Thermal denaturation of engineered tet repressor proteins and their complexes with tet operator and tetracycline studied by temperature gradient gel electrophoresis

The effects of Trp to Phe exchanges in the Tet repressor on the thermal stability of the proteins and their complexes with operator DNA and inducer have been studied by temperature gradient polyacrylamide gel electrophoresis. The denaturation temperatures obtained by this method are compared with the results from temperature-dependent fluorescence and binding activities of the proteins. It is established that exchanging the interior Trp75 to Phe reduces the thermal stability of the Tet repressor by 8 degrees C while exchanging the exterior Trp43 to Phe has no effect on the stability of the protein. Binding of the inducer tetracycline increases the thermal stability of wild-type and Trp43 to Phe mutant Tet repressors by 5 degrees C, while the ones with the Trp75 to Phe mutation are stabilized by 10 degrees C. The stabilizing effect of operator binding is 20 degrees C in the Trp75 to Phe mutant and only 9 degrees C in the ones with the Trp43 to Phe exchange. In addition to the denaturation temperatures, the gel mobility shifts observed in temperature gradient gel electrophoresis reveal also information about the intermediates of the denaturation reaction. The free proteins and their complexes with the inducer tetracycline exhibit monophasic transitions upon denaturation. The operator complexes of wild-type and Trp75 to Phe mutant repressors denature in more complex reactions. At low temperature they exhibit a stoichiometry of two repressor dimers per tandem tet operator DNA. Upon elevating the temperature they form complexes with only one repressor dimer per DNA fragment. When the temperature is further increased the double-stranded DNA begins to melt from one end resulting in a complex with partially single-stranded DNA which exists only in a narrow temperature range. Finally, the denatured protein and single-stranded DNA are formed at high temperature. The associated mobility shifts are analyzed by changing the ionic strength and characterizing multiphasic melting of a pure DNA fragment by temperature gradient gel electrophoresis.     

Fluorescence and Phosphorescence Study of Tet Repressor–Operator Interaction

Fluorescence and phosphorescence measurements have been carried out on single-p tryptophan (Trp 43 or Trp 75)-containing mutants of Tet repressor (Tet R). Tet R containing Trp 43, the residue localized in the DNA recognition helix of the repressor, has been used to observe the binding of Tet R to two 20-bp DNA sequences of tet O₁ and tet O₂ operators. Binding of Tet R to tet O₁ operator leads to a 78% decrease of the repressor fluorescence intensity, with an accompanying 20-nm blue shift of its fluorescence emission maximum to 330 nm. Upon binding of Tet R to tet O₂ operator, the Trp 43 fluorescence intensity is quenched by 60%, and a 10-nm shift of its emission maximum to 340 nm occurs. Solute fluorescence quenching studies, using acrylamide, performed at low ionic strength indicate that in both the complex of Tet R with the O₁ and that with the O₂ operator, Trp 43 is moderately buried, as indicated by a bimolecular rate quenching constant of about 1.8 × 10⁹ M^–1 sec^–1. In contrast to the Tet R–tet O₂ complex, the Stern–Volmer acrylamide quenching constant K _sv of the complex with tet O₁ operator changes from 7.5 M^–1 at 5 mM NaCl to 22 M^–1 at 200 mM NaCl, indicating different exposures of Trp 43 in the two complexes in solutions of higher ionic strength. Phosphorescence studies showed a 0–0 vibronic transition at 408 and 403 nm for Trp 43 and Trp 75, respectively. Upon binding of Tet R to the tet operators, we observed red shifts of 0–0 vibronic bands of Trp 43 to 413 and 412 nm for tet O₁ and tet O₂ operator, respectively, and the phosphorescence triplet lifetime of Trp 43 at 75 K was quenched from 6.0–5.5 to 3.5–3.3 sec. The thermal phosphorescence quenching profile ranged from –200°C to –20°C, and differed drastically for the two complexes, suggesting different dynamics of the microenvironment of the Trp 43 residue. The luminescence data for Trp 43 of Tet R suggest that the recognition helix of Tet R interacts in different fashions with the tet O₁ and tet O₂ operators.     

