Properties of the histidine residues of indole-chymotrypsin. Implications for the activation process and catalytic mechanism.

The use of a linear free-energy relationship shows that both histidine residues of alpha-chymotrypsin and chymotrypsinogen are super-reactive toward 1-fluoro-2,4-dinitrobenzene. The binding of indole to the specificity site of alpha-chymotrypsin causes both histidine residues to become less reactive. On the basis of these results and those from X-ray-crystallographic studies, the following conclusions are made. (1) The super-reactivity of the catalytic-site histidine-57 is due to charge transfer from aspartic acid-102 by means of hydrogen bonding. (2) The aspartic acid-102-histidine-57-serine-195 'charge-relay' system is not complete in the zymogen or native enzyme and only on binding of a suitable substrate or ligand to the specificity site of the enzyme is the charge transfer to serine-195 completed. (3) The lack of substantial enzymic activity in the zymogen is due to the absence of a completed specificity site, and therefore it cannot bind suitable substrates or ligands to induce completion of the charge-relay system.     

Raman spectroscopic study of the changes in secondary structure of chymotrypsin: effect of pH and pressure on the salt bridge

Conformational changes of alpha-chymotrypsin, induced by pH and pressure, have been studied with Raman spectroscopy. The secondary structure of alpha-chymotrypsin, chymotrypsinogen and DFP-chymotrypsin has been calculated by a singular value analysis of the Raman amide-I band. The changes in secondary structure, with pH and pressure titration of alpha-chymotrypsin, indicate a conformational transition. The salt bridge between Asp-194 and Ile-16 is disrupted, and the enzyme becomes inactive. No changes are observed for chymotrypsinogen. It is concluded that the proenzyme exhibits the same conformation at different pH values as alpha-chymotrypsin at alkaline pH. The results for DFP-chymotrypsin indicate that the active conformation is stabilized by the presence of the DFP inhibitor in the binding site.     

Kinetic specificities of BPN' and Carlsberg subtilisins. Mapping the aromatic binding site.

The kinetic specificities of BPN' and Carlsberg subtilisins [EC 3.4.21.14] were examined with various nucleus-substituted derivatives of Nalpha-acetylated aromatic amino acid methyl esters for mapping their hydrophobic binding sites in comparison with that of alpha-chymotrypsin. The Carlsberg enzyme was generally much more reactive than the BPN' enzyme due to the larger kcat value. The fact that the two sutilisins hydrolyzed Ac-Tyr(PABz)-OMe, which is a derivative of tyrosine bearing a planar trans-p-phenylazobenzoyl group at the OH-function, with the smallest Km value showed that these enzymes possess a more extended aromatic binding site than has so far been demonstrated. Ac-Phe(4-NO2)-OMe was remarkable in being hydrolyzed with a particularly large kcat value (5,500 +/- 700 s-1 at pH 7.8 for Carlsberg subtilisin). Ac-Phe(4-NO2)-OMe and Ac-Tyr-OMe were distinguished by Carlsberg subtilisin in terms of kcat but not by BPN' subtilisin, suggesting that the specificity site of the former is more sensitive to a small change in size of substituent than that of the latter. Ac-Trp(NCps)-OMe and Ac-Trp(NCps)-OH were bound to the enzyme's active site but in a competitive manner. A difference in the standard free energies of binding between the two enzymes may indicate that the hydrophobic cleft of Carlsberg subtilisin is somewhat deeper and/or narrower than that of BPN' subtilisin.     

