Interaction of negative (CytT) and positive (cAMP-CRP) regulation in the promoter region of the uridine phosphorylase (udp) gene in Escherichia coli K-12

Interaction of negative (CytR) and positive (cAMP-CRP) control in the promoter region of the uridine phosphorylase (udp) gene of Escherichia coli has been studied by using udp-lac operon fusions in which the structural lacZ gene is expressed from the wild type promoter udpP+ or from mutant promoters udpP1 and udpP18. The specific activity of beta-galactosidase was examined in these fusions in cytR+ and cytR- backgrounds after introduction of specific mutations in crp locus, crp* and crp(a) altering interaction of CRP protein with catabolite-sensitive promoters. The data obtained using crp* mutation confirm the proposed model of the udp gene regulation, according to which CytR repressor protein interferes with CRP binding site in the promoter-operator region of the udp gene and thereby prevents the positive action of cAMP-CRP complex on the udp expression. Additional data in favor of this model were obtained using crp(a) mutation which most probably alters the structure of CRP protein in such a way that it exhibits more high affinity to the udp promoter, as compared to the CytR repressor protein. Indeed, taken by itself, the crp(a) mutation did not lead to any increase in the expression of udpP+-lac fusion under the conditions of cAMP limitation (on glucose-grown cells), in spite of whether or not the CytR repressor was present. However, when combined with the ptsG mutation or when cells were grown on succinate medium, complete constitutive expression of udpP+-lac fusion is observed, even in the presence of the cytR gene product. The effect of the crp(a) mutation was virtually the same in strains harboring udpP1-lac fusion. These data are in accordance with suggestion that udpP1 is a mutation in the site of the promoter-operator region that responds to the cytR gene product, while the corresponding binding site for CRP protein is still unaltered in this mutant. On the other hand, the crp(a) mutation causes only slight alteration in the expression of udpP18-lac fusion, providing additional evidence that udpP18 mutation seems to comprise a modification of the promoter-operator region, where binding sites for CRP and CytR proteins overlap.     

Cloning the uridine phosphorylase (udp) gene of Escherichia coli and its expression in recombinant plasmids

On the basis of Escherichia coli DNA and vectors pBR322, pUC19, hybrid plasmids restoring Udp+ phenotype in the E. coli deletion (delta udp) mutant have been obtained. The udp gene is carried by a 8 kb PstI fragment (on the pUD2) and by a smaller 2.87 kb PstI-SalGI fragment from the PstI fragment (pUD7). The uridine phosphorylase level was 30 times higher in the cells containing hybrid plasmid as compared to the strain with chromosomal location of the udp gene. On the other hand, the measurements of uridine phosphorylase activity in the cytR- and cya- background indicate that expression of the cloned udp gene escapes partially negative control of the CytR repressor and positive control of cAMP--CRP complex. These data suggest that the 2.87 kb PstI--SalGI-fragment contains the intact udp gene which is transcribed from its own promoter. Increase in the activity of beta-galactosidase encoded by udp-lacZ fusion has been observed in the presence of pUD2 or pUD7, which was suggested to be the consequence of titration of CytR repressor molecules in the operator region of the cloned udp.     

A novel function of the cAMP-CRP complex in Escherichia coli: cAMP-CRP functions as an adaptor for the CytR repressor in the deo operon

Unlike classical bacterial repressors, the CytR repressor of Escherichia coli cannot independently regulate gene expression. Here we show that CytR binding to the deoP2 promoter relies on interaction with the master gene regulatory protein, CRP, and, furthermore, that cAMP-CRP and CytR bind co-operatively to deoP2. Using mutant promoters we show that tandem, properly spaced DNA-bound cAMP-CRP complexes are required for this co-operative binding. These data suggest that CytR forms a bridge between tandem cAMP-CRP complexes, and that cAMP-CRP functions as an adaptor for CytR. The implications of this new version of negative control in E. coli on bacterial gene expression and on combinatorial gene regulation in higher organisms are discussed.     

Promoter-like mutants with increased expression of the Escherichia coli uridine phosphorylase structural gene.