Structural analysis of the operator binding domain of Tn10-encoded Tet repressor: a time-resolved fluorescence and anisotropy study.

An engineered Tn10-encoded Tet repressor, bearing a single Trp residue at position 43, in the putative alpha-helix-turn-alpha-helix motif of the operator binding domain, was studied by time-resolved fluorescence and anisotropy. Fluorescence intensity decay data suggested the existence of two classes of Trp-43, defined by different lifetimes. Analysis of anisotropy data were consistent with a model in which each class was defined by a different lifetime, rotational correlation time, and fluorescence emission maximum. The long-lifetime class had a red-shifted spectrum, similar to that of tryptophan zwitterion in water, and a short rotational correlation time. In contrast, the spectrum of the short-lifetime class was blue-shifted 10 nm compared to that of the long-lifetime class. Its correlation time was similar to that of the protein, which showed that Trp in this class was entirely constrained. Trp in this latter class could not be quenched by iodide, whereas most of the long-lifetime class was easily accessible. Presence of disruptive agents, such as 1 M GuCl or 3 M KCl, did not alter markedly the lifetimes but increased the weight of the short-lifetime component. In the same time, the rotational correlation time of this component was dramatically reduced. Taken together, our data suggest that the long-lifetime class could correspond to the tryptophan residues exposed to solvent whereas the short-lifetime class would correspond to the tryptophan residues embedded inside the hydrophobic core holding the helix-turn-helix motif. Destabilization of hydrophobic interactions would lead to an increase in the weight of the latter class for entropic reasons. Analysis of the fluorescence parameters of Trp-43 could provide structural information on the operator binding domain of Tet repressor.     

Engineered Tet repressor mutants with single tryptophan residues as fluorescent probes. Solvent accessibilities of DNA and inducer binding sites and interaction with tetracycline

Mutants of the Tn10-encoded Tet repressor containing single or no tryptophan residues were constructed by oligonucleotide-directed mutagenesis. The Trp-75 to Phe exchange reduces the dissociation rate of the complex with the inducer tetracycline by a factor of 2. The Trp-43 to Phe exchange has no effect on inducer binding. The fluorescence emission spectra of both tryptophan residues are quenched to a different extent by binding of tetracycline: Trp-75 is quenched to zero and Trp-43 to only 50%. It is concluded that Trp-75 is in the vicinity of the inducer binding site. The different fluorescence emission spectra of both tryptophan residues depend on the native structure of Tet repressor. Quenching studies with iodide indicate that the DNA binding motif is solvent exposed in free repressor and moves towards the interior of the protein upon inducer binding. The inducer binding site is in the interior of the protein. The fluorescence of tetracycline is enhanced upon binding to Tet repressor. The excitation at 280 nm results mainly from the change in environment and in part from energy transfer from tryptophan to the drug.     

Trp scanning analysis of Tet repressor reveals conformational changes associated with operator and anhydrotetracycline binding.

We analysed the conformational states of free, tet operator-bound and anhydrotetracycline-bound Tet repressor employing a Trp-scanning approach. The two wild-type Trp residues in Tet repressor were replaced by Tyr or Phe and single Trp residues were introduced at each of the positions 162-173, representing part of an unstructured loop and the N-terminal six residues of alpha-helix 9. All mutants retained in vivo inducibility, but anhydrotetracycline-binding constants were decreased up to 7.5-fold when Trp was in positions 169, 170 and 173. Helical positions (168-173) differed from those in the loop (162-167) in terms of their fluorescence emission maxima, quenching rate constants with acrylamide and anisotropies in the free and tet operator-complexed proteins. Trp fluorescence emission decreased drastically upon atc binding, mainly due to energy transfer. For all proteins, either free, tet operator bound or anhydrtetracycline-bound, mean fluorescence lifetimes were determined to derive quenching rate constants. Solvent-accessible surfaces of the respective Trp side chains were calculated and compared with the quenching rate constants in the anhydrotetracycline-bound complexes. The results support a model, in which residues in the loop become more exposed, whereas residues in alpha-helix 9 become more buried upon the induction of TetR by anhydrotetracycline.     

