Role of CRP in transcription activation at Escherichia coli lac promoter: CRP is dispensable after the formation of open complex

Evolution of Regulated Transcription

The genomes of all organisms abound with various cis-regulatory elements, which control gene activity. Transcriptional enhancers are a key group of such elements in eukaryotes and are DNA regions that form physical contacts with gene promoters and precisely orchestrate gene expression programs. Here, we follow gradual evolution of this regulatory system and discuss its features in different organisms. In eubacteria, an enhancer-like element is often a single regulatory element, is usually proximal to the core promoter, and is occupied by one or a few activators. Activation of gene expression in archaea is accompanied by the recruitment of an activator to several enhancer-like sites in the upstream promoter region. In eukaryotes, activation of expression is accompanied by the recruitment of activators to multiple enhancers, which may be distant from the core promoter, and the activators act through coactivators. The role of the general DNA architecture in transcription control increases in evolution. As a whole, it can be seen that enhancers of multicellular eukaryotes evolved from the corresponding prototypic enhancer-like regulatory elements with the gradually increasing genome size of organisms.

ChIP-exo interrogation of Crp, DNA, and RNAP holoenzyme interactions

Numerous in vitro studies have yielded a refined picture of the structural and molecular associations between Cyclic-AMP receptor protein (Crp), the DNA motif, and RNA polymerase (RNAP) holoenzyme. In this study, high-resolution ChIP-exonuclease (ChIP-exo) was applied to study Crp binding in vivo and at genome-scale. Surprisingly, Crp was found to provide little to no protection of the DNA motif under activating conditions. Instead, Crp demonstrated binding patterns that closely resembled those generated by σ⁷⁰. The binding patterns of both Crp and σ⁷⁰ are indicative of RNAP holoenzyme DNA footprinting profiles associated with stages during transcription initiation that occur post-recruitment. This is marked by a pronounced advancement of the template strand footprint profile to the +20 position relative to the transcription start site and a multimodal distribution on the nontemplate strand. This trend was also observed in the familial transcription factor, Fnr, but full protection of the motif was seen in the repressor ArcA. Given the time-scale of ChIP studies and that the rate-limiting step in transcription initiation is typically post recruitment, we propose a hypothesis where Crp is absent from the DNA motif but remains associated with RNAP holoenzyme post-recruitment during transcription initiation. The release of Crp from the DNA motif may be a result of energetic changes that occur as RNAP holoenzyme traverses the various stable intermediates towards elongation complex formation.

Link between the causative genes of holoprosencephaly: Zic2 directly regulates Tgif1 expression

One of the causal genes for holoprosencephaly (HPE) is ZIC2 (HPE5). It belongs to the zinc finger protein of the cerebellum (Zic) family of genes that share a C2H2-type zinc finger domain, similar to the GLI family of genes. In order to clarify the role of Zic2 in gene regulation, we searched for its direct target genes using chromatin immunoprecipitation (ChIP). We identified TGIF1 (HPE4), another holoprosencephaly-causative gene in humans. We identified Zic2-binding sites (ZBS) on the 5′ flanking region of Tgif1 by in vitro DNA binding assays. ZBS were essential for Zic2-dependent transcriptional activation in reporter gene assays. Zic2 showed a higher affinity to ZBS than GLI-binding sequences. Zic2-binding to the cis-regulatory element near the Tgif1 promoter may be involved in the mechanism underlying forebrain development and incidences of HPE.

Cyclic AMP Receptor Protein Acts as a Transcription Regulator in Response to Stresses in Deinococcus radiodurans

The cyclic AMP receptor protein family of transcription factors regulates various metabolic pathways in bacteria, and also play roles in response to environmental changes. Here, we identify four homologs of the CRP family in Deinococcus radiodurans, one of which tolerates extremely high levels of oxidative stress and DNA-damaging reagents. Transcriptional levels of CRP were increased under hydrogen peroxide (H₂O₂) treatment during the stationary growth phase, indicating that CRPs function in response to oxidative stress. By constructing all CRP single knockout mutants, we found that the dr0997 mutant showed the lowest tolerance toward H₂O₂, ultraviolet radiation, ionizing radiation, and mitomycin C, while the phenotypes of the dr2362, dr0834, and dr1646 mutants showed slight or no significant differences from those of the wild-type strain. Taking advantage of the conservation of the CRP-binding site in many bacteria, we found that transcription of 18 genes, including genes encoding chromosome-partitioning protein (dr0998), Lon proteases (dr0349 and dr1974), NADH-quinone oxidoreductase (dr1506), thiosulfate sulfurtransferase (dr2531), the DNA repair protein UvsE (dr1819), PprA (dra0346), and RecN (dr1447), are directly regulated by DR0997. Quantitative real-time polymerase chain reaction (qRT-PCR) analyses showed that certain genes involved in anti-oxidative responses, DNA repair, and various cellular pathways are transcriptionally attenuated in the dr0997 mutant. Interestingly, DR0997 also regulate the transcriptional levels of all CRP genes in this bacterium. These data suggest that DR0997 contributes to the extreme stress resistance of D. radiodurans via its regulatory role in multiple cellular pathways, such as anti-oxidation and DNA repair pathways.