X-ray crystal structure of the bovine alpha-chymotrypsin/eglin c complex at 2.6 A resolution

The crystal structure of the molecular complex formed by bovine alpha-chymotrypsin and the recombinant serine proteinase inhibitor eglin c from Hirudo medicinalis has been solved using monoclinic crystals of the complex, reported previously. Four circle diffractometer data at 3.0 A resolution were employed to determine the structure by molecular replacement techniques. Bovine alpha-chymotrypsin alone was used as the search model; it allowed us to correctly orient and translate the enzyme in the unit cell and to obtain sufficient electron density for positioning the eglin c molecule. After independent rigid body refinement of the two complex components, the molecular model yielded a crystallographic R factor of 0.39. Five iterative cycles of restrained crystallographic refinement and model building were conducted, gradually increasing resolution. The current R factor at 2.6 A resolution (diffractometer data) is 0.18. The model includes 56 solvent molecules. Eglin c binds to bovine alpha-chymotrypsin in a manner consistent with other known serine proteinase/inhibitor complex structures. The reactive site loop shows the expected conformation for productive binding and is in tight contact with bovine alpha-chymotrypsin between subsites P3 and P'2; Leu 451 acts as the P1 residue, located in the primary specificity S1 site of the enzyme. Hydrogen bonds equivalent to those observed in complexes of trypsin(ogen) with the pancreatic basic- and secretory-inhibitors are found around the scissile peptide bond.     

The refinement and the structure of the dimer of alpha-chymotrypsin at 1.67-A resolution

The two molecules of the asymmetric unit of the pH 3.5 conformer of alpha-chymotrypsin have been refined at 1.67-A resolution using restrained least squares methods with Hendrickson's program (PROLSQ). The final R factor is 0.179 (including 247 water molecules). The folding of the main chain of the independent molecules is the same within experimental error but the same does not generally apply to the side chain stereochemistry. From this we conclude that the folding of a protein structure is basically independent of most of the detailed stereochemistry of its side chains. The side chains of the interface region between the independent molecules display pronounced asymmetry. This asymmetry suggests that dynamic and asymmetrical structural changes take place at the time of oligomerization leading to more energetically favorable interactions for the dimer. Comparison of the structures of the independent molecules of alpha-chymotrypsin with the structure of monomeric gamma-chymotrypsin revealed that although the folding of the three molecules is essentially the same, numerous and significant differences pervade the side chain stereochemistry attributable to general flexibility. The specificity site of alpha-chymotrypsin is occupied by ordered water molecules in a similar way to gamma-chymotrypsin and other proteins. Some of these water molecules are displaced when substrate binds to the enzyme, while the others appear to help identify and position the aromatic side chain in catalysis.     

The chemoselective fluorescence labeling of alpha-chymotrypsin

The covalent fixation of the phosphinoyl residues in the active site of alpha-chymotrypsin is proved by the application of the fluorescent phosphinoyl fluorides 1 [( 5-(dimethylamino)-1-naphthyl]phenylphosphinoyl-fluoride) or 4 [(5-methoxy-1-naphthyl)phenyl-phosphinoylfluoride]. The differences in the rates of the phosphinoylation of alpha-chymotrypsin and "methyl-alpha-chymotrypsin" as compared to 1 agree with model reactions. In both enzymes the serine-OH in the active site is phosphinoylated. The non-fluorescent 4-nitrophenyl [5-(dimethylamino)-1-naphthyl]phenylphospinate (3) and the corresponding non-fluorescent 5-methoxynaphthyl derivative 5 inhibit alpha-chymotrypsin far more slowly than the corresponding fluorides 1 and 4. The phosphinoyl residues of the nitrophenyl esters 3 and 5 are covalently linked in a yield of 80% to the active site of the enzyme with evolution of fluorescence. 20% of the nitrophenyl ester inhibits the enzyme by adsorption.     

