Mutation of Glu-166 Blocks the Substrate-Induced Dimerization of SARS Coronavirus Main Protease

The maturation of SARS coronavirus involves the autocleavage of polyproteins 1a and 1ab by the main protease (Mpro) and a papain-like protease; these represent attractive targets for the development of anti-SARS drugs. The functional unit of Mpro is a homodimer, and each subunit has a His-41?Cys-145 catalytic dyad. Current thinking in this area is that Mpro dimerization is essential for catalysis, although the influence of the substrate binding on the dimer formation has never been explored. Here, we delineate the contributions of the peptide substrate to Mpro dimerization. Enzyme kinetic assays indicate that the monomeric mutant R298A/L exhibits lower activity but in a cooperative manner. Analytical ultracentrifugation analyses indicate that in the presence of substrates, the major species of R298A/L shows a significant size shift toward the dimeric form and the monomer-dimer dissociation constant of R298A/L decreases by 12- to 17-fold, approaching that for wild-type. Furthermore, this substrate-induced dimerization was found to be reversible after substrates were removed. Based on the crystal structures, a key residue, Glu-166, which is responsible for recognizing the Gln-P1 of the substrate and binding to Ser-1 of another protomer, will interact with Asn-142 and block the S1 subsite entrance in the monomer. Our studies indicate that mutation of Glu-166 in the R298A mutant indeed blocks the substrate-induced dimerization. This demonstrates that Glu-166 plays a pivotal role in connecting the substrate binding site with the dimer interface. We conclude that protein-ligand and protein-protein interactions are closely correlated in Mpro.     

Interaction between D-amino acid oxidase and small molecules.

1. From the standpoint of monomer-dimer equilibrium of hog kidney D-amino acid oxidase [EC 1.4.3.3] and the interaction between the enzyme and small molecules, the effect of pH on the binding of p-aminobenzoate to the monomer and dimer of the enzyme was studied by kinetic methods and spectrophotometric titration. 2. The maximum binding number of p-aminobenzoate to the dimer is two molecules, and there is no interaction between the two active sites of the dimer (i.e., no cooperativity) over the range of pH from 6.5 to 10. 3. The affinity of the dimer for p-aminobenzoate is several times higher than that of the monomer at pH 6.5-10, and consequently p-aminobenzoate induces dimerization in the equilibrium state of D-amino acid oxidase. The interaction energy of two subunits of the dimer is stabilized by the binding of p-aminobenzoate by 1-2 kcal/mole over the pH range studied. 4. The binding sites of the quasi-substrate, p-aminobenzoate, in the dimer and the intersubunit binding site of the dimer are clearly different, because p-aminobenzoate induces dimerization of the enzyme. 5. The pK values of ionizing groups in the free monomer and the free dimer which participate in the binding of the competitive inhibitor, p-aminobenzoate, are approximately the same, 8.7, as determined from the pH dependence of the affinity of the inhibitor for the enzyme. Furthermore, no pK for the enzyme-inhibitor complex in the pH range 6.5-10 was observed. 6. There is no interaction between the two ionizing groups of the dimer during protonation-deprotonation, because a theoretical equation involving no cooperativity between the two ionizing groups in the dimer explains the results well.     

A quantitative model for allosteric control of purine reduction by murine ribonucleotide reductase

The reduction of purine nucleoside diphosphates by murine ribonucleotide reductase requires catalytic (R1) and free radical-containing (R2) enzyme subunits and deoxynucleoside triphosphate allosteric effectors. A quantitative 16 species model is presented, in which all pertinent equilibrium constants are evaluated, that accounts for the effects of the purine substrates ADP and GDP, the deoxynucleoside triphosphate allosteric effectors dGTP and dTTP, and the dimeric murine R2 subunit on both the quaternary structure of murine R1 subunit and the dependence of holoenzyme (R1(2)R2(2)) activity on substrate and effector concentrations. R1, monomeric in the absence of ligands, dimerizes in the presence of substrate, effectors, or R2(2) because each of these ligands binds R1(2) with higher affinity than R1 monomer. This leads to apparent positive heterotropic cooperativity between substrate and allosteric effector binding that is not observed when binding to the dimeric protein itself is evaluated. Allosteric activation results from an increase in k(cat) for substrate reduction upon binding of the correct effector, rather than from heterotropic cooperativity between effector and substrate. Neither the allosteric site nor the active site displays nucleotide base specificity: dissociation constants for dGTP and dTTP are nearly equivalent and K(m) and k(cat) values for both ADP and GDP are similar. R2(2) binding to R1(2) shows negative heterotropic cooperativity vis-à-vis effectors but positive heterotropic cooperativity vis-à-vis substrates. Binding of allosteric effectors to the holoenzyme shows homotropic cooperativity, suggestive of a conformational change induced by activator binding. This is consistent with kinetic results indicating full dimer activation upon binding a single equivalent of effector per R1(2)R2(2).     

