Asymmetric contributions to RNA binding by the Thr(45) residues of the MS2 coat protein dimer.

A prominent feature of the interaction of MS2 coat protein with RNA is the quasi-symmetric insertion of a bulged adenine (A-10) and a loop adenine (A-4) into conserved pockets on each subunit of the coat protein dimer. Because of its presence in both of these adenine-binding pockets, Thr(45) is thought to play an important role in interaction with RNA on both subunits of the dimer. To test the significance of Thr(45), we introduced all 19 amino acid substitutions. However, we were initially unable to determine the effects of the mutations on RNA binding because every substitution compromised the ability of coat protein to fold correctly. Genetic fusion of coat protein subunits reverted these protein structural defects, allowing us to show that the RNA binding activity of coat protein tolerates substitution of Thr(45), but only on one or the other subunit of the dimer. Single-chain heterodimer complementation experiments suggest that the primary site of Thr(45) interaction with RNA is with A-4 in the translational operator. Either contact of Thr(45) with A-10 makes little contribution to stability of the RNA-protein complex, or the effects of Thr(45) substitution are offset by conformational adjustments that introduce new, favorable contacts at nearby sites.

Inhibition of human telomerase by a retrovirus expressing telomeric antisense RNA.

Human telomerase, the RNA-dependent DNA polymerase that adds TTAGGG repeats to chromosome ends, is selectively expressed in immortalised cells and most tumours, suggesting a potential role for telomerase inhibitors in cancer therapy. Replication-deficient retroviruses were used to determine whether mRNA containing UUAGGG, the complementary sequence to the template region of the hTR telomerase RNA, is sufficient to inhibit telomerase activity. Telomerase activities measured by the telomeric repeat amplification protocol (TRAP) assay in extracts prepared from immortalised mouse fibroblasts, human HeLa cells and human kidney carcinoma cells were inhibited by 75% or greater in 26 of 56 cell clones expressing UUAGGG. Telomerase activity was not inhibited by expression of mRNA containing a transposed sequence, GGGAUU. Telomerase activities in vivo were inferred from changes in cellular morphology, proliferation capacity, growth rate and measurement of the content of telomere DNA. Giant senescent-like cells emerged shortly after cloning mouse PA317 and human HeLa cells expressing UUAGGG. The fraction of giant cells varied from 100% at the fifth population doubling (PD) in one culture to 2-6% at 50 PD in several other cultures. Giant cells were absent in all parental cells and clones expressing GGGAUU. The average cellular content of telomere DNA was independent of telomerase activity over 50 PD. The results indicate that expression of RNA complementary to the template region of hTR is sufficient to inhibit telomerase in vitro and in vivo, but that the effect of inhibition on individual cells is highly variable.

Effect of lac repressor oligomerization on regulatory outcome.

Regulatory outcome in a bacterial operon depends on the interactions of all the components which influence mRNA production. Levels of mRNA can be altered profoundly by both negative and positive regulatory elements which modulate initiation of transcription. The occupancy of regulatory sites on the DNA by repressors and activators is determined not only by the affinity of these proteins for their cognate site(s) but also by the oligomeric state of the regulatory protein. The lac operon in Escherichia coli provides an excellent prototypic example of the influence of protein assembly on the transcriptional status of the associated structural genes. DNA loop formation is essential for maximal repression of the lac operon and is contingent upon the presence of multiple operator sites in the DNA and the ability of the repressor to self-associate to form a bidentate tetramer. The stability of this looped complex is enhanced significantly by DNA supercoiling. Tetramer assembly from dimers apparently occurs via interactions of a 'leucine zipper' motif in the C-terminal domain of the protein, and the tetramer is essential to formation of looped complexes. Furthermore, analysis of the DNA-binding characteristics of dimeric mutants has established that the monomer-dimer association and dimer-DNA binding (monomer does not bind to DNA) are coupled equilibria. Thus, dimer assembly is essential for generating a DNA-binding unit, and tetramer assembly is required for formation of the stable looped DNA structure that maximally represses mRNA synthesis. Protein-protein interactions therefore play a pivotal role in the regulatory activities of the lac repressor and must be considered when analysing the activities of any oligomeric DNA-binding protein.

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.

Characterization of mutations in oligomerization domain of Lac repressor protein.

