Mutants in position 69 of the Trp repressor ofEscherichia coli K12 with altered DNA-binding specificity

Structural analysis by X-ray crystallography has indicated that direct contact occurs between Arg69, the second residue of the first helix of the helix-turn-helix (HTH) motif of the Trp repressor, and guanine in position 9 of the -centred consensustrp operator. We therefore replaced residue 69 of the Trp repressor with Gly, Ile, Leu or Gln and tested the resultant repressor mutants for their binding to synthetic symmetrical -or -centredtrp operator variants, in vivo and in vitro. We present genetic and biochemical evidence that Ile in position 69 of the Trp repressor interacts specifically with thymine in position 9 of the -centredtrp operator. There are also interactions with other bases in positions 8 and 9 of the -centredtrp operator. In vitro, the Trp repressor of mutant RI69 binds to the consensus -centredtrp operator and a similartrp operator variant that carries a T in position 9. In vivo analysis of the interactions of Trp repressor mutant RI69 with symmetrical variants of the -centredtrp operator shows a change in the specificity of binding to a -centred symmetricaltrp operator variant with a gua-nine to thymine substitution in position 5, which corresponds to position 9 of the -centredtrp operator.     

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of β-galactosidase with symmetric variants of α- and β-centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the α-centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the α-centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. AI80, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for α-centered trp operator variants with exchanges in positions 3, 4 and 5.     

Co-operative binding of two Trp repressor dimers to α- or β-centred trp operators

The α-centred trp operator binds one dimer of the Trp repressor, whereas the β-centred trp operator binds two dimers of the Trp repressor (Carey et al., 1991; Haran et al., 1992). The Trp repressor with a Tyr-Gly-7 substitution binds almost as well as the wild-type Trp repressor to the α-centred trp operator, but it does not bind to the β-centred trp operator. This confirms that Tyr-7 is involved in the interaction between Trp repressor dimers, as seen in the crystal structure (Lawson and Carey, 1993). Further experiments with a-centred trp operator variants showed that positions 1 of the a-centred trp operators play a crucial role in tetramerisation. The two innermost base pairs of the α-centred trp operator are not involved in contacts with the dimer of the Trp repressor binding to it. However, substitutions in these positions (T-A to G-T) effectively transform the α-centred trp operator into a β-centred trp operator, and thus encourage the binding of two Trp repressor dimers to this operator. Finally, we demonstrate, with suitable heterodimers, that one subunit of each dimer suffices to bind to a β-centred trp operator.     

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of -galactosidase with symmetric variants of - and -centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the -centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the -centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. AI80, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for -centered trp operator variants with exchanges in positions 3, 4 and 5.     

Direct identification of the amino acid changes in two mutant lac repressors.

Deletions extending into the trp operon at one terminus and the lacI control region at the other terminus have been examined. One of these, B116, ends within the trp leader sequence and eliminates the trp attenuator site, placing the synthesis of lac repressor under trp control. We have isolated and characterized the B116 repressor. The protein sequence of the aminoterminus of B116 shows that an additional 16 residues are added to the amino-terminal end of wild-type repressor. Moreover, a valine residue appears in place of methionine at position 17 (the original amino-terminal residue of the wild-type repressor). A comparison of the messenger RNA sequence of the trp leader region and of the I leader region demonstrates that the translation of the B116 repressor is initiated at an AUG codon within the trp leader sequence. The GUG initiation codon at the start point for translation of wild-type repressor is now read as valine, since it appears at an internal position (residue 17 of the altered repressor). The B116 repressor accumulates at levels as high as 1% of the soluble cell protein in trpR^? strains. The efficiency of the trp leader initiation codon in translation suggests that in wild-type strains this AUG is also active in directing protein synthesis, which would result in a polypeptide consisting of 14 amino acids. We have examined the physical properties of the B116 repressor, which shows a marked tendency to form higher aggregates. Other characteristics of B116 are also described.     

Complex structure of the membrane nuclease of Streptococcus pneumoniae revealed by two-dimensional electrophoresis

Close contacts between Escherichia coli RNA polymerase and specific purine residues in the tryptophan (trp) operon promoter of Salmonella typhimurium were revealed using the methylating agent dimethyl sulfate. RNA polymerase bound to trp promoter DNA caused alterations in the rate of methylation at seven specific sites; in the anti-sense strand, guanine residues at positions ?37, ?34 and ?2 showed enhanced methylation, while those at positions ?14, ?6 and +3 showed reduced methylation. In the sense strand, only the guanine residue at ?32 showed reduced methylation. No RNA polymerase contacts with adenine residues were observed. Using the same method, close interactions between E. coli trp repressor and purine residues in the trp operator of S. typhimurium were examined. Bound trp repressor alters the methylation rates of both guanine and adenine residues from positions ?25 to +3. The points of contact are distributed rather symmetrically on both DNA strands. Three points of close contact are shared by RNA polymerase and trp repressor, supporting previous models of trp repressor action.     

Relations between divalent cation binding and ATPase activity in coupling factor from chloroplast.