Substrate modulation of enzyme activity in the herpesvirus protease family

The herpesvirus proteases are an example in which allosteric regulation of an enzyme activity is achieved through the formation of quaternary structure. Here, we report a 1.7 A resolution structure of Kaposi's sarcoma-associated herpesvirus protease in complex with a hexapeptide transition state analogue that stabilizes the dimeric state of the enzyme. Extended substrate binding sites are induced upon peptide binding. In particular, 104 A2 of surface are buried in the newly formed S4 pocket when tyrosine binds at this site. The peptide inhibitor also induces a rearrangement of residues that stabilizes the oxyanion hole and the dimer interface. Concomitant with the structural changes, an increase in catalytic efficiency of the enzyme results upon extended substrate binding. A nearly 20-fold increase in kcat/KM results upon extending the peptide substrate from a tetrapeptide to a hexapeptide exclusively due to a KM effect. This suggests that the mechanism by which herpesvirus proteases achieve their high specificity is by using extended substrates to modulate both the structure and activity of the enzyme.     

The effects of chemical modification on the refolding transition of alpha-chymotrypsin.

The role of several active site residues of alpha-chymotrypsin in the prototypical refolding transition between active and inactive forms of this enzyme is examined using chemical modification. Oxidation of Met-192 to the sulfoxide results in a derivative which remains entirely in an active state from pH 6 to 9. The derivative becomes inactive only at high pH with pKa = 10.3, delta H0 = 9.5 kcal and delta S0 = -15 eu., indicating the sulfoxide group supplies about 2.1 kcal of active state stabilization relative to the unoxidized methionine side chain. The refolding transition of N-methyl-His-57-alpha-chymotrypsin, in which a nitrogen of the "charge relay" histidine is methylated, displays one ionization process with an apparent pKa of 9.45. The absence of an additional ionization process with a pKa near 7 provides evidence that one of the ionizations in the six state mechanism which describes this transition in alpha-chymotrypsin is linked to the charge relay system. We also demonstrate, using alpha-chymotrypsin, Met-192-sulfoxide-alpha-chymotrypsin and N-methyl-His-57-alpha-chymotrypsin, that the 230 nm circular dichroism band is a quantitative probe of the active-inactive equilibrium, although the chromophore or chromophores responsible for this and another very large negative band at 202 nm have not been identified. Circular dichroism was used to observe the active-inactive equilibrium in methan sulfonyl-alpha-chymotrypsin and phenylmethane sulfonyl-alpha-chymotrypsin. The enhanced stability of the active state of these derivatives relative to alpha-chymotrypsin can be rationalized in terms of steric effects in the substrate side chain binding site.     

Detection of native peptides as potent inhibitors of enzymes. Crystal structure of the complex formed between treated bovine alpha-chymotrypsin and an autocatalytically produced fragment, IIe-Val-Asn-Gly-Glu-Glu-Ala-Val-Pro-Gly-Ser-Trp-Pro-Trp, at 2.2 angstroms resolution

Chymotrypsin is a prominent member of the family of serine proteases. The present studies demonstrate the presence of a native fragment containing 14 residues from Ile16 to Trp29 in alpha-chymotrypsin that binds to chymotrypsin at the active site with an exceptionally high affinity of 2.7 +/- 0.3 x 10(-11) M and thus works as a highly potent competitive inhibitor. The commercially available alpha-chymotrypsin was processed through a three phase partitioning system (TPP). The treated enzyme showed considerably enhanced activity. The 14 residue fragment was produced by autodigestion of a TPP-treated alpha-chymotrypsin during a long crystallization process that lasted more than four months. The treated enzyme was purified and kept for crystallization using vapour the diffusion method at 295 K. Twenty milligrams of lyophilized protein were dissolved in 1 mL of 25 mM sodium acetate buffer, pH 4.8. It was equilibrated against the same buffer containing 1.2 M ammonium sulfate. The rectangular crystals of small dimensions of 0.24 x 0.15 x 0.10 mm(3) were obtained. The X-ray intensity data were collected at 2.2 angstroms resolution and the structure was refined to an R-factor of 0.192. An extra electron density was observed at the binding site of alpha-chymotrypsin, which was readily interpreted as a 14 residue fragment of alpha-chymotrypsin corresponding to Ile-Val-Asn-Gly-Glu-Glu-Ala-Val-Pro-Gly-Ser-Trp-Pro-Trp(16-29). The electron density for the eight residues of the C-terminus, i.e. Ala22-Trp29, which were completely buried in the binding cleft of the enzyme, was of excellent quality and all the side chains of these eight residues were clearly modeled into it. However, the remaining six residues from the N-terminus, Ile16-Glu21 were poorly defined although the backbone density was good. There was a continuous electron density at 3.0 sigma between the active site Ser195 Ogamma and the carbonyl carbon atom of Trp29 of the fragment. The final refined coordinates showed a distance of 1.35 angstroms between Ser195 Ogamma and Trp29 C indicating the presence of a covalent linkage between the enzyme and the native fragment. This meant that the enzyme formed an acyl intermediate with the autodigested fragment Ile16-Trp29. In addition to the O-C covalent bond, there were several hydrogen bonds and hydrophobic interactions between the enzyme and the native fragment. The fragment showed a high complementarity with the binding site of alpha-chymotrypsin and the buried part of the fragment matched excellently with the corresponding buried part of Turkey ovomucoid inhibitor of alpha-chymotrypsin.     

