Mapping, sequence, and apparent lack of function of araJ, a gene of the Escherichia coli arabinose regulon

Reeder, Thadd; Schleif, Robert

doi:10.1128/jb.173.24.7765-7771.1991

Cited by 34 publications

(23 citation statements)

References 36 publications

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“…Both the NagC and putative Mlc proteins may influence the acetate metabolism of the host strain in a similar manner. Although the ORF gene downstream of the araJ gene 28 ) did not have this property, making large colonies, there is a possibility that this gene is not transcribed (the 5 f -region has not been sequenced).…”

Section: Discussionmentioning

confidence: 99%

“…The NagC protein, the regulator of the nag operon encoding proteins involved in the use of N-acetylglucosamine, 27) the ORF (the sequence published is incomplete and the function is unknown) downstream of the araJ gene 28 ) in E. coli, and the XylR protein, the regulator of the xyl operon encoding proteins involved in the use of xylose, in Bacillus subtilis 29 ) were found to have high homologies with the putative Mlc protein (Fig. 5).…”

Section: Mapping Dna Sequencing and Identification Of The Product Omentioning

confidence: 99%

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Decreasing Accumulation of Acetate in a Rich Medium byEscherichia colion Introduction of Genes on a Multicopy Plasmid

Hosono¹,

Kakuda²,

Ichihara³

1995

Bioscience, Biotechnology, and Biochemistry

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Section: Discussionmentioning

confidence: 99%

Section: Mapping Dna Sequencing and Identification Of The Product Omentioning

confidence: 99%

Decreasing Accumulation of Acetate in a Rich Medium byEscherichia colion Introduction of Genes on a Multicopy Plasmid

Hosono¹,

Kakuda²,

Ichihara³

1995

Bioscience, Biotechnology, and Biochemistry

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“…These facts suggest that specific contacts are made between the AraC protein and RNA polymerase at p BAD . Providing further support for this theory is the almost identical arrangement of the protein binding sites for araBAD, araE, and araJ, a weak, arabinose-inducible promoter whose gene product is nonessential (24). Surprisingly, the araFGH promoter, p FGH , possesses a radically different structure (Fig.…”

mentioning

confidence: 93%

In vivo induction kinetics of the arabinose promoters in Escherichia coli

Johnson

Schleif

1995

J Bacteriol

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In Escherichia coli, the AraC protein represses transcription from its own promoter, p C , and when associated with arabinose, activates transcription from three other promoters, p BAD , p E , and p FGH . Expression from all four of these promoters is also regulated by cyclic AMP-catabolite activator protein; however, the arrangement of the protein binding sites is not identical for each promoter. We are interested in determining how the AraC protein is able to activate p BAD , p E , and p FGH despite their differences. We have characterized the induction response of the wild-type arabinose operons from their native chromosomal locations by primer extension analysis. In this analysis, mRNA from the four arabinose operons plus an internal standard could all be assayed in the RNA obtained from a single sample of cells. We found that each of the operons shows a rapid, within 15 to 30 s, response to arabinose. We also found that the expression of araFGH is more sensitive to catabolite repression but not to arabinose concentration than are araE and araBAD. Finally, we have determined the relative levels of inducibility in wild-type cells of araBAD, araFGH, and araE to be 6.5, 5, and 1, respectively. These results provide a basis for subsequent studies to determine the mechanism(s) by which AraC protein activates transcription from the different arabinose promoters.Arabinose utilization in Escherichia coli requires the expression of the metabolic operon, araBAD (8,9,33), and expression of either the low-affinity transport operon, araE (22), or the high-affinity transport operon, araFGH (3,12,15). Induction of each of these operons normally requires the AraC protein (5) complexed with arabinose and the catabolite activator protein (CAP) complexed with cyclic AMP (cAMP). The regulatory protein binding sites and the transcription start sites at each of the arabinose-responsive promoters have been determined (10, 17, 18, 23, 31, 32). Studies of the araBAD promoter, p BAD , show that to activate transcription the AraC protein binding site must overlap the Ϫ35 region of the promoter by 4 bp (25) (Fig. 1). Further, the two half-sites recognized by the dimeric AraC protein must be in the same direct repeat orientation (4, 21) to activate transcription. These facts suggest that specific contacts are made between the AraC protein and RNA polymerase at p BAD . Providing further support for this theory is the almost identical arrangement of the protein binding sites for araBAD, araE, and araJ, a weak, arabinose-inducible promoter whose gene product is nonessential (24). Surprisingly, the araFGH promoter, p FGH , possesses a radically different structure (Fig. 1). In p FGH the CAP site, rather than the AraC site, overlaps the Ϫ35 recognition sequence of RNA polymerase. Additionally, the AraC sites in araFGH are arranged in the opposite direct repeat orientation (Fig. 1).This work is a first step in studying the mechanism(s) by which AraC regulates transcription at the araE promoter, p E , and at p FGH . In the present study, we ha...

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“…One is encoded downstream of the araJ gene o f I:. coli, possibly as part of the ara regulon (Reeder & Schleif, 1991), whereas the other is distantly linked to the na<<t--I gene coding for a hyaluronidase of Clustridiztm perfriqms (Carnard et al, GenBank M81878, unpublished:. Table 2 presents the binary percentage identity and RDF2 comp:it-tcon scores for most of the sequenced protein members of the ROK family.…”

Section: Evolutionary Relationships Between Sugar Kinases and Transcrmentioning

confidence: 99%

Evolutionary relationships between sugar kinases and transcriptional repressors in bacteria

et al. 1994

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Mapping, sequence, and apparent lack of function of araJ, a gene of the Escherichia coli arabinose regulon

Cited by 34 publications

References 36 publications

Decreasing Accumulation of Acetate in a Rich Medium byEscherichia colion Introduction of Genes on a Multicopy Plasmid

Decreasing Accumulation of Acetate in a Rich Medium byEscherichia colion Introduction of Genes on a Multicopy Plasmid

In vivo induction kinetics of the arabinose promoters in Escherichia coli

Evolutionary relationships between sugar kinases and transcriptional repressors in bacteria

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