Molecular analysis of the interaction between the Bacillus subtilis trehalose repressor TreR and the tre operator

The trehalose operon of Bacillus subtilis is subject to regulation by induction, mediated by the repressor TreR, and by carbon catabolite repression (CCR). For in vitro investigations, TreR from B. subtilis was overproduced and purified. Its molecular mass, as estimated by SDS-PAGE, is 27?kDa. Size fractionation under native conditions yielded a size estimate of 56?kDa, indicating that TreR exists as a dimer in its native state. Analysis of its interaction with various DNA fragments shows that TreR is able to recognize two tre operators with different efficiencies, and indicates cooperative binding. Previous results have suggested that CCR of the tre operon occurs by a mechanism in which the specific regulator, TreR, may be involved independently of the central component, CcpA. The data presented here indicate that the TreR-tre operator interaction is influenced by several effectors. Thus, the presence of trehalose-6-phosphate, as well as glucose-1-phosphate and sodium chloride, inhibits tre operator binding. Glucose-6-phosphate can act as an anti-inducer, which might reflect its additional role in CCR exerted by glucose.     

Molecular analysis of the interaction between the Bacillus subtilis trehalose repressor TreR and the tre operator

The trehalose operon of Bacillus subtilis is subject to regulation by induction, mediated by the repressor TreR, and by carbon catabolite repression (CCR). For in vitro investigations, TreR from B. subtilis was overproduced and purified. Its molecular mass, as estimated by SDS-PAGE, is 27 kDa. Size fractionation under native conditions yielded a size estimate of 56 kDa, indicating that TreR exists as a dimer in its native state. Analysis of its interaction with various DNA fragments shows that TreR is able to recognize two tre operators with different efficiencies, and indicates cooperative binding. Previous results have suggested that CCR of the tre operon occurs by a mechanism in which the specific regulator, TreR, may be involved independently of the central component, CcpA. The data presented here indicate that the TreR-tre operator interaction is influenced by several effectors. Thus, the presence of trehalose-6-phosphate, as well as glucose-1-phosphate and sodium chloride, inhibits tre operator binding. Glucose-6-phosphate can act as an anti-inducer, which might reflect its additional role in CCR exerted by glucose. Received: 28 April 1998 / Accepted: 8 July 1998     

Crystal structure of trehalose-6-phosphate phosphatase-related protein: biochemical and biological implications

We report here the crystal structure of a trehalose-6-phosphate phosphatase-related protein (T6PP) from Thermoplasma acidophilum, TA1209, determined by the dual-wavelength anomalous diffraction (DAD) method. T6PP is a member of the haloacid dehalogenase (HAD) superfamily with significant sequence homology with trehalose-6-phosphate phosphatase, phosphoserine phosphatase, P-type ATPases and other members of the family. T6PP possesses a core domain of known alpha/beta-hydrolase fold, characteristic of the HAD family, and a cap domain, with a tertiary fold consisting of a four-stranded beta-sheet with two alpha-helices on one side of the sheet. An active-site magnesium ion and a glycerol molecule bound at the interface between the two domains provide insight into the mode of substrate binding by T6PP. A trehalose-6-phosphate molecule modeled into a cage formed by the two domains makes favorable interactions with the protein molecule. We have confirmed that T6PP is a trehalose phosphatase from amino acid sequence, three-dimensional structure, and biochemical assays.     

Parallel evolution of ligand specificity between LacI/GalR family repressors and periplasmic sugar-binding proteins

