The RNA polymerase of Chlamydia trachomatis has a flexible sequence requirement at the -10 and -35 boxes of its promoters

Diversity of σ66-Specific Promoters Contributes to Regulation of Developmental Gene Expression in Chlamydia trachomatis

Promoter recognition by the RNA polymerase (RNAP) holoenzyme is a key step in gene regulation. In Chlamydia trachomatis, a medically important obligate intracellular bacterium, σ⁶⁶ allows the RNAP to initiate promoter-specific transcription throughout the chlamydial developmental cycle. Here, we investigated the intrinsic properties of σ⁶⁶-specific promoters with emphasis on their role in the developmental gene expression of C. trachomatis. First, we examined whether promoters that contain a 5'-T(-15)G(-14)-3' (TG) motif upstream from the -10 element appear more often than others in genes that are preferentially expressed during the early, middle, or late stages of the C. trachomatis developmental cycle. We then determined the critical genetic elements that are required for transcription initiation in vitro. We also assessed the activity of promoters in the presence of Scc4, which can directly interact with σ⁶⁶RNAP. Finally, we evaluated the promoter-specific dynamics during C. trachomatis infection using a reporter assay. These results reveal that the TG motif is an important determinant in certain early or late promoters. The TG promoters that have the -35 element are recognized by σ⁶⁶RNAP and Scc4 differently from those lacking the -35 element. Based on these properties, the σ⁶⁶-specific promoters can fall into three classes. Architectural diversity, behavioral plasticity, and the specific interplays between promoters and the σ⁶⁶RNAP likely contribute to developmental gene transcription in C. trachomatis. IMPORTANCE Meticulous promoter elucidation is required to understand the foundations of transcription initiation. However, knowledge of promoter-specific transcription remains limited in C. trachomatis. This work underscores the structural and functional plasticity of σ⁶⁶-specific promoters that are regulated by σ⁶⁶RNAP, as well as their importance in the developmental gene regulation of C. trachomatis.

Chlamydial type III secretion system is encoded on ten operons preceded by sigma 70-like promoter elements

Many gram-negative bacterial pathogens employ type III secretion systems for infectious processes. Chlamydiae are obligate intracellular bacteria that encode a conserved type III secretion system that is likely requisite for growth. Typically, genes encoding type III secretion systems are located in a single locus; however, for chlamydiae these genes are scattered throughout the genome. Little is known regarding the gene regulatory mechanisms for this essential virulence determinant. To facilitate identification of cis-acting transcriptional regulatory elements, the operon structure was determined. This analysis revealed 10 operons that contained 37 genes associated with the type III secretion system. Linkage within these operons suggests a role in type III secretion for each of these genes, including 13 genes encoding proteins with unknown function. The transcriptional start site for each operon was determined. In conjunction with promoter activity assays, this analysis revealed that the type III secretion system operons encode sigma(70)-like promoter elements. Transcriptional initiation by a sigma factor responsible for constitutive gene expression indicates that undefined activators or repressors regulate developmental stage-specific expression of chlamydial type III secretion system genes.

Selective promoter recognition by chlamydial sigma28 holoenzyme

The sigma transcription factor confers the promoter recognition specificity of RNA polymerase (RNAP) in eubacteria. Chlamydia trachomatis has three known sigma factors, sigma(66), sigma(54), and sigma(28). We developed two methods to facilitate the characterization of promoter sequences recognized by C. trachomatis sigma(28) (sigma(28)(Ct)). One involved the arabinose-induced expression of plasmid-encoded sigma(28)(Ct) in a strain of Escherichia coli defective in the sigma(28) structural gene, fliA. The second was an analysis of transcription in vitro with a hybrid holoenzyme reconstituted with E. coli RNAP core and recombinant sigma(28)(Ct). These approaches were used to investigate the interactions of sigma(28)(Ct) with the sigma(28)(Ct)-dependent hctB promoter and selected E. coli sigma(28) (sigma(28)(Ec))-dependent promoters, in parallel, compared with the promoter recognition properties of sigma(28)(EC). Our results indicate that RNAP containing sigma(28)(Ct) has at least three characteristics: (i) it is capable of recognizing some but not all sigma(28)(EC)-dependent promoters; (ii) it can distinguish different promoter structures, preferentially activating promoters with upstream AT-rich sequences; and (iii) it possesses a greater flexibility than sigma(28)(EC) in recognizing variants with different spacing lengths separating the -35 and -10 elements of the core promoter.