Comparison of the theoretical and real-world evolutionary potential of a genetic circuit

With the development of next-generation sequencing technologies, many large scale experimental efforts aim to map genotypic variability among individuals. This natural variability in populations fuels many fundamental biological processes, ranging from evolutionary adaptation and speciation to the spread of genetic diseases and drug resistance. An interesting and important component of this variability is present within the regulatory regions of genes. As these regions evolve, accumulated mutations lead to modulation of gene expression, which may have consequences for the phenotype. A simple model system where the link between genetic variability, gene regulation and function can be studied in detail is missing. In this article we develop a model to explore how the sequence of the wild-type lac promoter dictates the fold-change in gene expression. The model combines single-base pair resolution maps of transcription factor and RNA polymerase binding energies with a comprehensive thermodynamic model of gene regulation. The model was validated by predicting and then measuring the variability of lac operon regulation in a collection of natural isolates. We then implement the model to analyze the sensitivity of the promoter sequence to the regulatory output, and predict the potential for regulation to evolve due to point mutations in the promoter region.

The cooperative binding energetics of CytR and cAMP receptor protein support a quantitative model of differential activation and repression of CytR-regulated class III Escherichia coli promoters

cAMP receptor protein (CRP) and CytR mediate positive and negative control of nine genes in Escherichia coli, most of which are involved in nucleoside catabolism and recycling. Five promoters share a common architecture in which tandem CRP sites flank an intervening CytR operator (CytO). CytR and CRP bind cooperatively to these promoters to form a three-protein, DNA-bound complex that controls activation and repression, the levels of which vary markedly among the promoters. To understand the specific combinatorial control mechanisms that are responsible for this outcome, we have used quantitative DNase I footprinting to generate individual site isotherms for each site of protein-DNA interaction. The intrinsic affinities of each transcription factor for its respective site and the specific patterns of cooperativity and competition underlying the molecular interactions at each promoter were determined by a global analysis of these titration data. Here we present results obtained for nupGP and tsxP2, adding to results published previously for deoP2, udpP, and cddP. These data allowed us to correlate the reported levels of activation, repression, and induction with the ligation states of these five promoters under physiologically relevant conditions. A general pattern of transcriptional regulation emerges that allows for complex patterns of regulation in this seemingly simple system.

Transcription activation by the siderophore sensor Btr is mediated by ligand-dependent stimulation of promoter clearance

Bacterial transcription factors often function as DNA-binding proteins that selectively activate or repress promoters, although the biochemical mechanisms vary. In most well-understood examples, activators function by either increasing the affinity of RNA polymerase (RNAP) for the target promoter, or by increasing the isomerization of the initial closed complex to the open complex. We report that Bacillus subtilis Btr, a member of the AraC family of activators, functions principally as a ligand-dependent activator of promoter clearance. In the presence of its co-activator, the siderophore bacillibactin (BB), the Btr:BB complex enhances productive transcription, while having only modest effects on either RNAP promoter association or the production of abortive transcripts. Btr binds to two direct repeat sequences adjacent to the −35 region; recognition of the downstream motif is most important for establishing a productive interaction between the Btr:BB complex and RNAP. The resulting Btr:BB dependent increase in transcription enables the production of the ferric-BB importer to be activated by the presence of its cognate substrate.

Unexpected coregulator range for the global regulator Lrp of Escherichia coli and Proteus mirabilis

The Lrp/AsnC family of transcription factors links gene regulation to metabolism in bacteria and archaea. Members of this family, collectively, respond to a wide range of amino acids as coregulators. In Escherichia coli, Lrp regulates over 200 genes directly and is well known to respond to leucine and, to a somewhat lesser extent, alanine. We focused on Lrp from Proteus mirabilis and E. coli, orthologs with 98% identity overall and identical helix-turn-helix motifs, for which a previous study nevertheless found functional differences. Sequence differences between these orthologs, within and adjacent to the amino acid-responsive RAM domain, led us to test for differential sensitivity to coregulatory amino acids. In the course of this investigation, we found, via in vivo reporter fusion assays and in vitro electrophoretic mobility shift experiments, that E. coli Lrp itself responded to a broader range of amino acids than was previously appreciated. In particular, for both the E. coli and P. mirabilis orthologs, Lrp responsiveness to methionine was similar in magnitude to that to leucine. Both Lrp orthologs are also fairly sensitive to Ile, His, and Thr. These observations suggest that Lrp ties gene expression in the Enterobacteriaceae rather extensively to physiological status, as reflected in amino acid pools. These findings also have substantial implications for attempts to model regulatory architecture from transcriptome measurements or to infer such architecture from genome sequences, and they suggest that even well-studied regulators deserve ongoing exploration.

