DNA binding properties of protein TrwA, a possible structural variant of the Arc repressor superfamily

Conjugative DNA processing of plasmid R388 requires the concerted action of two proteins, the relaxase-helicase TrwC and the relaxase enhancer TrwA. TrwA can be aligned with DNA binding proteins belonging to the ribbon-helix-helix (RHH) protein family. To further analyse TrwA function, the structural domains of the protein have been identified and dissected by limited proteolysis. Two stable domains were found that resulted to be, according to DNA binding experiments and oligomerization analysis, an N-terminal DNA binding domain and a C-terminal tetramerization domain. Using the three-dimensional structure of the Arc repressor as a guide, it was possible to model TrwA DNA binding site with atomic detail. As a result, TrwA polar amino acids Q8, R10 and S12, contained in the polar face of a putative N-terminal beta-strand, were found to be directly involved in DNA binding, in a manner analogous to RHH proteins. In this respect, TrwA seemed to be a new member of the RHH family. However, secondary structure analyses underscored the existence of a substantial difference in the architecture of the TrwA-oriT complex when compared to the Arc repressor-operator complex.     

Sequence-specific 1H NMR assignment and secondary structure of the Arc repressor of bacteriophage P22, as determined by two-dimensional 1H NMR spectroscopy

The Arc repressor of bacteriophage P22 is a DNA binding protein that does not belong to any of the known classes of such proteins. We have undertaken a 1H NMR study of the protein with the aim of elucidating its three-dimensional structure in solution and its mode of binding of operator DNA. Here we present the 1H nuclear magnetic resonance (NMR) assignments of all backbone protons and most of the side-chain protons of Arc repressor. Elements of secondary structure have been identified on the basis of networks of characteristic sequential and medium-range nuclear Overhauser enhancements (NOEs). Two alpha-helical regions have been found in the peptide regions 16-29 and 35-45. The ends of the helices could not yet be firmly established and could extend to residue 31 for the first helix and to residue 49 for the second. Immediately before the first helix, between residues 8 and 14, a region is present with beta-sheet characteristics dominated by a close proximity of the alpha-protons of residues 9 and 13. Because of the dimeric nature of the protein there are still two possible ways in which the NOEs in the beta-sheet region can be interpreted. If the NOEs are intramonomer, this requires a tight turn involving residues 10-12. Alternatively, if the NOEs are intermonomer, then and antiparallel beta-sheet would be implicated comprising two strands of different Arc monomers. While the data presently do not allow an unambiguous choice between these two possibilities, some evidence is discussed that favors the latter (beta-sheet between monomers).(ABSTRACT TRUNCATED AT 250 WORDS)     

The solution structure and dynamics of an Arc repressor mutant reveal premelting conformational changes related to DNA binding.

The solution structure of the hyperstable MYL mutant (R31M/E36Y/R40L) of the Arc repressor of bacteriophage P22 was determined by NMR spectroscopy and compared to that of the wild-type Arc repressor. A backbone rmsd versus the average of 0.37 A was obtained for the well-defined core region. For both Arc-MYL and the wild-type Arc repressor, evidence for a fast equilibrium between a packed ("in") conformation and an extended ("out") conformation of the side chain of Phe 10 was found. In the MYL mutant, the "out" conformation is more highly populated than in the wild-type Arc repressor. The Phe 10 is situated in the DNA-binding beta-sheet of the Arc dimer. While its "in" conformation appears to be the most stable, the "out" conformation is known to be present in the operator-bound form of Arc, where the Phe 10 ring contacts the phosphate backbone [Raumann, B. E., et al. (1994) Nature 367, 754-757]. As well as DNA binding, denaturation by urea and high temperatures induces the functionally active "out" conformation. With a repacking of the hydrophobic core, this characterizes a premelting transition of the Arc repressor. The dynamical properties of the Arc-MYL and the wild-type Arc repressor were further characterized by 15N relaxation and hydrogen-deuterium exchange experiments. The increased main chain mobility at the DNA binding site compared to that of the core of the protein as well as the reorientation of the side chain of Phe 10 is suggested to play an important role in specific DNA binding.     

