Purification and partial characterization of the DNA-dependent RNA polymerase from Rickettsia prowazekii

Establishment of an in vitro RNA polymerase transcription system: a new tool to study transcriptional activation in Borrelia burgdorferi

The Lyme disease spirochete Borrelia burgdorferi exhibits dramatic changes in gene expression as it transits between its tick vector and vertebrate host. A major hurdle to understanding the mechanisms underlying gene regulation in B. burgdorferi has been the lack of a functional assay to test how gene regulatory proteins and sigma factors interact with RNA polymerase to direct transcription. To gain mechanistic insight into transcriptional control in B. burgdorferi, and address sigma factor function and specificity, we developed an in vitro transcription assay using the B. burgdorferi RNA polymerase holoenzyme. We established reaction conditions for maximal RNA polymerase activity by optimizing pH, temperature, and the requirement for divalent metals. Using this assay system, we analyzed the promoter specificity of the housekeeping sigma factor RpoD to promoters encoding previously identified RpoD consensus sequences in B. burgdorferi. Collectively, this study established an in vitro transcription assay that revealed RpoD-dependent promoter selectivity by RNA polymerase and the requirement of specific metal cofactors for maximal RNA polymerase activity. The establishment of this functional assay will facilitate molecular and biochemical studies on how gene regulatory proteins and sigma factors exert control of gene expression in B. burgdorferi required for the completion of its enzootic cycle.

Isolation and characterization of Ehrlichia chaffeensis RNA polymerase and its use in evaluating p28 outer membrane protein gene promoters

Background

Ehrlichia chaffeensis is a tick-transmitted rickettsial pathogen responsible for an important emerging disease, human monocytic ehrlichiosis. To date how E. chaffeensis and many related tick-borne rickettsial pathogens adapt and persist in vertebrate and tick hosts remain largely unknown. In recent studies, we demonstrated significant host-specific differences in protein expression in E. chaffeensis originating from its tick and vertebrate host cells. The adaptive response of the pathogen to different host environments entails switch of gene expression regulated at the level of transcription, possibly by altering RNA polymerase activity.

Results

In an effort to understand the molecular basis of pathogen gene expression differences, we isolated native E. chaffeensis RNA polymerase using a heparin-agarose purification method and developed an in vitro transcription system to map promoter regions of two differentially expressed genes of the p28 outer membrane protein locus, p28-Omp14 and p28-Omp19. We also prepared a recombinant protein of E. chaffeensis σ70 homologue and used it for in vitro promoter analysis studies. The possible role of one or more proteins presents in E. chaffeensis lysates in binding to the promoter segments and on the modulation of in vitro transcription was also assessed.

Conclusions

Our experiments demonstrated that both the native and recombinant proteins are functional and have similar enzyme properties in driving the transcription from E. chaffeensis promoters. This is the first report of the functional characterization of E. chaffeensis RNA polymerase and in vitro mapping of the pathogen promoters using the enzyme. This study marks the beginning to broadly characterize the mechanisms controlling the transcription by Anaplasmataceae pathogens.

Analysis of convergent gene transcripts in the obligate intracellular bacterium Rickettsia prowazekii

Termination of transcription is an important component of bacterial gene expression. However, little is known concerning this process in the obligate intracellular pathogen and model for reductive evolution, Rickettsia prowazekii. To assess transcriptional termination in this bacterium, transcripts of convergent gene pairs, some containing predicted intrinsic terminators, were analyzed. These analyses revealed that, rather than terminating at a specific site within the intervening region between the convergent genes, most of the transcripts demonstrated either a lack of termination within this region, which generated antisense RNA, or a putative non-site-specific termination that occurred throughout the intervening sequence. Transcripts terminating at predicted intrinsic terminators, as well as at a putative Rho-dependant terminator, were also examined and found to vary based on the rickettsial host environment. These results suggest that transcriptional termination, or lack thereof, plays a role in rickettsial gene regulation.

A fluorescence-based assay for multisubunit DNA-dependent RNA polymerases

The properties of DNA-dependent RNA polymerases have been studied since the 1960s, but considerable interest in probing RNA polymerase structure/function relationships, the roles of different classes of RNA polymerases in cellular processes, and the feasibility of using RNA polymerases as drug targets still exists. Historically, RNA polymerase activity has been measured by the incorporation into RNA of radioisotopically labeled nucleotides. We report the development of an assay for RNA polymerase activity that uses the dye RiboGreen to detect transcripts by fluorescence and is thus free of the expense, short shelf life, and high handling costs of radioisotopes. The method is relatively quick and can be performed entirely in microplate format, allowing for the processing of dozens to hundreds of samples in parallel. It should thus be well-suited to use in drug screening and analysis of chromatographic fractions. As RiboGreen fluorescence is enhanced by binding to either RNA or DNA, template DNA must be removed by DNase digestion and ultrafiltration between the transcription and the detection phases of the assay procedure. Although RiboGreen fluorescence is sensitive to changes in solvent environment, solvent exchange in the ultrafiltration step allows comparison of transcription levels even under extremes of salt, pH, etc.

