The Escherichia coli gal operon has the structure Pgal-galE-galTgalK-galM. During early log growth, a gradient in gene expression, named type 2 polarity, is established, as follows: galE > galT > galK > galM. However, during late-log growth, type 1 polarity is established in which galK is greater than galT, as follows: galE > galK > galT > galM. We found that type 2 polarity occurs as a result of the downregulation of galK, which is caused by two different molecular mechanisms: Spot 42-mediated degradation of the galK-specific mRNA, mK2, and Spot 42-mediated Rho-dependent transcription termination at the end of galT. Because the concentration of Spot 42 drops during the transition period of the polarity type switch, these results demonstrate that type 1 polarity is the result of alleviation of Spot 42-mediated galK down-regulation. Because the Spot 42-binding site overlaps with a putative Rho-binding site, a molecular mechanism is proposed to explain how Spot 42, possibly with Hfq, enhances Rhomediated transcription termination at the end of galT.D uring the exponential growth phase of Escherichia coli cells, transcription termination at the end of each cistron of the gal operon operates with less than 100% efficiency; a certain proportion of the transcription initiated from the two promoters of the gal operon terminates at the end of each constituent gene, galE, galT, galK, and galM, of the operon (1). The termination efficiencies measured at the end of each cistron are 16%, 29%, 65%, and 71%, respectively (1). Transcription termination at the end of each cistron generates four mRNA species: mE1, mT1, mK1, and mM1 (Fig.
We have found, using a newly developed genetic method, a protein (named Cnu, for oriC-binding nucleoidassociated) that binds to a specific 26-base-pair sequence (named cnb) in the origin of replication of Escherichia coli, oriC. Cnu is composed of 71 amino acids (8.4 kDa) and shows extensive amino acid identity to a group of proteins belonging to the Hha/YmoA family. Cnu was previously discovered as a protein that, like Hha, complexes with H-NS in vitro. Our in vivo and in vitro assays confirm the results and further suggest that the complex formation with H-NS is involved in Cnu/Hha binding to cnb. Unlike the hns mutants, elimination of either the cnu or hha gene did not disturb the growth rate, origin content, and synchrony of DNA replication initiation of the mutants compared to the wild-type cells. However, the cnu hha double mutant was moderately reduced in origin content. The Cnu/Hha complex with H-NS thus could play a role in optimal activity of oriC.The chromosomal DNA replication in Escherichia coli starts from a single locus called oriC that is minimally 258 base pairs (bp) long. This DNA sequence contains DNA-binding sites for many different proteins that participate in DNA replication (Fig. 1). There are eight binding sites (DnaA boxes and I sites) for the initiator protein DnaA (19,35). The IciA and DpiA proteins bind to the AT-rich 13-mer repeats in oriC. IciA inhibits unwinding of the repeats (11), and overexpression of DpiA can cause SOS response (20). Nucleoid proteins such as IHF and Fis bind specifically to oriC and bend oriC upon binding (27). Another nucleoid protein, HU, binds to oriC nonspecifically but modulates the binding of IHF to oriC (5). Binding of these nucleoid proteins was shown in vitro to assist the action of DnaA protein in the unwinding of oriC (12, 28). The SeqA protein known as a negative modulator of replication initiation (17) binds specifically to two sites in oriC and has higher affinity toward hemimethylated rather than fully methylated oriC (33,34). Nonspecific acid phosphatase also preferentially binds to hemimethylated oriC (26). Rob binds to the right region of oriC (31), while phosphorylated ArcA protein binds to the left region of oriC (16). Although deletion of the rob gene has no phenotype, phosphorylated ArcA inhibits chromosomal replication in vitro (16). Finally, CspD, a singlestranded DNA-binding protein, was shown to inhibit DNA replication in vitro (37).The control of chromosomal DNA replication is a complex process in which many proteins are needed to allow initiation at the right time and frequency in accordance with the changing environment. Because the process remains to be satisfactorily understood, we contemplated that there could be more oriC-binding proteins yet to be discovered. In an attempt to find new oriC-binding proteins, we used a genetic strategy that employs transcriptional repression that is caused by DNA binding of a protein to an operator (15). This assay revealed a novel oriC-binding protein, which we have named Cnu (oriCbinding nucle...