Chloroperoxidase-catalyzed oxidation of 4,6-dimethyldibenzothiophene as dimer complexes: evidence for kinetic cooperativity

A sigmoidal kinetic behavior of chloroperoxidase for the oxidation of 4,6-dimethyldibenzothiophene (4,6-DMDBT) in water-miscible organic solvent is for the first time reported. Kinetics of 4,6-DMDBT oxidation showed a cooperative profile probably due to the capacity of chloroperoxidase to recognize a substrate dimer (pi-pi dimer) in its active site. Experimental evidence is given for dimer formation and its presence in the active site of chloroperoxidase. The kinetic data were adjusted for a binding site able to interact with either monomer or dimer substrates, producing a cooperative model describing a one-site binding of two related species. Determination of kinetics constants by iterative calculations of possible oxidation paths of 4,6-DMDBT suggests that kinetics oxidation of dimer substrate is preferred when compared to monomer oxidation. Steady-state fluorometry of substrate in the absence and presence of chloroperoxidase, described by the spectral center of mass, supports this last conclusion.     

Insights into the regulatory mechanism for caspase-8 activation

In the death receptor induced apoptotic pathway, caspase-8 autocatalytically cleaves itself at specific cleavage sites. To better understand the regulatory mechanisms behind caspase-8 activation, we compared active wild-type caspase-8 (wtC8) and an uncleavable form of procaspase-8 (uncleavable C8). We demonstrate that wtC8 predominantly exists as a monomer and dimerizes in a concentration and inhibitor binding-dependent fashion. The K(D) for dimeric wtC8 is approximately 50 micro M and decreases when inhibitor bound. Uncleavable C8 is mainly monomeric, but a small amount that dimerizes is as active as wtC8. Inhibitor binding does not favor dimerization but induces active site rearrangements in uncleavable C8. Our findings suggest that dimerization is the crucial factor for caspase-8 activation.     

The membrane-proximal intracellular domain of the epidermal growth factor receptor underlies negative cooperativity in ligand binding

The binding of EGF induces dimerization of its receptor, leading to the stimulation of its intracellular tyrosine kinase activity. Kinase activation occurs within the context of an asymmetric dimer in which one kinase domain serves as the activator for the other kinase domain but is not itself activated. How ligand binding is related to the formation and dynamics of this asymmetric dimer is not known. The binding of EGF to its receptor is negatively cooperative--that is, EGF binds with lower affinity to the second site on the dimer than to the first site on the dimer. In this study, we analyzed the binding of (125)I-EGF to a series of EGF receptor mutants in the intracellular juxtamembrane domain and demonstrate that the most membrane-proximal portion of this region plays a significant role in the genesis of negative cooperativity in the EGF receptor. The data are consistent with a model in which the binding of EGF to the first site on the dimer induces the formation of one asymmetric kinase dimer. The binding of EGF to the second site is required to disrupt the initial asymmetric dimer and allow the formation of the reciprocal asymmetric dimer. Thus, some of the energy of binding to the second site is used to reorient the first asymmetric dimer, leading to a lower binding affinity and the observed negative cooperativity.     

Cooperative effects of CTP on calf liver CTP synthetase.

In all previous kinetics studies of calf liver CTP synthetase, simple Michaelis-Menten hyperbolic plots were obtained. In this study it was shown that calf liver CTP synthetase could generate sigmoidal kinetic plots as a function of the substrate UTP when in the presence of the product of the reaction, CTP. The Hill number was estimated to be 2.8. The enzyme did not generate sigmoidal plots as a function of the other substrates (L-glutamine and ATP) either in the presence or absence of CTP. Thus, CTP apparently induced changes in the liver enzyme which altered the binding of UTP to the enzyme by acting at a site distinct from the UTP binding site (allosteric site). This concept was further strengthened by the fact that 3-deazaUTP, a known competitive inhibitor of the liver enzyme, did not induce sigmoidal kinetic plots. It was also shown that CTP had no effect upon the dimerization of the enzyme, thus ruling out monomer to dimer transitions as a potential mechanism for the observed sigmoidal kinetics.     

