Equilibrium unfolding of dimeric desulfoferrodoxin involves a monomeric intermediate: iron cofactors dissociate after polypeptide unfolding

Here we report the conformational stability of homodimeric desulfoferrodoxin (dfx) from Desulfovibrio desulfuricans (ATCC 27774). The dimer is formed by two dfx monomers linked through beta-strand interactions in two domains; in addition, each monomer contains two different iron centers: one Fe-(S-Cys)(4) center and one Fe-[S-Cys+(N-His)(4)] center. The dissociation constant for dfx was determined to be 1 microM (DeltaG = 34 kJ/mol of dimer) from the concentration dependence of aromatic residue emission. Upon addition of the chemical denaturant guanidine hydrochloride (GuHCl) to dfx, a reversible fluorescence change occurred at 2-3 M GuHCl. This transition was dependent upon protein concentration, in accord with a dimer to monomer reaction [DeltaG(H(2)O) = 46 kJ/mol of dimer]. The secondary structure did not disappear, according to far-UV circular dichroism (CD), until 6 M GuHCl was added; this transition was reversible (for incubation times of < 1 h) and independent of dfx concentration [DeltaG(H(2)O) = 50 kJ/mol of monomer]. Thus, dfx equilibrium unfolding is at least three-state, involving a monomeric intermediate with native-like secondary structure. Only after complete polypeptide unfolding (and incubation times of > 1 h) did the iron centers dissociate, as monitored by disappearance of ligand-to-metal charge transfer absorption, fluorescence of an iron indicator, and reactivity of cysteines to Ellman's reagent. Iron dissociation took place over several hours and resulted in an irreversibly denatured dfx. It appears as if the presence of the iron centers, the amino acid composition, and, to a lesser extent, the dimeric structure are factors that aid in facilitating dfx's unusually high thermodynamic stability for a mesophilic protein.     

Refolding and aggregation of bovine carbonic anhydrase B: quasi-elastic light scattering analysis

Bovine carbonic anhydrase B (CAB) is chosen as the model protein to study the phenomenon of protein aggregation, which often occurs during the refolding process. Refolding of CAB from 5 M GuHCl has been observed by quasi-elastic light scattering (QLS), which confirms the formation of a molten globular protein structure as reported previously [Semisotnov, G. V., Rodionova, N. A., Kutyshenko, V. P., Ebert, B., Blanck, J., & Ptitsyn, O. B. (1987) FEBS Lett. 224, 9-13]. QLS analysis reveals the formation of multimeric species prior to precipitation. Activity and cross-linking studies have confirmed the presence of inactive multimeric protein species. The dimer formation has been determined to be the initiating step in the aggregation of CAB during refolding. Activity studies have indicated that the first intermediate observed in the refolding pathway of CAB aggregates to form the inactive dimer. The rate of formation of the dimer has a stoichiometric dependence on the final protein concentration. The dimer formation rate is a function of the final guanidine hydrochloride (GuHCl) concentration to the inverse 6.7 power, which correlates well with the binding of GuHCl to the native protein in 0.60-0.80 M GuHCl. These rate dependencies require the refolding of CAB to be performed at high GuHCl concentrations (1 M GuHCl) and low protein concentrations (less than 1 mg/mL) to avoid the formation of aggregates. Alternatively, refolding can be performed by allowing the first intermediate to form the second intermediate prior to further dilution or dialysis. The aggregation of a hydrophobic first intermediate species is likely to be common to the refolding of other molten globular proteins.     

Reversible denaturation of the gene V protein of bacteriophage f1

The guanidine hydrochloride (GuHCl)-induced denaturation of the gene V protein of bacteriophage f1 has been studied, using the chemical reactivity of a cysteine residue that is buried in the folded protein and the circular dichroism (CD) at 211 and 229 nm as measures of the fraction of polypeptide chains in the folded form. It is found that this dimeric protein unfolds in a single cooperative transition from a folded dimer to two unfolded monomers. A folded, monomeric form of the gene V protein was not detected at equilibrium. The kinetics of unfolding of the gene V protein in 3 M GuHCl and the refolding in 2 M GuHCl are also consistent with a transition between a folded dimer and two unfolded monomers. The GuHCl concentration dependence of the rates of folding and unfolding suggests that the transition state for folding is near the folded conformation.     

