Structural basis of gene regulation by the tetracycline inducible Tet repressor-operator system

The tetracycline repressor (TetR) regulates the most abundant resistance mechanism against the antibiotic tetracycline in grain-negative bacteria. The TetR protein and its mutants are commonly used as control elements to regulate gene expression in higher eukaryotes. We present the crystal structure of the TetR homodimer in complex with its palindromic DNA operator at 2.5 A resolution. Comparison to the structure of TetR in complex with the inducer tetracycline-Mg2+ allows the mechanism of induction to be deduced. Inducer binding in the repressor core initiates conformational changes starting with C-terminal unwinding and shifting of the short helix a6 in each monomer. This forces a pendulum-like motion of helix a4, which increases the separation of the attached DNA binding domains by 3 A, abolishing the affinity of TetR for its operator DNA.     

Tet repressor induction by tetracycline: a molecular dynamics, continuum electrostatics, and crystallographic study

The Tet repressor (TetR) mediates the most important mechanism of bacterial resistance against tetracycline (Tc) antibiotics. In the absence of Tc, TetR is tightly bound to its operator DNA; upon binding of Tc with an associated Mg²⁺ ion, it dissociates from the DNA, allowing expression of the repressed genes. Its tight control by Tc makes TetR broadly useful in genetic engineering. The Tc binding site is over 20 Å from the DNA, so the binding signal must propagate a long distance. We use molecular dynamics simulations and continuum electrostatic calculations to test two models of the allosteric mechanism. We simulate the TetR:DNA complex, the Tc-bound, “induced” TetR, and the transition pathway between them. The simulations support the model inferred previously from the crystal structures and reveal new details. When [Tc:Mg]⁺ binds, the Mg²⁺ ion makes direct and water-mediated interactions with helix 8 of one TetR monomer and helix 6 of the other monomer, and helix 6 is pulled in towards the central core of the structure. Hydrophobic interactions with helix 6 then pull helix 4 in a pendulum motion, with a maximal displacement at its N-terminus: the DNA interface. The crystal structure of an additional TetR reported here corroborates this motion. The N-terminal residue of helix 4, Lys48, is highly conserved in DNA-binding regulatory proteins of the TetR class and makes the largest contribution of any amino acid to the TetR:DNA binding free energy. Thus, the conformational changes lead to a drastic reduction in the TetR:DNA binding affinity, allowing TetR to detach itself from the DNA. Tc plays the role of a specific Mg²⁺ carrier, whereas the Mg²⁺ ion itself makes key interactions that trigger the allosteric transition in the TetR:Tc complex.     

A differential scanning calorimetry study of tetracycline repressor.

Tetracycline repressor (TetR), which constitutes the most common mechanism of bacterial resistance to an antibiotic, is a homodimeric protein composed of two identical subunits, each of which contains a domain possessing a helix-turn-helix motif and a domain responsible for binding tetracycline. Binding of tetracycline in the protein pocket is accompanied by conformational changes in TetR, which abolish the specific interaction between the protein and DNA. Differential scanning calorimetry (DSC) and CD measurements, performed at pH 8.0, were used to observe the thermal denaturation of TetR in the absence and presence of tetracycline. The DSC results show that, in the absence of tetracycline, the thermally induced transitions of TetR can be described as an irreversible process, strongly dependent on scan rate and indicating that the protein denaturation is under kinetic control described by the simple kinetic scheme: N(2)--->D(2), where k is a first-order kinetic constant, N is the native state, and D is the denatured state. On the other hand, analysis of the scan rate effect on the transitions of TetR in the presence of tetracycline shows that thermal unfolding of the protein can be described by the two-state model: N(2)<--->U(2)--->D. In the proposed model, TetR in the presence of tetracycline undergoes co-operative unfolding, characterized by an enthalpy change (DeltaH(cal) = 1067 kJ x mol(-1)) and an entropy change (DeltaS = 3.1 kJ x mol(-1)).     

