Diversity of SIRV-like Viruses from a North American Population

Diversity of SIRV-like Viruses from a North American Population

A small subset of acidic hot springs sampled in Yellowstone National Park yielded rod-shaped viruses which lysed liquid host cultures and formed clear plaques on lawns of host cells. Three isolates chosen for detailed analysis were found to be genetically related to previously described isolates of...

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Bibliographic Details
Main Authors: Dworjan, M. (Author), Fackler, J.R (Author), Gazi, K.S (Author), Grogan, D.W (Author)
Format: Article
Language:English
Published: MDPI 2022
Subjects:
adult
archaeal virus
archaeal viruses
article
clustered regularly interspaced short palindromic repeat
Enterobacteria phage lambda
fimbria
high temperature
host cell
human
local populations
national park
natural population
natural variation
nonhuman
North American
phenotype
resistant host variants
Sulfolobales
Sulfolobus islandicus
Sulfolobus islandicus rod-shaped virus (SIRV)
survivor
suspension cell culture
thermal spring
ultraviolet C radiation
virion
virion stability
virus strain
Online Access:View Fulltext in Publisher
Description
Summary:A small subset of acidic hot springs sampled in Yellowstone National Park yielded rod-shaped viruses which lysed liquid host cultures and formed clear plaques on lawns of host cells. Three isolates chosen for detailed analysis were found to be genetically related to previously described isolates of the Sulfolobus islandicus rod-shaped virus (SIRV), but distinct from them and from each other. Functional stability of the new isolates was assessed in a series of inactivation experiments. UV-C radiation inactivated one of the isolates somewhat faster than bacteriophage λ, suggesting that encapsidation in the SIRV-like virion did not confer unusual protection of the DNA from UV damage. With respect to high temperature, the new isolates were extremely, but not equally, stable. Several chemical treatments were found to inactivate the virions and, in some cases, to reveal apparent differences in virion stability among the isolates. Screening a larger set of isolates identified greater variation of these stability properties but found few correlations among the resulting profiles. The majority of host cells infected by the new isolates were killed, but survivors exhibited heritable resistance, which could not be attributed to CRISPR spacer acquisition or the loss of the pilus-related genes identified by earlier studies. Virus-resistant host variants arose at high frequency and most were resistant to multiple viral strains; conversely, resistant host clones generated virus-sensitive variants, also at high frequency. Virus-resistant cells lacked the ability of virus-sensitive cells to bind virions in liquid suspensions. Rapid interconversion of sensitive and resistant forms of a host strain suggests the operation of a yet-unidentified mechanism that acts to allow both the lytic virus and its host to propagate in highly localized natural populations, whereas variation of virion-stability phenotypes among the new viral isolates suggests that multiple molecular features contribute to the biological durability of these viruses. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.
ISBN:19994915 (ISSN)
DOI:10.3390/v14071439

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