2.0A resolution crystal structures of the ternary complexes of human phenylalanine hydroxylase catalytic domain with tetrahydrobiopterin and 3-(2-thienyl)-L-alanine or L-norleucine: substrate specificity and molecular motions related to substrate binding

The crystal structures of the catalytic domain of human phenylalanine hydroxylase (hPheOH) in complex with the physiological cofactor 6(R)-L-erythro-5,6,7,8-tetrahydrobiopterin (BH(4)) and the substrate analogues 3-(2-thienyl)-L-alanine (THA) or L-norleucine (NLE) have been determined at 2.0A resolution. The ternary THA complex confirms a previous 2.5A structure, and the ternary NLE complex shows that similar large conformational changes occur on binding of NLE as those observed for THA. Both structures demonstrate that substrate binding triggers structural changes throughout the entire protomer, including the displacement of Tyr138 from a surface position to a buried position at the active site, with a maximum displacement of 20.7A for its hydroxyl group. Two hinge-bending regions, centred at Leu197 and Asn223, act in consort upon substrate binding to create further large structural changes for parts of the C terminus. Thus, THA/L-Phe binding to the active site is likely to represent the epicentre of the global conformational changes observed in the full-length tetrameric enzyme. The carboxyl and amino groups of THA and NLE are positioned identically in the two structures, supporting the conclusion that these groups are of key importance in substrate binding, thus explaining the broad non-physiological substrate specificity observed for artificially activated forms of the enzyme. However, the specific activity with NLE as the substrate was only about 5% of that with THA, which is explained by the different affinities of binding and different catalytic turnover.     

tRNA-dependent active site assembly in a class I aminoacyl-tRNA synthetase

The crystal structure of ligand-free E. coli glutaminyl-tRNA synthetase (GlnRS) at 2.4 A resolution shows that substrate binding is essential to construction of a catalytically proficient active site. tRNA binding generates structural changes throughout the enzyme, repositioning key active site peptides that bind glutamine and ATP. The structure gives insight into longstanding questions regarding the tRNA dependence of glutaminyl adenylate formation, the coupling of amino acid and tRNA selectivities, and the roles of specific pathways for transmission of tRNA binding signals to the active site. Comparative analysis of the unliganded and tRNA-bound structures shows, in detail, how flexibility is built into the enzyme architecture and suggests that the induced-fit transitions are a key underlying determinant of both amino acid and tRNA specificity.     