Arc repressor-operator DNA interactions and contribution of Phe10 to binding specificity

Solution properties of Arc repressors (wild-type and F10H variant) from Salmonella bacteriophage P22 and their complexes with operator DNA (Arc-wt-DNA and Arc-F10H-DNA) were characterized by circular dichroism, fluorescence, and Raman difference spectroscopy and compared with the crystal structures of free and DNA-bound Arc repressors (wild-type and F10V variant). From the crystal structure of Arc-wt-operator DNA complex, it is known that amino acids Phe10/10' flip out of the hydrophobic protein core, and in the Arc-F10V-DNA complex, the methyl groups of Val10/10' rotate toward the DNA. Arc-wt and Arc-F10H significantly perturb the Raman signatures of the operator DNA upon complex formation. The two proteins induce similar changes in the DNA spectra. Raman markers in the difference spectra (spectrum of the complex minus spectra of DNA and Arc) indicate binding of Arc in the major groove, several direct contacts, e.g., hydrogen bonds of protein residues with bases, and slight perturbations of the deoxyribose ring systems that are consistent with bending of the operator DNA. Trp14, the only one tryptophan of Arc repressor monomers, serves as a very sensitive tool for changes of the hydrophobic core of the protein. The Raman spectra identify in the free Arc-F10H variant a largely different chi(2,1) rotation angle of Trp14 compared to that in wild-type Arc. In the Arc-wt-DNA and Arc-F10H-DNA complexes, however, the Trp14 chi(2,1) rotation angles are similar in both proteins. Furthermore, in both complexes, a strengthening of the van der Waals interactions of the aromatic ring of Trp14 is indicated compared to these interactions in the free proteins. According to the fluorescence and Raman data, His10 is buried in the hydrophobic core of free Arc-F10H, resembling the "core" conformation of Phe10 in Arc-wt, but His10 is looped out in the complex with DNA resembling the "bound" conformation of Phe10 in the Arc-wt-operator DNA complex.     

Solution structure of switch Arc,a mutant with 3(10) helices replacing a wild-type beta-ribbon

Adjacent N11L and L12N mutations in the antiparallel beta-ribbon of Arc repressor result in dramatic changes in local structure in which each beta-strand is replaced by a right-handed helix. The full solution structure of this "switch" Arc mutant shows that irregular 3(10) helices compose the new secondary structure. This structural metamorphosis conserves the number of main-chain and side-chain to main-chain hydrogen bonds and the number of fully buried core residues. Apart from a slight widening of the interhelical angle between alpha-helices A and B and changes in side-chain conformation of a few core residues in Arc, no large-scale structural adjustments in the remainder of the protein are necessary to accommodate the ribbon-to-helix change. Nevertheless, some changes in hydrogen-exchange rates are observed, even in regions that have very similar structures in the two proteins. The surface of switch Arc is packed poorly compared to wild-type, leading to approximately 1000A(2) of additional solvent-accessible surface area, and the N termini of the 3(10) helices make unfavorable head-to-head electrostatic interactions. These structural features account for the positive m value and salt dependence of the ribbon-to-helix transition in Arc-N11L, a variant that can adopt either the mutant or wild-type structures. The tertiary fold is capped in different ways in switch and wild-type Arc, showing how stepwise evolutionary transformations can arise through small changes in amino acid sequence.     

