The betaproteobacterial degradation specialist Aromatoleum aromaticum EbN1T utilizes several plant-derived 3-phenylpropanoids coupled to denitrification. In vivo responsiveness of A. aromaticum EbN1T was studied by exposing non-adapted cells to distinct pulses (spanning 100 μM to 0.1 nM) of 3-phenylpropanoate, cinnamate, 3-(4-hydroxyphenyl)propanoate, or p-coumarate. Time-resolved, targeted transcript analyses via qRT-PCR of four selected 3-phenylpropanoid genes revealed a response threshold of 30–50 nM for p-coumarate and 1–10 nM for the other three tested 3-phenylpropanoids. At these concentrations, transmembrane effector equilibration is attained by passive diffusion rather than active uptake via the ABC transporter presumably serving the studied 3-phenylpropanoids as well as benzoate. Highly substrate-specific enzyme formation (EbA5316–21) for the shared peripheral degradation pathway putatively involves the predicted TetR-type transcriptional repressor PprR. Accordingly, relative transcript abundances of ebA5316–21 are lower in succinate- and benzoate-grown wildtype cells compared to an unmarked in-frame ΔpprR mutant. In trans complementation of pprR into the ΔpprR background restored wildtype-like transcript levels. When adapted to p-coumarate, the three genotypes had similar relative transcript abundances of ebA5316–21, despite a significantly longer lag-phase of the pprR-complemented mutant (∼100-fold higher pprR transcript level than wildtype). Notably, transcript levels of ebA5316–21 were ∼10–100-fold higher in p-coumarate- versus succinate- or benzoate-adapted cells across all three genotypes. This possibly indicates the additional involvement of a yet unknown transcriptional regulator. Furthermore, physiological, transcriptional and (aromatic) acyl-CoA ester intermediate analyses of wildtype and ΔpprR mutant grown with binary substrate mixtures suggest a mode of catabolite repression of superior order to PprR.
IMPORTANCE Lignin is a ubiquitous hetero-biopolymer built from of a suite of 3-phenylpropanoid subunits. It not only accounts for more than 30% of the global plant dry material, but lignin-related compounds are also increasingly released into the environment from anthropogenic sources, i.e., by wastewater effluents from the paper and pulp industry. Hence, following biological or industrial decomplexation of lignin, vast amounts of structurally diverse 3-phenylpropanoids enter terrestrial and aquatic habitats, where they serve as substrates for microbial degradation. This raises the question what signaling systems environmental bacteria employ to detect these nutritionally attractive compounds and to adjust their catabolism accordingly. Moreover, determining in vivo response thresholds of an anaerobic degradation specialist such as A. aromaticum EbN1T for these aromatic compounds provides insights into the environmental fate of the latter, i.e., when they could escape biodegradation due to too low ambient concentrations.