Unusual organization, complexity and redundancy at the Escherichia coli hcp-hcr operon promoter

Expression from the Escherichia coli hcp-hcr operon promoter is optimally induced during anaerobic conditions in the presence of nitrite. This expression depends on transcription activation by FNR (fumarate and nitrate reduction regulator), which binds to a target centred at position −72.5 upstream of the transcript start site. Mutational analysis was exploited to identify the corresponding −10 and −35 hexamer elements. A DNA site for NarL and NarP, located at position −104.5, plays only a minor role, whereas NsrR binding to a DNA target centred at position +6 plays a major role in induction of the hcp-hcr operon promoter. Electrophoretic mobility-shift assays show that NsrR binds to this target. The consequences of this for the kinetics of induction of the hcp-hcr operon are discussed.

Regulation of Excision Genes of the Bacteroides Conjugative Transposon CTnDOT

ABSTRACT The first step in the transfer of the Bacteroides conjugative transposon CTnDOT is excision of the integrated element from the chromosome to form a circular transfer intermediate. Excision occurs only after the bacteria are exposed to tetracycline. Previously, four excision genes were identified. One was the integrase gene intDOT, which appeared to be expressed constitutively. Three other genes essential for excision (orf2c, orf2d, and exc) were found located in a cluster 13 kbp downstream of intDOT. By using uidA fusions and real-time reverse transcriptase PCR, we demonstrate here that the excision genes orf2c, orf2d, and exc are part of an operon that also contains open reading frame orf3, previously shown not to be essential for excision. We also show that operon expression is regulated at the transcriptional level in response to tetracycline. The transcript start site for the operon has been localized. Three CTnDOT regulatory genes are thought to be involved in tetracycline regulation of excision, rteA, rteB, and rteC. By placing rteC under the control of a heterologous promoter, we found that RteC alone was sufficient for induction of the orf2c operon. If, however, the rteC gene was under the control of its own promoter, it was not able to induce orf2c operon expression unless rteA and rteB were present. Thus, RteA and RteB participate in excision by stimulating transcription of rteC. Using electrophoretic mobility shift analysis, we found that a purified His6-tagged form of RteC bound DNA upstream of the −33 region of the promoter. Changing the sequence in the region between bp −50 and −70 reduced the expression of the orf2c operon in vivo. Taken together, our results support the hypothesis that RteC acts as a DNA-binding protein that binds upstream of the orf2c promoter and is responsible for tetracycline-regulated transcriptional regulation of the orf2c operon.

FNR-Mediated Oxygen-Responsive Regulation of the nrdDG Operon of Escherichia coli

ABSTRACT Transcription of the nrdDG operon, which encodes the class III nucleotide reductase, which is only active under anaerobic conditions, was strongly induced after a shift to anaerobiosis. The induction was completely dependent on the transcriptional activator FNR and was independent of the ArcA-ArcB two-component response regulator system. The nrdD transcript start site was mapped to a position immediately downstream of two FNR binding sites. Transcription of the other two nucleotide reductase operons, nrdAB and nrdEF, did not respond to oxygen conditions in a wild-type background, but nrdAB expression was increased in the fnr mutant under anaerobic conditions.

Characterization of the Overlapping Promoters of nolB and nolW, Two Soybean Cultivar Specificity Genes from Rhizobium fredii Strain USDA257

The transcripts of nolW and nolB, two divergently oriented cultivar specificity genes of Rhizobium fredii strain USDA257, are known to be initiated 14 bp apart from promoters that face one another. We show here that expression of nolB is dependent both on induction with flavonoid signals and on the regulatory gene, nodD1. Expression of nolW is constitutive and independent of flavonoids and nodD1. Normal expression of nolB is retained with a promoter that extends only 61 bp upstream of the transcript start site, but it is lost if an additional 24 bp are removed. Substantial expression of nolW is retained with a promoter that contains only 34 bp of DNA upstream from the transcript initiation site. The dual control region for the two genes is thus only about 109 bp in length.

Molecular control of the induction of alcohol dehydrogenase by ethanol in Drosophila melanogaster larvae.

The activity of alcohol dehydrogenase (ADH:EC 1.1.1.1), the initial enzyme in the major pathway for ethanol degradation, is induced in Drosophila melanogaster larvae by low concentrations of dietary ethanol. Two lines of evidence indicate that the metabolic products of the ADH pathway for ethanol degradation are not directly involved in the induction of Adh. First, the accumulation of the proximal transcript in Adhn2 larvae was increased when the intracellular level of ethanol was elevated. In addition, the ADH activity, the proximal Adh mRNA, and the intracellular concentration of ethanol were elevated coordinately in wild-type larvae fed hexadeuterated-ethanol, which is metabolized more slowly than normal ethanol. An examination of P element transformant lines with specific deletions in the 5' regulatory DNA of the Adh gene showed that a DNA sequence between +527 and +604 of the distal transcript start site is essential for the induction of the Adh gene [corrected]. The DNA sequence between -660 and about -5000 of the distal transcript start site was important for the down-regulation of the induction response.