Structural properties and peptide ligand binding of the capsid homology domains of human Arc

The activity-regulated cytoskeleton-associated protein (Arc) is important for synaptic plasticity and the normal function of the brain. Arc interacts with neuronal postsynaptic proteins, but the mechanistic details of its function have not been fully established. The C-terminal domain of Arc consists of tandem domains, termed the N- and C-lobe. The N-lobe harbours a peptide binding site, able to bind multiple targets. By measuring the affinity of human Arc towards various peptides from stargazin and guanylate kinase-associated protein (GKAP), we have refined its specificity determinants. We found two sites in the GKAP repeat region that bind to Arc and confirmed these interactions by X-ray crystallography. Phosphorylation of the stargazin peptide did not affect binding affinity but caused changes in thermodynamic parameters. Comparison of the crystal structures of three high-resolution human Arc-peptide complexes identifies three conserved C–H…π interactions at the binding cavity, explaining the sequence specificity of short linear motif binding by Arc. We further characterise central residues of the Arc lobe fold, show the effects of peptide binding on protein dynamics, and identify acyl carrier proteins as structures similar to the Arc lobes. We hypothesise that Arc may affect protein-protein interactions and phase separation at the postsynaptic density, affecting protein turnover and re-modelling of the synapse. The present data on Arc structure and ligand binding will help in further deciphering these processes.     

The yeast protein Arc1p binds to tRNA and functions as a cofactor for the methionyl- and glutamyl-tRNA synthetases.

Arc1p was found in a screen for components that interact genetically with Los1p, a nuclear pore-associated yeast protein involved in tRNA biogenesis. Arc1p is associated with two proteins which were identified as methionyl-tRNA and glutamyl-tRNA synthetase (MetRS and GluRS) by a new mass spectrometry method. ARC1 gene disruption leads to slow growth and reduced MetRS activity, and synthetically lethal arc1- mutants are complemented by the genes for MetRS and GluRS. Recombinant Arc1p binds in vitro to purified monomeric yeast MetRS, but not to an N-terminal truncated form, and strongly increases its apparent affinity for tRNAMet. Furthermore, Arc1p, which is allelic to the quadruplex nucleic acid binding protein G4p1, exhibits specific binding to tRNA as determined by gel retardation and UV-cross-linking. Arc1p is, therefore, a yeast protein with dual specificity: it associates with tRNA and aminoacyl-tRNA synthetases. This functional interaction may be required for efficient aminoacylation in vivo.     

Equilibrium dissociation and unfolding of the Arc repressor dimer

The equilibrium unfolding reaction of Arc repressor, a dimeric DNA binding protein encoded by bacteriophage P22, can be monitored by fluorescence or circular dichroism changes. The stability of Arc is concentration dependent, and the unfolding reaction is well described as a two-state transition from folded dimer to unfolded monomer. The stability of the protein is decreased at low pH and increased by high salt concentration. The salt dependence suggests that two ions bind preferentially to the folded protein. In 10 mM potassium phosphate (pH 7.3) and 100 mM KCl, the unfolding free energy reaches a maximum near room temperature. The results suggest that at the low protein concentrations where operator DNA binding is normally measured, Arc is predominantly monomeric and unfolded.     

Investigation of the cAMP receptor protein secondary structure by Raman spectroscopy

Raman spectroscopy was employed to examine the secondary structure of the cAMP receptor protein (CRP). Spectra were obtained over the range 400-1900 cm-1 from solutions of CRP and from CRP-cAMP cocrystals. The spectra of CRP dissolved in 30 mM sodium phosphate and 0.15 M NaCl buffered at either pH 6 or pH 8 or dissolved in 0.15-0.2 M NaCl at protein concentrations of 5, 15, and 30 mg/mL were examined. Estimates of the secondary structure distribution were made by analyzing the amide I region of the spectra (1630-1700 cm-1). CRP secondary structure distributions were essentially the same in either pH and at all protein concentrations examined. The amide I analyses indicated a structural distribution of 44% alpha-helix, 28% beta-strand, 18% turn, and 10% undefined for CRP in solution. Raman spectra of CRP-cAMP cocrystals differed from the spectra of CRP in solution. Some differences were assigned to interfering background bands, whereas other spectral differences were attributed to changes in CRP structure. Differences in the amide III region and in the intensity at 935 cm-1 were consistent with alterations in secondary structure. Analysis of the amide I region of the CRP-cAMP cocrystal spectrum indicated a secondary structure distribution of 37% alpha-helix, 33% beta-strand, 17% turn, and 12% undefined. This result is in agreement with a published secondary structure distribution derived from X-ray analysis of CRP-cAMP cocrystals (37% alpha-helix and 36% beta-strand).(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate-induced conformational changes of the periplasmic N-terminus of an outer-membrane transporter by site-directed spin labeling