Zinc-mediated Allosteric Inhibition of Caspase-6

Zinc and caspase-6 have independently been implicated in several neurodegenerative disorders. Depletion of zinc intracellularly leads to apoptosis by an unknown mechanism. Zinc inhibits cysteine proteases, including the apoptotic caspases, leading to the hypothesis that zinc-mediated inhibition of caspase-6 might contribute to its regulation in a neurodegenerative context. Using inductively coupled plasma optical emission spectroscopy, we observed that caspase-6 binds one zinc per monomer, under the same conditions where the zinc leads to complete loss of enzymatic activity. To understand the molecular details of zinc binding and inhibition, we performed an anomalous diffraction experiment above the zinc edge. The anomalous difference maps showed strong 5σ peaks, indicating the presence of one zinc/monomer bound at an exosite distal from the active site. Zinc was not observed bound to the active site. The zinc in the exosite was liganded by Lys-36, Glu-244, and His-287 with a water molecule serving as the fourth ligand, forming a distorted tetrahedral ligation sphere. This exosite appears to be unique to caspase-6, as the residues involved in zinc binding were not conserved across the caspase family. Our data suggest that binding of zinc at the exosite is the primary route of inhibition, potentially locking caspase-6 into the inactive helical conformation.     

Molecular mechanism for dimerization to regulate the catalytic activity of human cytomegalovirus protease

Biochemical studies indicate that dimerization is required for the catalytic activity of herpesvirus proteases, whereas structural studies show a complete active site in each monomer, away from the dimer interface. Here we report kinetic, biophysical and crystallographic characterizations of structure-based mutants in the dimer interface of human cytomegalovirus (HCMV) protease. Such mutations can produce a 1,700-fold reduction in the kcat while having minimal effects on the K(m). Dimer stability is not affected by these mutations, suggesting that dimerization itself is insufficient for activity. There are large changes in monomer conformation and dimer organization of the apo S225Y mutant enzyme. However, binding of an activated peptidomimetic inhibitor induced a conformation remarkably similar to the wild type protease. Our studies suggest that appropriate dimer formation may be required to indirectly stabilize the protease oxyanion hole, revealing a novel mechanism for dimerization to regulate enzyme activity.     

Preparation of monomeric cytochrome C oxidase: its kinetics differ from those of the dimeric enzyme

Bovine cytochrome c oxidase in 0.1% dodecylmaltoside, 50 mM KCl and 10 mM Tris-HCl, pH 7.4 is monodisperse with an apparent Mr 360,000 (dimer) as estimated by filtration on Ultrogel AcA 34. In the absence of added KCl the apparent Mr is 160,000 (monomer). The dimeric enzyme has a high and a low affinity site for cytochrome c; the monomeric, only the high affinity site. The results are consistent with the existence of one active site per monomer, having high affinity for cytochrome c. Since in a dimer the two sites are in close proximity, the binding of the first molecule of cytochrome c to the first site hinders the binding of the second molecule to the second site. The kinetic data fit with a model of homotropic negative cooperativity. The effect of salts on the cytochrome c oxidase kinetics is also present in isolated bovine heart mitochondria.     

Modulation of dimer stability in yeast pyrophosphatase by mutations at the subunit interface and ligand binding to the active site

Yeast (Saccharomyces cerevisiae) pyrophosphatase (Y-PPase) is a tight homodimer with two active sites separated in space from the subunit interface. The present study addresses the effects of mutation of four amino acid residues at the subunit interface on dimer stability and catalytic activity. The W52S variant of Y-PPase is monomeric up to an enzyme concentration of 300 microm, whereas R51S, H87T, and W279S variants produce monomer only in dilute solutions at pH > or = 8.5, as revealed by sedimentation, gel electrophoresis, and activity measurements. Monomeric Y-PPase is considerably more sensitive to the SH reagents N-ethylmaleimide and p-hydroxymercurobenzosulfonate than the dimeric protein. Additionally, replacement of a single cysteine residue (Cys(83)), which is not part of the subunit interface or active site, with Ser resulted in insensitivity of the monomer to SH reagents and stabilization against spontaneous inactivation during storage. Active site ligands (Mg(2+) cofactor, P(i) product, and the PP(i) analog imidodiphosphate) stabilized the W279S dimer versus monomer predominantly by decreasing the rate of dimer to monomer conversion. The monomeric protein exhibited a markedly increased (5-9-fold) Michaelis constant, whereas k(cat) remained virtually unchanged, compared with dimer. These results indicate that dimerization of Y-PPase improves its substrate binding performance and, conversely, that active site adjustment through cofactor, product, or substrate binding strengthens intersubunit interactions. Both effects appear to be mediated by a conformational change involving the C-terminal segment that generally shields the Cys(83) residue in the dimer.     