Tet repressor binding induced curvature of tet operator DNA.

Tet repressor dimer binds to two tet operator sites spaced by 30 bp in the Tn10 encoded tet regulatory DNA. The effect of repressor binding on the gel mobility of circular permutated DNA fragments containing either one or both operator sequences is reported. The EcoRI induced bending of DNA is used to compare the results with other protein binding induced structural perturbations of DNA. Tet repressor bends a DNA fragment with a single tet operator to an angle of 42 degrees +/- 7 degrees. The apparent bend angle of DNA fragments containing the tandem tet operator arrangement occupied by two Tet repressor dimers turns out to be 52 degrees +/- 9 degrees. These results are interpreted with respect to the end to end distances of the bent DNA fragments. They indicate that either the intervening tet regulatory DNA between the operators or the bound operator sequences themselves contain additional perturbations from the canonical B-DNA structure. This finding is discussed in the light of previously obtained results from CD, neutron scattering, and electrooptical studies.     

A fluorescence study of Tn10-encoded Tet repressor

Steady-state fluorescence quenching and time-resolved measurements have been performed to resolve the fluorescence contributions of the two tryptophan residues, W43 and W75, in the subunit of the homodimer of the Tet repressor fromEscherichia coli. The W43 residue is localized within the helix-turn-helix structural domain, which is responsible for sequence-specific binding of the Tet repressor to thetet operator. The W75 residue is in the protein matrix near the tetracycline-binding site. The assignment of the two residues has been confirmed by use of single-tryptophan mutants carrying either W43 or W75. The FQRS (fluorescence-quenching-resolved-spectra) method has been used to decompose the total emission spectrum of the wild-type protein into spectral components. The resolved spectra have maxima of fluorescence at 349 and 324 nm for the W43 and W75 residues, respectively. The maxima of the resolved spectra are in excellent agreement with those found using single-tryptophan-containing mutants. The fluorescence decay properties of the wild type as well as of both mutants of Tet repressor have been characterized by carrying out a multitemperature study. The decays of the wild-type Tet repressor and W43-containing mutant can be described as being of double-exponential type. The W75 mutant decay can be described by a Gaussian continuous distribution centered at 5.0 nsec with a bandwidth equal to 1.34 nsec. The quenching experiments have shown the presence of two classes of W43 emission. One of the components, exposed to solvent, has a maximum of fluorescence emission at 355 nm, with the second one at about 334 nm. The red-emitting component can be characterized by bimolecular-quenching rate constant,k _q equal to 2.6×10⁹, 2.8×10⁹, and 2.0×10⁹ M^–1 sec^–1 for acrylamide, iodide, and succinimide, respectively. The bluer component is unquenchable by any of the quenchers used. The W75 residue of the Tet repressor has quenching rate constant equal to 0.85×10⁹ and 0.28 × 10⁹ M^–1 sec^–1 for acrylamide and succinimide, respectively. These values indicate that the W75 is not deeply buried within the protein matrix. Our results indicate that the Tet repressor can exist in its ground state in two distinct conformational states which differ in the microenvironment of the W43 residue.Abbreviations FQRS fluorescence-quenching-resolved spectra - HTH helix-turn-helix motif - TetR tetracycline repressor fromE. coli - WT wild-type TetR - W43 single point mutant with phenyloalanine substituted for tryptophan at position 75 in both subunits - W75 single point mutant with phenyloalanine substituted for tryptophan at position 43 in both subunits     

Tet repressor-tet operator contacts probed by operator DNA-modification interference studies