A series of mutant lac repressor proteins at positions 281 or 282 was isolated for detailed characterization. Although Cys281 modification by sulfhydryl reagents abrogates pH effects on inducer binding and diminishes operator binding (Daly, T. J., Olson, J. S., and Matthews, K. S. (1986) Biochemistry 25, 5468-5474), substitution at this site by alanine, serine, phenylalanine, isoleucine, or methionine did not abolish completely the pH shift nor affect operator affinity. Thus, ionization of the sulfhydryl residue does not account fully for the alterations in inducer affinity and cooperativity of binding observed with elevated pH. Substitution for Cys281 did, however, alter the kinetic parameters for inducer association with the protein. The polarity of the side chain at 281 influenced the rates of sugar binding, presumably by altering the rate of opening/closing of the binding site. Furthermore, the presence of the branched side chain of isoleucine at position 281 disrupted oligomerization of the repressor. In contrast to the tolerance for substitution at 281, the only amino acid side chain exchanges for Tyr282 which yielded tetrameric protein with near normal operator binding characteristics were phenylalanine and leucine; this result is consistent with studies of suppressed nonsense mutations at position 282 which indicated repression occurred only for the corresponding substitutions (Kleina, L. G., and Miller, J. H. (1990) J. Mol. Biol. 221, 295-318). Despite the tetrameric character of the Y282F mutant protein, the pH dependence and cooperativity of inducer binding for this mutant protein were altered. All amino acid substitutions other than phenylalanine and leucine at this position resulted in either monomeric protein or no detectable repressor in the cell. Thus, the hydrophobic character of the side chain at position 282 is essential for tetramer formation, and the phenyl ring alone alters inducer binding parameters. The monomeric mutant proteins with substitutions for Tyr282 exhibited lower stability than their tetrameric counterparts, and the absence of dimer formation suggests alterations at this site affect both dimer and tetramer interfaces. Based on previous genetic studies and our detailed mutant characterization, the region encompassing 281 and 282, indicated by secondary structure prediction to be a turn or coil, is essential for oligomer formation and additionally exerts a strong influence on the dynamic properties of the protein, presumably mediated by interactions at the subunit interface which regulate the rate of opening and closing of the inducer binding cleft.

Evidence for leucine zipper motif in lactose repressor protein.

Amino acid sequence homology between the carboxyl-terminal segment of the lac repressor and eukaryotic proteins containing the leucine zipper motif with associated basic DNA binding region (bZIP) has been identified. Based on the sequence comparisons, site-specific mutations have been generated at two sites predicted to participate in oligomer formation based on the three-leucine heptad repeat at positions 342, 349, and 356. Leu342----Ala, Leu349----Ala, and Leu349----Pro have been isolated and their oligomeric state and ligand binding properties evaluated. These mutant proteins do not form tetramers but exist as stable dimers with inducer binding comparable with the wild-type protein. Apparent operator affinities for lac repressor proteins with mutations in the proposed bZIP domain were significantly lower than the corresponding wild-type values. For these dimeric mutant proteins, the monomer-dimer equilibrium is linked to the apparent operator binding constant. The values for the monomer-monomer binding constant and for the intrinsic operator binding constant for the dimer cannot be resolved from measurements of the observed Kd for operator DNA. Further studies on these proteins are in progress.

Macromolecular binding equilibria in the lac repressor system: studies using high-pressure fluorescence spectroscopy.

High hydrostatic pressure coupled with fluorescence polarization has been used to investigate protein subunit interactions and protein-operator association in lac repressor labeled with a long-lived fluorescent probe. On the basis of observation of a concentration-dependent sigmoidal decrease in the dansyl fluorescence polarization, we conclude that application of high hydrostatic pressure results in dissociation of the lac repressor tetramer. The 2-fold decrease in the rotational relaxation time and the high-pressure plateau are consistent with a tetramer to dimer transition. The volume change for tetramer dissociation to dimer is -82 +/- 5 mL/mol. The dissociation constant calculated from the data taken at 4.5 degrees C is 4.3 +/- 1.3 nM. The tetramer dissociation constant increases by a factor of 3 when the temperature is raised from 4.5 to 21 degrees C. A very small effect of inducer binding on the subunit dissociation is observed at 4.5 degrees C; the Kd increases from 4.5 to 7.1 nM. At 21 degrees C, however, inducer binding stabilizes the tetramer by approximately 0.8 kcal/mol. Pressure-induced monomer formation is indicated by the curves obtained upon raising the pH to 9.2. The addition of IPTG shifts the pressure transition to only slightly higher pressures at this pH, indicating that the stabilization of the tetramer by inducer is not as marked as that observed at pH 7.1. From the decrease in the polarization of the dansyl repressor-operator complexes, we also conclude that the application of pressure results their dissociation and that the volume change is large in absolute value (approximately 200 mL/mol). The lac repressor-operator complex is more readily dissociated upon the application of pressure than the tetramer alone, indicating that operator binding destabilizes the lac repressor tetramer.

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)

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.