Radiation abolishes inducer binding to lactose repressor

The lactose operon functions under the control of the repressor-operator system. Binding of the repressor to the operator prevents the expression of the structural genes. This interaction can be destroyed by the binding of an inducer to the repressor. If ionizing radiations damage the partners, a dramatic dysfunction of the regulation system may be expected. We showed previously that gamma irradiation hinders repressor-operator binding through protein damage. Here we show that irradiation of the repressor abolishes the binding of the gratuitous inducer isopropyl-1-beta-D-thiogalactoside (IPTG) to the repressor. The observed lack of release of the repressor from the complex results from the loss of the ability of the inducer to bind to the repressor due to the destruction of the IPTG binding site. Fluorescence measurements show that both tryptophan residues located in or near the IPTG binding site are damaged. Since tryptophan damage is strongly correlated with the loss of IPTG binding ability, we conclude that it plays a critical role in the effect. A model was built that takes into account the kinetic analysis of damage production and the observed protection of its binding site by IPTG. This model satisfactorily accounts for the experimental results and allows us to understand the radiation-induced effects.     

Allosteric regulation of inducer and operator binding to the lactose repressor

The effects of cysteine modification and variations in pH on the equilibrium parameters for inducer and operator binding to the lactose repressor protein were examined. Operator binding affinity was minimally affected by increasing the pH from 7.5 to 9.2, whereas inducer binding was decreased for both the unliganded protein and the repressor-operator complex over the same range. Inducer binding to the repressor became more cooperative at high pH. The midpoint for the change in inducer affinity and cooperativity was pH 8.3; this value correlates well with cysteine ionization. The differential between repressor-operator affinity in the presence and absence of inducer was significantly decreased by modification of the protein with methyl methanethiosulfonate (MMTS). In contrast to unreacted protein, the inducer binding parameters for MMTS-modified repressor were largely unaffected by pH variation. The free energy for formation of the completely liganded protein was calculated for two pathways; the delta G values for these two independent routes were equivalent only for stoichiometries of four inducers and two operators per repressor molecule. All of the binding data were analyzed quantitatively by using a Monod-Wyman-Changeux two-state model for allosteric regulation. The observed dependences of the isopropyl beta-D-thiogalactoside binding curves on pH, DNA concentration, and MMTS modification were fitted by varying only the equilibrium constant between the two conformational states of the protein. With this analysis, high pH favors the T (high operator/low inducer affinity) state, while modification of cysteine-281 with MMTS elicits a shift into the R (high inducer/low operator affinity) state.(ABSTRACT TRUNCATED AT 250 WORDS)     

A mutant lactose repressor with altered inducer and operator binding parameters

The lactose repressor protein from the mutant Escherichia coli BG185 contains valine at position 81 instead of alanine. Spectroscopic, chemical and direct binding measurements demonstrate that the BG185 protein exhibits properties similar to the wild-type repressor-inducer complex. Kinetic measurements of inducer binding to BG185 repressor yielded rate constants that were more than two orders of magnitude smaller than those observed for wild-type repressor; these results suggest that the structural transitions required for inducer binding are markedly impaired by the mutation. The fluorescence spectral shift in response to inducer binding was identical for mutant and wild-type proteins. This identity indicates direct effects of inducer binding on the tryptophan(s) near the sugar binding site rather than environmental changes consequent to conformational shifts. Analogy to the bacterial sugar binding proteins suggest that the Ala to Val change at position 81 in BG185 repressor yields a molecule that is fixed in a closed, sugar-binding conformation.     

Arginine 197 of lac repressor contributes significant energy to inducer binding. Confirmation of homology to periplasmic sugar binding proteins.

Based on primary sequence homology between the lactose repressor protein and periplasmic sugar-binding proteins (Müller-Hill, B. (1983) Nature 302, 163-164), a hypothetical sugar-binding site for the lac repressor was proposed using the solved x-ray crystallographic structure of the arabinose-binding protein (ABP) (Sams, C. F., Vyas, N. K., Quiocho, F. A., and Matthews, K. S. (1984) Nature 310, 429-430). By analogy to Arg151 in the ABP sugar site, Arg197 is predicted to play an important role in lac repressor binding to inducer sugars. Hydrogen bonding occurs between Arg151 and the ring oxygen and 4-hydroxyl of the sugar ligand, two backbone carbonyls, and a side chain in ABP, and similar interactions in the lac repressor would be anticipated. To test this hypothesis, Arg197 in the lac repressor protein was altered by oligonucleotide-directed site-specific mutagenesis to substitute Gly, Leu, or Lys. Introduction of these substitutions at position 197 had no effect on operator binding parameters of the isolated mutant proteins, whereas the affinity for inducer was dramatically decreased, consistent with in vivo phenotypic behavior obtained by suppression of nonsense mutations at this site (Kleina, L. G., and Miller, J. H. (1990) J. Mol. Biol. 212, 295-318). Inducer binding affinity was reduced approximately 3 orders of magnitude for Leu, Gly, or Lys substitutions, corresponding to a loss of 50% of the free energy of binding. The pH shift characteristic of wild-type repressor is conserved in these mutants. Circular dichroic spectra demonstrated no significant alterations in secondary structure for these mutants. Thus, the primary effect of substitution for Arg197 is a very significant decrease in the affinity for inducer sugars. Arginine is uniquely able to make the multiple contacts found in the ABP sugar site, and we conclude that this residue plays a similar role in sugar binding for lactose repressor protein. These results provide experimental validation for the proposed homology between ABP and the lac repressor and suggest that homology with ABP may be employed to generate additional insight into the structure and function of this regulatory protein.     