The bacterial LacI/GalR family repressors such as lactose operon repressor (LacI), purine nucleotide synthesis repressor (PurR), and trehalose operon repressor (TreR) consist of not only the N-terminal helix-turn-helix DNA-binding domain but also the C-terminal ligand-binding domain that is structurally homologous to periplasmic sugar-binding proteins. These structural features imply that the repressor family evolved by acquiring the DNA-binding domain in the N-terminal of an ancestral periplasmic binding protein (PBP). Phylogenetic analysis of the LacI/GalR family repressors and their PBP homologues revealed that the acquisition of the DNA-binding domain occurred first in the family, and ligand specificity then evolved. The phylogenetic tree also indicates that the acquisition occurred only once before the divergence of the major lineages of eubacteria, and that the LacI/GalR and the PBP families have since undergone extensive gene duplication/loss independently along the evolutionary lineages. Multiple alignments of the repressors and PBPs furthermore revealed that repressors and PBPs with the same ligand specificity have the same or similar residues in their binding sites. This result, together with the phylogenetic relationship, demonstrates that the repressors and the PBPs individually acquired the same ligand specificity by homoplasious replacement, even though their genes are encoded in the same operon.     

Ion concentration and temperature dependence of DNA binding: comparison of PurR and LacI repressor proteins.

Purine repressor (PurR) binding to specific DNA is enhanced by complexing with purines, whereas lactose repressor (LacI) binding is diminished by interaction with inducer sugars despite 30% identity in their protein sequences and highly homologous tertiary structures. Nonetheless, in switching from low- to high-affinity DNA binding, these proteins undergo a similar structural change in which the hinge region connecting the DNA and effector binding domains folds into an alpha-helix and contacts the DNA minor groove. The differences in response to effector for these proteins should be manifest in the polyelectrolyte effect which arises from cations displaced from DNA by interaction with positively charged side chains on a protein and is quantitated by measurement of DNA binding affinity as a function of ion concentration. Consistent with structural data for these proteins, high-affinity operator DNA binding by the PurR-purine complex involved approximately 15 ion pairs, a value significantly greater than that for the corresponding state of LacI (approximately 6 ion pairs). For both proteins, however, conversion to the low-affinity state results in a decrease of approximately 2-fold in the number of cations released per dimeric DNA binding site. Heat capacity changes (DeltaC(p)) that accompany DNA binding, derived from buried apolar surface area, coupled folding, and restriction of motional freedom of polar groups in the interface, also reflect the differences between these homologous repressor proteins. DNA binding of the PurR-guanine complex is accompanied by a DeltaC(p) (-2.8 kcal mol(-1) K(-1)) more negative than that observed previously for LacI (-0.9 to -1.5 kcal mol(-1) K(-1)), suggesting that more extensive protein folding and/or enhanced structural rigidity may occur upon DNA binding for PurR compared to DNA binding for LacI. The differences between these proteins illustrate plasticity of function despite high-level sequence and structural homology and undermine efforts to predict protein behavior on the basis of such similarities.     

Lactose repressor hinge domain independently binds DNA

The short 8–10 amino acid “hinge” sequence in lactose repressor (LacI), present in other LacI/GalR family members, links DNA and inducer‐binding domains. Structural studies of full‐length or truncated LacI‐operator DNA complexes demonstrate insertion of the dimeric helical “hinge” structure at the center of the operator sequence. This association bends the DNA ～40° and aligns flanking semi‐symmetric DNA sites for optimal contact by the N‐terminal helix‐turn‐helix (HtH) sequences within each dimer. In contrast, the hinge region remains unfolded when bound to nonspecific DNA sequences. To determine ability of the hinge helix alone to mediate DNA binding, we examined (i) binding of LacI variants with deletion of residues 1–50 to remove the HtH DNA binding domain or residues 1–58 to remove both HtH and hinge domains and (ii) binding of a synthetic peptide corresponding to the hinge sequence with a Val52Cys substitution that allows reversible dimer formation via a disulfide linkage. Binding affinity for DNA is orders of magnitude lower in the absence of the helix‐turn‐helix domain with its highly positive charge. LacI missing residues 1–50 binds to DNA with ～4‐fold greater affinity for operator than for nonspecific sequences with minimal impact of inducer presence; in contrast, LacI missing residues 1–58 exhibits no detectable affinity for DNA. In oxidized form, the dimeric hinge peptide alone binds to O1 and nonspecific DNA with similarly small difference in affinity; reduction to monomer diminished binding to both O1 and nonspecific targets. These results comport with recent reports regarding LacI hinge interaction with DNA sequences.     