Hydrophobic interaction of alpha-chymotrypsin with low molecular weight compounds

Data on alpha-chymotrypsin interactions with hydrophobic low-molecular compounds have been generalized. Existence of two sites of noncovalent interaction with hydrophobic nuclei of a ligand molecule is shown. When the substance to be bound contains only one hydrophobic nucleus, the interaction is mediated by a "hydrophobic pocket" of the enzyme--a binding site of amino acid residues which are, in the P1-position relative to the cleaved bond. Under these conditions substances with an asymmetric hydrophobic nucleus (of the tryptophan type) are better ligands for binding. In case of compounds containing several hydrophobic groups scattered in the space, interaction with the enzyme proceeds in two binding sites. New data are presented on the ligand specificity for binding sites of chymotrypsin in lower vertebrates. Relative position of hydrophobic groups of the ligand is shown as that of great importance for interaction with the enzyme. It is concluded that the binding sites of trypsin- and chymotrypsin-like proteinases of the lower vertebrates differ but less from each other as compared to binding sites of trypsin and chymotrypsin in mammals.     

Structure of a coenzyme A pyrophosphatase from Deinococcus radiodurans: a member of the Nudix family

Gene Dr1184 from Deinococcus radiodurans codes for a Nudix enzyme (DR-CoAse) that hydrolyzes the pyrophosphate moiety of coenzyme A (CoA). Nudix enzymes with the same specificity have been found in yeast, humans, and mice. The three-dimensional structure of DR-CoAse, the first of a Nudix hydrolase with this specificity, reveals that this enzyme contains, in addition to the fold observed in other Nudix enzymes, insertions that are characteristic of a CoA-hydrolyzing Nudix subfamily. The structure of the complex of the enzyme with Mg(2+), its activating cation, reveals the position of the catalytic site. A helix, part of the N-terminal insertion, partially occludes the binding site and has to change its position to permit substrate binding. Comparison of the structure of DR-CoAse to those of other Nudix enzymes, together with the location in the structure of the sequence characteristic of CoAses, suggests a mode of binding of the substrate to the enzyme that is compatible with all available data.     

Structure of a mannan-specific family 35 carbohydrate-binding module: evidence for significant conformational changes upon ligand binding

Enzymes that digest plant cell wall polysaccharides generally contain non-catalytic, carbohydrate-binding modules (CBMs) that function by attaching the enzyme to the substrate, potentiating catalytic activity. Here, we present the first structure of a family 35 CBM, derived from the Cellvibrio japonicus beta-1,4-mannanase Man5C. The NMR structure has been determined for both the free protein and the protein bound to mannopentaose. The data show that the protein displays a typical beta-jelly-roll fold. Ligand binding is not located on the concave surface of the protein, as occurs in many CBMs that display the jelly-roll fold, but is formed by the loops that link the two beta-sheets of the protein, similar to family 6 CBMs. In contrast to the majority of CBMs, which are generally rigid proteins, CBM35 undergoes significant conformational change upon ligand binding. The curvature of the binding site and the narrow binding cleft are likely to be the main determinants of binding specificity. The predicted solvent exposure of O6 at several subsites provides an explanation for the observed accommodation of decorated mannans. Two of the key aromatic residues in Man5C-CBM35 that interact with mannopentaose are conserved in mannanase-derived CBM35s, which will guide specificity predictions based on the primary sequence of proteins in this CBM family.     

Co-Factor Binding Confers Substrate Specificity to Xylose Reductase from Debaryomyces hansenii

Binding of substrates into the active site, often through complementarity of shapes and charges, is central to the specificity of an enzyme. In many cases, substrate binding induces conformational changes in the active site, promoting specific interactions between them. In contrast, non-substrates either fail to bind or do not induce the requisite conformational changes upon binding and thus no catalysis occurs. In principle, both lock and key and induced-fit binding can provide specific interactions between the substrate and the enzyme. In this study, we present an interesting case where cofactor binding pre-tunes the active site geometry to recognize only the cognate substrates. We illustrate this principle by studying the substrate binding and kinetic properties of Xylose Reductase from Debaryomyces hansenii (DhXR), an AKR family enzyme which catalyzes the reduction of carbonyl substrates using NADPH as co-factor. DhXR reduces D-xylose with increased specificity and shows no activity towards “non-substrate” sugars like L-rhamnose. Interestingly, apo-DhXR binds to D-xylose and L-rhamnose with similar affinity (K_d∼5.0–10.0 mM). Crystal structure of apo-DhXR-rhamnose complex shows that L-rhamnose is bound to the active site cavity. L-rhamnose does not bind to holo-DhXR complex and thus, it cannot competitively inhibit D-xylose binding and catalysis even at 4–5 fold molar excess. Comparison of K_d values with K_m values reveals that increased specificity for D-xylose is achieved at the cost of moderately reduced affinity. The present work reveals a latent regulatory role for cofactor binding which was previously unknown and suggests that cofactor induced conformational changes may increase the complimentarity between D-xylose and active site similar to specificity achieved through induced-fit mechanism.     