Transcriptional effects of CRP* expression in Escherichia coli

Background

Escherichia coli exhibits diauxic growth in sugar mixtures due to CRP-mediated catabolite repression and inducer exclusion related to phosphotransferase system enzyme activity. Replacement of the native crp gene with a catabolite repression mutant (referred to as crp*) enables co-utilization of glucose and other sugars in E. coli. While previous studies have examined the effects of expressing CRP* mutants on the expression of specific catabolic genes, little is known about the global transcriptional effects of CRP* expression. In this study, we compare the transcriptome of E. coli W3110 (expressing wild-type CRP) to that of mutant strain PC05 (expressing CRP*) in the presence and absence of glucose.

Results

The glucose effect is significantly suppressed in strain PC05 relative to strain W3110. The expression levels of glucose-sensitive genes are generally not altered by glucose to the same extent in strain PCO5 as compared to W3110. Only 23 of the 80 genes showing significant differential expression in the presence of glucose for strain PC05 are present among the 418 genes believed to be directly regulated by CRP. Genes involved in central carbon metabolism (including several TCA cycle genes) and amino acid biosynthesis, as well as genes encoding nutrient transport systems are among those whose transcript levels are most significantly affected by CRP* expression.

We present a detailed transcription analysis and relate these results to phenotypic differences between strains expressing wild-type CRP and CRP*. Notably, CRP* expression in the presence of glucose results in an elevated intracellular NADPH concentration and reduced NADH concentration relative to wild-type CRP. Meanwhile, a more drastic decrease in the NADPH/NADP⁺ ratio is observed for the case of CRP* expression in strains engineered to reduce xylose to xylitol via a heterologously expressed, NADPH-dependent xylose reductase. Altered expression levels of transhydrogenase and TCA cycle genes, among others, are consistent with these observations.

Conclusion

While the simplest model of CRP*-mediated gene expression assumes insensitivity to glucose (or cAMP), our results show that gene expression in the context of CRP* is very different from that of wild-type in the absence of glucose, and is influenced by the presence of glucose. Most of the transcription changes in response to CRP* expression are difficult to interpret in terms of possible systematic effects on metabolism. Elevated NADPH availability resulting from CRP* expression suggests potential biocatalytic applications of crp* strains that extend beyond relief of catabolite repression.

Chemical linkage at allosteric activation of E. coli cAMP receptor protein

Cyclic AMP Receptor protein (CRP) regulates transcription initiation in E. coli. The ligand and DNA binding data yields the following results: (1) There are two different types of cAMP binding sites; weak and strong. (2) CRP-DNA-cAMP is the active form of all CRP conformers and this complex prefers to form from CRP-DNA rather than CRP-cAMP form. (3) Binding of additional cAMP(s) to CRP-DNA-cAMP complex greatly reduces DNA binding affinity. (4) Variants showed that ribose moiety of cAMP is important to transmit the signal to the DNA binding domain to activate specific DNA binding. (5) Deconvolution of DNA binding data leads us to propose a model for cAMP's role in transcription initiation process.

Effect of salt bridge on transcription activation of CRP-dependent lactose operon in Escherichia coli

Expression of catabolite-sensitive operons in Escherichia coli is cAMP-dependent and mediated through the CRP:cAMP complex binding to specific sequences in DNA. Five specific ionic or polar interactions occur in cAMP binding pocket of CRP. E72 interacts with the cAMP 2' OH, R82 and S83 interact with the negatively charged phosphate moiety, and T127 and S128 interact with the adenine ring. There is evidence to suggest that E72 and R82 may mediate an essential CRP molecular switch mechanism. Therefore, stimulation of CRP transcription activation was examined by perturbing these residues. Further, CRP:cAMP complex was treated with a specific DNA sequence containing the lac CRP binding site along with RNA polymerase to mimic in vivo conditions. Biochemical and biophysical results revealed that regulation of transcription activation depends on alignment of CRP tertiary structure through inter-domain communication and it was concluded that positions 72 and 82 are essential in the activation of CRP by cAMP.

lacP1 promoter with an extended -10 motif. Pleiotropic effects of cyclic AMP protein at different steps of transcription initiation

The cyclic AMP receptor protein (CRP), which activates transcription from the wild-type lacP1 promoter and most of its mutants, represses productive RNA synthesis from a lacP1 promoter variant that contains an extended -10 element, although CRP enhances RNA polymerase binding as well as open complex formation in both promoters. Moreover, abortive RNA synthesis, which is already higher in the extended -10 variant compared with the parent promoter, was further enhanced by CRP. These results, together with the observed decrease in productive RNA synthesis, indicate that CRP, while facilitating the earlier steps of initiation, inhibits transcription from the extended -10 lacP1 by hindering promoter clearance. We propose that CRP decreases energetic barriers to RNA polymerase binding, isomerization, and abortive RNA synthesis but stabilizes the abortive RNA initiating complex, which results in increasing the activation energy of the transition state before the elongation complex. The results demonstrate for the first time that a DNA-binding regulatory protein acts as an activator or a repressor in different steps of the transcription initiation pathway because of the energetic differences of the intermediate complex in the same promoter.