Crystallization and preliminary X-ray studies on the co-repressor binding domain of the Escherichia coli purine repressor.

The purine repressor is a putative helix-turn-helix DNA-binding protein that regulates several genetic loci important in purine and pyrimidine metabolism in Escherichia coli. The protein is composed of two domains, an N-terminal DNA-binding domain and a C-terminal core that binds the purine co-repressors, guanine and hypoxanthine. The co-repressor binding domain (residues 53 to 341) has been crystallized from polyethylene glycol 600-MgCl2 solutions. They are of the monoclinic form, space group P2(1), with a = 38.2 A, b = 125.7 A, c = 61.8 A and beta = 100.2 degrees. They diffract to a resolution of at least 2.2 A and contain two monomers per asymmetric unit. The importance of the structural determination of this domain is underscored by the high degree of sequence homology displayed within the effector binding sites among a sub-class of helix-turn-helix proteins, of which LacI and GalR are members. The structure of the PurR co-repressor binding domain will provide a high resolution view of one such domain and could serve as a possible model for future effector site structural determinations. Perhaps more important will be this structure's contribution to the further understanding of how protein-DNA interactions are modulated.     

A genetically encoded Förster resonance energy transfer sensor for monitoring in vivo trehalose-6-phosphate dynamics

Trehalose-6-phosphate is a pivotal regulator of sugar metabolism, growth, and osmotic equilibrium in bacteria, yeasts, and plants. To directly visualize the intracellular levels of intracellular trehalose-6-phosphate, we developed a series of specific Förster resonance energy transfer (FRET) sensors for in vivo microscopy. We demonstrated real-time monitoring of regulation in the trehalose pathway of Escherichia coli. In Saccharomyces cerevisiae, we could show that the concentration of free trehalose-6-phosphate during growth on glucose is in a range sufficient for inhibition of hexokinase. These findings support the hypothesis of trehalose-6-phosphate as the effector of a negative feedback system, similar to the inhibition of hexokinase by glucose-6-phosphate in mammalian cells and controlling glycolytic flux.     

Structural basis of gene regulation by the tetracycline inducible Tet repressor-operator system

The tetracycline repressor (TetR) regulates the most abundant resistance mechanism against the antibiotic tetracycline in grain-negative bacteria. The TetR protein and its mutants are commonly used as control elements to regulate gene expression in higher eukaryotes. We present the crystal structure of the TetR homodimer in complex with its palindromic DNA operator at 2.5 A resolution. Comparison to the structure of TetR in complex with the inducer tetracycline-Mg2+ allows the mechanism of induction to be deduced. Inducer binding in the repressor core initiates conformational changes starting with C-terminal unwinding and shifting of the short helix a6 in each monomer. This forces a pendulum-like motion of helix a4, which increases the separation of the attached DNA binding domains by 3 A, abolishing the affinity of TetR for its operator DNA.     

Trehalose transport and metabolism in Escherichia coli.

Trehalose metabolism in Escherichia coli is complicated by the fact that cells grown at high osmolarity synthesize internal trehalose as an osmoprotectant, independent of the carbon source, although trehalose can serve as a carbon source at both high and low osmolarity. The elucidation of the pathway of trehalose metabolism was facilitated by the isolation of mutants defective in the genes encoding transport proteins and degradative enzymes. The analysis of the phenotypes of these mutants and of the reactions catalyzed by the enzymes in vitro allowed the formulation of the degradative pathway at low osmolarity. Thus, trehalose utilization begins with phosphotransferase (IITre/IIIGlc)-mediated uptake delivering trehalose-6-phosphate to the cytoplasm. It continues with hydrolysis to trehalose and proceeds by splitting trehalose, releasing one glucose residue with the simultaneous transfer of the other to a polysaccharide acceptor. The enzyme catalyzing this reaction was named amylotrehalase. Amylotrehalase and EIITre were induced by trehalose in the medium but not at high osmolarity. treC and treB encoding these two enzymes mapped at 96.5 min on the E. coli linkage map but were not located in the same operon. Use of a mutation in trehalose-6-phosphate phosphatase allowed demonstration of the phosphoenolpyruvate- and IITre-dependent in vitro phosphorylation of trehalose. The phenotype of this mutant indicated that trehalose-6-phosphate is the effective in vivo inducer of the system.     