Synthesis and evaluation of 19F labeled sulfonyl fluorides as probes of protease structure: alpha-chymotrypsin

Active site Ser-195-fluorine-labeled derivatives of alpha-chymotrypsin were prepared from a series of N-(trifluoromethylphenyl)-fluorosulfonylphenyl carboxamides whose synthesis is described. The six new 19F spin labels varied in the position of the -CF3 substituent (o-, m-, and p-) and the fluorosulfonyl substituent (m- or p-). The chemical shifts of these covalently bound analogs of "tosyl-chymotrypsin" were each uniquely sensitive to their environment in the catalytic center as evidenced by differences in resonance line position for each label. Upon titrating these derivatives with the reversible competitive inhibitor, indole, a downfield shift was observed (with all but one label), which could be fit in each case to an apparent dissociation constant for indole binding. Indole binding to the p-sulfonyl derivatives was essentially unaltered from that for the native enzyme, while the m-sulfonyl derivatives required some additional free energy of binding to saturate the enzyme. The results are consistent with a partial embedding of the phenylsulfonyl moiety in the aromatic specificity pocket.     

The reactions of alpha-chymotrypsin and related proteins with ester substrates in non-aqueous solvents.

1. The reactivity of alpha-chymotrypsin toward p-nitrophenylacetate has been studied in dimethylformamide, dimethylsulfoxide, formamide and methylacetamide. p-Nitrophenol is liberated in dimethylsulfoxide only. 2. The reactions of alpha-chymotrypsin in dimethylsulfoxide are characterized by the same kinetic and equilibrium constants with either the p-nitrophenyl esters of straight chain carboxylic acids (from acetic to n-caprylic) or with the "specific substrate", N-carbobenzoxy-DL-phenylalanine p-nitrophenyl ester. This signifies that reactions of alpha-chymotrypsin in dimethylsulfoxide, unlike those in aqueous medium, have no specificity toward su-strate structure. 3. The stoichiometry of alpha-chymotrypsin reactions in dimethylsulfoxide was shown to be about five moles of substrate per mole of enzyme. After attaining this stoichiometry, the reaction is completed. 4. Optical rotatory dispersion spectra indicate that in non-aqueous media alpha-chymotrypsin undergoes a large conformational transition which results in a random coil. 5. Chymotrypsinogen, trypsin, trysinogen, lysozyme and serum albumin react with p-nitrophenylacetate in dimethylsulfoxide at rates which are approximately equal to those of alpha-chymotrypsin. Thus, the "activity" of alpha-chymotrypsin in dimethylsulfoxide toward p-nitrophenylacetate does not differ from the "activity" of other proteins, some of which are not even hydrolytic enzymes.     

Identification of a protein-binding surface by differential amide hydrogen-exchange measurements. Application to Bowman-Birk serine-protease inhibitor.