Contacts between tet operator DNA and Tet repressor protein are characterized by modification interference studies. The modified DNA fragments are separated into fractions with high, intermediate and low affinities for Tet repressor by polyacrylamide gel electrophoresis. Ethylation of the phosphates with N-ethylnitrosourea reveals 12 contacts of a repressor dimer to tet operator. Eight of these contacts appear to be important for Tet repressor binding, as judged by the strong interference at these positions, while four contacts are probably less important. All of the phosphate contacts are located on the same side of the B-DNA structure. The sequences of tet operators proposed to interact with the recognition alpha-helix of Tet repressor are TCTATC in three cases and CCTATC in one case. After methylation of N-7 with dimethylsulfate, strong interference is observed at the guanine residues at positions +/- 2. None of the N-7 functions of other guanine residues seems to be involved in tight contacts to Tet repressor. Tet repressor subunits form identical phosphate and guanine N-7 contacts with each half side of the two tet operators indicating twofold dyad symmetry of the complexes. Attempts to analyze the methylation interference at the adenine N-3 sites reveal different results for the operators. Modification of DNA fragments with diethylpyrocarbonate yields hypersensitive sites in the tet operators, indicating different local DNA structures. Carbethoxylation interference studies confirm the contacts at the purines found by methylation interference. All of the sequence-specific protein-DNA contacts detected in this study are centered at the inside four base-pairs in each tet operator half side. The contacts are discussed with respect to the structure of the repressor-operator complex.     

Contacts between Tet repressor and tet operator revealed by new recognition specificities of single amino acid replacement mutants.

We have analyzed the DNA binding properties of Tet-repressor mutants with single amino acid residue replacements at eight positions within the alpha-helix-turn-alpha-helix DNA-binding motif. A saturation mutagenesis of Gln38, Pro39, Thr40, Tyr42, Trp43 and His44 in the second alpha-helix was performed; in addition, several substitutions of Thr27 and Arg28 in the first alpha-helix were constructed. The abilities of these mutant repressors to bind a set of 16 operator variants were determined and revealed 23 new binding specificities. All repressor mutants with DNA-binding activity were inducible by tetracycline, while mutants lacking binding activity were trans-dominant over the wild-type. All mutant proteins were present at the same intracellular steady-state concentrations as the wild-type. These results suggest the structural integrity of the mutant repressors. On the basis of the new recognition specificities, five contacts between a repressor monomer and each operator half-site and the chemical nature of these repressor-operator interactions are proposed. We suggest that Arg28 contacts guanine of the G.C base-pair at operator position 2 with two H-bonds, Gln38 binds adenine of the A.T base-pair at position 3 with two H-bonds, and the methyl group of Thr40 participates in a van der Waals' contact with cytosine of the G.C base-pair at position 6 of tet operator. A previously unrecognized type of interaction is proposed for Pro39, which inserts its side-chain between the methyl groups of the thymines of T.A and A.T base-pairs at positions 4 and 5. Computer modeling of these proposed contacts reveals that they are possible using the canonical structures of the helix-turn-helix motif and B-DNA. These contacts suggest an inverse orientation of the Tet repressor helix-turn-helix with respect to the operator center as compared with non-inducible repressor-operator complexes, and are supported by similar contacts of other repressor-operator complexes.     

Saturation mutagenesis of the Tn10-encoded tet operator O1. Identification of base-pairs involved in Tet repressor recognition

Saturation mutagenesis of Tn10-encoded tet operator O1 was performed by chemical synthesis of 30 sequence variants yielding all possible point mutations of an operator half side. Their effect on Tet repressor binding was scored by an in-vivo repressor titration system. Tet repressor affinities of selected operator mutants were further characterized in vitro by dissociation rate measurements. The O1 sequence spans 19 base-pairs. Out of these, all 18 palindromic base-pairs are involved in Tet repressor recognition. The central base-pair does not contribute to sequence-specific binding of Tet repressor. At position 1 a pyrimidine residue is sufficient for maximal affinity to the repressor. At positions 2, 3 and 4, each mutation reduces repressor binding at least tenfold. Mutations at positions 5, 6, 7, 8 and 9 result in less drastic reductions of Tet repressor binding. Differential effects of mutations at a given position are used to deduce the chemical functions contacted by Tet repressor. The T.A to A.T transversion at position 9 increases Tet repressor affinity slightly, while all other mutations decrease repressor binding. The increased affinity of the wild-type tet operator O2 compared to wild-type O1 results from the addition of two favorable transversions at positions +/- 9 and an unfavorable T.A to C.G transition at position -7. Deletion or palindromic doubling of the central base-pair of the O1 palindrome reveals that the wild-type spacing of both operator half sides is crucial for efficient Tet repressor binding.     