Mechanism of Tet repressor induction by tetracyclines: length compensates for sequence in the alpha8-alpha9 loop

Natural Tet repressor (TetR) variants are alpha-helical proteins bearing a large loop between helices 8 and 9, which is variable in sequence and length. We have deleted this loop consisting of 14 amino acid residues in TetR(D) and rebuilt it stepwise with up to 42 alanine residues. All except the mutant with the longest alanine loop show wild-type repression, but none is inducible with tetracycline. This demonstrates the importance of the alpha8-alpha9 loop and its amino acid sequence for induction. The induction efficiencies increase with loop length, when the more tightly binding inducer anhydrotetracycline is used. The largest increase of inducibility was observed for TetR mutants with loop lengths between eight and 17 alanine residues. Since loop residues Asp/Glu157 and Arg158 are conserved in the natural TetR sequence variants, we constructed a mutant in which all other residues of the loop were replaced by alanine. This mutant exhibits increased anhydrotetracycline induction compared to the corresponding alanine variant. Thus, these residues are important for induction. Binding constants for the anhydrotetracycline-TetR interaction are below the detection level of 10(5) M(-1) for the mutant with a loop of two alanine residues and increase sharply until a loop size of ten residues is reached. TetR variants with longer loops have similar anhydrotetracycline-binding constants, ranging between 2.6 x 10(9) M(-1) and 8.0 x 10(9) M(-1), about 500-fold lower than wild-type TetR. The increase of the affinity occurs at shorter loop lengths than that of inducibility. We conclude that the induction defect of the polyalanine variants arises from two increments: (i) the loop must have a minimal length-to allow efficient inducer binding; (ii) the loop must structurally participate in the conformational change associated with induction.     

Tet repressor-tetracycline interaction

Previous studies [Wasylewskiet al. (1996),J. Protein Chem. 15, 45–58] have shown that the W43 residue localized within the helix-turn-helix structure domain of Tet repressor can exist in the ground state in two conformational states. In this paper we investigate the fluorescence properties of W43 of TetR upon binding of tetracycline inducer and its chemical analogs such as anhydro- and epitetracycline. Binding of the drug inducer to the protein indicates that the W43 residue still exists in two conformational states; however, its environment changes drastically, as can be judged by the changes in fluorescence parameters. The FQRS (fluorescence-quenching-resolved spectra) method was used to decompose the total emission spectrum. The resolved spectra exhibit maxima of fluorescence at 346 and 332 nm and the component quenchable by KI (346 nm) is shifted 9 nm toward the blue side of the spectrum upon inducer binding. The observed shift does not result from the changes in the exposure of W43, since the bimolecular quenching rate constant remains the same and is equal to about 2.7×10⁹M^–1sec^–1. The binding of tetracycline leads to drastic decrease of the W43 fluorescence intensity and increase of the tetracycline intensity as well as the decrease of fluorescence lifetime, especially of the W43 component characterized by the emission at 332 nm. The observed energy transfer from W43 to tetracycline is more efficient for the state characterized by the fluorescence emission at 332 nm (88%) than for the component quenchable by iodide (53%) Tetracycline and several of its derivatives were also used to observe how chemical modifications of the hydrophilic groups in tetracycline influence the mechanism of binding of the antibiotic to Tet repressor. By use of pulsed-laser photoacoustic spectroscopy it is shown that the binding of tetracyclines to Tet repressor leads to significant increase of tetracycline fluorescence quantum yields. Steady-state fluorescence quenching of tetracycline analogs in complexes with Tet repressor using potassium iodide as a quencher allowed us to determine the dependence of the exposure of bound antibiotic on the modifications of hydrophilic substituents of tetracycline. Circular dichroism studies of the TetR-[Mg · tc]⁺ complex do not indicate dramatic changes in the secondary structure of the protein; however, the observed small decrease in the TetR helicity may occur due to partial unfolding of the DNA recognition helix of the protein. The observed changes may play an important role in the process of induction in which tetracycline binding results in the loss of specific DNA binding.Abbreviations FQRS fluorescence-quenching-resolved spectra - HTH helix-turn-helix motif - tc tetracycline - TetR tetracycline repressor from Escherichia coli - TetR WT wild-type TetR - TetR W43 single point mutant with phenylalanine substituted for tryptophan at position 75 in both subunits     

A direct photo-activated affinity modification of tetracycline transcription repressor protein TetR(D) with tetracycline(1)

Results of a first successful application of a direct photo-induced affinity modification of Tet repressor (TetR(D)) protein with tetracycline within a complex of known three-dimensional structure are described. The conditions of the modification have provided suitable yields of the modified complex and allowed characterization of the modified segments of the protein. The potential of tetracycline as a fine modifying reagent was established. In the complex of TetR(D) protein with tetracycline, the antibiotic modifies at least two segments, Ile59-Glu73 and Ala173-Glu183, which form a binding tunnel for the drug according to the X-ray analysis. These data open possibilities for the use of different tetracycline targets for structural studies in solution.     