Identification of IFN regulatory factor-1 binding site in IL-12 p40 gene promoter

IL-12 is a heterodimer composed of p40 and p35 and is a key cytokine that functions to protect the host from viral and microbial infections. IL-12 links the innate immune system with the acquired immune system during infection, and induces differentiation of type 1 T cells that play an important role in the eradication of microbes. The induction of the IL-12 p40 gene is regulated by NF-kappaB in the presence of IFN-gamma. IFN-gamma induces IFN regulatory factor-1 (IRF-1), which in turn induces the transcription of the IL-12 p40 gene. However, the IRF-1 binding site in the promoter region of the IL-12 p40 gene has not yet been formally determined. In the present study, we demonstrated that IRF-1 directly binds to the IL-12 p40 gene promoter and identified its binding site. The IRF-1 binding site in the promoter region of the IL-12 p40 gene is shown to be in the -72 to -58 area of the 5'-upstream region. The -63 to -61 position is the critical site within this region for the binding of IRF-1 to the IL-12 p40 gene promoter. While IFN-gamma must be present for IL-12 p40 gene induction, the p35 gene is strongly induced by LPS, even in the absence of IFN-gamma, and therefore the induction of the p35 gene is IRF-1 independent.

Allosteric regulation of the cAMP receptor protein

The cyclic AMP receptor protein (CRP) of Escherichia coli is a dimer made up of identical subunits. Each CRP subunit contains a cyclic nucleotide binding pocket and the CRP dimer exhibits negative cooperativity in binding cAMP. In solutions containing cAMP, CRP undergoes sequential conformation changes from the inactive apo-form through the active CRP:(cAMP)(1) complex to the less active CRP:(cAMP)(2) complex depending on the cAMP concentration. Apo-CRP binds DNA with low affinity and no apparent sequence specificity. The CRP:(cAMP)(1) complex exhibits high affinity, sequence-specific DNA binding and interacts with RNA polymerase, whether free in solution or complexed with DNA. The results of genetic, biochemical and biophysical studies have helped to uncover many of the details of cAMP-mediated allosteric control over CRP conformation and activity as a transcription factor. These studies indicate that cAMP binding produces only small, but significant, changes in CRP structure; changes that include subunit realignment and concerted motion of the secondary structure elements within the C-terminal DNA binding domain of each subunit. These adjustments promote CRP surface-patch interaction with RNA polymerase and protrusion of the F-helix to promote CRP site-specific interaction with DNA. Interactions between CRP and RNA polymerase at CRP-dependent promoters produce active ternary transcription complexes.

RNA polymerase-cNMP-ligated cAMP receptor protein (CRP) mutant interactions in the enhancement of transcription by CRP mutants

The enhancement of the transcription of three synthetic promoters by cNMP-ligated cAMP receptor protein (CRP)/mutant complexes was determined from the transcription yields of a short AAUU transcript in an abortive initiation in vitro transcription assay. The cNMP-ligated CRP and mutants were cAMP, cGMP, and cIMP ligated with CRP, T127L CRP, S128A CRP, and T127L/S128A CRP. The transcriptional activation of a 152-base pair lacUV5 promoter (synlac promoter) with a CRP consensus binding site sequence (syncon promoter) was enhanced by an average factor of 12.3 +/- 0.5 with the cAMP-ligated complexes of CRP/mutants and cGMP-ligated T127L, although their promoter binding site affinities varied by a factor of 5. However, in the presence of bound RNA polymerase, the binding affinities only ranged from 0.8 +/- 0.2 x 10(7) m(-)(1) for cAMP-ligated CRP* to 1.8 +/- 0. 3 x 10(7) m(-)(1) for cAMP-ligated CRP, indicating that the CRP/mutant interacts with the bound RNA polymerase, which would account for the near constancy of the enhancement factors. The corresponding enhancement factors for the synlac promoter and a promoter with a different CRP binding site sequence (syngal promoter) were also nearly the same, 7.2 +/- 0.7 and 6 +/- 1, respectively. The binding reaction of the syncon promoter to the RNA polymerase is exothermic, with a binding constant (K(b)) = 2.1 +/- 0. 2 x 10(7) m(-1).

Mechanism of catabolite repression in the bgl operon of Escherichia coli: involvement of the anti-terminator BglG, CRP-cAMP and EIIAGlc in mediating glucose effect downstream of transcription initiation

BACKGROUND

Expression of the bgl operon of Escherichia coli, involved in the regulated uptake and utilization of aromatic beta-glucosides, is extremely sensitive to the presence of glucose in the growth medium. We have analysed the mechanism by which glucose exerts its inhibitory effect on bgl expression.