Rickettsia prowazekii transports UMP and GMP, but not CMP, as building blocks for RNA synthesis

Rickettsia prowazekii, the etiological agent of epidemic typhus, is an obligate intracellular bacterium and is apparently unable to synthesize ribonucleotides de novo. Here, we show that as an alternative, isolated, purified R. prowazekii organisms transported exogenous uridyl- and guanylribonucleotides and incorporated these labeled precursors into their RNA in a rifampin-sensitive manner. Transport systems for nucleotides, which we have shown previously and show here are present in rickettsiae, have never been reported in free-living bacteria, and the usual nucleobase and nucleoside transport systems are absent in rickettsiae. There was a clear preference for the monophosphate form of ribonucleotides as the transported substrate. In contrast, rickettsiae did not transport cytidylribonucleotides. The source of rickettsial CTP appears to be the transport of UMP followed by its phosphorylation and the amination of intrarickettsial UTP to CTP by CTP synthetase. A complete schema of nucleotide metabolism in rickettsiae is presented that is based on a combination of biochemical, physiological, and genetic information.

Witnessing the evolution of transcription in mitochondria: the mitochondrial genome of the primitive brown alga Pylaiella littoralis (L.) Kjellm. Encodes a T7-like RNA polymerase

A region of the mitochondrial genome of the primitive brown alga Pylaiella littoralis containing a plasmid-like insert which contains a transcribed T7-phage-type RNA polymerase gene is described. This is a first report of a phage-type RNA polymerase gene integrated in a mitochondrial genome. As the mitochondrial genome of this alga also contains sigma-70 proteobacterial promoter regions, i.e. traces of the ancestral alpha2betabeta'sigma-70 proteobacterial RNA polymerase, this genome witnesses two types of RNA polymerases. As such the mitochondrial genome of P. littoralis represents a unique stage in the evolution of transcription in mitochondria, which contrasts with that of the primitive protist Reclinomonas americana, which still retains the ancestral alpha2betabeta'sigma-70 proteobacterial RNA polymerase genes, and with animals, land plants and fungi, which use phage-type polymerases.

Transcriptional characterization of the Rickettsia prowazekii major macromolecular synthesis operon

Recent studies have demonstrated that Rickettsia prowazekii can regulate transcription of selected genes at the level of initiation. However, little information concerning the existence of operons and coordinate gene regulation in this obligate intracellular parasitic bacterium is available. To address these issues, we have focused on the rpoD gene linkage group (greA-open reading frame 23 [ORF23]-dnaG-rpoD), which includes the rickettsial analog (ORF23-dnaG-rpoD) of the major macromolecular synthesis operon (MMSO). The rickettsial MMSO consists of an ORF coding for a protein of unknown function the structural genes for DNA primase (dnaG) and the major sigma factor of RNA polymerase (rpoD). RNase protection assays (RPA) were used to determine if these genes are organized into an operon controlled by multiple promoters and the quantities of transcripts produced by these genes relative to each other. RPA with a probe spanning the 270-base greA-ORF23 intervening region identified a putative transcriptional promoter within the intervening sequence. Multiple RPA probes spanning the next 4,041 bases of the linkage group demonstrated the presence of a continuous transcript and thus the existence of an operon. A probe spanning the dnaG-rpoD region revealed that two additional mRNA fragments were also protected, which enabled us to identify additional putative promoters for rpoD within dnaG. Primer extension determined that the 5' ends of the three transcripts consist separately of adenine (located 227 bases upstream of ORF23) and uracil and adenine (located 336 and 250 bases upstream of rpoD, respectively). Quantitation of transcripts produced by the three ORFs determined the relative amounts of transcripts (ORF23 to dnaG to rpoD) to be 1:2.7:5.1.

