Persistent chlamydial envelope antigens in antibiotic-exposed infected cells trigger neutrophil chemotaxis.

An in vitro coculture model system was used to explore conditions that trigger neutrophil chemotaxis to Chlamydia trachomatis infected human epithelial cells (HEC-1B). Polarized HEC-1B monolayers growing on extracellular matrix (ECM) were infected with C. trachomatis serovar E. By 36 h, coincident with the secretion of chlamydial lipopolysaccharide and major outer membrane protein to the surfaces of infected cells, human polymorphonuclear neutrophils (PMNL) loaded with azithromycin migrated through the ECM and infiltrated the HEC-1B monolayer. Bioreactive azithromycin was delivered by the chemotactic PMNL to infected epithelial cells in concentrations sufficient to kill intracellular chlamydiae. However, residual chlamydial envelopes persisted for 4 weeks, and PMNL chemotaxis was triggered to epithelial cells containing residual envelopes. Infected endometrial cells demonstrated up-regulation of ENA-78 and GCP-2 chemokine mRNA. Thus, despite appropriate antimicrobial therapy, residual chlamydial envelope antigens may persist in infected tissues of culture-negative women and provide one source for sustained inflammation.

Allosteric mechanism of induction of CytR-regulated gene expression. Cytr repressor-cytidine interaction.

Transcription from cistrons of the Escherichia coli CytR regulon is activated by E. coli cAMP receptor protein (CRP) and repressed by a multiprotein complex composed of CRP and CytR. De-repression results when CytR binds cytidine. CytR is a homodimer and a LacI family member. A central question for all LacI family proteins concerns the allosteric mechanism that couples ligand binding to the protein-DNA and protein-protein interactions that regulate transcription. To explore this mechanism for CytR, we analyzed nucleoside binding in vitro and its coupling to cooperative CytR binding to operator DNA. Analysis of the thermodynamic linkage between sequential cytidine binding to dimeric CytR and cooperative binding of CytR to deoP2 indicates that de-repression results from just one of the two cytidine binding steps. To test this conclusion in vivo, CytR mutants that have wild-type repressor function but are cytidine induction-deficient (CID) were identified. Each has a substitution for Asp281 or neighboring residue. CID CytR281N was found to bind cytidine with three orders of magnitude lower affinity than wild-type CytR. Other CytR mutants that do not exhibit the CID phenotype were found to bind cytidine with affinity similar to wild-type CytR. The rate of transcription regulated by heterodimeric CytR composed of one CytR281N and one wild-type subunit was compared with that regulated by wild-type CytR under inducing conditions. The data support the conclusion that the first cytidine binding step alone is sufficient to induce.

Characterization of cytR mutations that influence oligomerization of mutant repressor subunits.

In Escherichia coli, the transport and catabolism of nucleosides require expression of the genes composing the CytR regulon. The role of the CytR repressor in transcriptional regulation has been examined through a study of mutant CytR proteins. Two important and interrelated CytR mutants are encoded by cytR delta M149, a dominant negative allele, and cytRC289R. Studies with CytR delta M149 indicated that the native, repression-competent CytR protein is multimeric while the CytR amino acid substitution C-289-->R has been proposed to affect subunit oligomerization on the basis of its ability to suppress the transdominance of CytR delta M149. The present study identifies other CytR amino acid residues proximal to Cys-289 that may also participate in normal subunit oligomerization. Mutations in these CytR residues, cytRA307P, cytRM308R, and cytRL309P, encoded inactive repressors in a CytR- background and, when combined with cytR delta M149, yielded hybrid repressors that were recessive in a CytR+ genetic background. Because the stability and solubility observed for the new, mutant CytR proteins and the wild-type CytR protein were indistinguishable, these residue replacements, like the C-289-->R substitution, are envisaged as being located at the subunit interface and thus suppress the CytR delta M149 transdominance by blocking efficient and stable assembly of wild-type and hybrid CytR subunits. The assignment of CytR amino acids to a protein region involved in subunit association is also consistent with the observations that these CytR amino acids are roughly colinear with regions of the LacI repressor that influence monomer-dimer association and would be surface located by alignment to the E. coli galactose-binding protein crystal structure.

Amino acid substitutions in the CytR repressor which alter its capacity to regulate gene expression.

In Escherichia coli, transport and catabolism of nucleosides require expression of the genes composing the CytR regulon. Transcription initiation of cistrons in this gene family is activated by cyclic AMP-catabolite activator protein (cAMP-CAP), repressed by the CytR protein, and induced by cytidine. A random proofreading mutagenesis procedure and a genetic screen using udp-lac fusions have allowed the identification of distinct regions of the 341-amino-acid CytR polypeptide that are critical for repression of gene expression and response to induction. Determination of the ability of various CytR mutants to control gene expression in vivo indicated that the intrinsic affinity of the CytR protein for operator DNA is gene specific and that efficient repression of transcription by wild-type CytR is dependent on the interaction of CytR with cAMP-CAP. CytR mutants that were cytidine induction defective (CID) were characterized; these mutant proteins had only Asp-281 replaced. Data obtained with cytR delta M149, a dominant negative allele, indicated that the native CytR repressor is an oligomeric protein. Representative cytR mutations were combined with cytR delta M149, and the resulting hybrid repressors were tested for transdominance in a CytR+ E. coli strain. Amino acid substitutions A209E and C289Y suppressed the transdominance of CytR delta M149, suggesting that these replacements alter the normal protein contacts involved in repressor subunit-subunit association. In contrast, amino acid substitutions located in the N-terminal portion of the CytR protein had no effect on the transdominance of CytR delta M149. The results from this study suggest that the CytR repressor is an oligomeric, allosteric protein in which conformational changes are required for repression and derepression.

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.

Identification of the Escherichia coli deoR and cytR gene products.

The protein products encoded by the Escherichia coli deoR and cytR structural genes have been identified based on results obtained from E. coli maxicells harboring (i) recombinant plasmids carrying wild-type deoR and cytR genes, (ii) deletion derivatives of the deoR+ and cytR+ plasmids, (iii) plasmids containing site-specific mutations in the deoR and cytR structural genes, and (iv) plasmids which have transposon Tn1000 inserted into the deoR and cytR structural genes. Analysis of the protein profiles obtained from all the maxicell experiments demonstrated that the deoR gene encodes a protein with a subunit molecular weight of 30,500 and that the product of the cytR gene is a protein with a subunit molecular weight of 37,000.

Studies on deo operon regulation in Escherichia coli: cloning and expression of the cytR structural gene.

The structural gene that encodes one repressor (the cytR-encoded repressor) of the Escherichia coli deo operon has been cloned from a lambda dmet transducing phage into the multicopy plasmid pBR322 by selecting for ApR, Lac- transformants of E. coli SS110(delta lac, cytR, tsx::lac). Restriction maps for the cytR+ plasmids have been generated and the position of the cytR gene on the cloned insert of these plasmids has been determined through deletion analysis. Results from maxicell experiments employing pCB001 and its cytR- derivatives suggest that the cytR gene encodes a protein with a subunit Mr of 37 000. In contrast to the complete repression of the deo operon obtained when deoR+ plasmids were introduced into E. coli SS201 (deoR, cytR), transformation of this DeoR-, CytR- strain with any of the cytR+ plasmids yields only clones which have phenotypes and Deo enzyme levels characteristic of a DeoR- single mutant. The data presented in this study are consistent with the interpretation that, in E. coli, the deoR-encoded repressor controls deo operon transcription initiating from both deo promoter-operator sites, PO1 and PO2. In contrast, the cytR-encoded repressor regulates deo operon expression only through deo promoter-operator site PO2.