RESULTS

Our studies show that initiation of transcription from the bgl promoter is only marginally sensitive to glucose. Instead, glucose exerts a more significant inhibition on the elongation of transcription beyond the rho-independent terminator present within the leader sequence. Transcriptional analyses using plasmids that carry mutations in bglG or within the terminator, suggest that the target for glucose-mediated repression is the anti-terminator protein, BglG. Introduction of multiple copies of bglG or the presence of mutations that inhibit its phosphorylation by Enzyme IIBgl (BglF), result in loss of glucose repression. Studies using crp, cya and crr strains show that both CRP-cAMP and the Enzyme IIAGlc (EIIAGlc) are involved in the regulation. Although transcription initiation is normal in a crp, cya double mutant, no detectable transcription is seen downstream of the terminator, which is restored by a mutation within the terminator. Transcription past the terminator is also partly restored by the addition of exogenous cAMP to glucose-grown cultures of a crp+ strain. Glucose repression is lost in the crr mutant strain.

CONCLUSIONS

The results summarized above indicate that glucose repression in the bgl operon is mediated at the level of transcription anti-termination, and glucose affects the activity of BglG by altering its phosphorylation by BglF. The CRP-cAMP complex is also involved in this regulation. The results using the crr mutant suggest a negative role for EIIAGlc in the catabolite repression of the bgl genes.

Transcription activation by catabolite activator protein (CAP)

Transcription activation by Escherichia coli catabolite activator protein (CAP) at each of two classes of simple CAP-dependent promoters is understood in structural and mechanistic detail. At class I CAP-dependent promoters, CAP activates transcription from a DNA site located upstream of the DNA site for RNA polymerase holoenzyme (RNAP); at these promoters, transcription activation involves protein-protein interactions between CAP and the RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex. At class II CAP-dependent promoters, CAP activates transcription from a DNA site that overlaps the DNA site for RNAP; at these promoters, transcription activation involves both: (i) protein-protein interactions between CAP and RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex; and (ii) protein-protein interactions between CAP and RNAP alpha subunit N-terminal domain that facilitates isomerization of the RNAP-promoter closed complex to the RNAP-promoter open complex. Straightforward combination of the mechanisms for transcription activation at class I and class II CAP-dependent promoters permits synergistic transcription activation by multiple molecules of CAP, or by CAP and other activators. Interference with determinants of CAP or RNAP involved in transcription activation at class I and class II CAP-dependent promoters permits "anti-activation" by negative regulators. Basic features of transcription activation at class I and class II CAP-dependent promoters appear to be generalizable to other activators.

Glycerol-3-phosphate-mediated repression of malT in Escherichia coli does not require metabolism, depends on enzyme IIAGlc and is mediated by cAMP levels

malT encodes the central activator of the maltose system in Escherichia coli, a gene that is typically under positive control of the cAMP/CAP catabolite repression system. When cells were grown in tryptone broth, the addition of glycerol reduced malT expression two- to threefold. Phosphorylation of glycerol to glycerol-3-phosphate (G3P) was necessary for this repression, but further metabolism to dihydroxyacetone phosphate was not. Mutants lacking adenylate cyclase and harbouring a crp* mutation (synthesizing a cAMP receptor protein that is independent of cAMP) no longer repressed a transcriptional malT-lacZ fusion but still repressed a translational malT-lacZ fusion. Similar results were obtained with a mutant lacking enzyme IIAGlc. For the translational fusion (in a cya crp* genetic background) to be repressed by glycerol, a drop to pH 5 of the growth medium was necessary. Thus, while transcriptional repression by glycerol requires enzyme IIAGlc, cAMP and CAP, pH-mediated translational repression is cAMP independent. Other sugars that are not transported by the phosphotransferase system, most notably D-xylose, showed the same effect as glycerol.

Negative regulation of the pts operon by Mlc: mechanism underlying glucose induction in Escherichia coli

BACKGROUND

The pts operon of Escherichia coli consists of three genes ptsH, ptsI and crr, each encoding for central components of the phosphoenolpyruvate: carbohydrate phosphotransferase system, HPr, enzyme I and IIAGlc, respectively. Transcription of the pts operon is stimulated when glucose is present in the culture medium. One of the two major promoters, P0, is responsible for this glucose induction. However, no regulatory protein responsible for the glucose induction of the pts operon has been identified yet and molecular mechanism by which glucose stimulates the pts transcription is not known.

RESULTS

We found by Northern blotting that the pts mRNA levels in cells lacking Mlc, a new global repressor of carbohydrate metabolism, were increased without external glucose and that the addition of glucose had no effect on the pts mRNA levels in the mutant cells. Western blotting revealed that the enzyme I level in the mlc- cells was also elevated without glucose and no further increase in the enzyme I level was observed in the presence of glucose. S1 analysis revealed that transcription of the glucose-sensitive promoter, P0, occurs constitutively in the mlc- cells independently from the external glucose. In vitro transcription studies indicated that Mlc strongly inhibited P0 transcription. DNase I footprinting experiment revealed that Mlc bound to P0 promoter region to prevent RNA polymerase binding at P0.