The crystal structure of p13suc1, a p34cdc2-interacting cell cycle control protein.

p13suc1 binds to p34cdc2 kinase and is essential for cell cycle progression in eukaryotic cells. The crystal structure of S.pombe p13suc1 has been solved to 2.7 A resolution using data collected at the ESRF source, Grenoble, from both native crystals and crystals of a seleno-methionine derivative. The starting point for structure solution was the determination of the six selenium sites by direct methods. The structure is dominated by a four-stranded beta-sheet, with four further alpha-helical regions. p13suc1 crystallizes as a dimer in the asymmetric unit stabilized by the binding of two zinc ions. A third zinc site stabilizes the higher-order crystal packing. The sites are consistent with a requirement for zinc during crystal growth. A likely site for p13suc1-protein interaction is immediately evident on one face of the p13suc1 surface. This region comprises a group of conserved, exposed aromatic and hydrophobic residues below a flexible negatively charged loop. A conserved positively charged area would also present a notable surface feature in the monomer, but is buried at the dimer interface. p13suc1 is larger than its recently solved human homologue p9CKS2, with the extra polypeptide forming a helical N-terminal extension and a surface loop between alpha-helices 3 and 4. Notably, p13suc1 does not show the unusual beta-strand exchange that creates an intimate p9CKS2 dimer. p13suc1 cannot oligomerize to form a stable hexamer as has been proposed for p9CKS2.     

Investigation of the four cooperative unfolding units existing in the MICAL-1 CH domain

The solution structure of human MICAL-1 calpolnin homology (CH) domain is composed of six alpha helices and one 3(10) helix. To study the unfolding of this domain, we carry out native-state hydrogen exchange, intrinsic fluorescence and far-UV circular dichroism experiments. The free energy of unfolding, DeltaG(H2O), is calculated to be 7.11+/-0.58 kcal mol(-1) from GuHCl denaturation at pH 6.5. Four cooperative unfolding units are found using native-state hydrogen exchange experiment. Forty-seven slow-exchange residues can be studied by native-state hydrogen exchange experiments. From the concentration dependence of exchange rates, free energy of amide hydrogen with solvent, DeltaG(HX) and m-value (sensitivity of exposure to denaturant) are obtained, which reveal four cooperative unfolding units. The slowest exchanging protons are distributed throughout the whole hydrophobic core of the protein, which might be the folding core. These results will help us understand the structure of MICAL-1 CH domain more deeply.     

The unfolding pathway for Apo Escherichia coli aspartate aminotransferase is dependent on the choice of denaturant

The guanidine hydrochloride (GdnHCl) mediated denaturation pathway for the apo form of homodimeric Escherichia coli aspartate aminotransferase (eAATase) (molecular mass = 43.5 kDa/monomer) includes a partially folded monomeric intermediate, M* [Herold, M., and Kirschner, K. (1990) Biochemistry 29, 1907-1913; Birolo, L., Dal Piaz, F., Pucci, P., and Marino, G. (2002) J. Biol. Chem. 277, 17428-17437]. The present investigation of the urea-mediated denaturation of eAATase finds no evidence for an M* species but uncovers a partially denatured dimeric form, D*, that is unpopulated in GdnHCl. Thus, the unfolding process is a function of the employed denaturant. D* retains less than 50% of the native secondary structure (circular dichroism), conserves significant quaternary and tertiary interactions, and unfolds cooperatively (mD*<==>U = 3.4 +/- 0.3 kcal mol-1 M-1). Therefore, the following equilibria obtain in the denaturation of apo-eAATase: D <==> 2M 2M* <==> 2U in GdnHCl and D <==> D* <==> 2U in urea (D = native dimer, M = folded monomer, and U = unfolded state). The free energy of unfolding of apo-eAATase (D <==> 2U) is 36 +/- 3 kcal mol-1, while that for the D* 2U transition is 24 +/- 2 kcal mol-1, both at 1 M standard state and pH 7.5.     

Association-dissociation of histone oligomers. A spin label study

The spin label method has been used to obtain information about conformational changes of histone oligomers taking advantage of the fact that at a low ionic strength and in the presence of other histones about 45% of cysteine residues of histone H3 react with the 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl spin label. For the labeled complexes H3-H4 and H nu the degree of immobilization of the spin label is a function of the ionic strength. This variation is identical for both complexes within a long range of ionic strengths, including the interval of 0.8-2 M NaCl, under which conditions interactions are known to exist between the tetramer (H3)2 (H4)2 and the dimer (H2A) (H2B). This finding suggests a negligible influence of the dimer for modifying the cysteine residue environment of histone H3 on octamer formation. GuHCl treatment at high ionic strength of the labeled complexes gives rise to a non-lineal increase in the degree of mobility of the spin label. This increase, at low GuHCl concentration (0-0.5 M GuHCl), is interpreted as showing a lowering in rigidity for the Cys residue environment, without affecting the general stability of the tetramer (H3)2 (H4)2. At higher GuHCl concentration (2-3 M GuHCl) the increase in the spin label mobility is related to a dissociation of the complexes in single histones. Our results are consistent with the view that the overall structure of the tetramer, as well as its conformational changes during complex structuration or denaturation, are not strongly affected by the presence of the dimer (H2A) (H2B).     

