gosalbes et al 2011), although it is an expensive strategy.…”

Section: Discussionmentioning

confidence: 99%

Comparison of real-time PCR assay and plate count for Lactobacillus paracasei enumeration in yoghurt

et al. 2015

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Lactobacillus paracasei is a mesophilic lactic acid bacterium technologically active in food fermentation. Culture-independent methods have rapidly been recognized as a valuable alternative to culture-dependent methods for lactic acid bacteria enumeration. In the present work, the efficacy of different protocols to extract DNA from yoghurt were compared, real-time PCR (qPCR) targeting tuf gene for L. paracasei enumeration was evaluated, and qPCR and plate counts of L. paracasei in yoghurt samples were compared. Total DNA concentrations from commercial yoghurts were higher using DNAzol method 2 than using the other tested methods. Standard curves presented suitable mean efficiency values of 91 % (pure L. paracasei strain CTT 7501), 95 % (pure L. paracasei strain FNU), and 103 % (yoghurt with L. paracasei strain FNU). Limit of detection is 3 log DNA copy number, corresponding to 2.78 log CFU, a suitable range of CFU enumeration for probiotic bacteria in yoghurt samples, considering that they should be present in large amounts. The L. paracasei (CFU) enumerated by qPCR were compared to culturable L. paracasei enumerated by plate counts at 7, 14, 21, and 28 days of yoghurt manufacture. Differences between qPCR and plate counts were observed only 28 days after yoghurt preparation, counts were similar at 7, 14, and 21 days. In conclusion, this qPCR assay is a useful and rapid tool to enumerate L. paracasei in yoghurt, although it does not distinguish dead and viable cells.

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Recent developments in the use of viability dyes and quantitative PCR in the food microbiology field

Cited by 150 publications

References 93 publications

Application of viability PCR to discriminate the infectivity of hepatitis A virus in food samples

Application of viability PCR to discriminate the infectivity of hepatitis A virus in food samples

Dead or Alive: Molecular Assessment of Microbial Viability

Comparison of real-time PCR assay and plate count for Lactobacillus paracasei enumeration in yoghurt

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