CONCLUSION

We conclude that Mlc is a repressor for the pts transcription acting as a major regulatory protein involved in the glucose induction of pts operon. We propose that glucose induces the pts transcription by modulating the Mlc activity. The mechanism by which glucose modulates the Mlc action remains to be studied.

Transcription activation by CooA, the CO-sensing factor from Rhodospirillum rubrum. The interaction between CooA and the C-terminal domain of the alpha subunit of RNA polymerase

CooA, a member of the cAMP receptor protein (CRP) family, is a CO-sensing transcription activator from Rhodospirillum rubrum that binds specific DNA sequences in response to CO. The location of the CooA-binding sites relative to the start sites of transcription suggested that the CooA-dependent promoters are analogous to class II CRP-dependent promoters. In this study, we developed an in vivo CooA reporter system in Escherichia coli and an in vitro transcription assay using RNA polymerases (RNAP) from E. coli and from Rhodobacter sphaeroides to study the transcription properties of CooA and the protein-protein interaction between CooA and RNAP. The ability of CooA to activate CO-dependent transcription in vivo in heterologous backgrounds suggested that CooA is sufficient to direct RNAP to initiate transcription and that no other factors are required. This hypothesis was confirmed in vitro with purified CooA and purified RNAP. Use of a mutant form of E. coli RNAP with alpha subunits lacking their C-terminal domain (alpha-CTD) dramatically decreased CooA-dependent transcription of the CooA-regulated R. rubrum promoter PcooF in vitro, which indicates that alpha-CTD plays an important role in this activation. DNase I footprinting analysis showed that CooA facilitates binding of wild-type RNAP, but not alpha-CTD-truncated RNAP, to PcooF. This facilitated binding provides evidence for a direct contact between CooA and alpha-CTD of RNAP during activation of transcription. Mapping the CooA-contact site in alpha-CTD suggests that CooA is similar but not identical to CRP in terms of its contact sites to the alpha-CTD at class II promoters.

CAP, the -45 region, and RNA polymerase: three partners in transcription initiation at lacP1 in Escherichia coli

The lac operon of Escherichia coli is positively regulated by the catabolite activator protein (CAP) bound upstream of the -45 region (CAP binding is centered at -61.5; the -45 region extends from -50 to -38). Certain mutations within the -45 region generate sequences that resemble UP elements in base composition and mimic the stimulation by the rrnBP1 UP element, yielding up to 15-fold stimulation in vivo. These -45 region "UP mutants" are compromised in their CAP stimulation. CAP and UP elements do not act in a fully additive manner in vivo at the lac operon. Transcription assays with the wild-type lac promoter and an UP mutant of lac indicate that CAP and UP DNA also fail to act in a completely additive manner in vitro. RNA polymerase can stabilize CAP binding to promoter DNA with a -45 region UP element against a heparin challenge. This shows that CAP and the UP DNA do not compete for the alpha-CTD as a mechanism for their lack of additivity. CAP and UP elements both demonstrate decreased stimulation of transcription as RNA polymerase concentration is increased from 0.05 to 10 nM in in vitro transcription experiments. In addition CAP also stimulates transcription in a manner that does not decrease as RNA polymerase is varied over this concentration range. This invariable stimulation is by two- to threefold and occurs both in vivo and in vitro. It is not dependent upon the alpha-CTD of RNA polymerase and is maintained in the presence of the AR1 CAP mutant HL159. This two- to threefold invariable CAP stimulation appears to depend on the -45 region sequence as our -45 region mutants demonstrate different responses to HL159 CAP stimulation in vivo.

A global repressor (Mlc) is involved in glucose induction of the ptsG gene encoding major glucose transporter in Escherichia coli

Glucose stimulates the expression of ptsG encoding the major glucose transporter in Escherichia coli. We isolated Tn 10 insertion mutations that confer constitutive expression of ptsG. The mutated gene was identified as mlc, encoding a protein that is known to be a repressor for transcription of several genes involved in carbohydrate utilization. Expression of ptsG was eliminated in a mlc crp double-negative mutant. The Mlc protein was overproduced and purified. In vitro transcription studies demonstrated that transcription of ptsG is stimulated by CRP-cAMP and repressed by Mlc. The action of Mlc is dominant over that of CRP-cAMP. DNase I footprinting experiments revealed that CRP-cAMP binds at two sites centred at -40.5 and -95.5 and that Mlc binds at two regions centred around -8 and -175. The binding of CRP-cAMP stimulated the binding of RNA polymerase to the promoter while Mlc inhibited the binding of RNA polymerase but not the binding of CRP-cAMP. Gel-mobility shift assay indicated that glucose does not affect the Mlc binding to the ptsG promoter. Our results suggest that Mlc is responsible for the repression of ptsG transcription and that glucose modulates the Mlc activity by unknown mechanism.