Rickettsia prowazekii sigma factor sigma 73 can be overexpressed in Escherichia coli and promotes RNA polymerase binding and transcription

The sigma factor sigma 73 of the obligate intracytoplasmic bacterium Rickettsia prowazekii was overexpressed and purified from Escherichia coli. The rickettsial rpoD gene encoding sigma 73 was cloned into a Ndel-BamHI-cleaved pET-15b vector under control of T7 transcription and translation signals. The recombinant plasmid encoded a 75 kDa fusion protein that was overproduced in E. coli BL21(DE3) and purified from inclusion bodies after solubilization with guanidine hydrochloride and using His. Bind metal chelation resin. The N-terminal His. Tag sequence of the 75 kDa fusion protein was removed by thrombin treatment to obtain R. prowazekii sigma 73T. The R. prowazekii sigma 73T as well as the 75 kDa fusion protein had the ability to bind to core DNA-dependent RNA polymerase of both R. prowazekii and E. coli and to stimulate their interaction with a rickettsial promoter.

Transcriptional analysis of the 16s rRNA gene in Rickettsia prowazekii

The control of rRNA synthesis in the etiological agent of epidemic typhus, Rickettsia prowazekii, a slowly growing obligate intracytoplasmic bacterium, was investigated. Transcription of the rickettsial 16S rRNA gene (rrs), of which there is only a single copy, was controlled by a single promoter region, and the site for the initiation of transcription (base A) was found 117 bp upstream of the rrs coding region for the mature product. The promoter region contained an Escherichia coli promoter-like sequence, TTGACA-N17-TATAAC, centered 139 bp upstream of the coding region for the mature product. To investigate whether transcription of the rickettsial rrs responds to amino acid starvation conditions, total RNA was isolated from R. prowazekii-infected mouse L929 cells with or without methionine starvation. The level of newly synthesized 16S rRNA precursors in R. prowazekii, as analyzed by ribonuclease protection assays, decreased significantly after methionine starvation for 6 h and then recovered within 12 h after the addition of methionine. The chemical half-lives of the 16S rRNA precursors in the methionine-starved rickettsiae did not differ significantly from those in the normal rickettsiae. These results suggest that R. prowazekii regulates transcription of the rrs in response to amino acid starvation conditions.

Instability of Rickettsia prowazekii RNA polymerase-promoter complexes

The Rickettsia prowazekii sigma factor was overexpressed, purified, and used to reconstitute RNA polymerase holoenzyme species. R. prowazekii RNA polymerase-promoter complexes were unstable and remained dissociable and heparin sensitive under conditions in which the corresponding Escherichia coli complexes were not. The R. prowazekii core played the major role in determining heparin sensitivity.

The molar ratio of sigma 73 to core polymerase in the obligate intracellular bacterium, Rickettsia prowazekii

In the obligate intracellular parasitic bacterium, Rickettsia prowazekii, the molar ratio of sigma 73 to core RNA polymerase, that is, the degree of saturation of the core polymerase by the catalytically active sigma factor, was very low. This ratio was determined from the radioactivity in rickettsial RNA polymerase immunoprecipitated from crude extracts of infected L929 cells in which the parasite was exponentially growing. If we assume that, as is true for the sigma subunit, in R. prowazekii and Escherichia coli the beta', and beta subunits of the RNA polymerase have similar methionine and cysteine contents (the radiolabelled amino acids), the molar ratio of sigma 73 to core polymerase in R. prowazekii would be 0.1. This is in striking contrast to E. coli where the ratio is typically 0.4. It remains to be established whether this low sigma saturation results in a limitation of active RNA polymerase in R. prowazekii and contributes to its slow growth.

R17 coat protein binding site: a convenient reporter for in vitro transcription

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Isolation and characterization of the gene coding for the major sigma factor of Rickettsia prowazekii DNA-dependent RNA polymerase

The gene coding for the major sigma factor of Rickettsia prowazekii, an obligate intracellular parasitic bacterium, has been isolated utilizing an oligodeoxyribonucleotide as a probe to a conserved region of major sigma factors. Nucleotide sequence analysis revealed an open reading frame of 1905 bp that could encode a protein of 635 amino acids (aa) with a calculated molecular size of 73 kDa (sigma 73). R. prowazekii sigma 73 displayed extensive homology with major sigma factors from a variety of eubacteria. Comparison of the major sigma factors from Escherichia coli and R. prowazekii revealed 44.9% aa identity. R. prowazekii sigma 73 produced in E. coli minicells migrated as a 85-kDa protein when analyzed by sodium dodecyl sulfate-polyacrylamide-gel electrophoresis. This anomalous migration is characteristic of eubacterial major sigma factors and agrees with the migration noted for the purified rickettsial sigma protein. Despite a similarity to the E. coli sigma 70 encoded by rpoD, R. prowazekii sigma 73 did not complement E. coli rpoD temperature-sensitive mutants.