Molecular dynamics studies of caspase-3

Caspase-3 is a fundamental target for pharmaceutical interventions against a variety of diseases involving disregulated apoptosis. The enzyme is active as a dimer with two symmetry-related active sites, each featuring a Cys-His catalytic dyad and a selectivity loop, which recognizes the characteristic DEVD pattern of the substrate. Here, a molecular dynamics study of the enzyme in complex with two pentapeptide substrates DEVDG is presented, which provides a characterization of the dynamic properties of the active form in aqueous solution. The mobility of the substrate and that of the catalytic residues are rather low indicating a distinct preorganization effect of the Michaelis complex. An essential mode analysis permits us to identify coupled motions between the two monomers. In particular, it is found that the motions of the two active site loops are correlated and tend to steer the substrate toward the reactive center, suggesting that dimerization has a distinct effect on the dynamic properties of the active site regions. The selectivity loop of one monomer turns out to be correlated with the N-terminal region of the p12 subunit of the other monomer, an interaction that is also found to play a fundamental role in the electrostatic stabilization of the quaternary structure. To further characterize the specific influence of dimerization on the enzyme essential motions, a molecular dynamics analysis is also performed on the isolated monomer.     

Sequential binding and sensing of Zn(II) by Bacillus subtilis Zur

Bacillus subtilis Zur (BsZur) represses high-affinity zinc-uptake systems and alternative ribosomal proteins in response to zinc replete conditions. Sequence alignments and structural studies of related Fur family proteins suggest that BsZur may contain three zinc-binding sites (sites 1-3). Mutational analyses confirm the essential structural role of site 1, while mutants affected in sites 2 and 3 retain partial repressor function. Purified BsZur binds a maximum of two Zn(II) per monomer at site 1 and site 2. Site 3 residues are important for dimerization, but do not directly bind Zn(II). Analyses of metal-binding affinities reveals negative cooperativity between the two site 2 binding events in each dimer. DNA-binding studies indicate that BsZur is sequentially activated from an inactive dimer (Zur(2):Zn(2)) to a partially active asymmetric dimer (Zur(2):Zn(3)), and finally to the fully zinc-loaded active form (Zur(2):Zn(4)). BsZur with a C84S mutation in site 2 forms a Zur(2):Zn(3) form with normal metal- and DNA-binding affinities but is impaired in formation of the Zur(2):Zn(4) high affinity DNA-binding state. This mutant retains partial repressor activity in vivo, thereby supporting a model in which stepwise activation by zinc serves to broaden the physiological response to a wider range of metal concentrations.     

Domain organization and functional analysis of type IIS restriction endonuclease Eco31I

Type IIS restriction endonuclease Eco31I harbors a single HNH active site and cleaves both DNA strands close to its recognition sequence, 5'-GGTCTC(1/5). A two-domain organization of Eco31I was determined by limited proteolysis. Analysis of proteolytic fragments revealed that the N-terminal domain of Eco31I is responsible for the specific DNA binding, while the C-terminal domain contains the HNH nuclease-like active site. Gel-shift and gel-filtration experiments revealed that a monomer of the N-terminal domain of Eco31I is able to bind a single copy of cognate DNA. However, in contrast to other studied type IIS enzymes, the isolated catalytic domain of Eco31I was inactive. Steady-state and transient kinetic analysis of Eco31I reactions was inconsistent with dimerization of Eco31I on DNA. Thus, we propose that Eco31I interacts with individual copies of its recognition sequence in its monomeric form and presumably remains a monomer as it cleaves both strands of double-stranded DNA. The domain organization and reaction mechanism established for Eco31I should be common for a group of evolutionary related type IIS restriction endonucleases Alw26I, BsaI, BsmAI, BsmBI and Esp3I that recognize DNA sequences bearing the common pentanucleotide 5'-GTCTC.     