A HU-like protein binds to specific sites within nod promoters of Rhizobium leguminosarum

Nodulation genes (nod) of rhizobia are essential for establishment of its symbiosis with specific legume hosts and are usually located on the Sym(biosis) megaplasmid. In this work we identified a new Sym plasmid independent protein in Rhizobium leguminosarum, Px, by its ability to bind to nod promoters and induce DNA bending. Depending upon its concentrations relative to DNA templates, Px could either stimulate or inhibit in vitro transcription of the major regulatory nodulation gene nodD. This may result from its property to bind to specific sites within nod promoters at lower concentration or in the presence of competitor calf thymus DNA but nonspecifically associate with DNA at higher levels or in the absence of competitors. Its binding sites within nodD and nodF promoters were determined by DNase I footprinting but showed no sequence consensus. N-terminal sequencing and Western blot revealed that Px belongs to the HU class of prokaryotic histone-like proteins. Its binding feature and functioning mechanism were discussed in the light of this discovery.

Transcription activation at promoters carrying tandem DNA sites for the Escherichia coli cyclic AMP receptor protein: organisation of the RNA polymerase alpha subunits

We have constructed a family of promoters carrying tandem DNA sites for the Escherichia coli cyclic AMP receptor protein (CRP), with one of the sites centred between base-pairs 41 and 42 upstream from the transcription start site, and the second site located further upstream. In vivo activity measurements show that the activity of these promoters is completely dependent on CRP and that, depending on the precise location, CRP bound at the upstream site increases transcription activation. Hydroxyl radical footprinting was exploited to investigate the binding of CRP and RNA polymerase holoenzyme (RNAP) to these promoters. The study shows that the C-terminal domains of the RNAP alpha subunits bind adjacent to the upstream CRP and that their precise positioning depends on the location of upstream-bound CRP. The C-terminal domains of the RNAP alpha subunits interact with both the upstream and downstream-bound CRP via activating region 1 of CRP.

Positive activation of gene expression

Most bacterial transcription activators function by making direct contact with RNA polymerase at target promoters. Some activators contact the carboxy-terminal domain of the RNA polymerase alpha subunit, some contact region 4 of the sigma70 subunit, whilst others interact with other contact sites. A number of activators are ambidextrous and can, apparently simultaneously, contact more than one target site on RNA polymerase. Expression from many promoters is co-dependent on two or more activators. There are several different mechanisms for coupling promoter activity to more than one activator: in one such mechanism, the different activators make independent contacts with different target sites on RNA polymerase.

A common role of CRP in transcription activation: CRP acts transiently to stimulate events leading to open complex formation at a diverse set of promoters

We have shown previously that the cyclic AMP receptor protein (CRP) is not required after the formation of the open complex at the lac promoter (Tagami and Aiba, 1995, Nucleic Acids Res., 19, 6705-6712). In this paper, we investigate the role of CRP in transcription activation at the malT and gal promoters. At the malT promoter, RNA polymerase (RNAP) forms a nonproductive RNAP-promoter binary complex in the absence of CRP and a productive CRP-RNAP-promoter ternary complex in the presence of CRP. CRP can be removed from the malT ternary complex by a moderate concentration of heparin. The resulting binary complex is functionally identical to the ternary complex. At the gal promoter, RNAP predominantly forms a binary complex at the P2 promoter in the absence of CRP and a ternary complex at the P1 promoter in the presence of CRP. A very high concentration of heparin is able to dissociate CRP from the galP1 ternary complex without changing the properties of the complex. These data indicate that CRP is not required for the maintenance of the ternary complex and plays no role in the subsequent steps, irrespective of the promoter. We conclude that the common role of CRP in the activation of transcription is to stimulate events leading to the formation of a productive open complex at a diverse set of CRP-dependent promoters. We suggest that the interaction between CRP and RNAP is needed only transiently for the activation of transcription.

Making chemistry selectable by linking it to infectivity

The link between recognition and replication is fundamental to the operation of the immune system. In recent years, modeling this process in a format of phage-display combinatorial libraries has afforded a powerful tool for obtaining valuable antibodies. However, the ability to readily select and isolate rare catalysts would expand the scope of library technology. A technique in which phage infection controlled the link between recognition and replication was applied to show that chemistry is a selectable process. An antibody that operated by covalent catalysis to form an acyl intermediate restored phage infectivity and allowed selection from a library in which the catalyst constituted 1 in 10(5) members. Three different selection approaches were examined for their convenience and generality. Incorporating these protocols together with well known affinity labels and mechanism-based inactivators should allow the procurement of a wide range of novel catalytic antibodies.