A possible tertiary structure change induced by acrylamide in the DNA-binding domain of the Tn10-encoded Tet repressor. A fluorescence study

A thorough investigation of the acrylamide fluorescence quenching of F75TetR, a mutant of the Tn10-encoded TetR repressor containing a single Trp residue at position 43, was carried out. The Trp-43 residue is located in a helix-turn-helix (H-t-H) motif involved in the specific binding of F75TetR to the operator site in specific DNA. Distinct Ranges of acrylamide concentration have been assumed. At acrylamide concentrations below 0.15–0.2 M (a usual range of values in fluorescence quenching studies) the observed limited tertiary structure change induced by acrylamide is consistent with a noncooperative local unfolding of the DNA-binding domain. It is suggested that penetration of the neutral quencher could cause the deletion of a hydrophobic tertiary structure contact, partly involving TrP-43, responsible for the anchoring of the H-t-H motif inside the three-helix protein bundle, characterizing the N-terminal part. Correspondingly, the affinity of the mutant repressor for the operator was shown to decrease substantially (about five orders of magnitude), seemingly losing its specificity. A subsequent phase, up to 0.8 M acrylamide, was observed in which the involved intermediate protein structure is not further perturbed, nor is DNA binding.Abbreviations Tris tris(hydroxymethyl)aminomethane - DTT dithiothreitol - FVSTetR engineered tetracycline repressor in which the Trp residue at the position 75 in the wild-type repressor TetR is replaced by a Phe residue - H-t-H helix-turn-helix super-secondary structure     

Functional roles of amino acid residues involved in forming the alpha-helix-turn-alpha-helix operator DNA binding motif of Tet repressor from Tn10.

The Tn10 derived Tet repressor contains an amino acid segment with high homology to the alpha-helix-turn-alpha-helix motif (HTH) of other DNA binding proteins. The five most conserved amino acids in HTH are probably involved in structural formation of the motif. Their functional role was probed by saturation mutagenesis yielding 95 single amino acid replacement mutants of Tet repressor. Their binding efficiencies to tet operator were quantitatively determined in vivo. All functional mutants contain amino acid substitutions consistent with their proposed role in a HTH. In particular, only the two smallest amino acids (serine, glycine) can substitute a conserved alanine in the proposed first alpha-helix without loss of activity. The last position of the first alpha-helix, the second position in the turn, and the fourth position in the second alpha-helix require mostly hydrophobic residues. The proposed C-terminus of the first alpha-helix is supported by a more active asparagine compared to glutamine replacement mutant of the wt leucine residue. The turn is located close to the protein surface as indicated by functional lysine and arginine replacements for valine. A glycine residue at the first position in the turn can be replaced by any amino acid yielding mutants with at least residual tet operator affinity. A structural model of the HTH of Tet repressor is presented.     

Nucleotide sequence of the gene, protein purification and characterization of the pSC101-encoded tetracycline resistance-gene-repressor

The nucleotide sequence of the pSC101-encoded tetracycline repressor gene (tetR) was confirmed. The deduced amino acid sequence is compared to that of other repressor proteins. To overproduce the repressor protein, tetR was placed under the control of bacteriophage lambda promoter pL. Tet repressor protein was purified to homogeneity and shown to bind specifically to two tet operators and also to tetracycline (Tc). The inducer function of Tc is demonstrated by the loss of the specific binding between the tet operator DNA and the Tet repressor-Tc complex.     

