Abstract
AbstractAquatic bacteria frequently are divided into lifestyle categoriesoligotrophorcopiotroph. Oligotrophs have proportionately fewer transcriptional regulatory genes than copiotrophs and are generally non-motile/chemotactic. We hypothesized that the absence of chemotaxis/motility in oligotrophs prevents them from occupying nutrient patches long enough to benefit from transcriptional regulation. We first confirmed that marine oligotrophs are generally reduced in genes for transcriptional regulation and motility/chemotaxis. Next, using a non-motile oligotroph (Ca. Pelagibacter st. HTCC7211), a motile copiotroph (Alteromonas macleodiist. HOT1A3), and [14C]L-alanine, we confirmed that L-alanine catabolism is not transcriptionally regulated in HTCC7211 but is in HOT1A3. We then found that HOT1A3 took 2.5-4 min to initiate L-alanine oxidation at patch L-alanine concentrations, compared to <30s for HTCC7211. By modeling cell trajectories, we predicted that, in most scenarios, non-motile cells spend <2 min in patches, compared to >4 mins for chemotactic/motile cells. Thus, the time necessary for transcriptional regulation to initiate prevents transcriptional regulation from being beneficial for non-motile oligotrophs. This is supported by a mechanistic model we developed, which predicted that HTCC7211 cells with transcriptional regulation of L-alanine metabolism would produce 12% of their standing ATP stock upon encountering an L-alanine patch, compared to 880% in HTCC7211 cells without transcriptional regulation.
Publisher
Cold Spring Harbor Laboratory