Mutational analysis of the Chlamydia trachomatis dnaK promoter defines the optimal -35 promoter element

A long-standing question in the biology of the intracellular bacterium, Chlamydia, has been the structure of the promoter recognized by its RNA polymerase. The 'RNA polymerase sigma subunit paradox' refers to the difficulty reconciling the conservation between the RNA polymerases of Chlamydia and Escherichia coli, especially at the level of the promoter-recognition sigma subunit, with the general lack of homology between chlamydial promoters and the E.coli sigma(70) consensus promoter. While the -10 promoter element appears to be conserved between Chlamydia and E.coli, the structure of the chlamydial -35 promoter element has not been defined. We have investigated the structure of the -35 element of the Chlamydia trachomatis dnaK promoter by measuring the effects of single base pair substitutions on in vitro promoter activity. Most substitutions produced large decreases in promoter activity, which allowed us to define the optimal -35 sequence in the context of the dnaK promoter. We found that the optimal chlamydial -35 promoter sequence is identical to the E.coli sigma(70) consensus -35 promoter element (TTGACA). These results indicate that the optimal promoter specificities of the major form of chlamydial RNA polymerase and E.coli sigma(70) RNA polymerase are in fact highly conserved. A further implication of our results is that many chlamydial promoters have a suboptimal promoter structure. We hypothesize that these chlamydial promoters are intrinsically weak promoters that can be regulated during the chlamydial developmental cycle by additional transcription factors.

Characterization of integration host factor (IHF) binding upstream of the cysteine-rich protein operon (omcAB) promoter of Chlamydia trachomatis LGV serovar L2

Chlamydiae are bacterial parasites that carry out a distinct developmental cycle within host cells; however, the mechanisms by which these organisms regulate stage-specific gene expression are not known. We identified a DNA element located between nucleotide (nt) -135 and -90 upstream from the transcription start point of the late stage-specific CRP operon (omcAB) of Chlamydia trachomatis, to which a protein in extracts of chlamydiae harvested at 23 h after infection binds. A recombinant protein of C. trachomatis open reading frame (ORF) CT267, which is homologous to bacterial integration host factor (IHF) and the heat-unstable nucleoid protein (HU), bound to the same element and produced the same DNase I footprint as the protein in chlamydial extracts. Recombinant ORF CT267 protein bound with high affinity to the DNA element and induced a sharp bend in a DNA fragment containing the binding site, suggesting that ORF CT267 encodes a protein with IHF-like activity, and recombinant protein had a positive effect on in vitro transcription of the CRP operon. IHF-binding activity and IHF protein were detected in extracts of C. trachomatis during the early to intermediate phases of the late stage of the developmental cycle (between 17 and 30 h after infection), but were absent in the extreme late phase of the cycle and in the infectious form of chlamydiae. The presence of an IHF binding site upstream of the CRP operon and the presence of chlamydial IHF-like protein when late stage genes are transcribed suggests that the chlamydial IHF may play a role in stage-specific gene expression.

Identifying regulators of transcription in an obligate intracellular pathogen: a metal-dependent repressor in Chlamydia trachomatis

A prominent feature exhibited by Chlamydia trachomatis growing in an iron-limiting environment is a differential pattern of protein expression. In many bacteria, iron-responsive proteins are regulated at the level of transcription by a family of repressors resembling the Escherichia coli ferric uptake regulator (Fur) protein. Although the chlamydial genome sequencing project did not unveil an obvious Fur homologue, a detailed examination indicated five unassigned open reading frames (ORFs) that would encode products with limited sequence homology to Fur. In this report, each chlamydial ORF was engineered in E. coli, and recombinant proteins were examined for functional characteristics resembling Fur. A Fur-specific polyclonal antiserum revealed that the protein encoded by ORF CT296 shares antigenic cross-recognition. Moreover, this protein forms dimers in solution in a fashion analogous to E. coli Fur. Further studies confirmed that the product of ORF CT296 is able to (i) complement Fur activity in a mutant strain of E. coli; and (ii) specifically bind to a 19 bp consensus sequence found in promoters of iron-regulated genes in E. coli. We propose a designation of dcrA (divalent cation-dependent regulator A) for ORF CT296, which encodes a protein distantly related to E. coli Fur. DcrA represents the first repressor described for this obligate intracellular bacterium.