Structure of the Trehalose-6-phosphate Phosphatase from Brugia malayi Reveals Key Design Principles for Anthelmintic Drugs

Parasitic nematodes are responsible for devastating illnesses that plague many of the world''s poorest populations indigenous to the tropical areas of developing nations. Among these diseases is lymphatic filariasis, a major cause of permanent and long-term disability. Proteins essential to nematodes that do not have mammalian counterparts represent targets for therapeutic inhibitor discovery. One promising target is trehalose-6-phosphate phosphatase (T6PP) from Brugia malayi. In the model nematode Caenorhabditis elegans, T6PP is essential for survival due to the toxic effect(s) of the accumulation of trehalose 6-phosphate. T6PP has also been shown to be essential in Mycobacterium tuberculosis. We determined the X-ray crystal structure of T6PP from B. malayi. The protein structure revealed a stabilizing N-terminal MIT-like domain and a catalytic C-terminal C2B-type HAD phosphatase fold. Structure-guided mutagenesis, combined with kinetic analyses using a designed competitive inhibitor, trehalose 6-sulfate, identified five residues important for binding and catalysis. This structure-function analysis along with computational mapping provided the basis for the proposed model of the T6PP-trehalose 6-phosphate complex. The model indicates a substrate-binding mode wherein shape complementarity and van der Waals interactions drive recognition. The mode of binding is in sharp contrast to the homolog sucrose-6-phosphate phosphatase where extensive hydrogen-bond interactions are made to the substrate. Together these results suggest that high-affinity inhibitors will be bi-dentate, taking advantage of substrate-like binding to the phosphoryl-binding pocket while simultaneously utilizing non-native binding to the trehalose pocket. The conservation of the key residues that enforce the shape of the substrate pocket in T6PP enzymes suggest that development of broad-range anthelmintic and antibacterial therapeutics employing this platform may be possible.     

Ligand interactions with lactose repressor protein and the repressor-operator complex: the effects of ionization and oligomerization on binding

Specific interactions between proteins and ligands that modify their functions are crucial in biology. Here, we examine sugars that bind the lactose repressor protein (LacI) and modify repressor affinity for operator DNA using isothermal titration calorimetry and equilibrium DNA binding experiments. High affinity binding of the commonly-used inducer isopropyl-beta,D-thiogalactoside is strongly driven by enthalpic forces, whereas inducer 2-phenylethyl-beta,D-galactoside has weaker affinity with low enthalpic contributions. Perturbing the dimer interface with either pH or oligomeric state shows that weak inducer binding is sensitive to changes in this distant region. Effects of the neutral compound o-nitrophenyl-beta,D-galactoside are sensitive to oligomerization, and at elevated pH this compound converts to an anti-inducer ligand with slightly enhanced enthalpic contributions to the binding energy. Anti-inducer o-nitrophenyl-beta,D-fucoside exhibits slightly enhanced affinity and increased enthalpic contributions at elevated pH. Collectively, these results both demonstrate the range of energetic consequences that occur with LacI binding to structurally-similar ligands and expand our insight into the link between effector binding and structural changes at the subunit interface.     

