Resistance to serine in Bacillus subtilis : identification of the serine transporter YbeC and of a metabolic network that links serine and threonine metabolism
| Autor: | Rolf Daniel, Byoung-Mo Koo, Carol A. Gross, Daniel Reuss, Larissa Krueger, Anika Klewing, Joerg Stuelke, Anja Poehlein |
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| Rok vydání: | 2020 |
| Předmět: |
Threonine
Amino Acid Transport Systems Mutant Bacillus subtilis medicine.disease_cause Microbiology Serine 03 medical and health sciences Bacterial Proteins Drug Resistance Bacterial Escherichia coli medicine Research Articles Ecology Evolution Behavior and Systematics 030304 developmental biology chemistry.chemical_classification 0303 health sciences biology 030306 microbiology Permease biology.organism_classification 3. Good health Amino acid Complementation Biochemistry chemistry Mutation Metabolic Networks and Pathways Research Article |
| Zdroj: | Environmental Microbiology |
| ISSN: | 1462-2920 1462-2912 |
| DOI: | 10.1111/1462-2920.15179 |
| Popis: | SummaryThe Gram-positive bacteriumBacillus subtilisuses serine not only as building block for proteins but also as an important precursor in many anabolic reactions. Moreover, a lack of serine results in the initiation of biofilm formation. However, in excess serine inhibits the growth ofB. subtilis. To unravel the underlying mechanisms, we isolated suppressor mutants that can tolerate toxic serine concentrations by three targeted and non-targeted genome-wide screens. All screens as well as genetic complementation inEscherichia coliidentified the so far uncharacterized permease YbeC as the major serine transporter ofB. subtilis. In addition to YbeC, the threonine transporters BcaP and YbxG make minor contributions to serine uptake. A strain lacking these three transporters was able to tolerate 100 mM serine whereas the wild type strain was already inhibited by 1 mM of the amino acid. The screen for serine-resistant mutants also identified mutations that result in increased serine degradation and in increased expression of threonine biosynthetic enzymes suggesting that serine toxicity results from interference with threonine biosynthesis.Originality-Significance StatementSerine is an important precursor for many biosynthetic reactions, and lack of this amino acid can induce biofilm formation inBacillus subtilis. However, serine is toxic for the growth ofB. subtilis. To understand the reason(s) for this toxicity and to identify the so far unknown serine transporter(s) of this bacterium, we performed exhaustive mutant screens to isolate serine-resistant mutants. This screen identified YbeC, the major serine transporter ofB. subtilis. Moreover, we observed an intimate link between serine and threonine metabolism that is responsible for serine toxicity by inhibiting threonine biosynthesis. |
| Databáze: | OpenAIRE |
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