The structure and dynamics of the N-terminal and core regions of BtuB, an outer membrane vitamin B(12) transporter from Escherichia coli, were investigated by site-directed spin labeling. Cysteine mutants were generated by site-directed mutagenesis to place spin labels in the N-terminal region (residues 1-17), the core region (residues 25-30), and double labels into the Ton box (residues 6-12). BtuB mutants were expressed, spin labeled, purified, and reconstituted into phosphatidylcholine. In the presence of substrate (vitamin B(12)), EPR spectroscopy demonstrates that there is a conformational change in the Ton box similar to that seen previously for BtuB in intact outer membranes. The Ton box is positioned within the beta-barrel of BtuB in the absence of substrate (docked configuration) but becomes unfolded and increases its aqueous exposure upon substrate binding (undocked configuration). This conformational change and the similarity in the EPR spectra between reconstituted and native membranes indicate that BtuB is correctly folded and functional in the reconstituted system. The protein segment on the N-terminal side of the Ton box is highly mobile, and it becomes more mobile in the presence of substrate. Side chains in the region C-terminal to the Ton box also show increases in mobility with substrate addition, but position 16 appears to define a hinge point for this conformation change. EPR line shapes and relaxation data indicate that residues 25-30 form a beta-strand structure, which is analogous to the first beta-strand in the cores of the homologous iron transporters. When substrate binds to BtuB, this first beta-strand remains folded. The EPR spectra of double-nitroxide labels within the Ton box are broadened because of dipolar and collisional exchange interactions. The broadening pattern indicates that the Ton box is not helical but is in an extended or beta-strand structure.     

The role of the N terminus in Tet repressor for tet operator binding determined by a mutational analysis.

The N-terminal residues preceding the alpha-helix-turn-alpha-helix motif on the Tn10 Tet repressor protein were probed by oligonucleotide-directed deletion mutagenesis for their role in protein activity. All deletion mutants showed decreased repression in vivo, emphasizing the importance of the N terminus for tet operator binding. Only two of the mutants, TetR delta 2-23 and TetR delta 3-8 displayed a reduced intracellular protein level. The remaining deletion mutants showed either reduced binding to tet operator and inducibility by tetracycline or transdominance. We conclude that these deletions do not affect stability and overall protein structure. DNA binding activities of residue-wise increasing deletions, TetR delta 9 through TetR delta 9-13, reveal a pattern consistent with an alpha-helical structure of the affected residues. This conclusion is supported by the helical wheel projection and the hydrophobic moment profile calculated for the protein segment ranging from residues S7-V20. We propose that these residues form an amphipathic alpha-helix which packs closely against the alpha-helix-turn-alpha-helix motif and is essential for Tet repressor activity. The residues preceding this putative alpha-helix contribute to DNA binding, but no direct interactions with base pairs of tet operator were revealed in a loss of contact analysis. Individual mutation of the 4 charged residues to alanine at the N terminus shows that no single residue can account for the reduction in repression observed for the deletion mutants.     

