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Full-Text Articles in Bioinformatics
Draft Genome Sequence Of Clinical Isolate Alcaligenaceae Sp. Strain 429, Catherine Putonti, Michael Zilliox, Paul Schreckenberger
Draft Genome Sequence Of Clinical Isolate Alcaligenaceae Sp. Strain 429, Catherine Putonti, Michael Zilliox, Paul Schreckenberger
Bioinformatics Faculty Publications
Here, we present the 3.53-Mb genome for Alcaligenaceae sp. strain 429, isolated from a patient with unknown etiology. While the 16S rRNA gene most closely resembles Paenalcaligenes species, average amino acid identity (AAI) analysis did not meet the threshold to classify our strain as a species of this family.
Assessment Of A Metaviromic Dataset Generated From Nearshore Lake Michigan, Siobhan C. Watkins, Neil Kuehnle, C Anthony Ruggeri, Kema Malki, Katherine Bruder, Jinan Elayyan, Kristina Damisch, Naushin Vahora, Paul O'Malley, Brianne Ruggles-Sage, Zachary Romer, Catherine Putonti
Assessment Of A Metaviromic Dataset Generated From Nearshore Lake Michigan, Siobhan C. Watkins, Neil Kuehnle, C Anthony Ruggeri, Kema Malki, Katherine Bruder, Jinan Elayyan, Kristina Damisch, Naushin Vahora, Paul O'Malley, Brianne Ruggles-Sage, Zachary Romer, Catherine Putonti
Bioinformatics Faculty Publications
Bacteriophages are powerful ecosystem engineers. They drive bacterial mortality rates and genetic diversity, and affect microbially mediated biogeochemical processes on a global scale. This has been demonstrated in marine environments; however, phage communities have been less studied in freshwaters, despite representing a potentially more diverse environment. Lake Michigan is one of the largest bodies of freshwater on the planet, yet to date the diversity of its phages has yet to be examined. Here, we present a composite survey of viral ecology in the nearshore waters of Lake Michigan. Sequence analysis was performed using a web server previously used to analyse …
Mechanisms Responsible For A Φx174 Mutant's Ability To Infect Escherichia Coli By Phosphorylation, Jennifer Cox, Catherine Putonti
Mechanisms Responsible For A Φx174 Mutant's Ability To Infect Escherichia Coli By Phosphorylation, Jennifer Cox, Catherine Putonti
Bioinformatics Faculty Publications
The ability for a virus to expand its host range is dependent upon a successful mode of viral entry. As such, the host range of the well-studied ΦX174 bacteriophage is dictated by the presence of a particular lipopolysaccharide (LPS) on the bacterial surface. The mutant ΦX174 strain JACS-K, unlike its ancestor, is capable of infecting both its native host Escherichia coli C and E. coli K-12, which does not have the necessary LPS. The conversion of an alanine to a very reactive threonine on its virion surface was found to be responsible for the strain's expanded host range.