Mutations in the lac P2 promoter

Influence of catabolite repression and inducer exclusion on the bistable behavior of the lac operon

A mathematical model of the lac operon which includes all of the known regulatory mechanisms, including external-glucose-dependent catabolite repression and inducer exclusion, as well as the time delays inherent to transcription and translation, is presented. With this model we investigate the influence of external glucose, by means of catabolite repression and the regulation of lactose uptake, on the bistable behavior of this system.

Kinetics of transcription initiation at lacP1. Multiple roles of cyclic AMP receptor protein

The cyclic AMP receptor protein (CRP) acts as a transcription activator at many promoters of Escherichia coli. We have examined the kinetics of open complex formation at the lacP1 promoter using tryptophan fluorescence of RNA polymerase and DNA fragments with 2-aminopurine substituted at specific positions. Apart from the closed complex formation and promoter clearance, we were able to detect three steps. The first step after the closed complex formation leads to a rapid increase of 2-aminopurine fluorescence. This was followed by another rapid step in which quenching of tryptophan fluorescence of RNA polymerase was observed. The slowest step detected by 2-aminopurine fluorescence increase is assigned to the final open complex formation. We have found that CRP not only enhances RNA polymerase binding at the promoter, but also enhances the slowest isomerization step by about 2-fold. Furthermore, potassium permanganate probing shows that the conformation of the open complex in the presence of CRP appears qualitatively and quantitatively different from that in the absence of CRP, suggesting that contact with RNA polymerase is maintained throughout the transcription initiation.

Obligatory activator-polymerase addition order at promoters

The kinetics of open complex formation were measured by migration retardation assay and DNase I footprinting at the activator-dependent promoters ara P1, lac P1 and gal P1. In each case, the rate of open complex formation was significantly faster if the activator, AraC for ara and CAP for lac and gal, had been added before RNA polymerase. The results indicate that complexes of transcriptional activators, RNA polymerase and promoter can exist in two states, one which can form open complexes rapidly and one which cannot.

Roles of catabolite activator protein sites centered at -81.5 and -41.5 in the activation of the Klebsiella aerogenes histidine utilization operon hutUH

The Klebsiella aerogenes hutUH operon is preceded by a promoter region, hut(P), that contains two divergent promoters (hutUp and Pc) which overlap and are alternately expressed. In the absence of the catabolite gene activator protein-cyclic AMP (CAP-cAMP) complex, Pc is predominantly expressed while hutUp is largely repressed. CAP-cAMP has the dual effect of repressing transcription from Pc while simultaneously activating transcription from hutUp. DNA deletion mutations in this region were used to identify DNA sequences required for transcription of these two promoters. We showed that inactivation of Pc by DNA deletion did not result in activation of hutUp in vitro or in vivo. In addition, Escherichia coli CAP mutants that are known to bind and bend DNA normally but are unable to activate various CAP-dependent promoters were also unable to activate hutUp in vivo. These results invalidate an indirect activation model by which CAP-mediated repression of Pc in itself would led to activation of hutUp. Gel retardation asays with various deletion mutations of hut(P) and DNase I protection analyses revealed a high-affinity CAP binding site (CAP site 1) centered at -81.5 relative to the hutUp start of transcription and a second low-affinity CAP site (CAP site 2) centered at about -41.5. CAP site 1 is essential for activation of hutUp. Although CAP site 2 by itself is unable to activate hutUp in vivo under catabolite-activating conditions, it appears to be required for maximal transcription from a site centered at -41.5, does not activate hutUp suggests that the role of CAP-cAMP at the weaker CAP site may be different from that of other promoters containing a similarly positioned site. We propose that CAP directly stimulates the activity of RNA polymerase at hutUp and that this reaction is completely dependent on a naturally occurring CAP site centered at -81.5 and also involves a second CAP site centered at about -41.5 for maximal activation.

Stimulation of the phage lambda pL promoter by integration host factor requires the carboxy terminus of the alpha-subunit of RNA polymerase

Escherichia coli integration host factor (IHF) binds with high affinity to two tandem IHF consensus sequences located upstream from the pL promoter of bacteriophage lambda. IHF was shown to stimulate transcription initiation from the pL promoter by increasing close complex formation (KB). We show here, by the use of reconstituted mutant RNA polymerases, that the C-terminal portion of the alpha subunit of RNA polymerase plays an essential role in the stimulation of transcription by IHF. Our results are in agreement with the hypothesis that IHF, like the cAMP-CRP activator, increases the affinity of RNA polymerase to the promoter by protein-protein interaction.

