Functional dissection of the molybdate-responsive transcription regulator, ModE, from Escherichia coli.

The product of the Escherichia coli modE gene, ModE, is a member of a unique class of molybdate-responsive DNA binding proteins. Here we investigated the roles of the N- and C-terminal domains of ModE in mediating DNA binding and protein dimerization, respectively. Compared to the full-length protein, the N-terminal half of ModE has a greatly diminished capacity to bind the modA promoter in vitro and to repress expression from a modA-lacZ operon fusion in vivo. Fusing a protein dimerization domain, encoded by the C terminus of lambda CI repressor protein, to the truncated ModE protein generated a ModE-CI fusion protein that not only displayed a greatly increased in vivo repressor activity but could also substitute for ModE at the moaA and dmsA promoters. In the reciprocal experiment, we restored repressor activity to a truncated CI protein by addition of the C-terminal domain of ModE, which is comprised of two MopI-like subdomains. By an in vivo competition assay, we also demonstrated that the CI-ModE chimeric protein retained the ability to interact with wild-type ModE. Finally, specific deletions within the ModE portion of the CI-ModE protein chimera abolished both in vivo repression and the ability to interact with wild-type ModE. Together, these data demonstrate that the N-terminal domain of ModE is sufficient to mediate DNA binding, although efficient binding requires that ModE form a dimer, a function that is supplied by the C-terminal MopI-like subdomains.

Characterization of the ModE DNA-binding sites in the control regions of modABCD and moaABCDE of Escherichia coli.

The Escherichia coli molybdate transporter, encoded by the modABCD operon, is negatively regulated by the modE gene product in response to the intracellular molybdate concentration. Utilizing an in vivo titration assay, we localized the ModE-binding site to the start of modA transcription. This localization was further characterized using in vitro gel-shift assays and DNase I footprinting. ModE bound the wild-type modA promoter with an apparent dissociation constant (Kd) of 45 nM, and addition of molybdate, in physiologically relevant amounts, significantly increased DNA binding. Consistent with these data, modA promoter fragments containing mutations that reduced ModE repression in vivo displayed proportionately higher apparent Kd values in vitro. DNase I footprinting of the modA promoter revealed a single protected region that overlapped the start site of transcription and extended from position -18 to +10, relative to the transcript start site. Gel-shifting assays, employing the promoter regions from the tor, nrf, moa and moe operons, revealed that ModE bound only the moa promoter region, with an apparent Kd of 24nM. Footprint analysis of the moaA promoter revealed a single protected region located immediately upstream of the putative -35 consensus sequence and extending from position -202 to -174, relative to the start of translation. In vivo expression of a moaA-lacZ operon fusion was stimulated twofold by ModE. However, relative to modA, binding of ModE to the moaA promoter appeared to be largely molybdate independent both in vitro and in vivo. These findings demonstrate that ModE acts both as a repressor and activator of the mod and moa operons, respectively, depending on the properties of the binding site.

The terminal reductases for selenate and nitrate respiration in Thauera selenatis are two distinct enzymes.

A number of approaches have been used to show that a recently isolated selenate-respiring bacterium, Thauera selenatis, is able to synthesize both a selenate reductase (SR) and a nitrate reductase (NR). (i) The pH optimum of the SR was found to be 6.0; that of the NR was 7.0. (ii) The presence of nitrate did not inhibit selenate reduction in selenate-grown cells. (iii) In cell extracts, the highest SR or NR activity was observed in cells grown with the respective electron acceptor. (iv) Mutants that were unable to grow with nitrate as the terminal electron acceptor and lacked NR activity were isolated; these mutants grew normally with selenate and synthesized SR. (v) The SR was found in the periplasmic space of the cell, whereas the NR was present in the cytoplasmic membrane. A hypothetical electron transport system involving the SR is described.