Cloning and characterization of ribonucleotide reductase from Chlamydia trachomatis

In all organisms the deoxyribonucleotide precursors required for DNA synthesis are synthesized from ribonucleotides, a reaction catalyzed by ribonucleotide reductase. In a previous study we showed that Chlamydia trachomatis growth was inhibited by hydroxyurea, an inhibitor of ribonucleotide reductase, and a mutant resistant to the cytotoxic effects of the drug was isolated. Here we report the cloning, expression, and purification of the R1 and R2 subunits of the C. trachomatis ribonucleotide reductase. In comparison with other ribonucleotide reductases, the primary sequence of protein R1 has an extended amino terminus, and the R2 protein has a phenylalanine where the essential tyrosine is normally located. Despite its unusual primary structure, the recombinant enzyme catalyzes the reduction of CDP to dCDP. Results from deletion mutagenesis experiments indicate that while the extended amino terminus of the R1 protein is not required for enzyme activity, it is needed for allosteric inhibition mediated by dATP. Results with site-directed mutants of protein R2 suggest that the essential tyrosine is situated two amino acids downstream of its normal location. Finally, Western blot analysis show that the hydroxyurea-resistant mutant C. trachomatis isolate overexpresses both subunits of ribonucleotide reductase. At the genetic level, compared with wild type C. trachomatis, the resistant isolate has a single base mutation just upstream of the ATG start codon of the R2 protein. The possibility that this mutation affects translational efficiency is discussed.

Identification and mapping of sigma-54 promoters in Chlamydia trachomatis

The first sigma(54) promoters in Chlamydia trachomatis L2 were mapped upstream of hypothetical proteins CT652.1 and CT683. Comparative genomics indicated that these sigma(54) promoters and potential upstream activation binding sites are conserved in orthologous C. trachomatis D, C. trachomatis mouse pneumonitis strain, and Chlamydia pneumoniae (CWL029 and AR39) genes.

Identification and characterization of promoters regulating tuf expression in Chlamydia trachomatis serovar F

Gene expression in the obligate intracellular bacterium Chlamydia trachomatis ranges from nil in the infectious EB form to high in the dividing RB form. Little is known about the mechanisms of gene regulation in chlamydiae and only a few promoter sequences have been characterized. The purpose of our study was to examine the expression of a cluster of genes that are required for translation in C. trachomatis serovar F: infA (encoding Initiation Factor 1), tRNA(Thr), tuf (encoding Elongation Factor Tu), and tRNA(Trp). Primer extension analysis indicated that tuf is expressed in three different mRNAs. Putative promoter sequences for these transcripts were defined as P1 (upstream of tRNA(Thr)), P2 (within infA) and P3 (upstream of infA). Quantitative RT-PCR analysis revealed that P1 transcripts were most abundant at 16 h postinfection (pi), whereas P2 transcripts predominated at 24 h pi. P3 was active at all times pi; however, transcription terminated upstream of tuf at early times pi and continued through tuf at later times. P1 and P3 were active in Escherichia coli, as assessed by CAT expression in promoter-fusion vectors and a chlamydial in vitro transcription system. Site-specific mutagenesis confirmed the importance of the -35 and -10 hexamers in the P1 and P3 promoters. P2 was weakly active in E. coli and inactive in the in vitro transcription system, indicating either that the P2 transcript is processed from a longer transcript or that P2 expression requires a sigma or transcription factor which is not present in E. coli or the in vitro transcription system. Our data suggest that multiple processes play a role in the regulation of tuf gene expression during the developmental cycle.

Mutational analysis of the Chlamydia trachomatis rRNA P1 promoter defines four regions important for transcription in vitro

We have characterized the Chlamydia trachomatis ribosomal promoter, rRNA P1, by measuring the effect of substitutions and deletions on in vitro transcription with partially purified C. trachomatis RNA polymerase. Our analyses indicate that rRNA P1 contains potential -10 and -35 elements, analogous to Escherichia coli promoters recognized by E-sigma70. We identified a novel AT-rich region immediately downstream of the -35 region. The effect of this region was specific for C. trachomatis RNA polymerase and strongly attenuated by single G or C substitutions. Upstream of the -35 region was an AT-rich sequence that enhanced transcription by C. trachomatis and E. coli RNA polymerases. We propose that this region functions as an UP element.

Identification of sequences necessary for transcription in vitro from the Chlamydia trachomatis rRNA P1 promoter

Chlamydia trachomatis RNA polymerase was partially purified by heparin-agarose chromatography and used in conjunction with a plasmid-borne G-less cassette template to characterize the C. trachomatis rRNA P1 promoter in vitro. Stepwise mutational analysis revealed that sequences in the -10, -25, and -35 regions are necessary for promoter activity, but no sequence upstream of position -40 is required. Partially purified C. trachomatis RNA polymerase and purified Escherichia coli holoenzyme exhibited some differences in promoter specificity.