Diethyl pyrocarbonate reaction with the lactose repressor protein affects both inducer and DNA binding

Modification of the lactose repressor protein of Escherichia coli with diethyl pyrocarbonate (DPC) results in decreased inducer binding as well as operator and nonspecific DNA binding. Spectrophotometric measurements indicated a maximum of three histidines per subunit was modified, and quantitation of lysine residues with trinitrobenzenesulfonate revealed the modification of one lysine residue. The loss of DNA binding, both operator and nonspecific, was correlated with histidine modification; removal of the carbethoxy groups from the histidines by hydroxylamine was accompanied by significant recovery of DNA binding function. The presence of inducing sugars during the DPC reaction had no effect on histidine modification or the loss of DNA binding activity. In contrast, inducer binding was not recovered upon reversal of the histidine modification. However, the presence of inducer during reaction protected lysine from reaction and also prevented the decrease in inducer binding; these results indicate that reaction of the lysine residue(s) may correlate to the loss of sugar binding activity. Since no difference in incorporation of radiolabeled carbethoxy was observed following reaction with diethyl pyrocarbonate in the presence or absence of inducer, the reagent appears to function as a catalyst in the modification of the lysine. The formation of an amide bond between the affected lysine and a nearby carboxylic acid moiety provides a possible mechanism for the activity loss. Reaction of the isolated NH2-terminal domain resulted in loss of DNA binding with modification of the single histidine at position 29. Results from the modification of core domain paralleled observations with intact repressor.     

Time resolved spectroscopy of the tryptophyl fluorescence of the E. coli LAC repressor.

A new crystal form of a mitogenic lectin from pea seeds ($\text{Pisum sativum}$) has been obtained which is suitable for high resolution structural work. The crystals are orthorhombic, space group P2₁2₁2₁, with unit cell dimensions: $\text{a}$ = 64.2Å, $\text{b}$ = 72. 7Å, $\text{c}$ = 108. 3Å. The asymmetric unit contains one protein molecule.     

Comparison of the E. coli lac repressor and its tryptic core by hydrogen exchange studies. Effect of inducer binding.

The effect of the tryptophan pyrolysis product harman on colony forming ability, DNA-synthesis and DNA-repair was investigated in human alveolar tumor cells A549. Colony forming ability and overall DNA synthetic capacity decreased linearly with increasing harman concentration and reached values of 20 % and 29 % of untreated controls, respectively, at 200 μM. Harman also inhibited the repair of N-acetoxy-2-acetylaminofluorene induced DNA damage, as measured by the alkaline elution procedure. While incision of parental DNA occurred normally in the presence of harman the reconstitution of control molecular weights was strongly inhibited. These effects of harman may play a role in its co-mutagenic activity.     

Sequence-specific binding of arc repressor to DNA. Effects of operator mutations and modifications

A set of arc operators with transition and/or transversion mutations at each operator base pair has been constructed. By determining the ability of Arc to bind these variant operators, the importance of each base pair for Arc recognition has been assessed. Methylation protection experiments have also been used to probe points of close contact between Arc and most of the mutant operators. These data, together with phosphate interference results obtained previously for the wild type operator, provide information about the operator surface that is contacted when Arc binds.     

