Waterborne viruses can exhibit resistance
to common water disinfectants,
yet the mechanisms that allow them to tolerate disinfection are poorly
understood. Here, we generated echovirus 11 (E11) with resistance
to chlorine dioxide (ClO2) by experimental evolution, and
we assessed the associated genotypic and phenotypic traits. ClO2 resistance emerged after E11 populations were repeatedly
reduced (either by ClO2-exposure or by dilution) and then
regrown in cell culture. The resistance was linked to an improved
capacity of E11 to bind to its host cells, which was further attributed
to two potential causes: first, the resistant E11 populations possessed
mutations that caused amino acid substitutions from ClO2-labile to ClO2-stable residues in the viral proteins,
which likely increased the chemical stability of the capsid toward
ClO2. Second, resistant E11 mutants exhibited the capacity
to utilize alternative cell receptors for host binding. Interestingly,
the emergence of ClO2 resistance resulted in an enhanced
replicative fitness compared to the less resistant starting population.
Overall this study contributes to a better understanding of the mechanism
underlying disinfection resistance in waterborne viruses, and processes
that drive resistance development.
Common water disinfectants like chlorine have been reported to select for resistant viruses, yet little attention has been devoted to characterizing disinfection resistance. Here, we investigated the resistance of MS2 coliphage to inactivation by chlorine dioxide (ClO). ClO inactivates MS2 by degrading its structural proteins, thereby disrupting the ability of MS2 to attach to and infect its host. ClO-resistant virus populations emerged not only after repeated cycles of ClO disinfection followed by regrowth but also after dilution-regrowth cycles in the absence of ClO. The resistant populations exhibited several fixed mutations which caused the substitution of ClO-labile by ClO-stable amino acids. On a phenotypic level, these mutations resulted in a more stable host binding during inactivation compared to the wild-type, thus resulting in a greater ability to maintain infectivity. This conclusion was supported by cryo-electron microscopy reconstruction of the virus particle, which demonstrated that most structural modification occurred in the putative A protein, an important binding factor. Resistance was specific to the inactivation mechanism of ClO and did not result in significant cross-resistance to genome-damaging disinfectants. Overall, our data indicate that resistant viruses may emerge even in the absence of ClO pressure but that they can be inactivated by other common disinfectants.
The emergence of waterborne viruses with resistance to disinfection has been demonstrated in the laboratory and in the environment. Yet, the implications of such resistance for virus control remain obscure. In this study we investigate if viruses with resistance to a given disinfection method exhibit cross-resistance to other disinfectants. Chlorine dioxide (ClO2)- or UV-resistant populations of echovirus 11 were exposed to five inactivating treatments (free chlorine, ClO2, UV radiation, sunlight, and heat), and the extent of cross-resistance was determined. The ClO2-resistant population exhibited cross-resistance to free chlorine, but to none of the other inactivating treatments tested. We furthermore demonstrated that ClO2 and free chlorine act by a similar mechanism, in that they mainly inhibit the binding of echovirus 11 to its host cell. As such, viruses with host binding mechanisms that can withstand ClO2 treatment were also better able to withstand oxidation by free chlorine. Conversely, the UV-resistant population was not significantly cross-resistant to any other disinfection treatment. Overall, our results indicate that viruses with resistance to multiple disinfectants exist, but that they can be controlled by inactivating methods that operate by a distinctly different mechanism. We therefore suggest to utilize two disinfection barriers that act by different mechanisms in order to control disinfection-resistant viruses.
Ultraviolet light in the UVC range is a commonly used disinfectant to control viruses in clinical settings and water treatment. However, it is currently unknown whether human viral pathogens may develop resistance to such stressor. Here, we investigate the adaptation of an enteric pathogen, human echovirus 11, to disinfection by UVC, and characterized the underlying phenotypic and genotypic changes. Repeated exposure to UVC lead to a reduction in the UVC inactivation rate of approximately 15 per cent compared to that of the wild-type and the control populations. Time-series next-generation sequencing data revealed that this adaptation to UVC was accompanied by a decrease in the virus mutation rate. The inactivation efficiency of UVC was additionally compromised by a shift from first-order to biphasic inactivation kinetics, a form of ‘viral persistence’ present in the UVC resistant and control populations. Importantly, populations with biphasic inactivation kinetics also exhibited resistance to ribavirin, an antiviral drug that, as UVC, interferes with the viral replication. Overall, the ability of echovirus 11 to adapt to UVC is limited, but it may have relevant consequences for disinfection in clinical settings and water treatment plants.
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