Although 150 individual samples of milk from Italian water buffalo (Bubalus arnee) were examined by acid and alkaline gel electrophoresis, no polymorphism was observed for α-lactalbumin and β-lactoglobulin. After isolation and purification of these two proteins their amino acid compositions were determined and compared with those of the corresponding bovine proteins. The sequence alignments of 36 and 17 amino-acids from the N-terminal ends and 2 amino-acids from the C-terminal ends of buffalo α-lactalbumin and β-lactoglobulin, respectively, have been established. Our results indicate that buffalo α-lactalbumin differs from its cow B counterpart by a substitution Asn/Gly at position 17 and by another substitution, likely Glu/Gln or Asp/Asn, at an unknown position. Buffalo β-lactoglobulin is homologous to the bovine B variant. Three substitutions differentiate the two proteins: Ile/Leu and Val/Ile at positions 1 and 162 respectively; a further one, Gln/Ile, has not yet been located. According to these results the B variant of bovine β-lactoglobulin might be the wild type of the Bos genus.     

Computational design of a substrate specificity mutant of a protein

The wild-type trp repressor of E. coli bound 5-methoxytryptophan, a Trp analogue, less tightly than Trp. A mutant repressor (Val⁵⁸→Ala) that should bind 5-methoxytryptophan preferentially to Trp was computationally designed by free-energy calculations accompanied by free-energy decomposition. The designed mutant was demonstrated by experiments to bind 5-methoxytryptophan more tightly than Trp, consistent with the computational prediction. This success indicates the usefulness of free energy decomposition in protein design. Proteins 26:459–464 © 1996 Wiley-Liss, Inc.     

lac repressor mutants with double or triple exchanges in the recognition helix bind specifically to lac operator variants with multiple exchanges.

Several lac repressor mutants have been isolated which repress beta-galactosidase synthesis in Escherichia coli up to 200-fold. They do so by binding specifically to particular symmetrical lac Oc operator variants. The mutations in the lac repressor are localized in two separate parts of the recognition helix comprising (i) residues 1 and 2 which interact with base pairs 4 and 5 of lac operator and (ii) residue 6 which recognizes operator base pair 6. Mutations of residues 1 and 2 may be combined with a mutation of residue 6. The resulting mutant protein binds specifically to an operator variant with three symmetric exchanges in base pairs 4, 5 and 6.     

Effects of mutations in the beta subunit hinge domain on ATP synthase F1 sector rotation: interaction between Ser 174 and Ile 163

A complex of γ, ε, and c subunits rotates in ATP synthase (F_oF₁) coupling with proton transport. Replacement of βSer174 by Phe in β-sheet4 of the β subunit (βS174F) caused slow γ subunit revolution of the F₁ sector, consistent with the decreased ATPase activity [M. Nakanishi-Matsui, S. Kashiwagi, T. Ubukata, A. Iwamoto-Kihara, Y. Wada, M. Futai, Rotational catalysis of Escherichia coli ATP synthase F1 sector. Stochastic fluctuation and a key domain of the β subunit, J. Biol. Chem. 282 (2007) 20698-20704]. Modeling of the domain including β-sheet4 and α-helixB predicted that the mutant βPhe174 residue undergoes strong and weak hydrophobic interactions with βIle163 and βIle166, respectively. Supporting this prediction, the replacement of βIle163 in α-helixB by Ala partially suppressed the βS174F mutation: in the double mutant, the revolution speed and ATPase activity recovered to about half of the levels in the wild-type. Replacement of βIle166 by Ala lowered the revolution speed and ATPase activity to the same levels as in βS174F. Consistent with the weak hydrophobic interaction, βIle166 to Ala mutation did not suppress βS174F. Importance of the hinge domain [phosphate-binding loop (P-loop)/α-helixB/loop/β-sheet4, βPhe148-βGly186] as to driving rotational catalysis is discussed.     

Involvement of Val 315 located in the C-terminal region of thermolysin in its expression in Escherichia coli and its thermal stability

Thermolysin is a thermophilic and halophilic zinc metalloproteinase that consists of β-rich N-terminal (residues 1–157) and α-rich C-terminal (residues 158–316) domains. Expression of thermolysin variants truncated from the C-terminus was examined in E. coli culture. The C-terminal Lys316 residue was not significant in the expression, but Val315 was critical. Variants in which Val315 was substituted with fourteen amino acids were prepared. The variants substituted with hydrophobic amino acids such as Leu and Ile were almost the same as wild-type thermolysin (WT) in the expression amount, α-helix content, and stability. Variants with charged (Asp, Glu, Lys, and Arg), bulky (Trp), or small (Gly) amino acids were lower in these characteristics than WT. All variants exhibited considerably high activities (50–100% of WT) in hydrolyzing protein and peptide substrates. The expression amount, helix content, and stability of variants showed good correlation with hydropathy indexes of the amino acids substituted for Val315. Crystallographic study of thermolysin has indicated that V315 is a member of the C-terminal hydrophobic cluster. The results obtained in the present study indicate that stabilization of the cluster increases thermolysin stability and that the variants with higher stability are expressed more in the culture. Although thermolysin activity was not severely affected by the variation at position 315, the stability and specificity were modified significantly, suggesting the long-range interaction between the C-terminal region and active site.     