A fluorescence study of Tn10-encoded Tet repressor

Steady-state fluorescence quenching and time-resolved measurements have been performed to resolve the fluorescence contributions of the two tryptophan residues, W43 and W75, in the subunit of the homodimer of the Tet repressor fromEscherichia coli. The W43 residue is localized within the helix-turn-helix structural domain, which is responsible for sequence-specific binding of the Tet repressor to thetet operator. The W75 residue is in the protein matrix near the tetracycline-binding site. The assignment of the two residues has been confirmed by use of single-tryptophan mutants carrying either W43 or W75. The FQRS (fluorescence-quenching-resolved-spectra) method has been used to decompose the total emission spectrum of the wild-type protein into spectral components. The resolved spectra have maxima of fluorescence at 349 and 324 nm for the W43 and W75 residues, respectively. The maxima of the resolved spectra are in excellent agreement with those found using single-tryptophan-containing mutants. The fluorescence decay properties of the wild type as well as of both mutants of Tet repressor have been characterized by carrying out a multitemperature study. The decays of the wild-type Tet repressor and W43-containing mutant can be described as being of double-exponential type. The W75 mutant decay can be described by a Gaussian continuous distribution centered at 5.0 nsec with a bandwidth equal to 1.34 nsec. The quenching experiments have shown the presence of two classes of W43 emission. One of the components, exposed to solvent, has a maximum of fluorescence emission at 355 nm, with the second one at about 334 nm. The red-emitting component can be characterized by bimolecular-quenching rate constant,k _q equal to 2.6×10⁹, 2.8×10⁹, and 2.0×10⁹ M^?1 sec^?1 for acrylamide, iodide, and succinimide, respectively. The bluer component is unquenchable by any of the quenchers used. The W75 residue of the Tet repressor has quenching rate constant equal to 0.85×10⁹ and 0.28 × 10⁹ M^?1 sec^?1 for acrylamide and succinimide, respectively. These values indicate that the W75 is not deeply buried within the protein matrix. Our results indicate that the Tet repressor can exist in its ground state in two distinct conformational states which differ in the microenvironment of the W43 residue.     

Resolution of the fluorescence decay of the two tryptophan residues of lac repressor using single tryptophan mutants.

We have studied the time-resolved intrinsic tryptophan fluorescence of the lac repressor (a symmetric tetramer containing two tryptophan residues per monomer) and two single-tryptophan mutant repressors obtained by site-directed mutagenesis, lac W201Y and lac W220Y. These mutant repressor proteins have tyrosine substituted for tryptophan at positions 201 and 220, respectively, leaving a single tryptophan residue per monomeric subunit at position 220 for the W201Y mutant and at position 201 in the W220Y mutant. It was found that the two decay rates recovered from the analysis of the wild type data do not correspond to the rates recovered from the analysis of the decays of the mutant proteins. Each of these residues in the mutant repressors displays at least two decay rates. Global analysis of the multiwavelength data from all three proteins, however, yielded results consistent with the fluorescence decay of the wild type lac repressor corresponding simply to the weighted linear combination of the decays from the mutant proteins. The effect of ligation by the antagonistic ligands, inducer and operator DNA, was similar for all three proteins. The binding of the inducer sugar resulted in a quenching of the long-lived species, while binding by the operator decreased the lifetime of the short components. Investigation of the time-resolved anisotropy of the intrinsic tryptophan fluorescence in these three proteins revealed that the depolarization of fluorescence resulted from a fast motion and the global tumbling of the macromolecule. Results from the simultaneous global analysis of the frequency domain data sets from the three proteins revealed anisotropic rotations for the macromolecule, consistent with the known elongated shape of the repressor tetramer. In addition, it appears that the excited-state dipole of tryptophan 220 is alighed with the long axis of the repressor.     

Fluorescence Quenching Studies of Trp Repressor–Operator Interaction

Steady-state quenching and time-resolved fluorescence measurements of L-tryptophan binding to the tryptophan-free mutant W19/99F of the tryptophan repressor of Escherichia coli have been used to observe the coreperessor microenvirnment changes upon ligand binding. Using iodide and acrylamide as quenchers, we have resolved the emission spectra of the corepressor into two components. The bluer component of L-tryptophan buried in the holorepressor exhibits a maximum of the fluorescence emission at 336 nm and can be characterized by a Stern–Volmer quenching constant equal to about 2.0–2.3 M^?1. The second, redder component is exposed to the solvent and possesses the fluorescence emission and Stern–Volmer quenching constant characteristic of L-tryptophan in the solvent. When the Trp holorepressor is bound to the DNA operator, further alterations in the corepressor fluorescence are observed. Acrylamide quenching experiments indicate that the Stern–Volmer quenching constant of the buried component of the corepressor decreases drastically to a value of 0.56 M^?1. The fluorescence lifetimes of L-tryptophan in a complex with Trp repressor decrease substantially upon binding to DNA, which indicates a dynamic mechanism of the quenching process.     

