EfgA is a Conserved Formaldehyde Sensor That Leads to Bacterial Growth Arrest in Response to Elevated Formaldehyde

Jannell V Bazurto; Dipti D Nayak; Tomislav Ticak; Milya Davlieva; Chandler N Hellenbrand; Leah B Lambert; Olivia J Benski; Caleb J Quates; Jill L Johnson; Jagdish Suresh Patel; Marty Ytreberg; Yousif Shamoo; Christopher J Marx

doi:10.1371/journal.pbio.3001208

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EfgA is a Conserved Formaldehyde Sensor That Leads to Bacterial Growth Arrest in Response to Elevated Formaldehyde

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EfgA is a Conserved Formaldehyde Sensor That Leads to Bacterial Growth Arrest in Response to Elevated Formaldehyde

Jannell V Bazurto, Dipti D Nayak, Tomislav Ticak, Milya Davlieva, Chandler N Hellenbrand, Leah B Lambert, Olivia J Benski, Caleb J Quates, Jill L Johnson, Jagdish Suresh Patel, …

PLOS Biology, Vol.19(5), p.e3001208

2021

DOI: https://doi.org/10.1371/journal.pbio.3001208

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Title: EfgA is a Conserved Formaldehyde Sensor That Leads to Bacterial Growth Arrest in Response to Elevated Formaldehyde
Creators: Jannell V Bazurto - University of Idaho
Dipti D Nayak - University of Idaho
Tomislav Ticak - University of Idaho
Milya Davlieva - Rice University
Chandler N Hellenbrand - University of Minnesota
Leah B Lambert - University of Idaho
Olivia J Benski - University of Idaho
Caleb J Quates - University of Idaho
Jill L Johnson - University of Idaho
Jagdish Suresh Patel - University of Idaho
Marty Ytreberg
Yousif Shamoo - Rice University
Christopher J Marx - University of Idaho
Publication Details: PLOS Biology, Vol.19(5), p.e3001208
Identifiers: 996630531801851
Academic Unit: Initiative for Bioinformatics and Evolutionary Studies; Biological Sciences; Institute for Modeling Collaboration and Innovation; Institute for Health in the Human Ecosystem; Physics
Language: English
Resource Type: Journal article