Structural basis of the interaction between RalA and Sec5, a subunit of the sec6/8 complex

The sec6/8 complex or exocyst is an octameric protein complex that functions during cell polarization by regulating the site of exocytic vesicle docking to the plasma membrane, in concert with small GTP-binding proteins. The Sec5 subunit of the mammalian sec6/8 complex binds Ral in a GTP-dependent manner. Here we report the crystal structure of the complex between the Ral-binding domain of Sec5 and RalA bound to a non-hydrolyzable GTP analog (GppNHp) at 2.1 A resolution, providing the first structural insights into the mechanism and specificity of sec6/8 regulation. The Sec5 Ral-binding domain folds into an immunoglobulin-like beta-sandwich structure, which represents a novel fold for an effector of a GTP-binding protein. The interface between the two proteins involves a continuous antiparallel beta-sheet, similar to that found in other effector/G-protein complexes, such as Ras and Rap1A. Specific interactions unique to the RalA.Sec5 complex include Sec5 Thr11 and Arg27, and RalA Glu38, which we show are required for complex formation by isothermal titration calorimetry. Comparison of the structures of GppNHp- and GDP-bound RalA suggests a nucleotide-dependent switch mechanism for Sec5 binding.     

Repressor--operator interaction in the lac operon. II. Observations at the tyrosines and tryptophans

This paper shows that ¹⁹F-nuelear magnetic resonance spectroscopy on 3-fluoro-tyrosine and 5-fluorotryptophan-substituted wild-type lactose operon repressors from Escherichia coli can be used to examine the interactions with lac operator DNA.A survey of inducer and salt concentration effects on the repressor-operator complex is presented. The data lead us to a scheme for the interactions between the repressor, operator and inducer, in both binary and ternary complexes, that accommodate the results published by others.The complex between the tetrameric repressor and one 36 base-pair operator DNA fragment results in the simultaneous broadening of the resonances from all four N-terminal DNA binding domains. The actual contacts made by these binding domains are similar but probably not identical.The binding of the inducer molecule to the tetrameric repressor results in an allosteric change that can be monitored by the increased intensity of the resonances from individual tyrosine residues in the N-terminal binding domain. This increased N-terminal tyrosine resonance intensity in the complex is transmitted to repressor subunits that have not yet bound an inducer molecule.     

Biochemical characterization of rice trehalose-6-phosphate phosphatases supports distinctive functions of these plant enzymes

Substantial levels of trehalose accumulate in bacteria, fungi, and invertebrates, where it serves as a storage carbohydrate or as a protectant against environmental stresses. In higher plants, trehalose is detected at fairly low levels; therefore, a regulatory or signaling function has been proposed for this molecule. In many organisms, trehalose-6-phosphate phosphatase is the enzyme governing the final step of trehalose biosynthesis. Here we report that OsTPP1 and OsTPP2 are the two major trehalose-6-phosphate phosphatase genes expressed in vegetative tissues of rice. Similar to results obtained from our previous OsTPP1 study, complementation analysis of a yeast trehalose-6-phosphate phosphatase mutant and activity measurement of the recombinant protein demonstrated that OsTPP2 encodes a functional trehalose-6-phosphate phosphatase enzyme. OsTPP2 expression is transiently induced in response to chilling and other abiotic stresses. Enzymatic characterization of recombinant OsTPP1 and OsTPP2 revealed stringent substrate specificity for trehalose 6-phosphate and about 10 times lower K(m) values for trehalose 6-phosphate as compared with trehalose-6-phosphate phosphatase enzymes from microorganisms. OsTPP1 and OsTPP2 also clearly contrasted with microbial enzymes, in that they are generally unstable, almost completely losing activity when subjected to heat treatment at 50 degrees C for 4 min. These characteristics of rice trehalose-6-phosphate phosphatase enzymes are consistent with very low cellular substrate concentration and tightly regulated gene expression. These data also support a plant-specific function of trehalose biosynthesis in response to environmental stresses.     

