trp repressor/trp operator interaction. Equilibrium and kinetic analysis of complex formation and stability

Riboregulation in bacteria: From general principles to novel mechanisms of the trp attenuator and its sRNA and peptide products

Gene expression strategies ensuring bacterial survival and competitiveness rely on cis- and trans-acting RNA-regulators (riboregulators). Among the cis-acting riboregulators are transcriptional and translational attenuators, and antisense RNAs (asRNAs). The trans-acting riboregulators are small RNAs (sRNAs) that bind proteins or base pairs with other RNAs. This classification is artificial since some regulatory RNAs act both in cis and in trans, or function in addition as small mRNAs. A prominent example is the archetypical, ribosome-dependent attenuator of tryptophan (Trp) biosynthesis genes. It responds by transcription attenuation to two signals, Trp availability and inhibition of translation, and gives rise to two trans-acting products, the attenuator sRNA rnTrpL and the leader peptide peTrpL. In Escherichia coli, rnTrpL links Trp availability to initiation of chromosome replication and in Sinorhizobium meliloti, it coordinates regulation of split tryptophan biosynthesis operons. Furthermore, in S. meliloti, peTrpL is involved in mRNA destabilization in response to antibiotic exposure. It forms two types of asRNA-containing, antibiotic-dependent ribonucleoprotein complexes (ARNPs), one of them changing the target specificity of rnTrpL. The posttranscriptional role of peTrpL indicates two emerging paradigms: (1) sRNA reprograming by small molecules and (2) direct involvement of antibiotics in regulatory RNPs. They broaden our view on RNA-based mechanisms and may inspire new approaches for studying, detecting, and using antibacterial compounds. This article is categorized under: RNA Interactions with Proteins and Other Molecules > Small Molecule-RNA Interactions RNA Interactions with Proteins and Other Molecules > RNA-Protein Complexes Regulatory RNAs/RNAi/Riboswitches > Regulatory RNAs.

A small-molecule chemical interface for molecular programs

In vitro molecular circuits, based on DNA-programmable chemistries, can perform an increasing range of high-level functions, such as molecular level computation, image or chemical pattern recognition and pattern generation. Most reported demonstrations, however, can only accept nucleic acids as input signals. Real-world applications of these programmable chemistries critically depend on strategies to interface them with a variety of non-DNA inputs, in particular small biologically relevant chemicals. We introduce here a general strategy to interface DNA-based circuits with non-DNA signals, based on input-translating modules. These translating modules contain a DNA response part and an allosteric protein sensing part, and use a simple design that renders them fully tunable and modular. They can be repurposed to either transmit or invert the response associated with the presence of a given input. By combining these translating-modules with robust and leak-free amplification motifs, we build sensing circuits that provide a fluorescent quantitative time-response to the concentration of their small-molecule input, with good specificity and sensitivity. The programmability of the DNA layer can be leveraged to perform DNA based signal processing operations, which we demonstrate here with logical inversion, signal modulation and a classification task on two inputs. The DNA circuits are also compatible with standard biochemical conditions, and we show the one-pot detection of an enzyme through its native metabolic activity. We anticipate that this sensitive small-molecule-to-DNA conversion strategy will play a critical role in the future applications of molecular-level circuitry.

Optimal performance of the tryptophan operon of E. coli: a stochastic, dynamical, mathematical-modeling approach

In this work, we develop a detailed, stochastic, dynamical model for the tryptophan operon of E. coli, and estimate all of the model parameters from reported experimental data. We further employ the model to study the system performance, considering the amount of biochemical noise in the trp level, the system rise time after a nutritional shift, and the amount of repressor molecules necessary to maintain an adequate level of repression, as indicators of the system performance regime. We demonstrate that the level of cooperativity between repressor molecules bound to the first two operators in the trp promoter affects all of the above enlisted performance characteristics. Moreover, the cooperativity level found in the wild-type bacterial strain optimizes a cost-benefit function involving low biochemical noise in the tryptophan level, short rise time after a nutritional shift, and low number of regulatory molecules.