Combining mutations in HIV-1 protease to understand mechanisms of resistance

HIV-1 develops resistance to protease inhibitors predominantly by selecting mutations in the protease gene. Studies of resistant mutants of HIV-1 protease with single amino acid substitutions have shown a range of independent effects on specificity, inhibition, and stability. Four double mutants, K45I/L90M, K45I/V82S, D30N/V82S, and N88D/L90M were selected for analysis on the basis of observations of increased or decreased stability or enzymatic activity for the respective single mutants. The double mutants were assayed for catalysis, inhibition, and stability. Crystal structures were analyzed for the double mutants at resolutions of 2.2-1.2 A to determine the associated molecular changes. Sequence-dependent changes in protease-inhibitor interactions were observed in the crystal structures. Mutations D30N, K45I, and V82S showed altered interactions with inhibitor residues at P2/P2', P3/P3'/P4/P4', and P1/P1', respectively. One of the conformations of Met90 in K45I/L90M has an unfavorably close contact with the carbonyl oxygen of Asp25, as observed previously in the L90M single mutant. The observed catalytic efficiency and inhibition for the double mutants depended on the specific substrate or inhibitor. In particular, large variation in cleavage of p6(pol)-PR substrate was observed, which is likely to result in defects in the maturation of the protease from the Gag-Pol precursor and hence viral replication. Three of the double mutants showed values for stability that were intermediate between the values observed for the respective single mutants. D30N/V82S mutant showed lower stability than either of the two individual mutations, which is possibly due to concerted changes in the central P2-P2' and S2-S2' sites. The complex effects of combining mutations are discussed.     

Solution NMR study of the monomeric form of p13suc1 protein sheds light on the hinge region determining the affinity for a phosphorylated substrate.

Cyclin-dependent kinase subunit (CKS) proteins bind to cyclin-dependent kinases and target various proteins to phosphorylation and proteolysis during cell division. Crystal structures showed that CKS can exist both in a closed monomeric conformation when bound to the kinase and in an inactive C-terminal beta-strand-exchanged conformation. With the exception of the hinge loop, however, both crystal structures are identical, and no new protein interface is formed in the dimer. Protein engineering studies have pinpointed the crucial role of the proline 90 residue of the p13(suc1) CKS protein from Schizosaccharomyces pombe in the monomer-dimer equilibrium and have led to the concept of a loaded molecular spring of the beta-hinge motif. Mutation of this hinge proline into an alanine stabilizes the protein and prevents the occurrence of swapping. However, other mutations further away from the hinge as well as ligand binding can equally shift the equilibrium between monomer and dimer. To address the question of differential affinity through relief of the strain, here we compare the ligand binding of the monomeric form of wild-type S. pombe p13(suc1) and its hinge mutant P90A in solution by NMR spectroscopy. We indeed observed a 5-fold difference in affinity with the wild-type protein being the most strongly binding. Our structural study further indicates that both wild-type and the P90A mutant proteins adopt in solution the closed conformation but display different dynamic properties in the C-terminal beta-sheet involved in domain swapping and protein interactions.     

The V108M mutation decreases the structural stability of catechol O-methyltransferase