Subdividing repressor function: DNA binding affinity, selectivity, and allostery can be altered by amino acid substitution of nonconserved residues in a LacI/GalR homologue

Many mutations that impact protein function occur at residues that do not directly contact ligand. To understand the functional contributions from the sequence that links the DNA-binding and regulatory domains of the LacI/GalR homologues, we have created a chimeric protein (LLhP), which comprises the LacI DNA-binding domain, the LacI linker, and the PurR regulatory domain. Although DNA binding site residues are identical in LLhP and LacI, thermodynamic measurements of DNA binding affinity show that LLhP does not discriminate between alternative DNA ligands as well as LacI. In addition, small-angle scattering experiments show that LLhP is more compact than LacI. When DNA is released, LacI shows a 20 A increase in length that was previously attributed to unfolding of the linker. This change is not seen in apo-LLhP, even though the linker sequences of the two proteins are identical. Together, results indicate that long-range functional and structural changes are propagated across the interface that forms between the linker and regulatory domain. These changes could be mediated via the side chains of several linker residues that contact the regulatory domains of the naturally occurring proteins, LacI and PurR. Substitution of these residues in LLhP leads to a range of functional effects. Four variants exhibit altered affinity for DNA, with no changes in selectivity or allosteric response. Another two result in proteins that bind operator DNA with very low affinity and no allosteric response, similar to LacI binding nonspecific DNA sequences. Two more substitutions simultaneously diminish affinity, enhance allostery, and profoundly alter DNA ligand selectivity. Thus, positions within the linker can be varied to modulate different aspects of repressor function.     

Engineered disulfide linking the hinge regions within lactose repressor dimer increases operator affinity, decreases sequence selectivity, and alters allostery.

The hinge domain encompasses amino acids 51-60 of lactose repressor (LacI) and plays an important role in its regulatory interaction with operator DNA. This segment makes both hinge-DNA and hinge-hinge' contacts that are critical to DNA binding. Furthermore, this small region serves as a central element in communicating the allosteric response to inducer. Introducing a disulfide bond between partner hinges within a dimer via the mutation V52C results in a protein that has increased affinity for O(1) operator DNA compared to wild-type LacI and abolishes allosteric response to inducer [Falcon, C. M., Swint-Kruse, L., and Matthews, K. S. (1997) J. Biol. Chem. 272, 26818]. We have established that this high affinity is maintained for the disulfide-linked protein even when symmetry and half-site spacing within the operator region are altered, whereas binding by the reduced protein, as for wild-type LacI, is severely diminished by these alterations. Interestingly, the allosteric response to inducer for V52C-oxidized remains intact for a small group of operator variants. Temperature studies demonstrate that the presence of the disulfide alters the thermodynamics of the protein-DNA interaction, with a DeltaC(p) of significantly smaller magnitude compared to wild-type LacI. The results presented here establish the hinge region as an important element not only for LacI high-affinity operator binding but also for the essential communication between ligand binding domains. Moreover, the results confirm that DNA sequence/conformation can profoundly influence allostery for this prototypic regulatory protein.     

Role of residue 147 in the gene regulatory function of the Escherichia coli purine repressor.

The crystal structures of corepressor-bound and free Escherichia coli purine repressor (PurR) have delineated the roles of several residues in corepressor binding and specificity and the intramolecular signal transduction (allosterism) of this LacI/GalR family member. From these structures, residue W147 was implicated as a key component of the allosteric response, but in many members of the LacI/GalR family, position 147 is occupied by an arginine. To understand the role of this tryptophan at position 147, three proteins, substituted by phenylalanine (W147F), alanine (W147A), or arginine (W147R), were constructed and characterized in vivo and in vitro, and their structures were determined. W147F displays a decreased affinity for corepressor and is a poor repressor in vivo. W147A and W147R, on the other hand, are super repressors and bind corepressor 13.6 and 7.9 times more tightly, respectively, than wild-type. Each mutant PurR-hypoxanthine-purF operator holo complex crystallizes isomorphously to wild-type. Whereas the apo corepressor binding domain (CBD) of W147F crystallizes under those conditions used for the wild-type protein, neither the apo CBD of W147R nor W147A crystallizes, although screened extensively for new crystal forms. Structures of the holo repressor mutants have been solved to resolutions between 2.5 and 2.9 A, and the structure of the apo CBD of W147F has been solved to 2.4 A resolution. These structures provide insight into the altered biochemical properties and physiological functions of these mutants, which appear to depend on the sometimes subtle preference for one conformation (apo vs holo) over the other.