An analysis of the binding of repressor protein ModE to modABCD (molybdate transport) operator/promoter DNA of Escherichia coli

Expression of the modABCD operon in Escherichia coli, which codes for a molybdate-specific transporter, is repressed by ModE in vivo in a molybdate-dependent fashion. In vitro DNase I-footprinting experiments identified three distinct regions of protection by ModE-molybdate on the modA operator/promoter DNA, GTTATATT (-15 to -8; region 1), GCCTACAT (-4 to +4; region 2), and GTTACAT (+8 to +14; region 3). Within the three regions of the protected DNA, a pentamer sequence, TAYAT (Y = C or T), can be identified. DNA-electrophoretic mobility experiments showed that the protected regions 1 and 2 are essential for binding of ModE-molybdate to DNA, whereas the protected region 3 increases the affinity of the DNA to the repressor. The stoichiometry of this interaction was found to be two ModE-molybdate per modA operator DNA. ModE-molybdate at 5 nM completely protected the modABCD operator/promoter DNA from DNase I-catalyzed hydrolysis, whereas ModE alone failed to protect the DNA even at 100 nM. The apparent K(d) for the interaction between the modA operator DNA and ModE-molybdate was 0.3 nM, and the K(d) increased to 8 nM in the absence of molybdate. Among the various oxyanions tested, only tungstate replaced molybdate in the repression of modA by ModE, but the affinity of ModE-tungstate for modABCD operator DNA was 6 times lower than with ModE-molybdate. A mutant ModE(T125I) protein, which repressed modA-lac even in the absence of molybdate, protected the same region of modA operator DNA in the absence of molybdate. The apparent K(d) for the interaction between modA operator DNA and ModE(T125I) was 3 nM in the presence of molybdate and 4 nM without molybdate. The binding of molybdate to ModE resulted in a decrease in fluorescence emission, indicating a conformational change of the protein upon molybdate binding. The fluorescence emission spectra of mutant ModE proteins, ModE(T125I) and ModE(Q216*), were unaffected by molybdate. The molybdate-independent mutant ModE proteins apparently mimic in its conformation the native ModE-molybdate complex, which binds to a DNA sequence motif of TATAT-7bp-TAYAT.

Affinity and specificity of trp repressor-DNA interactions studied with fluorescent oligonucleotides

Fluorescence-based solution methods have been used to study the binding of the trp repressor of Escherichia coli to a series of oligonucleotides bearing all or partial determinants for high affinity specific binding. The tryptophan, salt concentration and competitor DNA dependence of the binding affinities was examined for these targets. Binding to a fluorescein-labeled 20 base-pair hairpin structure oligonucleotide, which contains a palindromic repressor binding site (GAACTAGTTAACTAGTAC) and is known to bind repressor in a 1 : 1 dimer-DNA complex, resulted in a protein concentration-dependent, competable static quenching of fluorescence in presence of co-repressor, l-tryptophan. The affinity recovered from the fits of these intensity profiles at 100 mM KCl was on the order of 4x10(8) M-1. In absence of co-repressor an increase in intensity at high repressor concentration (>10(-7) M) was observed. The salt concentration dependence of the specific binding of the holo-repressor to this oligonucleotide was approximately half as large as what would be predicted by the number of phosphate contacts in the crystal structures of the complex. Repressor binding to the fluorescein-labeled hairpin 20mer was compared with binding to a rhodamine-labeled 36 base-pair oligonucleotide bearing two inverted structural half-sites GNACT separated by an eight base-pair spacer containing none of the natural intervening sequence. The rather low affinity observed for the 36mer revealed that the intervening sequence in the natural operators contains energetic specificity determinants. Binding to a rhodamine-labeled oligonucleotide bearing a completely non-specific sequence was shown to occur over the same concentration range (>100 nM), regardless of tryptophan concentration, whereas binding to sequences bearing partial specificity ratio between 100 and 1000, depending upon the salt concentration. Even in absence of added KCl, the specificity ratio of trp repressor was greater than 100, implicating a significant free energy contribution from non-electrostatic interaction forces.

