Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UNIPROT:P51532 (
transcriptional activator
)
6,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In Rhizobium meliloti the NifA protein plays a central role in the expression of genes involved in nitrogen fixation. The R. meliloti NifA protein has been found to be oxygen sensitive and therefore acts as a
transcriptional activator
only under microaerobic conditions. In order to generate oxygen-tolerant variants of the NifA protein a plasmid carrying the R. meliloti nifA gene was mutagenized in vitro with
hydroxylamine
. About 70 mutated nifA genes were isolated which mediated up to 12-fold increased NifA activity at high oxygen concentrations. A cloning procedure involving the combination of DNA fragments from mutated and wild-type nifA genes allowed mapping of the mutation sites within the central part of the nifA gene. For 17 mutated nifA genes the exact mutation sites were determined by DNA sequence analysis. It was found that all 17 mutated nifA genes carried identical guanosine--adenosine mutations resulting in a methionine--isoleucine exchange (M217I) near the putative nucleotide binding site within the central domain. Secondary structure predictions indicated that the conformation of the putative nucleotide binding site may be altered in the oxygen-tolerant NifA proteins. A model is proposed which assumes that at high oxygen concentrations the loss of activity of the R. meliloti NifA protein is due to a conformational change in the nucleotide binding site that may abolish binding or hydrolysis of the nucleotide. Such a conformational change may be blocked in the oxygen-tolerant NifA protein, thus allowing interaction with the nucleotide at high oxygen concentrations.
...
PMID:A defined amino acid exchange close to the putative nucleotide binding site is responsible for an oxygen-tolerant variant of the Rhizobium meliloti NifA protein. 140 89
In Rhizobium leguminosarum (R.l.) biovar viciae, the nodulation gene nodD encodes a
transcriptional activator
(NodD) which binds to highly conserved DNA sequences (nod-boxes) in the promoters of other nod operons. In addition, NodD represses nodD transcription and this occurs at the divergent and overlapping nodA-nodD promoters. We mutagenised this region with
hydroxylamine
, and by cloning the mutagenised DNA into a vector carrying the lacZ reporter gene downstream from the cloning site identified mutations affecting nodD expression and repression. The resulting plasmids were transferred to R. l. viciae strains containing or lacking nodD. Two classes of promoter mutants were identified: those in which nodD transcription was altered and those in which NodD-dependent repression was altered. The nucleotide (nt) changes in the promoter region were found to be located within two inverted repeat sequences (A2 and A3) which are about 70 bp apart. A2 is important for nodD transcription and A3 (which is upstream from A2) is involved in NodD-dependent repression. The nt sequence at A3 shows some homology to the nod-box region of the nodA promoter. It is proposed that the NodD-dependent repression occurs as a result of NodD binding to both A3 and the nodA nod-box, forming a loop which prevents transcription of nodD from its promoter, A2, which lies between A3 and the nod-box. This model is supported by the observation that there are at least three sites for NodD binding in the nodA-nodD promoter region.
...
PMID:Two inverted repeats in the nodD promoter region are involved in nodD regulation in Rhizobium leguminosarum. 804 29
Conjugal transfer of Agrobacterium tumefaciens Ti plasmids is regulated by quorum sensing via the
transcriptional activator
TraR and the acyl-homoserine lactone Agrobacterium autoinducer (AAI). Unique to this system, the activity of TraR is negatively modulated by an antiactivator called TraM. Analyses from yeast two-hybrid studies suggest that TraM directly interacts with the activator, but the conditions under which these components interact and the region of TraR responsible for this interaction are not known. Induction of traM in a strain in which TraR was activating transcription of a reporter system led to rapid cessation of gene expression. As assessed by a genetic assay that measures AAI-dependent DNA binding, TraM inhibited TraR function before and after the transcription factor had bound to its DNA recognition site. Consistent with this observation, in gel retardation assays, purified TraM abolished the DNA binding activity of TraR in a concentration-dependent manner. Such inhibition occurred independent of the order of addition of the reactants. As assessed by far Western analyses TraM interacts with TraR by directly binding the activator. TraM in its native form interacted with native TraR and also with heat-treated TraR but only when SDS was included with the denatured protein. TraM interacted with TraR on blots prepared with total lysates of cells grown in the presence and absence of AAI. Far Western analysis of N- and C-terminal deletion mutants localized a domain of TraR contributing to TraM binding to the C-terminal portion of the activator protein. Random mutagenesis by
hydroxylamine
treatment and error-prone polymerase chain reaction identified several residues in this region of TraR important for interacting with TraM as well as for transcriptional activation or/and DNA binding. We conclude that TraM inhibits TraR by binding to the activator at a domain within or close to the helix-turn-helix motif located at the C terminus of the protein.
...
PMID:The antiactivator TraM interferes with the autoinducer-dependent binding of TraR to DNA by interacting with the C-terminal region of the quorum-sensing activator. 1071 83