From an Escherichia coli K-12 strain lacking adenylate cyclase (cya) and cyclic AMP receptor protein (crp), two mutants were isolated that synthesize uridine phosphorylase constitutively. The mutations differ from one another and also from a wild type in the maximum rate of uridine phosphorylase synthesis. They have constitutive expression of the uridine phosphorylase gene (udp) in the presence of repressor protein coded by the cytR regulatory gene and decrease the sensitivity of the udp gene simultaneously with catabolite repression. Both mutations cause a high level of udp expression whether they are in a cya crp or in a cya+ crp+ background. Another mutation (udpP1) isolated previously alters the response of udp gene to the ctyR repressor and produces a higher constitutive level of uridine phosphorylase in a cytR+ than in a cytR background when bacteria are grown in glucose. The synthesis of uridine phosphorylase in this mutant is dependent on an intact cyclic AMP-cyclic AMP receptor protein complex. All mutations studied are cis-acting and extremely closely linked to the udp structural gene, and appear to affect the uridine phosphorylase promoter-operator region. The data obtained are in accordance with a suggestion that the cytR repressor protein normally asserts its function by preventing the positive action of cyclic AMP-cyclic AMP receptor protein complex.     

The cyclic AMP (cAMP)-cAMP receptor protein complex functions both as an activator and as a corepressor at the tsx-p2 promoter of Escherichia coli K-12.

The tsx-p2 promoter is one of at least seven Escherichia coli promoters that are activated by the cyclic AMP (cAMP)-cAMP receptor protein (CRP) complex and negatively regulated by the CytR repressor. DNase I footprinting assays were used to study the interactions of these regulatory proteins with the tsx-p2 promoter region and to characterize tsx-p2 regulatory mutants exhibiting an altered response to CytR. We show that the cAMP-CRP activator complex recognizes two sites in tsx-p2 that are separated by 33 bp: a high-affinity site (CRP-1) overlaps the -35 region, and a low-affinity site (CRP-2) is centered around position -74 bp. The CytR repressor protects a DNA segment that is located between the two CRP sites and partially overlaps the CRP-1 target. In combination, the cAMP-CRP and CytR proteins bind cooperatively to tsx-p2, and the nucleoprotein complex formed covers a region of 78 bp extending from the CRP-2 site close to the -10 region. The inducer for the CytR repressor, cytidine, does not prevent in vitro DNA binding of CytR, but releases the repressor from the nucleoprotein complex and leaves the cAMP-CRP activator bound to its two DNA targets. Thus, cytidine interferes with the cooperative DNA binding of cAMP-CRP and CytR to tsx-p2. We characterized four tsx-p2 mutants exhibiting a reduced response to CytR; three carried mutations in the CRP-2 site, and one carried a mutation in the region between CRP-1 and the -10 sequence. Formation of the cAMP-CRP-CytR DNA nucleoprotein complex in vitro was perturbed in each mutant. These data indicate that the CytR repressor relies on the presence of the cAMP-CRP activator complex to regulate tsx-p2 promoter activity and that the formation of an active repression complex requires the combined interactions of cAMP-CRP and CytR at tsx-p2.     

Multiple conformations of the cytidine repressor DNA-binding domain coalesce to one upon recognition of a specific DNA surface

The cytidine repressor (CytR) is a member of the LacR family of bacterial repressors with distinct functional features. The Escherichia coli CytR regulon comprises nine operons whose palindromic operators vary in both sequence and, most significantly, spacing between the recognition half-sites. This suggests a strong likelihood that protein folding would be coupled to DNA binding as a mechanism to accommodate the variety of different operator architectures to which CytR is targeted. Such coupling is a common feature of sequence-specific DNA-binding proteins, including the LacR family repressors; however, there are no significant structural rearrangements upon DNA binding within the three-helix DNA-binding domains (DBDs) studied to date. We used nuclear magnetic resonance (NMR) spectroscopy to characterize the CytR DBD free in solution and to determine the high-resolution structure of a CytR DBD monomer bound specifically to one DNA half-site of the uridine phosphorylase (udp) operator. We find that the free DBD populates multiple distinct conformations distinguished by up to four sets of NMR peaks per residue. This structural heterogeneity is previously unknown in the LacR family. These stable structures coalesce into a single, more stable udp-bound form that features a three-helix bundle containing a canonical helix-turn-helix motif. However, this structure differs from all other LacR family members whose structures are known with regard to the packing of the helices and consequently their relative orientations. Aspects of CytR activity are unique among repressors; we identify here structural properties that are also distinct and that might underlie the different functional properties.     

Nucleotide sequence of the CytR regulatory gene of E. coli K-12.

We have determined the nucleotide sequence of the cytR gene, which codes for the Cyt repressor (CytR). The coding region consists of 1023 or 1029 bp. The subunits of CytR are thus predicted to consist of 341 or 343 residues. It is shown that the N-terminal segment of the polypeptide is structurally similar to the DNA-binding region of known DNA-binding proteins. In addition, there exists an exceptionally high amino acid sequence homology between CytR and the Gal repressor, indicating a common origin of evolution.