The human gene for catechol O-methyltransferase has a common single-nucleotide polymorphism that results in substitution of methionine (M) for valine (V) 108 in the soluble form of the enzyme (s-COMT). 108M s-COMT loses enzymatic activity more rapidly than 108V s-COMT at physiological temperature, and the 108M allele has been associated with increased risk of breast cancer and several neuropsychiatric disorders. We used circular dichroism (CD), dynamic light scattering, and fluorescence spectroscopy to examine how the 108V/M polymorphism affects the stability of the purified, recombinant protein to heat and guanidine hydrochloride (GuHCl). COMT contains two tryptophan residues, W143 and W38Y, which are located in loops that border the S-adenosylmethionine (SAM) and catechol binding sites. We therefore also studied the single-tryptophan mutants W38Y and W143Y in order to dissect the contributions of the individual tryptophans to the fluorescence signals. The 108V and 108M proteins differed in the stability of both the tertiary structure surrounding the active site, as probed by the fluorescence yields and emission spectra, and their global secondary structure as reflected by CD. With either probe, the midpoint of the thermal transition of 108M s-COMT was 5 to 7 degrees C lower than that of 108V s-COMT, and the free energy of unfolding at 25 degrees C was smaller by about 0.4 kcal/mol. 108M s-COMT also was more prone to aggregation or partial unfolding to a form with an increased radius of hydration at 37 degrees C. The co-substrate SAM stabilized the secondary structure of both 108V and 108M s-COMT. W143 dominates the tryptophan fluorescence of the folded protein and accounts for most of the decrease in fluorescence that accompanies unfolding by GuHCl. While replacing either tryptophan by tyrosine was mildly destabilizing, the lower stability of the 108M variant was retained in all cases.     

Major differences in stability and dimerization properties of two chimeric mutants of human stefins

Stefins A and B are cysteine proteinase inhibitors that have considerable sequence similarity but marked differences in their stability and folding properties. Two chimeric proteins were designed to shed light on these differences. The chimeric mutants have been expressed in Escherichia coli and have been isolated. The first, A37B, consists of 37 residues of stefin A, comprising the N-terminal and the alpha-helix, joined to 61 residues of stefin B; the second, A61B, consists of 61 N-terminal residues of stefin A, followed by 37 residues of stefin B. Spectroscopic properties of the chimeric proteins (absorption, CD, and NMR spectra), together with activity measurements, have confirmed that both have well-defined tertiary structure and are active as cysteine proteinase inhibitors. Characterization consisted of GuHCl denaturation, ANS binding as a function of pH, and monitoring of dimerization under partially denaturing conditions. The c(m) values are 1.3 M GuHCl for A61B as compared with 2.7 M GuHCl for stefin A, and 2.1 M GuHCl for A37B as compared with 1.4 M GuHCl for stefin B (all at pH 7.5, 25 degrees C). However (G degrees (N-U) is lower for both chimeric proteins (18 +/- 3 kJ/mol) than for the parent stefins (28 +/- 3 kJ/mol). In pH denaturation, unlike stefin B, neither chimeric mutant unfolds to I(N) below pH 5.4. At pH 3, where stefin B forms a molten globule and stefin A is native, both A37B and A61B show increased ANS fluorescence and aggregate visibly. Dimers at pre-denaturation conditions are observed in all the proteins under study, but they remain "trapped" only in stefin A.     

Folding of a three-stranded coiled coil

Coiled coils consist of two or more amphipathic a-helices wrapped around each other to form a superhelical structure stabilized at the interhelical interface by hydrophobic residues spaced in a repeating 3-4 sequence pattern. Dimeric coiled coils have been shown to often form in a single step reaction in which association and folding of peptide chains are tightly coupled. Here, we ask whether such a simple folding mechanism may also apply to the formation of a three-stranded coiled coil. The designed 29-residue peptide LZ16A was shown previously to be in a concentration-dependent equilibrium between unfolded monomer (M), folded dimer (D), and folded trimer (T). We show by time-resolved fluorescence change experiments that folding of LZ16A to D and T can be described by 2M (k1)<==>(k(-1)) D and M + D (k2)<==>(k(-2)) T. The following rate constants were determined (25 degrees C, pH 7): k1 = 7.8 x 10(4) M(-1) s(-1), k(-1) = 0.015 s(-1), k2 = 6.5 x 10(5) M(-1) s(-1), and k(-2) = 1.1 s(-1). In a separate experiment, equilibrium binding constants were determined from the change with concentration of the far-ultraviolet circular dichroism spectrum of LZ16A and were in good agreement with the kinetic rate constants according to K(D) = k1/2k(-1) and K(T) = k2/k(-2). Furthermore, pulsed hydrogen-exchange experiments indicated that only unfolded M and folded D and T were significantly populated during folding. The results are compatible with a two-step reaction in which a subpopulation of association competent (e.g., partly helical) monomers associate to dimeric and trimeric coiled coils.     