Thermodynamic analysis of inducer binding to the lactose repressor protein: contributions of galactosyl hydroxyl groups and beta substituents

Kinetic and equilibrium studies of the binding of modified beta-D-galactoside sugars to the lac repressor were carried out to generate thermodynamic data for protein-inducer interactions. The energetic contributions of the galactosyl hydroxyl groups to binding were assessed by using a series of methyl deoxyfluoro-beta-D-galactosides. The C-3 and C-6 hydroxyls contributed less than or equal to -2.3 and -1.7 +/- 0.3 kcal/mol to the binding free energy change, respectively, whereas the C-4 hydroxyl provided only a nominal contribution (-0.1 +/- 0.2 kcal/mol). Favorable contributions to the total binding free energy change were observed for replacement of O-methyl by S-methyl at the beta-anomeric position and for S-methyl by S-isopropyl. Negative delta H degrees values characteristic of protein-sugar complexes [Quiocho, F. A. (1986) Annu. Rev. Biochem. 55, 287-315] were observed for a series of beta-D-galactosides differing at the beta-glycosidic position. A decrease in delta H degrees of approximately 6 kcal/mol upon replacement of the O-methyl substituent by S-methyl indicates a substantial increase in van der Waals' interactions and/or hydrogen bonding in this region of the ligand binding site. The more favorable free energy change for the binding of the S-isopropyl vs S-methyl compound is due mainly to more positive entropic contributions, consistent with an increase in apolar interactions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formation of mixed disulfide adducts at cysteine-281 of the lactose repressor protein affects operator and inducer binding parameters

The lactose repressor protein has been modified with three sulfhydryl-specific reagents which form mixed disulfide adducts. Methyl methanethiosulfonate (MMTS) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) completely reacted with all three cysteine residues, whereas only partial reaction was observed with didansylcystine. Cysteines-107 and -140 reacted stoichiometrically with MMTS and DTNB, while Cys-281 was modified only at higher molar ratios. Didansylcystine reacted primarily with cysteines-107 and -140. Affinity of MMTS-modified repressor for 40 base pair operator DNA was decreased 30-fold compared to unmodified repressor, and this decrease correlated with modification of cysteine-281. DTNB-modified repressor bound operator DNA with a 50-fold weaker affinity than unmodified repressor. Modification of the lac repressor with didanylcystine decreased operator binding only 4-fold, and nonspecific DNA binding increased 3-fold compared to unmodified repressor. No change in the inducer equilibrium binding constant was observed following modification with any of these reagents. In contrast, inducer association and dissociation rate constants were decreased approximately 50-fold for repressor completely modified with MMTS or DTNB, while didansylcystine had minimal effect on inducer binding kinetics. Correlation between modification of Cys-281 and the observed decrease in rate constants indicates that this region of the protein regulates the accessibility of the sugar binding site. The parallel between the increase in the Kd for repressor binding to operator, the altered rate constant for inducer binding, and modification of cysteine-281 suggests that this region of the protein is crucially involved in the function of the repressor protein.     

Structure-based design of Tet repressor to optimize a new inducer specificity

We constructed a mutant of the tetracycline-inducible repressor protein TetR with specificity for the tc analogue 4-de(dimethylamino)anhydrotetracycline (4-ddma-atc), which is neither an antibiotic nor an inducer for the wild-type protein. The previously published relaxed specificity mutant TetR H64K S135L displays reduced induction by tc but full induction by doxycycline (dox), anhydrotetracycline (atc), and 4-de(dimethylamino)-6-demethyl-6-deoxytetracycline (cmt3). To create induction specificity for tc derivatives lacking the 4-dimethylamino grouping such as cmt3 and 4-ddma-atc, the residues at positions 82 and 138, which are located close to that moiety in the crystal structure of the TetR-[tc-Mg](+)(2) complex, were randomized. We anticipated that a residue with increased size may lead to sterical hindrance, and screening for 4-ddma-atc-specific induction indeed revealed the mutant TetR H64K S135L S138I. Out of 24 exchanges only the addition of S138I to TetR H64K S135L yielded a mutant with a pronounced reduction of affinity for atc and dox, while the one for 4-ddma-atc is not affected. The ratio of binding constants revealed a 200-fold specificity increase for 4-ddma-atc over atc. The contributions of each single mutant to specificity indicate that the tc variants bind slightly different positions in the TetR tc binding pocket.     

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.     

Two helix DNA binding motif of CAP found in lac repressor and gal repressor.

Comparison of both the DNA and protein sequences of catabolite gene activator protein (CAP) with the sequences of lac and gal repressors shows significant homologies between a sequence that forms a two alpha-helix motif in CAP and sequences near the amino terminus of both repressors. This two-helix motif is thought to be involved in specific DNA sequence recognition by CAP. The region in lac repressor to which CAP is homologous contains many i-d mutations that are defective in DNA binding. Less significant sequence homologies between CAP and phage repressors and activators are also shown. The amino acid residues that are critical to the formation of the two-helix motif are conserved, while those residues expected to interact with DNA are variable. These observations suggest the lac and gal repressors also have a two alpha-helix structural motif which is involved in DNA binding and that this two helix motif may be generally found in many bacterial and phage repressors. We conclude that one major mechanism by which proteins can recognize specific base sequences in double stranded DNA is via the amino acid side chains of alpha-helices fitting into the major groove of B-DNA.