Abstract
To address questions about algal virus persistence (i.e., continued existence) in the environment, rates of decay of infectivity for two viruses that infect Chlorella-like algae, ATCV-1 and CVM-1, and a virus that infects the prymnesiophyte Chrysochromulina parva, CpV-BQ1, were estimated from in situ incubations in a temperate, seasonally frozen pond. A series of experiments were conducted to estimate rates of decay of infectivity in all four seasons with incubations lasting 21 days in spring, summer and autumn, and 126 days in winter. Decay rates observed across this study were relatively low compared with previous estimates obtained for other algal viruses, and ranged from 0.012 to 11% h−1. Overall, the virus CpV-BQ1 decayed most rapidly whereas ATCV-1 decayed most slowly, but for all viruses the highest decay rates were observed during the summer and the lowest were observed during the winter. Furthermore, the winter incubations revealed the ability of each virus to overwinter under ice as ATCV-1, CVM-1 and CpV-BQ1 retained up to 48%, 19% and 9% of their infectivity after 126 days, respectively. The observed resilience of algal viruses in a seasonally frozen freshwater pond provides a mechanism that can support the maintenance of viral seed banks in nature. However, the high rates of decay observed in the summer demonstrate that virus survival and therefore environmental persistence can be subject to seasonal bottlenecks.
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Acknowledgements
Special thanks to Dr James Van Etten and colleagues at University of Nebraska, Lincoln for providing cell cultures of M. conductrix and C. heliozoae as well as isolates of ATCV-1 and CVM-1. We are also grateful to Cindy Short and Samia Mirza for their support in maintaining cell culture lines. This research was supported in part by the Canadian Foundation for Innovation Leaders Opportunity Fund and NSERC Discovery grants awarded to SMS.
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Long, A., Short, S. Seasonal determinations of algal virus decay rates reveal overwintering in a temperate freshwater pond. ISME J 10, 1602–1612 (2016). https://doi.org/10.1038/ismej.2015.240
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DOI: https://doi.org/10.1038/ismej.2015.240
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