Real-time detection of viable microorganisms by intracellular phototautomerism

• Main Authors: Schuren Frank, Verheij Herman, van Veen Sjaak, de Kat Angelino-Bart Alie, Nocker Andreas, Kort Remco, Montijn Roy
• Format: Article
• Language: English
• Published: BMC 2010-06-01
• Series: BMC Biotechnology
• Online Access: http://www.biomedcentral.com/1472-6750/10/45

<p>Abstract</p> <p>Background</p> <p>To date, the detection of live microorganisms present in the environment or involved in infections is carried out by enumeration of colony forming units on agar plates, which is time consuming, laborious and limited to readily cultivable microorganisms. Although cultivation-independent methods are available, they involve multiple incubation steps and do mostly not discriminate between dead or live microorganisms. We present a novel generic method that is able to specifically monitor living microorganisms in a real-time manner.</p> <p>Results</p> <p>The developed method includes exposure of cells to a weak acid probe at low pH. The neutral probe rapidly permeates the membrane and enters the cytosol. In dead cells no signal is obtained, as the cytosolic pH reflects that of the acidic extracellular environment. In live cells with a neutral internal pH, the probe dissociates into a fluorescent phototautomeric anion. After reaching peak fluorescence, the population of live cells decays. This decay can be followed real-time as cell death coincides with intracellular acidification and return of the probe to its uncharged non-fluorescent state. The rise and decay of the fluorescence signal depends on the probe structure and appears discriminative for bacteria, fungi, and spores. We identified 13 unique probes, which can be applied in the real-time viability method described here. Under the experimental conditions used in a microplate reader, the reported method shows a detection limit of 10⁶bacteria ml^-1, while the frequently used LIVE/DEAD BacLight™ Syto9 and propidium iodide stains show detection down to 10⁶and 10⁷bacteria ml^-1, respectively.</p> <p>Conclusions</p> <p>We present a novel fluorescence-based method for viability assessment, which is applicable to all bacteria and eukaryotic cell types tested so far. The RTV method will have a significant impact in many areas of applied microbiology including research on biocidal activity, improvement of preservation strategies and membrane permeation and stability. The assay allows for high-throughput applications and has great potential for rapid monitoring of microbial content in air, liquids or on surfaces.</p>