A threonine to alanine exchange at position 40 of Tet repressor alters the recognition of the sixth base pair of tet operator from GC to AT.

The tet operators of two naturally evolved tetracycline resistance determinants differ by a G.C to A.T transition at the sixth base pair. This mutation prevents heterologous recognition of these tet operators by their respective two Tet repressor proteins. The amino acid side chains responsible for this sequence-specific distinction of operators were determined. For this purpose in vitro recombinants of the two tetR genes were constructed. Restriction sites were introduced by oligonucleotide-directed mutagenesis in both genes followed by the exchange of different coding segments between them. The encoded chimeric Tet repressor proteins were expressed and their operator recognition specificity was scored in vivo. Exchanging gradually smaller coding segments led finally to a single amino acid exchange in both genes at position 40 of the primary structures. Each Tet repressor containing Thr at this position recognizes the G.C operator while those with Ala recognize the A.T operator regardless of the rest of the sequences. This result demonstrates clearly that the amino acid 40 of Tet repressor contacts and recognizes base pair 6 of tet operator. Sterical interference of the large Thr side chain with the methyl group of A.T and a possible involvement of the hydroxyl in hydrogen bonding to the operator are discussed as the molecular basis of this differentiation between A.T and G.C base pairs.     

TET repressor.tet operator complex formation induces conformational changes in the tet operator DNA.

The structural changes of the tet operator DNA upon binding of the TET repressor protein are examined by circular dichroism. For this purpose a 70 bp DNA fragment was prepared which contains both tet operators. About 67% of the base pairs of this DNA are involved in specific interaction with the TET repressor. A rather large change in the CD of the DNA is induced by binding of the TET repressor. The shape of the CD difference spectrum is similar to the respective difference found for the lac operator DNA upon complex formation with the lac repressor. However, the effect induced by the TET repressor on tet operator DNA seems to comprise both the specific and non-specific effect of the lac repressor on the structure of DNA [Culard, F. and Maurizot, J.C. (1981) Nucl. Acids Res. 9, 5157-5184]. Specificity of binding is confirmed by the lack of any effect of the TET repressor on the CD of a 95 bp lac operator containing DNA fragment, by the reduced mobility of TET repressor.tet operator complexes on polyacrylamide gels under CD conditions, and by a titration experiment of tet operator DNA with TET repressor employing the CD change. The latter experiment reveals a stoichiometry of four TET repressors per tet operon control region.     

Fluorescence quenching studies of Trp repressor-operator interaction

Steady-state quenching and time-resolved fluorescence measurements of L-tryptophan binding to the tryptophan-free mutant W19/99F of the tryptophan repressor of Escherichia coli have been used to observe the coreperessor microenvirnment changes upon ligand binding. Using iodide and acrylamide as quenchers, we have resolved the emission spectra of the corepressor into two components. The bluer component of L-tryptophan buried in the holorepressor exhibits a maximum of the fluorescence emission at 336 nm and can be characterized by a Stern–Volmer quenching constant equal to about 2.0–2.3 M^–1. The second, redder component is exposed to the solvent and possesses the fluorescence emission and Stern–Volmer quenching constant characteristic of L-tryptophan in the solvent. When the Trp holorepressor is bound to the DNA operator, further alterations in the corepressor fluorescence are observed. Acrylamide quenching experiments indicate that the Stern–Volmer quenching constant of the buried component of the corepressor decreases drastically to a value of 0.56 M^–1. The fluorescence lifetimes of L-tryptophan in a complex with Trp repressor decrease substantially upon binding to DNA, which indicates a dynamic mechanism of the quenching process.