Active transcription of rRNA operons condenses the nucleoid in Escherichia coli: examining the effect of transcription on nucleoid structure in the absence of transertion.

In Escherichia coli the genome must be compacted approximately 1,000-fold to be contained in a cellular structure termed the nucleoid. It is proposed that the structure of the nucleoid is determined by a balance of multiple compaction forces and one major expansion force. The latter is mediated by transertion, a coupling of transcription, translation, and translocation of nascent membrane proteins and/or exported proteins. In supporting this notion, it has been shown consistently that inhibition of transertion by the translation inhibitor chloramphenicol results in nucleoid condensation due to the compaction forces that remain active in the cell. Our previous study showed that during optimal growth, RNA polymerase is concentrated into transcription foci or "factories," analogous to the eukaryotic nucleolus, indicating that transcription and RNA polymerase distribution affect the nucleoid structure. However, the interpretation of the role of transcription in the structure of the nucleoid is complicated by the fact that transcription is implicated in both compacting forces and the expansion force. In this work, we used a new approach to further examine the effect of transcription, specifically from rRNA operons, on the structure of the nucleoid, when the major expansion force was eliminated. Our results showed that transcription is necessary for the chloramphenicol-induced nucleoid compaction. Further, an active transcription from multiple rRNA operons in chromosome is critical for the compaction of nucleoid induced by inhibition of translation. All together, our data demonstrated that transcription of rRNA operons is a key mechanism affecting genome compaction and nucleoid structure.

Coupling the distribution of RNA polymerase to global gene regulation and the dynamic structure of the bacterial nucleoid in Escherichia coli.

Prokaryotic genomes are contained in a cellular structure termed the nucleoid. However, despite a complete genome sequence and years of intensive study of Escherichia coli, our knowledge of nucleoid structure remains quite rudimentary. Moreover, little is known about the in vivo relationship between nucleoid structure and global gene regulation. Recent studies have shown that the structure of the nucleoid responds dynamically to changing environmental conditions and that this metastable nature of the nucleoid is mediated to a large extent by the distribution and activity of RNA polymerase (RNAP). For example, during rapid growth, the nucleoid is highly condensed with RNAP concentrated into transcription foci or factories, structures analogous to the eukaryotic nucleolus, where active transcription of rRNA genes occurs. However, during nutrient starvation and/or limitation, RNAP is redistributed throughout the genome and this is accompanied by a decondensation of the nucleoid. Thus, the distribution of RNAP, global gene regulation and the dynamic structure of the nucleoid are coupled in the bacterial cell.

Active transcription of rRNA operons is a driving force for the distribution of RNA polymerase in bacteria: effect of extrachromosomal copies of rrnB on the in vivo localization of RNA polymerase.

In contrast to eukaryotes, bacteria such as Escherichia coli contain only one form of RNA polymerase (RNAP), which is responsible for all cellular transcription. Using an RNAP-green fluorescent protein fusion protein, we showed previously that E. coli RNAP is partitioned exclusively in the nucleoid and that stable RNA synthesis, particularly rRNA transcription, is critical for concentrating a significant fraction of RNAP in transcription foci during exponential growth. The extent of focus formation varies under different physiological conditions, supporting the proposition that RNAP redistribution is an important element for global gene regulation. Here we show that extra, plasmid-borne copies of an rRNA operon recruit RNAP from the nucleoid into the cytoplasmic space and that this is accompanied by a reduction in the growth rate. Transcription of an intact rRNA operon is not necessary, although a minimal transcript length is required for this phenotype. Replacement of the ribosomal promoters with another strong promoter, Ptac, abolished the effect. These results demonstrate that active synthesis from rRNA promoters is a major driving force for the distribution of RNAP in bacteria. The implications of our results for the regulation of rRNA synthesis and cell growth are discussed.

Global transcriptional programs reveal a carbon source foraging strategy by Escherichia coli.

By exploring global gene expression of Escherichia coli growing on six different carbon sources, we discovered a striking genome transcription pattern: as carbon substrate quality declines, cells systematically increase the number of genes expressed. Gene induction occurs in a hierarchical manner and includes many factors for uptake and metabolism of better but currently unavailable carbon sources. Concomitantly, cells also increase their motility. Thus, as the growth potential of the environment decreases, cells appear to devote progressively more energy on the mere possibility of improving conditions. This adaptation is not what would be predicated by classic regulatory models alone. We also observe an inverse correlation between gene activation and rRNA synthesis suggesting that reapportioning RNA polymerase (RNAP) contributes to the expanded genome activation. Significant differences in RNAP distribution in vivo, monitored using an RNAP-green fluorescent protein fusion, from energy-rich and energy-poor carbon source cultures support this hypothesis. Together, these findings represent the integration of both substrate-specific and global regulatory systems, and may be a bacterial approximation to metazoan risk-prone foraging behavior.

Identification of a novel steroid inducible gene associated with the beta hsd locus of Comamonas testosteroni.