Arc repressor is tetrameric when bound to operator DNA

The Arc repressor of bacteriophage P22 is a member of a family of DNA-binding proteins that use N-terminal residues in a beta-sheet conformation for operator recognition. Here, Arc is shown to bind to its operator site as a tetramer. When mixtures of Arc (53 residues) and an active variant of Arc (78 residues) are used in gel retardation experiments, five discrete protein-DNA complexes are observed. This result is as expected for operators bearing heterotetramers containing 4:0, 3:1, 2:2, 1:3, and 0:4 ratios of the two proteins. Direct measurements of binding stoichiometry support the conclusion that Arc binds to a single 21-base-pair operator site as a tetramer. The Arc-operator binding reaction is highly cooperative (Hill constant = 3.5) and involves at least two coupled equilibria. In the first reaction, two unfolded monomers interact to form a folded dimer (Bowie & Sauer, 1989a). Rapid dilution experiments indicate that the Arc dimer is the kinetically significant DNA-binding species and allow an estimate of the equilibrium dissociation constant for dimerization [K1 = 5 (+/- 3) x 10(-9) M]. The rate of association of Arc-operator complexes shows the expected second-order dependence on the concentration of free Arc dimers, with k2 = 2.8 (+/- 0.7) x 10(18) M-2 s-1. The dissociation of Arc-operator complexes is a first-order process with k-2 = 1.6 (+/- 0.6) x 10(-4) s-1. The ratio of these kinetic constants [K2 = 5.7 (+/- 2.3) x 10(-23) M2] provides an estimate for the equilibrium constant for dissociation of the DNA-bound tetramer to two free Arc dimers and the operator. An independent determination of this complex equilibrium constant [K2 = 7.8 (+/- 4.8) x 10(-23) M2] was obtained from equilibrium binding experiments.     

Evidence for involvement of a hydrophobic patch in framework region 1 of human V4-34-encoded Igs in recognition of the red blood cell I antigen

The monoclonal IgM cold agglutinins that bind to the I/i carbohydrate Ags on the surface of RBCs all have Ig H chains encoded by the V4-34 gene segment. This mandatory use indicates that distinctive amino acid sequences may be involved in recognition. Critical amino acids exist in framework region 1 (FR1) of V4-34-encoded Ig, and these generate a specific Id determinant which apparently lies close to the I binding site. However, I binding by Id-expressing Ig can be modulated by sequences in complementarity-determining region (CDR)(H)3. Examination of the crystal structure of an anti-I cold agglutinin has revealed a hydrophobic patch in FR1 involving residue W7 on beta-strand A and the AVY motif (residues 23-25) on beta-strand B. In this study we used mutagenesis to show that each of the strand components of the hydrophobic patch is required for binding the I carbohydrate Ag. In addition, the crystal structure reveals that amino acids in the carboxyl-terminal region of CDR(H)3 form a surface region adjacent to the hydrophobic patch. We propose that the I carbohydrate Ag interacts simultaneously with the entire hydrophobic patch in FR1 and with the outside surface of CDR(H)3. This interaction could leave most of the conventional binding site available for binding other Ags.     

The Arc and Mnt repressors. A new class of sequence-specific DNA-binding protein

Genetic, biochemical, and biophysical studies have begun to reveal details of the structures of Arc and Mnt and show that these repressors use residues at their N-terminal ends for operator recognition and binding. Some of the DNA contacts made by these residues have been identified, and this information together with NMR studies has permitted the construction of models of the DNA binding region. Although the accuracy of these models remains to be determined, it seems clear that Arc and Mnt are members of a new class of DNA-binding proteins.     

Interaction of the bacteriophage P22 Arc repressor with operator DNA

Are repressor binds to a single, partially symmetric, 21 base-pair operator site that is centered between the -10 and -35 regions of the Pant promoter. Protection and interference experiments show that Arc makes contacts with the operator on one side of the DNA helix. Although Arc is a small protein (53 residues/subunit), it makes contacts that are farther from the center of the operator than those made by many larger repressors. These extended contacts include the phosphate groups at the ends of the 21 base-pair site. Under standard conditions (pH 7.5, 100 mM-KCl, 3 mM-MgCl2, 22 degrees C) half-maximal operator binding is observed at an Arc concentration of 2.5 X 10(-9) M and the protein-DNA complex is very stable (t1/2 approximately equal to 80 min).