A monomer form of the glutathione S-transferase Y7F mutant from Schistosoma japonicum at acidic pH

Dissociation and unfolding of homodimeric glutathione S-transferase Y7F mutant from Schistosoma japonicum (SjGST-Y7F) were investigated at equilibrium using urea as denaturant. The conserved residue Tyr7 plays a central role in the catalytic mechanism and the mutation Tyr-Phe yields an inactive enzyme that is able to bind the substrate GSH with a higher binding constant than the wild type enzyme. Mutant SjGST-Y7F is a dimer at pH 6 or higher and a stable monomer at pH 5 that binds GSH (K value of 1.2x10(5)+/-6.4x10(3)M(-1) at pH 6.5 and 6.3x10(4)+/-1.25x10(3)M(-1) at pH 5). The stability of the SjGST-Y7F mutant was studied by urea induced unfolding techniques (DeltaG(W)=13.86+/-0.63kcalmol(-1) at pH 6.5 and DeltaG(W)=11.22+/-0.25kcalmol(-1) at pH 5) and the monomeric form characterized by means of size exclusion chromatography, fluorescence, and electrophoretic techniques.     

Structural Correlation of the Neck Coil with the Coiled-coil (CC1)-Forkhead-associated (FHA) Tandem for Active Kinesin-3 KIF13A

Processive kinesin motors often contain a coiled-coil neck that controls the directionality and processivity. However, the neck coil (NC) of kinesin-3 is too short to form a stable coiled-coil dimer. Here, we found that the coiled-coil (CC1)-forkhead-associated (FHA) tandem (that is connected to NC by Pro-390) of kinesin-3 KIF13A assembles as an extended dimer. With the removal of Pro-390, the NC-CC1 tandem of KIF13A unexpectedly forms a continuous coiled-coil dimer that can be well aligned into the CC1-FHA dimer. The reverse introduction of Pro-390 breaks the NC-CC1 coiled-coil dimer but provides the intrinsic flexibility to couple NC with the CC1-FHA tandem. Mutations of either NC, CC1, or the FHA domain all significantly impaired the motor activity. Thus, the three elements within the NC-CC1-FHA tandem of KIF13A are structurally interrelated to form a stable dimer for activating the motor. This work also provides the first direct structural evidence to support the formation of a coiled-coil neck by the short characteristic neck domain of kinesin-3.     

Structurally and catalytically important residues in the phosphate binding loop of adenylate kinase of Escherichia coli

Amino acids in the phosphate binding loop of adenylate kinase of Escherichia coli were mutated by site-directed mutagenesis. The mutant proteins with a Pro-9----Gly (P9G) and with a Lys-13----Gln (K13Q) exchange were overexpressed and purified. They were characterized by steady-state kinetics, fluorescence binding, and structural studies, together with the phosphate binding loop mutants P9L and G10V prepared earlier [Reinstein, J., Brune, M., & Wittinghofer, A. (1988) Biochemistry 27, 4712-4720]. The results obtained show that all these mutations change the structure of the protein as evidenced by NMR spectroscopy and temperature-stability studies. All the mutant proteins have increased dissociation constants for substrates and inhibitors, but their catalytic activity, except for K13Q, is not reduced. The results obtained with K13Q suggest that this lysine residue, which is conserved in all guanine and many adenine nucleotide proteins, might have an important role in catalysis.     

Reversible thermal denaturation of human FGF-1 induced by low concentrations of guanidine hydrochloride.

Human acidic fibroblast growth factor (FGF-1) is a powerful mitogen and angiogenic factor with an apparent melting temperature (Tm) in the physiological range. FGF-1 is an example of a protein that is regulated, in part, by stability-based mechanisms. For example, the low Tm of FGF-1 has been postulated to play an important role in the unusual endoplasmic reticulum-independent secretion of this growth factor. Despite the close relationship between function and stability, accurate thermodynamic parameters of unfolding for FGF-1 have been unavailable, presumably due to effects of irreversible thermal denaturation. Here we report the determination of thermodynamic parameters of unfolding (DeltaH, DeltaG, and DeltaCp) for FGF-1 using differential scanning calorimetry (DSC). The thermal denaturation is demonstrated to be two-state and reversible upon the addition of low concentrations of added guanidine hydrochloride (GuHCl). DeltaG values from the DSC studies are in excellent agreement with values from isothermal GuHCl denaturation monitored by fluorescence and circular dichroism (CD) spectroscopy. Furthermore, the results indicate that irreversible denaturation is closely associated with the formation of an unfolding intermediate. GuHCl appears to promote reversible two-state denaturation by initially preventing aggregation of this unfolding intermediate, and at subsequently higher concentrations, by preventing formation of the intermediate.     