The lactose operon-controlling elements: a complex paradigm

The lactose-controlling elements have been considered to be the simple paradigm of a cis-acting genetic regulatory system, containing a promoter whose activity is modulated by an operator and a catabolite gene activator protein (CAP)-binding site. The reality is considerably more complex. We now know that transcription is negatively regulated as a result of the repressor binding to three binding sites: the operator, a secondary repressor-binding site within the lacZ gene and a tertiary repressor-binding site upstream near lacI. In addition to the promoter, the lac-controlling elements contain five promoter-like elements. The physiological role, if any, of these promoter-like elements is not clear, although three of them can be activated by single base pair changes to give high levels of in vivo expression. Finally, the positive activator protein CAP has been found to bind to a secondary site which is coincident with the operator. No role has been identified for this secondary CAP-DNA complex.

Catabolite gene activator protein activation of lac transcription

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Derivatives of CAP having no solvent-accessible cysteine residues, or having a unique solvent-accessible cysteine residue at amino acid 2 of the helix-turn-helix motif

The Escherichia coli catabolite gene activator protein (CAP) is a helix-turn-helix motif sequence-specific DNA binding protein. CAP contains a unique solvent-accessible cysteine residue at amino acid 10 of the helix-turn-helix motif. In published work, we have constructed a prototype semi-synthetic site-specific DNA cleavage agent from CAP by use of cysteine-specific chemical modification to incorporate a nucleolytic chelator-metal complex at amino acid 10 of the helix-turn-helix motif [Ebright, R., Ebright, Y., Pendergrast, P.S. and Gunasekera, A., Proc. Natl. Acad. Sci. USA 87, 2882-2886 (1990)]. Construction of second-generation semi-synthetic site-specific DNA cleavage agents from CAP requires the construction of derivatives of CAP having unique solvent-accessible cysteine residues at sites within CAP other than amino acid 10 of the helix-turn-helix motif. In the present work, we have constructed and characterized two derivatives of CAP having no solvent-accessible cysteine residues: [Ser178]CAP and [Leu178]CAP. In addition, in the present work, we have constructed and characterized one derivative of CAP having a unique solvent-accessible cysteine residue at amino acid 2 of the helix-turn-helix motif: [Cys170;Ser178]CAP.

Downstream deletion analysis of the lac promoter

We have generated a series of deletions in the downstream region of the lac promoter. The promoter activities of these mutations were compared by measuring the levels of beta-galactosidase gene expression in vivo. Our results show that deletion of downstream lac promoter sequences changes the promoter strength only two- to threefold. The effects of these deletions on transcription initiation site location were studied through primer extension assay of in vivo mRNAs. We found that the transcription start sites are primarily chosen as an approximate distance from the -10 region of the lac promoter; however, starts are sometimes manifested at a GAATT(C) sequence, which is identical to the wild-type preferred start site. lac promoter P2 and a newly identified promoter, P3, are transcribed in vivo at low levels. Catabolite activator protein complexed with cyclic AMP represses P2 and P3 expression in vivo. The secondary catabolite activator protein binding site plays at most a modest role in catabolite repression in vivo.

Escherichia coli catabolite gene activator protein mutants defective in positive control of lac operon transcription

We isolated three Escherichia coli catabolite gene activator protein mutants that are defective in the positive control of transcription initiation from the lac operon promoter region yet retain negative control of transcription from other promoters. One mutant has a substitution of valine for glutamate at residue 72, which lies in the cyclic AMP binding domain and contacts cyclic AMP. The other two mutants have substitutions of asparagine and cysteine for glycine 162, which lies in a surface-exposed turn of the DNA-binding domain. Surprisingly, although all three mutants can repress the lacP2/P3 promoters through the catabolite gene activator protein target site of lac, none displays strong dominance over the ability of wild-type catabolite gene activator protein to stimulate the lacP1 promoter.

Bipartite functional map of the E. coli RNA polymerase alpha subunit: involvement of the C-terminal region in transcription activation by cAMP-CRP

The alpha subunit of Escherichia coli RNA polymerase plays a major role in the subunit assembly. Carboxyterminal deletion derivatives lacking 73 or 94 amino acid residues were assembled in vitro into enzyme molecules. Core enzymes consisting of these C-terminal-truncated alpha subunits were as active in RNA synthesis as native core enzyme. By the addition of sigma 70 subunit, these mutant enzymes initiated transcription from certain promoters. The mutant RNA polymerases, however, did not show cAMP-CRP activated transcription. These results demonstrate that the N-terminal region of the alpha subunit is involved in the formation of active enzyme molecule, while the C-terminal region plays an essential role in response to transcription activation by cAMP-CRP.