bThe gal operon of Escherichia coli has 4 cistrons, galE, galT, galK, and galM. In our previous report (H. J. Lee, H. J. Jeon, S. C. Ji, S. H. Yun, H. M. Lim, J. Mol. Biol. 378:318 -327, 2008), we identified 6 different mRNA species, mE1, mE2, mT1, mK1, mK2, and mM1, in the gal operon and mapped these mRNAs. The mRNA map suggests a gradient of gene expression known as natural polarity. In this study, we investigated how the mRNAs are generated to understand the cause of natural polarity. Results indicated that mE1, mT1, mK1, and mM1, whose 3= ends are located at the end of each cistron, are generated by transcription termination. Since each transcription termination is operating with a certain frequency and those 4 mRNAs have 5= ends at the transcription initiation site(s), these transcription terminations are the basic cause of natural polarity. Transcription terminations at galEgalT and galT-galK junctions, making mE1 and mT1, are Rho dependent. However, the terminations to make mK1 and mM1 are partially Rho dependent. The 5= ends of mK2 are generated by an endonucleolytic cleavage of a pre-mK2 by RNase P, and the 3= ends are generated by Rho termination 260 nucleotides before the end of the operon. The 5= portion of pre-mK2 is likely to become mE2. These results also suggested that galK expression could be regulated through mK2 production independent from natural polarity. P olycistronic operons in bacteria show a differential expression of the constituent cistrons (1). A Northern blot analysis showed that there are 6 different species of mRNA specific to the galactose operon in wild-type E. coli cells grown exponentially in the presence of galactose (2). Five of the 6 mRNA species, mE1, mE2, mT1, mK1, and mM1, have their 5= ends at the transcription initiation region, and their 3= ends at 5 different locations within the operon, four of which (all but mE2) are at the ends of the galE, galT, galK, and galM cistrons, respectively (Fig. 1A). There is one distinct mRNA species, designated mK2, that has 5= ends not at the promoter region but at the middle of galT. The existence of these mRNA species automatically establishes a gradient of gene expression, higher in the promoter-proximal region and lower in the promoter-distal region, which has been referred to as "natural polarity" (3). Natural polarity is intrinsically different from what has been known as polarity that is caused by a mutation (4), because it can be observed in cells harboring the wild-type operon (2, 5-9). The term "polarity" refers to the phenomenon in which a mutation in one gene of an operon decreases the expression of the subsequent genes of the operon. The cause for polarity is well established. The cessation of translation by a nonsense mutation uncouples transcription from translation, allowing the transcription termination factor, Rho, to bind to the nascent RNA and terminate transcription at the next available termination signal. This Rho-mediated transcription termination leaves the rest of the operon untranscribed, creating polarity ...
Cnu (an OriC-binding nucleoid protein) associates with H-NS. A variant of Cnu was identified as a key factor for filamentous growth of a wild-type Escherichia coli strain at 37°C. This variant (CnuK9E) bears a substitution of a lysine to glutamic acid, causing a charge reversal in the first helix. The temperature-dependent filamentous growth of E. coli bearing CnuK9E could be reversed by either lowering the temperature to 25°C or lowering the CnuK9E concentration in the cell. Gene expression analysis suggested that downregulation of dicA by CnuK9E causes a burst of dicB transcription, which, in turn, elicits filamentous growth. In vivo assays indicated that DicA transcriptionally activates its own gene, by binding to its operator in a temperature-dependent manner. The antagonizing effect of CnuK9E with H-NS on DNA-binding activity of DicA was stronger at 37°C, presumably due to the lower operator binding of DicA at 37°C. These data suggest that the temperature-dependent negative effect of CnuK9E on DicA binding plays a major role in filamentous growth. The C-terminus of DicA shows significant amino acid sequence similarity to the DNA-binding domains of RovA and SlyA, regulators of pathogenic genes in Yersinia and Salmonella, respectively, which also show better DNA-binding activity at 25°C.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