Tet repressor residues indirectly recognizing anhydrotetracycline.

Two tetracycline repressor (TetR) sequence variants sharing 63% identical amino acids were investigated in terms of their recognition specificity for tetracycline and anhydrotetracycline. Thermodynamic complex stabilities determined by urea-dependent unfolding reveal that tetracycline stabilizes both variants to a similar extent but that anhydrotetracycline discriminates between them significantly. Isofunctional TetR hybrid proteins of these sequence variants were constructed and their denaturation profiles identified residues 57 and 61 as the complex stability determinant. Association kinetics reveal different recognition of these TetR variants by anhydrotetracycline, but the binding constants indicate similar stabilization. The identified residues connect to an internal water network, which suggests that the discrepancy in the observed thermodynamics may be caused by an entropy effect. Exchange of these interacting residues between the two TetR variants appears to influence the flexibility of this water organization, demonstrating the importance of buried, structural water molecules for ligand recognition and protein function. Therefore, this structural module seems to be a key requisite for the plasticity of the multiple ligand binding protein TetR.     

Domain motions accompanying Tet repressor induction defined by changes of interspin distances at selectively labeled sites.

To investigate internal movements in Tet repressor (TetR) during induction by tetracycline (tc) we determined the interspin distances between pairs of nitroxide spin labels attached to specific sites by electron paramagnetic resonance (EPR) spectroscopy. For this purpose, we constructed six TetR variants with engineered cysteine pairs located in regions with presumed conformational changes. These are I22C and N47C in the DNA reading head, T152C/Q175C, A161C/Q175C and R128C/D180C near the tc-binding pocket, and T202C in the dimerization surface. All TetR mutants show wild-type activities in vivo and in vitro. The binding of tc results in a considerable decrease of the distance between the nitroxide groups attached to both I22C residues in the TetR dimer and an increase of the distance between the N47C residues. These opposite effects are consistent with a twisting motion of the DNA reading heads. Changes of the spin-spin interactions between nitroxide groups attached to residues near the tc-binding pocket demonstrate that the C-terminal end of alpha-helix 9 moves away from the protein core upon DNA binding. Alterations of the dipolar interaction between nitroxide groups at T202C indicate different conformations for tc and DNA-bound repressor also in the dimerization area. These results are used to model structural changes of TetR upon induction.     

Teaching TetR to recognize a new inducer

Tet Repressor (TetR) recognizes the inducer tetracycline (tc) with high affinity. The tc analog 4-de(dimethylamino)-6-deoxy-6-demethyl-tetracycline (cmt3) is not an inducer for TetR. Induction specificity for cmt3 was generated by employing a directed evolution approach to screen appropriate TetR mutants in four successive steps. The specificity of the best TetR mutant is more than 20,000-fold increased for cmt3 over tc as judged by the ratio of their respective binding constants. Two rounds of directed evolution via DNA shuffling revealed His64 as a key residue for inducer specificity. The best TetR mutant with cmt3 specificity contains the H64K exchange, leading to a 300-fold decreased tc and a 20-fold increased cmt3 affinity. Another round of directed evolution made use of randomized oligonucleotides to mutate selected residues close to the tc-binding pocket of TetR and yielded TetR S135L with a 250-fold increased cmt3 affinity. The double mutant TetR H64K S135L was constructed and again subjected to directed evolution using randomized oligonucleotides to alter residues in the "secondary shell" of the tc-binding pocket. The resulting best mutants TetR H64K E114Q S135L, TetR A61V H64K Q109E Q116E S135L and TetR H64K T112K S135L are fully inducible by cmt3 and not by tc. Thus, their inducer specificity has been redesigned. The molecular mechanism of changed inducer recognition is discussed, based on binding constants with several tc analogs and in light of the TetR crystal structure.     