Equilibrium unfolding of kinetically stable serine protease milin: the presence of various active and inactive dimeric intermediates

Kinetically stable homodimeric serine protease milin reveals high conformational stability against temperature, pH and chaotrope [urea, guanidine hydrochloride (GuHCl) and guanidine isothiocynate (GuSCN)] denaturation as probed by circular dichroism, fluorescence, differential scanning calorimetry and activity measurements. GuSCN induces complete unfolding in milin, whereas temperature, urea and GuHCl induce only partial unfolding even at low pH, through several intermediates with distinct characteristics. Some of these intermediates are partially active (viz. in urea and 2 M GuHCl at pH 7.0), and some exhibited strong ANS binding as well. All three tryptophans in the protein seem to be buried in a rigid, compact core as evident from intrinsic fluorescence measurements coupled to equilibrium unfolding experiments. The protein unfolds as a dimer, where the unfolding event precedes dimer dissociation as confirmed by hydrodynamic studies. The solution studies performed here along with previous biochemical characterization indicate that the protein has α-helix and β-sheet rich regions or structural domains that unfold independently, and the monomer association is isologous. The complex unfolding pathway of milin and the intermediates has been characterized. The physical, physiological and probable therapeutic importance of the results has been discussed.     

Guanidinium chloride induced unfolding of a hemocyanin subunit from Carcinus aestuarii. I. Apo form

The effects of guanidinium chloride (GuHCl) on the stability of the apo form of the 5S non-reassociating subunit of hemocyanin from the crab Carcinus aestuarii (apo-CaeSS2) were investigated, using a variety of optical spectroscopy techniques (light scattering (LS), fluorescence (IF and EF) and circular dichroism (CD)). The fluorescence of 8-anilino-1-naphtalene sulphonate (ANS) was strongly enhanced in the presence of apo-CaeSS2, in contrast to holo-CaeSS2, suggesting the formation of a molten globule (MG)-like state, consequent to the removal of the two copper ions from the holo subunit. Other evidences, favouring the presence of this state in apo-CaeSS2, derive from an enhanced quenching of intrinsic fluorescence (IF) by acrylamide, a higher sensibility towards aggregation and a higher IF with respect to deoxy holo-CaeSS2. Aggregation of apo-CaeSS2 below 1.2 M GuHCl was detected by LS, suggesting the formation of an aggregation-prone intermediate, called I1. Due to this effect, fluorescence and CD data could only be collected above that denaturant concentration. Both IF (protein) and EF (ANS) fluorescence data were best fitted by a two-state cooperative transition, occurring between the intermediate I1 and the unfolded state U, with C(1/2) 1.6-1.7 M. A similar two-state transition, with a slightly higher C(1/2) value (1.9 M), was also inferred from far-UV CD data, suggesting the possible formation of another intermediate. Partial refolding of apo-CaeSS2 by dilution was found to occur above 1.2 M GuHCl, i.e. up to the level of I1, since at lower denaturant concentration protein aggregation took place, as also observed in unfolding. All thermodynamic parameters, derived from data above 1.2 M GuHCl, are therefore referred to transitions between intermediate and unfolded states only. Unfolding kinetics, followed by fluorescence stopped-flow, was biphasic in the whole GuHCl range investigated (3-5 M), suggesting the formation of a transient intermediate, possibly related to that observed under equilibrium conditions.     

Dimerization of the operator binding domain of phage lambda repressor

Dimerization of lambda repressor is required for its binding to operator DNA. As part of a continuing study of the structural basis of the coupling between dimer formation and operator binding, we have undertaken 1H NMR and gel filtration studies of the dimerization of the N-terminal domain of lambda repressor. Five protein fragments have been studied: three are wild-type fragments of different length (1-102, 1-92, and 1-90), and two are fragments bearing single amino acid substitutions in residues involved in the dimer interface (1-102, Tyr-88----Cys; 1-92, Ile-84----Ser). The tertiary structure of each species is essentially the same, as monitored by the 1H NMR resonances of internal aromatic groups. However, significant differences are observed in their dimerization properties. 1H NMR resonances of aromatic residues that are involved in the dimer contact allow the monomer-dimer equilibrium to be monitored in solution. The structure of the wild-type dimer contact appears to be similar to that deduced from X-ray crystallography and involves the hydrophobic packing of symmetry-related helices (helix 5) from each monomer. Removal of two contact residues, Val-91 and Ser-92, by limited proteolysis disrupts this interaction and also prevents crystallization. The Ile-84----Ser substitution also disrupts this interaction, which accounts for the severely reduced operator affinity of this mutant protein.