Thyroid-stimulating hormone-induced down-regulation of thyroid transcription factor 1 in rat thyroid FRTL-5 cells

Thyroid transcription factor 1 (TTF-1) is thought to play an important role in the expression of genes that encode thyroid-specific proteins such as thyroglobulin, thyroid peroxidase, and TSH-receptor. The role of TSH in the regulation of TTF-1 messenger RNA (mRNA) and protein abundance was investigated in rat thyroid FRTL-5 cells. Northern blot analysis revealed that TSH reduced TTF-1 mRNA abundance in a dose- and time-dependent manner. Immunoblot analysis with rabbit antibodies prepared against a recombinant fragment of TTF-1 expressed in bacteria showed that TSH also reduced the amount of TTF-1 protein in FRTL-5 cells. Whereas the effect of TSH on TTF-1 mRNA was apparent after 3 h, the effect on TTF-1 protein was not apparent until 12 h after TSH addition to the cells. Both TTF-1 mRNA and protein were significantly decreased after the addition of (Bu)2 cAMP or forskolin for 24 h, whereas they were not decreased by 12-O-tetradecanoyl-phorbol-13-acetate. These results indicate that TSH down-regulates TTF-1 expression in FRTL-5 cells via the cAMP pathway.

Inclusion of an upstream transcriptional terminator in phage display vectors abolishes background expression of toxic fusions with coat protein g3p

Expression of toxic gene products affects bacterial cell growth and phage display, causing a strong selection against plasmid maintenance and integrity. During phage propagation steps, in particular, phagemid instability can dramatically affect diversity of antibody libraries or even lead to the deletion of antibody genes. We constructed a modified phage display vector by introducing a strong transcriptional terminator upstream of the lac promoter, which together with glucose suppression of its CAP-dependent activation, very efficiently represses product formation before induction.

Activation and repression of E. coli promoters

There is no organism in which transcription initiation is better understood than Escherichia coli. Recent studies using genetics, biochemistry and structure analysis have revealed how RNA polymerase interactions at promoters are regulated. Prominent examples include the recruitment of polymerase by activators touching its alpha and sigma subunits; which subunit is touched depends on which activator is used and where it binds the DNA. The less-common cases centering on enhancer-dependent transcription use an entirely different mechanism, involving either DNA looping or tracking.

Effect of cAMP binding site mutations on the interaction of cAMP receptor protein with cyclic nucleoside monophosphate ligands and DNA

Although cAMP binding to wild type cAMP receptor protein (CRP) induces specific DNA binding and activates transcription, cyclic nucleoside monophosphate (cNMP) binding to the CRP mutant Ser128 --> Ala does not, whereas the double CRP mutant Thr127 --> Leu/Ser128 --> Ala activates transcription even in the absence of cNMP. Isothermal titration calorimetry measurements on the cNMP binding reactions to the S128A and T127L/S128A mutants show that the reactions are mainly entropically driven as is cAMP binding to CRP. In contrast to cAMP binding to CRP, the binding reactions are noncooperative and exothermic with binding enthalpies (DeltaHb) ranging from -23.4 +/- 0.9 kJ mol-1 for cAMP binding to S128A at 39 degrees C to -4.1 +/- 0.6 kJ mol-1 for cAMP binding to T127L/S128A at 24 degrees C and exhibit enthalpy-entropy compensation. To account for the inactivity of the S128A mutant, in vitro and in vivo DNA binding experiments were performed on the cAMP-ligated S128A mutant. The cAMP-ligated S128A mutant binds to the consensus DNA binding site with approximately the same affinity as that of cAMP-ligated CRP but forms a different type of complex, which may account for loss of transcriptional activity by the mutant. Energy minimization computations on the cAMP-ligated S128A mutant show that amino acid conformational differences between S128A and CRP occur at Ser179, Glu181, and Thr182 in the center of the DNA binding site, implying that these conformational changes may account for the difference in DNA binding.

Transcription factor recognition surface on the RNA polymerase alpha subunit is involved in contact with the DNA enhancer element

The carboxy-terminal one-third of Escherichia coli RNA polymerase alpha subunit plays a key role in transcription regulation by a group of protein transcription factors and DNA enhancer (UP) elements. The roles of individual amino acid residues within this regulatory domain of the alpha subunit were examined after systematic mutagenesis of the putative contact regions (residues 258-275 and 297-298) for the cAMP receptor protein (CRP). The reconstituted RNA polymerases containing the mutant alpha subunits were examined for their response to transcription activation by cAMP-CRP and the rrnBP1 UP element. Mutations affecting CRP responsiveness were located on the surface of the putative CRP contact helix and most of these mutations also influenced the response to the rrnB UP element. These observations raise the possibility that the CRP contact surface is also involved in contact with the DNA UP element, although some amino acid residues within this region play different roles in molecular communication with CRP and the UP element. Among the amino acid residues constituting the contact surface, Arg265 was found to play a major role in response to both CRP and the DNA UP element. Judged by DNase I footprinting analysis, alpha mutants defective in transcription from the CRP-dependent lacP1 promoter showed decreased activity in the cooperative binding of CRP. Likewise, mutants defective in rrnBP1 transcription showed decreased binding to the UP element. The amino acid residues important for contact with both CRP and DNA are conserved in the alpha subunits of not only bacterial, but also chloroplast RNA polymerases.