Stringent spacing requirements for transcription activation by CRP

The cyclic AMP receptor protein-cAMP complex (CRP-cAMP) binds at a variety of distances upstream of several E. coli promoters and activates transcription. We have constructed a model system in which a consensus CRP binding site is placed at different distances upstream of the melR promoter. CRP-cAMP activates transcription from melR when bound at a number of positions, all of which lie on the same face of the DNA helix. The two distances at which transcription is strongly activated correspond exactly to those at which CRP-cAMP binds upstream of the well-studied galP1 and lac promoters. Footprinting of the synthetic promoters reveals that RNA polymerase makes identical contacts with their -10 regions even though CRP-cAMP binds at a different distance in each case. Kinetic analysis in vitro indicates that CRP-cAMP activates transcription from these promoters in similar but distinct ways. A model is proposed to explain this two-position activation.

Identification of a contact between arginine-180 of the catabolite gene activator protein (CAP) and base pair 5 of the DNA site in the CAP-DNA complex

We have used site-directed mutagenesis to replace amino acid 1 of the recognition alpha-helix of the catabolite gene activator protein (CAP), Arg-180, with glycine and with alanine. Substitution of Arg-180 of CAP eliminated specificity between G.C, A.T, C.G, and T.A at base pair 5 of the DNA half-site. The effect was position-specific: substitution of Arg-180 did not eliminate specificity between G.C, A.T, C.G, and T.A at base pair 7 of the DNA half-site. We conclude, in agreement with the model for the structure of the CAP-DNA complex [Weber, I. & Steitz, T. (1984) Proc. Natl. Acad. Sci. USA 81, 3973-3977; and Ebright, R., Cossart, P., Gicquel-Sanzey, B. & Beckwith, J. (1984) Proc. Natl. Acad. Sci. USA 81, 7274-7278], that Arg-180 of CAP makes a specificity-determining contact with base pair 5 of the DNA half-site in the CAP-DNA complex. The identification of the contact by Arg-180 in this report, in conjunction with the identification of the contact by Glu-181 in a previous report [Ebright, R., Cossart, P., Gicquel-Sanzey, B. & Beckwith, J. (1984) Nature (London) 311, 232-235], provides information sufficient to define the orientation of the helix-turn-helix motif of CAP with respect to DNA in the CAP-DNA complex.

Lysine 188 of the catabolite gene activator protein (CAP) plays no role in specificity at base pair 7 of the DNA half site

Two similar, but not identical, models have been proposed for the amino acid-base pair contacts in the CAP-DNA complex ('model I,' Weber, I. and Steitz, T., Proc. Natl. Acad. Sci. USA, 81, 3973-3977, 1984; 'model II,' Ebright, et al., Proc. Natl. Acad. Sci. USA, 81, 7274-7278, 1984). The most important difference between the two models involves Lys188 of CAP. Model I predicts that Lys188 of CAP makes a specificity determining contact with base pair 7 of the DNA half site. In contrast, model II predicts that Lys188 makes no contact with base pair 7 of the DNA half site. In the present work, we have used site-directed mutagenesis to replace Lys188 of CAP by Asn, an amino acid unable to make the putative contact. We have assessed the specificities of the following proteins, both in vitro and in vivo: wild-type CAP, [Asn188]CAP, [Val181]CAP, and [Val181;Asn188]CAP. The results indicate that Lys188 makes no contribution to specificity at base pair 7 of the DNA half site. We propose, contrary to model I, that Lys188 makes no contact with base pair 7 of the DNA half site.

Two different mechanisms for urea action at the LAC and TNA operons in Escherichia coli

Urea, at concentrations which do not interfere with bacterial growth, specifically inhibits the expression of catabolite sensitive operons. To search for the target and the mechanism of urea action we measured lactose (lac) and tryptophanase (tna) specific mRNA synthesis in vivo and in vitro. We show that urea acts by two different mechanisms at these two catabolite sensitive operons, resembling the manner in which catabolite repression regulates lac and tna. At the lac promoter, urea abolishes transcription initiation or blocks an early step in mRNA elongation without interfering with the binding of RNA polymerase and catabolite gene activator protein (CAP). At the tna promoter, urea does not abolish transcription initiation but could interfere with tnaC translation.

RNA polymerase as a repressor of transcription in the hut(P) region of mutant Klebsiella aerogenes histidine utilization operons

Mutants of Klebsiella aerogenes able to express the hutUH operon in the absence of positive effectors were isolated and characterized. These mutations improve the hutUH promoter (PUH) by changing the -10 region to match the consensus sequence more closely. These mutations also affect another, oppositely oriented promoter in this region, PC. Although the mutations lie far outside PC, they cause PC to be inactive, apparently because binding of RNA polymerase to the PUH promoter blocks the overlapping PC site. Thus, in the mutants, RNA polymerase bound at the strong (mutant) PUH site effectively repress the PC promoter.