Thermodynamics,cooperativity and stability of the tetracycline repressor (TetR) upon tetracycline binding

Allosteric regulation of the Tet repressor (TetR) homodimer relies on tetracycline binding that abolishes the affinity for the DNA operator. Previously, interpretation of circular dichroism data called for unfolding of the α-helical DNA-binding domains in absence of binding to DNA or tetracycline. Our small angle X-ray scattering of TetR(D) in solution contradicts this unfolding as a physiological process. Instead, in the core domain crystal structures analyses show increased immobilisation of helix α9 and two C-terminal turns of helix α8 upon tetracycline binding. Tetracycline complexes of TetR(D) and four single-site alanine variants were characterised by isothermal titration calorimetry, fluorescence titration, X-ray crystal structures, and melting curves. Five crystal structures confirm that Thr103 is a key residue for the allosteric events of induction, with the T103A variant lacking induction by any tetracycline. The T103A variant shows anti-cooperative inducer binding, and a melting curve of the tetracycline complex different to TetR(D) and other variants. For the N82A variant inducer binding is clearly anti-cooperative but triggers the induced conformation.     

The roles of residues 5 and 9 of the recognition helix of Lac repressor in lac operator binding

We constructed expression libraries for Lac repressor mutants with amino acid exchanges in positions 1, 2, 5 and 9 of the recognition helix. We then analysed the interactions of residues 5 and 9 with operator variants bearing single or multiple symmetric base-pair exchanges in positions 3, 4 and 5 of the ideal fully symmetric lac operator. We isolated 37 independent Lac repressor mutants with five different amino acids in position 5 of the recognition helix that exhibit a strong preference for particular residues in position 2 and, to a lesser extent, in position 1 of the recognition helix. Our results suggest that residue 5 of the recognition helix (serine 21) contributes to the specific recognition of base-pair 4 of the lac operator. They further suggest that residue 9 of the recognition helix (asparagine 25) interacts non-specifically with a phosphate of the DNA backbone, possibly between base-pairs 2 and 3.     

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     

Effects of systematic variation of the minimal Escherichia coli met consensus operator site: in vivo and in vitro met repressor binding

We have produced a set of sequence variants based upon the idealized, minimal Escherichia coli met operator in which each position within the basic recognition unit, the 8bp met box (dAGACGTCT), has been changed to all other possible sequences containing single symmetrical base substitutions. The effects of these sequence variations have been assayed in vivo by monitoring the production of β-galactosidase from a standard promoter regulated by the operator variants, and in vitro by gel-retardation assay. The two sets of data are consistent and correlate well with expectations based on the three-dimensional structure of the holorepressor bound to a minimal idealized operator and the results of in vitro evolution experiments. Comparison with two natural operators, metA and metC, suggests that in vivo, with non-consensus operators, the repressor binds to at least four consecutive met boxes.     

The Primary Structure of Water Buffalo αs1- and β-Casein: Identification of Phosphorylation Sites and Characterization of a Novel β-Casein Variant

The primary structure of water buffalo α_s1-casein and of β-casein A and B variants has been determined using a combination of mass spectrometry and Edman degradation procedures. The phosphorylated residues were localized on the tryptic phosphopeptides after performing a β-elimination/thiol derivatization. Water buffalo α_s1-casein, resolved in three discrete bands by isoelectric focusing, was found to consist of a single protein containing eight, seven, or six phosphate groups. Compared to bovine α_s1-casein C variant, the water buffalo α_s1-casein presented ten amino acid substitutions, seven of which involved charged amino acid residues. With respect to bovine βA₂-casein variant, the two water buffalo β-casein variants A and B presented four and five amino acid substitutions, respectively. In addition to the phosphoserines, a phosphothreonine residue was identified in variant A. From the phylogenetic point of view, both water buffalo β-casein variants seem to be homologous to bovine βA₂-casein.     

Specificity of Mnt 'master residue' obtained from in vivo and in vitro selections

Mnt is a repressor from phage P22 that belongs to the ribbon–helix–helix family of DNA binding factors. Four amino acids from the N-terminus of the protein, Arg2, His6, Asn8 and Arg10, interact with the base pairs of the DNA to provide the sequence specificity. Raumann et al. (Nature Struct. Biol., 2, 1115–1122) identified position 6 as a ‘master residue’ that controls the specificity of the protein. Models for the interaction have residue 6 of Mnt interacting directly with position 5 of the operator. In vivo selections demonstrated that protein variants at residue 6 bound specifically to operator mutations at that position. Operators in which the wild-type G at position 5 was replaced by T specifically bound to several different protein variants, primarily hydrophobic residues. The obtained protein variants, plus some others, were used in in vitro selections to determine their preferred binding sites. The results showed that the residue at position 6 influenced the preference for binding site bases predominantly at position 5, but that the effects of altering it can extend over longer distances, consistent with its designation as a ‘master residue’. The similarities of binding sites for different residues do not correlate strongly with common measures of amino acid similarities.