Comamonas testosteroni is a soil bacterium, which can use a variety of steroids as carbon and energy source. Even if it can be estimated that the complete degradation of the steroid nucleus requires more than 20 enzymatic reactions, the complete molecular characterization of the genes encoding these steroid degradative enzymes as well as the genetic organization of them remain to be elucidated. We have previously reported the cloning and nucleotide sequence of two steroid-inducible genes, beta hsd and stdC encoding 3 beta-17 beta-hydroxysteroid dehydrogenase and a hypothetical protein respectively, located in both ends of a 3.2kb HindIII fragment. Herein, we report the cloning and characterization of another steroid-inducible gene, called sip48 (steroid inducible protein), located between these two genes. The analysis of Sip48 amino acid sequence predicts a protein of 438 amino acids with a molecular mass of 48.5 kDa. This protein bears high homology with conserved hypothetical proteins of unknown function described in Pseudomonas aeruginosa, Pseudomonas syringae, Pseudomonas putida, Burkholderia fungorum, Shewanella oneidensis, Pseudomonas fluorescens and Thauera aromatica. The predicted protein shows a typical structure of a leader peptide at its N-terminus. A 48.5 kDa protein encoded by the recombinant plasmid was detected by SDS-PAGE analysis of in vitro [35S]-methionine labeled polypeptides. Analysis of gene expression indicates that Sip48 is tightly controlled at the transcriptional level by several steroid compounds. In addition, transcriptional analysis of sip48 and beta hsd in a sip48 mutant strain, indicates that both genes are transcribed as a polycistronic mRNA. lacZ transcriptional fusions integrated into the chromosome of C. testosteroni demonstrate that a steroid-inducible promoter located upstream of sip48 regulates the expression of both genes.

TeiR, a LuxR-type transcription factor required for testosterone degradation in Comamonas testosteroni.

We have identified a new steroid-inducible gene (designated teiR [testosterone-inducible regulator]) in Comamonas testosteroni that is required for testosterone degradation. Nucleotide sequence analysis of teiR predicts a 391-amino-acid protein which shows homology between residues 327 and 380 (C-terminal domain) to the LuxR helix-turn-helix DNA binding domain and between residues 192 and 227 to the PAS sensor domain. This domain distribution resembles that described for TraR, a specific transcriptional regulator involved in quorum sensing in Agrobacterium tumefaciens. Analysis of the gene expression indicated that teiR is tightly controlled at the transcriptional level by the presence of testosterone in the culture medium. A teiR-disrupted mutant strain was completely unable to use testosterone as the sole carbon and energy source. In addition, the expression of several steroid-inducible genes was abolished in this mutant. Northern blot assays revealed that teiR is required for full expression of sip48-beta-HSD gene mRNA (encoding a steroid-inducible protein of 48 kDa and 3beta-17beta-hydroxysteroid dehydrogenase) and also of other steroid degradation genes, including those encoding 3alpha-hydroxysteroid dehydrogenase, Delta(5)-3-ketoisomerase, 3-oxo-steroid Delta(1)-dehydrogenase, and 3-oxo-steroid Delta(4)-(5alpha)-dehydrogenase enzymes. Moreover, when teiR was provided to the teiR-disrupted strain in trans, the transcription level of these genes was restored. These results indicate that TeiR positively regulates the transcription of genes involved in the initial enzymatic steps of steroid degradation in C. testosteroni.

The distribution of RNA polymerase in Escherichia coli is dynamic and sensitive to environmental cues.

Despite extensive genetic, biochemical and structural studies on Escherichia coli RNA polymerase (RNAP), little is known about its location and distribution in response to environmental changes. To visualize the RNAP by fluorescence microscopy in E. coli under different physiological conditions, we constructed a functional rpoC-gfp gene fusion on the chromosome. We show that, although RNAP is located in the nucleoid and at its periphery, the distribution of RNAP is dynamic and dramatically influenced by cell growth conditions, nutrient starvation and overall transcription activity inside the cell. Moreover, mutational analysis suggests that the stable RNA synthesis plays an important role in nucleoid condensation.

Fis stabilizes the interaction between RNA polymerase and the ribosomal promoter rrnB P1, leading to transcriptional activation.

It has been shown that Fis activates transcription of the ribosomal promoter rrnB P1; however, the mechanism by which Fis activates rrnB P1 transcription is not fully understood. Paradoxically, although Fis activates transcription of rrnB P1 in vitro, transcription from the promoter containing Fis sites (as measured from rrnB P1-lacZ fusions) is not reduced in a fis null mutant strain. In this study, we further investigated the mechanism by which Fis activates transcription of the rrnB P1 promoter and the role of Fis in rRNA synthesis and cell growth in Escherichia coli. Like all other stringent promoters investigated so far, open complex of rrnB P1 has been shown to be intrinsically unstable, making open complex stability a potential regulatory step in transcription of this class of promoters. Our results show that Fis acts at this regulatory step by stabilizing the interaction between RNA polymerase and rrnB P1 in the absence of NTPs. Mutational analysis of the Fis protein demonstrates that there is a complete correlation between Fis-mediated transcriptional activation of rrnB P1 and Fis-mediated stabilization of preinitiation complexes of the promoter. Thus, our study indicates that Fis-mediated stabilization of RNA polymerase-rrnB P1 preinitiation complexes, presumably at the open complex step, contributes prominently to transcriptional activation. Furthermore, our in vivo results show that rRNA synthesis from the P1 promoters of several rRNA operons are reduced 2-fold in a fis null mutant compared with the wild type strain, indicating that Fis plays an important role in the establishment of robust rRNA synthesis when E. coli cells are emerging from a growth-arrested phase to a rapid growth phase. Thus, our results resolve an apparent paradox of the role of Fis in vitro and in vivo in the field.