Functionally important residues of the Tet repressor inducing peptide TIP determined by a complete mutational analysis

Tet repressor (TetR) is widely used to control gene expression in pro- and eukaryotes. The mechanism of induction by its natural inducer tetracycline is well characterized. A 16-mer oligopeptide, called TIP, fused to thioredoxin A (TrxA) of Escherichia coli is an artificial inducer of TetR. We analyzed the sequence requirements of TIP by directed and random single amino acid substitutions and identified residues important for TetR induction. An alanine scanning analysis of the first twelve residues showed that all except the ones at position eleven and twelve are important for induction. A randomization of residues at positions one to twelve of TIP revealed the properties of each residue necessary for induction. These further insights into the specificity of TIP-TetR interaction are discussed in the light of the X-ray structure of the [TetR-TIP] complex. The last four residues of TIP contribute indirectly to TetR induction by increasing the steady-state level of the fusion protein. TIP mutants fused N-terminally or C-terminally to TrxA in E. coli induce with the same efficiency indicating identical binding and induction mechanisms, and the lack of contribution from TrxA.     

Structural basis for the transcriptional repressor NicR2 in nicotine degradation from Pseudomonas

Nicotine is an environmental toxicant in tobacco wastes, imposing severe hazards for the health of human and other mammalians. NicR2, a TetR‐like repressor from Pseudomonas putida S16, plays a critical role in regulating nicotine degradation. Here, we determined the crystal structures of NicR2 and its complex with the inducer 6‐hydroxy‐3‐succinoyl‐pyridine (HSP). The N‐terminal domain of NicR2 contains a conserved helix‐turn‐helix (HTH) DNA‐binding motif, while the C‐terminal domain contains a cleft for its selective recognition for HSP. Residues R91, Y114 and Q118 of NicR2 form hydrogen bonds with HSP, their indispensable roles in NicR2's recognition with HSP were confirmed by structure‐based mutagenesis combined with isothermal titration calorimetry analysis. Based on sequence alignment and structure comparison, Tyr67, Tyr68 and Lys72 of HTH motif were corroborated to take the major responsibility for DNA‐binding using site‐directed mutants. The 30‐residue N‐terminal extension of NicR2, especially residues 21–30 in the TFR arm, is required for the association with the operator DNA. Finally, we proposed that either NicR2 or the DNA would undergo a conformational change upon their association. Altogether, our structural and biochemical investigations unravel how NicR2 selectively recognizes HSP and DNA, and provide new insights into the TetR family of repressors.     

Non-native States of Bovine Beta-Lactoglobulin Induced by Acetonitrile: pH-Dependent Unfolding of the Two Genetic Variants A and B

Acetonitrile (ACN)-induced unfolding of the beta-lactoglobulin variants A and B was investigated at pH 2.0, 7.0 and 9.0. ACN caused α-helix induction at low concentrations but lead to major conformational alterations when the concentration was raised. ACN also induced a concentration-dependent increase in the surface hydrophobicity of both the variants. Induction of α-helical structure and exposure of hydrophobic patches were, however, somewhat more pronounced in case of variant B, whereas the loss of tertiary structure was more marked for variant A. Both protein aggregation and helix induction necessitated higher ACN concentrations at pH 2.0 than at 7.0 and 9.0, suggesting the greater stability of the variants at acidic pH.     

Two mutations in the tetracycline repressor change the inducer anhydrotetracycline to a corepressor

We report for the first time the in vitro characterization of a reverse tetracycline repressor (revTetR). The dimeric wild-type repressor (TetR) binds to tet operator tetO in the absence of the inducer anhydrotetracycline (atc) to confer tight repression. We have isolated the revTetR G96E L205S mutant, which, contrary to TetR, binds tetO only in the presence of atc. This reverse acting mutant was overproduced and purified. Effector and DNA binding properties were analyzed by EMSA and quantified by fluorescence titration and surface plasmon resonance. The association constant K_A of revTetR for binding of [atcMg]⁺ is ~10⁸ M^–1, four orders of magnitude lower than that of TetR. The affinity of TetR for tetO is 5.6 ± 2 × 10⁹ M^–1 and that for revTetR in the presence of atc is 1 ± 0.2 × 10⁸ M^–1. Both induced forms, the atc-bound TetR and the free revTetR, have the same low affinity of 4 ± 1 × 10⁵ M^–1 for DNA. Therefore, atc does not act as a dimerization agent for revTetR. We discuss the structural differences between TetR and revTetR potentially underlying this reversal of activity.