Mutagenesis of the P2 promoter of the major outer membrane protein gene of Chlamydia trachomatis

On the basis of position from the transcription start site, the P2 promoter of the gene encoding the major outer membrane protein (ompA) of Chlamydia trachomatis consists of a -35 hexamer region of -42 aaaaaga TATACAaa -28 and an unusual, GC-rich -10 hexamer region of -13 tTATCGCt -6. The P2 promoter was analyzed by in vitro transcription of templates containing deletions and site-specific mutations. The 5' extent of P2 was located at bp -42. Replacement of wild-type sequence with two G's at positions -41 and 40, -35 and 34, and -29 and 28 resulted in severely decreased transcription. Additionally, the spacing between the -35 and -10 hexamers could not be shortened without adversely affecting in vitro activity. Substitution of G at position -13, -10, -7, or -6 had little or no effect on transcription, whereas substitution of G at -11 or -12 significantly decreased promoter strength. Triple point mutations which changed the -10 hexamer from TATCGC to TATTAT,TATATT, or TATAAT had little effect on promoter activity. Unlike the partially purified C. trachomatis sigma66-RNA polymerase used in this study, purified Escherichia coli sigma70-RNA polymerase did not recognize the wild-type P2 promoter. Mutant P2 templates with -10 hexamers that resembled the consensus recognition site were transcribed by E. coli holoenzyme in vitro, suggesting that C. trachomatis sigma66-RNA polymerase has special promoter recognition properties not found in E. coli sigma70-holoenzyme.

Transcriptional regulation in the Chlamydia trachomatis pCT plasmid

We have analyzed transcriptional regulation of the chlamydial plasmid pCT. Transcription of a full-length 2.9-kb ORF1-ORF2 mRNA is likely to be regulated by the sigma 66 transcription factor which recognizes the TATAAT and TNGNCA sequences at the -10 and -35 DNA regions, respectively. RNA synthesis starts 39 nucleotides (nt) upstream from the ATG start codon of ORF1 and terminates within the downstream ORF3 DNA region. A 2.8-kb transcript transverses the ORF3-6 DNA region, while two transcripts of 2.2 and 1.9 kb cover the ORF4-6 DNA region. These mRNAs overlap two abundant transcripts which regulate the expression of the ORF3 and ORF4 genes. The accumulation of transcripts associated with these ORFs is likely to be regulated at the level of RNA synthesis by an unknown sigma factor which could select the RTTTAAA and TTYTTR sequences located at the -10 and -35 DNA regions, respectively. This new promoter consensus sequence could be unique to the gene expression machinery of Chlamydiae.

Identification of the Chlamydia trachomatis RecA-encoding gene

DNA sequencing of the major outer membrane protein (MOMP) gene (omp1) from Chlamydia trachomatis shows that some strains have a mosaic structure suggestive of homologous recombination between two distinct omp1 genes. On the basis of this conjecture, we attempted to clone by complementation and sequence the chlamydial recA homolog from C. trachomatis serovar L2. Chlamydial genomic DNA was partially restricted with XbaI, and fragments of 2 to 4 kb were ligated into pUC19. The recombinant plasmid was electroporated into Escherichia coli HB101 (RecA-), and colonies were selected in the presence of methyl methanesulfonate (MMS). A 2.1-kb fragment of C. trachomatis DNA in pUC19 conferred relative MMS resistance to E. coli HB101. When this recombinant plasmid (pX203) was electroporated into E. coli JC14604 (RecA- lacZ), lac+ recombinants were isolated. Rabbit polyclonal antibodies produced to purified E. coli RecA were immunoreactive in an immunoblot assay with a 35-kDa antigen in RecA- strains of E. coli transformed with pX203. The 2.1-kb insert was cycle sequenced by the dideoxy chain termination method. An open reading frame of 1,056 bp encoding 352 amino acids that had 44% sequence identity with E. coli RecA was identified. The finding of a recA homolog in C. trachomatis suggests that homologous recombination may occur in this organism. The cloned C. trachomatis RecA-encoding gene will be useful for the construction of a recA mutant once a gene transfer system is developed for chlamydiae.

A strand-specific endonucleolytic activity with DNA site preference for cleavage in Chlamydia trachomatis

Endonucleolytic activity was detected in high-salt extracts of Chlamydia trachomatis cell lysates. This nucleolytic activity showed specificity for one strand of a PCR fragment containing the strong chlamydial promoter that regulates synthesis of two short plasmid-specified RNAs. Strand specificity was also observed with supercoiled DNA containing the same region; once again, the same strand was cleaved. The sensitive strand is the nontemplate strand for two short transcripts which initiate at the same nucleotide. Alignment of sequences on either side of the nick sites revealed a consensus which may be required for recognition of the enzymatic activity.