The binding surface of soybean trypsin/chymotrypsin Bowman-Birk inhibitor in contact with alpha-chymotrypsin has been identified by measurement of the change in amide hydrogen-exchange rates between free and chymotrypsin-bound inhibitor. Exchange measurements were made for the enzyme-bound form of the inhibitor at pH 7.3, 25 degrees C using fast-flow affinity chromatography and direct measurement of exchange rates in the protein complex from one-dimensional and two-dimensional nuclear magnetic resonance spectra. The interface is characterized by a broad surface of contact involving residues 39 through 48 of the anti-chymotryptic domain beta-hairpin as well as residues 32, 33 and 37 in the anti-chymotryptic domain loop of the inhibitor. A number of residues in the anti-tryptic domain of the protein also have an altered exchange rate, suggesting that there are changes in the protein conformation upon binding to chymotrypsin. These changes in amide exchange behavior are discussed in light of a model of the complex based on the X-ray crystallographic structure of turkey ovomucoid inhibitor third domain bound to a alpha-chymotrypsin, and the structure of free Bowman-Birk inhibitor determined in solution by two-dimensional nuclear magnetic resonance spectroscopy. The chymotrypsin-binding loop of Bowman-Birk inhibitor in the model is remarkably similar to the binding loop conformation in crystal structures of enzyme-bound polypeptide chymotrypsin inhibitor-I from potatoes, turkey ovomucoid inhibitor third domain, and chymotrypsin inhibitor-II from barley seeds.     

Structure of a tetrahedral transition state complex of alpha-chymotrypsin dimer at 1.8-A resolution

A 1.8-A resolution x-ray crystallographic restrained least squares refinement has been carried out on the phenylethane boronic acid (PEBA) complex of alpha-chymotrypsin dimer (alpha-CHT), and it has been compared to the 1.67-A resolution structure of the native enzyme. PEBA has a high binding affinity for alpha-CHT, and the boronate forms a tetrahedral complex with Ser-195 OG of one molecule of the dimer; the boronate in the other molecule is severely disordered and does not form a tetrahedral complex. The former could be a model of the transition state of catalysis. The complex of PEBA X alpha-CHT displays significant nonequivalence in conformation of side chains between the independent molecules comparable to the native enzyme, but, like the latter, shows a high degree of fidelity in the folding of the main chain. The orientation of the phenyl ring, CA and CB of PEBA, in the specificity sites of the two molecules is similar, suggesting that recognition is fairly insensitive to small departures from local symmetry; the same does not apply to the boronate functionalities suggesting that greater precision is required for catalysis. The folding of the molecule remains the same upon PEBA binding, but some of the side chains respond nonequivalently. The latter is a consequence of the inherent nonequivalence of the native dimer and the asymmetrical nature of the PEBA binding.     

Thermodynamic and Structural Basis for Relaxation of Specificity in Protein–DNA Recognition

As a novel approach to the structural and functional properties that give rise to extremely stringent sequence specificity in protein–DNA interactions, we have exploited “promiscuous” mutants of EcoRI endonuclease to study the detailed mechanism by which changes in a protein can relax specificity. The A138T promiscuous mutant protein binds more tightly to the cognate GAATTC site than does wild-type EcoRI yet displays relaxed specificity deriving from tighter binding and faster cleavage at EcoRI* sites (one incorrect base pair). AAATTC EcoRI* sites are cleaved by A138T up to 170-fold faster than by wild-type enzyme if the site is abutted by a 5′-purine-pyrimidine (5′-RY) motif. When wild-type protein binds to an EcoRI* site, it forms structurally adapted complexes with thermodynamic parameters of binding that differ markedly from those of specific complexes. By contrast, we show that A138T complexes with 5′-RY-flanked AAATTC sites are virtually indistinguishable from wild-type-specific complexes with respect to the heat capacity change upon binding (?C°_P), the change in excluded macromolecular volume upon association, and contacts to the phosphate backbone. While the preference for the 5′-RY motif implicates contacts to flanking bases as important for relaxed specificity, local effects are not sufficient to explain the large differences in ?C°_P and excluded volume, as these parameters report on global features of the complex. Our findings therefore support the view that specificity does not derive from the additive effects of individual interactions but rather from a set of cooperative events that are uniquely associated with specific recognition.