The alphaproteobacterium Hyphomonas neptunium proliferates by a unique budding mechanism in which daughter cells emerge from the end of a stalk-like extension emanating from the mother cell body. Studies of this species so far have been hampered by the lack of a genetic system and of molecular tools allowing the regulated expression of target genes. Based on microarray analyses, this work identifies two H. neptunium promoters that are activated specifically by copper and zinc. Functional analyses show that they have low basal activity and a high dynamic range, meeting the requirements for use as a multipurpose expression system. To facilitate their application, the two promoters were incorporated into a set of integrative plasmids, featuring a choice of two different selection markers and various fluorescent protein genes. These constructs enable the straightforward generation and heavy metal-inducible synthesis of fluorescent protein fusions in H. neptunium, thereby opening the door to an in-depth analysis of polar growth and development in this species. Bacteria are a phylogenetically diverse group of organisms whose study has provided important insights into the mechanisms that mediate the spatiotemporal organization of cells. However, most of our knowledge on bacterial cell biology so far has come from the analysis of only a few well-established model species, such as Escherichia coli, Bacillus subtilis, and Caulobacter crescentus, which typically exhibit a rod-like morphology and divide by symmetric or asymmetric binary fission.To further our understanding of subcellular organization in bacteria, we have started to investigate the marine alphaproteobacterium Hyphomonas neptunium (1), a representative of the stalked budding bacteria (2, 3). Similar to other members of this polyphyletic bacterial group, H. neptunium is characterized by a unique mode of reproduction that involves the formation of buds at the tip of a stalk emanating from the mother cell body (Fig. 1A). During the budding process, the nascent daughter cell is equipped with a single polar flagellum at the pole opposite the stalk. Cytokinesis then gives rise to a motile swarmer cell, which initially is unable to replicate, and an immotile stalked cell, which immediately enters a new round of budding and cell division (4). At a defined time in the cell cycle, the swarmer cell undergoes a differentiation process during which it sheds the flagellum and establishes a stalk at the opposite pole. Subsequently, a bud emerges from the tip of the stalk, setting the stage for the next division event.H. neptunium was isolated from the harbor of Barcelona (Spain). Based on morphological criteria, it was originally described as Hyphomicrobium neptunium (1). Later, DNA-DNA hybridization experiments, 5S rRNA sequence analyses, and metabolic profiling revealed a close phylogenetic relationship to members of the genus Hyphomonas (5, 6). Interestingly, 16S rRNA-based phylogenetic studies identify H. neptunium as a member of the Rhodobacterales (7). However, 23S rR...
The β-proteobacterium Aromatoleum aromaticum degrades the aromatic ketone acetophenone, a key intermediate of anaerobic ethylbenzene metabolism, either aerobically or anaerobically via a complex ATP-dependent acetophenone carboxylase and a benzoylacetate-CoA ligase. The genes coding for these enzymes (apcABCDE and bal) are organized in an apparent operon and are expressed in the presence of the substrate acetophenone. To study the conditions under which this operon is expressed in more detail, we constructed a reporter strain by inserting a gene fusion of apcA, the first gene of the apc-bal operon, with the gene for the fluorescent protein mCherry into the chromosome of A. aromaticum. The fusion protein indeed accumulated consistently with the expression pattern of the acetophenone-metabolic enzymes under various growth conditions. After evaluating and quantifying the data by fluorescence microscopy, fluorescence-based flow cytometry and immunoblot analysis, mCherry production was found to be proportional to the applied acetophenone concentrations. The reporter strain allowed quantification of acetophenone within a concentration range of 50 μM (detection limit) to 250 μM after 12 and 24 h. Moreover, production of the Apc-mCherry fusion protein in the reporter strain was highly specific and responded to acetophenone and both enantiomers of 1-phenylethanol, which are easily converted to acetophenone. Other analogous substrates showed either a significantly weaker response or none at all. Therefore, the reporter strain provides a basis for the development of a specific bioreporter system for acetophenone with an application potential reaching from environmental monitoring to petroleum prospecting.
Shewanella oneidensis MR-1 possesses two different stator units to drive flagellar rotation, the Na -dependent PomAB stator and the H -driven MotAB stator, the latter possibly acquired by lateral gene transfer. Although either stator can independently drive swimming through liquid, MotAB-driven motors cannot support efficient motility in structured environments or swimming under anaerobic conditions. Using ΔpomAB cells we isolated spontaneous mutants able to move through soft agar. We show that a mutation that alters the structure of the plug domain in MotB affects motor functions and allows cells to swim through media of increased viscosity and under anaerobic conditions. The number and exchange rates of the mutant stator around the rotor were not significantly different from wild-type stators, suggesting that the number of stators engaged is not the cause of increased swimming efficiency. The swimming speeds of planktonic mutant MotAB-driven cells was reduced, and overexpression of some of these stators caused reduced growth rates, implying that mutant stators not engaged with the rotor allow some proton leakage. The results suggest that the mutations in the MotB plug domain alter the proton interactions with the stator ion channel in a way that both increases torque output and allows swimming at decreased pmf values.
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