Design and optimization of a capillary electrophoretic mobility shift assay involving trp repressor-DNA complexes

An investigation of DNA-protein interactions by capillary electrophoresis (CE) with laser fluorometric detection is performed that combines the rapid and minimal sample consumption methods of CE with the selective separation influence of mobility shift assays. An inspection of the well characterized interaction between the trp repressor of Escherichia coli and the trp operator (DNA) is the basis of the assay. The use of fluorescently tagged operator not only lends itself to laser-induced fluorescence detection but also precludes the use of radiolabeled detection. It is demonstrated that composition and pH of the running buffer are critical for maximized efficiency and resolution of operator from the repressor-operator complex. Quantitative studies showed reaction of repressor with operator resulted in the diminishing of free operator signal and the simultaneous creation of the repressor-operator peak that is well resolved from the free operator. Also examined was the ability to perform qualitative studies involving non-specific interactions between the operator and a complex protein sample. It is shown that the specificity of operator for repressor can be used to selectively separate the repressor from a complex sample that includes non-specific proteins.

Kinetic and thermodynamic analysis of the interaction between TRAP (trp RNA-binding attenuation protein) of Bacillus subtilis and trp leader RNA

In Bacillus subtilis, expression of the tryptophan biosynthetic genes is regulated in response to tryptophan by an RNA-binding protein called TRAP (trp RNA-binding attenuation protein). TRAP has been shown to contain 11 identical subunits arranged in a symmetrical ring. Kinetic and thermodynamic parameters of the interaction between tryptophan-activated TRAP and trp leader RNA were studied. Results from glycerol gradients and mobility shift gels indicate that two TRAP 11-mers bind to each trp leader RNA. A filter binding assay was used to determine an apparent binding constant of 8.0 +/- 1.3 x 10(9) m-1 (Kd = 0.12 +/- 0.02 nM) for TRAP and an RNA containing residues +36 to +92 of the trp leader RNA in 1 mM L-tryptophan at 37 degrees C. The temperature dependence of Kapp was somewhat unexpected demonstrating that the delta H of the interaction is highly unfavorable at + 15.9 kcal mol-1. Therefore, the interaction is completely driven by a delta S of +97 cal mol-1 K-1. The interaction between tryptophan-activated TRAP and trp leader RNA displayed broad salt and pH activity profiles. Finally, the rate of RNA dissociation from the RNA-TRAP.tryptophan ternary complex was found to be very slow in high concentrations of tryptophan (> 40 microM) but increased in lower tryptophan concentrations. This suggests that dissociation of tryptophan from the ternary complex is the rate-limiting step in RNA dissociation.

Fluorescence anisotropy assays implicate protein-protein interactions in regulating trp repressor DNA binding

The study of interactions between proteins and nucleic acids is central to the understanding of the control of genetic expression. Fluorescence anisotropy has been used to measure, in solution, the equilibrium binding profiles of a bacterial repressor protein, the tryptophan repressor (TR), to a fluorescently labeled oligonucleotide containing one of its target operator sequences. Investigation of the effects of changing concentrations of corepressor, operator DNA, and protein implicate TR oligomers in the regulation of DNA binding. These studies also demonstrate that the relatively straightforward technique of fluorescence anisotropy can be applied to the study of the interactions between proteins and nucleic acids. The fluorescence technique exhibits sufficient sensitivity to replace radioactive methods of detection in most cases. In addition, since it is a solution-based methodology, it offers a true equilibrium measure of the protein-nucleic acid equilibria, and the effects of changes in solution conditions such as salt and ligand concentration, pH, and temperature can be readily evaluated. Data acquisition is relatively simple and rapid, and the data are of sufficient quality for detailed thermodynamic analyses of complex systems. Given these attributes, fluorescence anisotropy will find multiple applications in the area of genetic regulation.