Dimerization of chemokine receptors and its functional consequences

It became clear over the recent years that most, if not all, G protein-coupled receptors (GPCR) are able to form dimers or higher order oligomers. Chemokine receptors make no exception to this new rule and both homo- and heterodimerization were demonstrated for CC and CXC receptors. Functional analyses demonstrated negative binding cooperativity between the two subunits of a dimer. The consequence is that only one chemokine can bind with high affinity onto a receptor dimer. In the context of receptor activation, this implies that the motions of helical domains triggered by the binding of agonists induce correlated changes in the other protomer. The impact of the chemokine dimerization process in terms of co-receptor function and drug development is discussed.     

Kinetic analysis of product release and metal ions in a metallonuclease

Most nucleases rely on divalent cations as cofactors to catalyze the hydrolysis of nucleic acid phosphodiester bonds. Here both equilibrium and kinetic experiments are used to test recently proposed models regarding the metal ion dependence of product release and the degree of cooperativity between metal ions bound in the active sites of the homodimeric PvuII endonuclease. Equilibrium fluorescence anisotropy studies indicate that product binding is dramatically weakened in the presence of metal ions. Pre-steady state kinetics indicate that product release is at least partially rate limiting. Steady state and pre-steady state data fit best to models in which metals remain bound to the enzyme after the release of product. Finally, analysis of cooperative and independent binding models for metal ions indicates that single turnover kinetic data are consistent with little to no positive cooperativity between the two metal ions binding each active site.     

Cooperative binding of the yeast Spt10p activator to the histone upstream activating sequences is mediated through an N-terminal dimerization domain

The yeast Spt10p activator is a putative histone acetyltransferase (HAT) possessing a sequence-specific DNA-binding domain (DBD) which binds to the upstream activation sequences (UAS elements) in the histone gene promoters. Spt10p binds to a pair of histone UAS elements with extreme positive cooperativity. The molecular basis of this cooperativity was addressed. Spt10p (640 residues) is an elongated dimer, but the isolated DBD (residues 283–396) is a monomer and binds non-cooperatively to DNA. A Spt10p fragment comprising the N-terminal domain (NTD), HAT domain and DBD (residues 1–396) binds cooperatively and is a dimer, whereas an overlapping Spt10p fragment comprising the DBD and C-terminal domains (residues 283–640) binds non-cooperatively and is a monomer. These observations imply that cooperative binding requires dimerization. The isolated NTD (residues 1–98) is a dimer and is responsible for dimerization. We propose that cooperativity involves a conformational change in the Spt10p dimer which facilitates the simultaneous recognition of two UAS elements. In vivo, deletion of the NTD results in poor growth, but does not prevent the binding at the HTA1 promoter, suggesting that dimerization is biologically important. Residues 1–396 are sufficient for normal growth, indicating that the critical functions of Spt10p reside in the N-terminal domains.     

Structure of yeast hexokinase: IV. Low-resolution structure of enzyme—Substrate complexes revealing negative co-operativity and allosteric interactions

We conclude from X-ray diffraction studies at low resolution (7 Å) that the binding of sugar and nucleotide substrates to dimeric yeast hexokinase BII crystals exhibits both negative co-operativity and positive allosteric co-operativity. Difference electron density maps show the positions of sugar and nucleotide binding sites and extensive substrate-induced structural changes in the protein. Sugar substrates and inhibitors bind in the deep cleft that divides each subunit into two lobes and nucleotide substrates bind nearby to one site per dimer, which lies between the subunits and on the molecular symmetry axis. Although the inhibitors o- and p-iodobenzoylglucosamine and o-toluoylglucosamine bind equally to both subunits, the degree of substitution of glucose or xylose is very different for the two subunits. The substrate analog β, γ-imido ATP shows only one strong binding site per dimer. This negative co-operativity in substrate binding may result from the heterologous or non-equivalent association of the two subunits (Anderson et al., 1974), which provides non-equivalent environments for the two chemically identical subunits.Further, there is a positive allosteric interaction between the sugar and nucleotide binding sites. Sugar binding is required for nucleotide binding at the intersubunit site and the binding of nucleotide modifies the binding of sugars. These positive heterotropic interactions appear to be mediated by extensive substrate-induced structural changes in the enzyme.     

Control of adenosylmethionine-dependent radical generation in biotin synthase: a kinetic and thermodynamic analysis of substrate binding to active and inactive forms of BioB

Biotin synthase (BS) is an AdoMet-dependent radical enzyme that catalyzes the insertion of sulfur into saturated C6 and C9 atoms in the substrate dethiobiotin. To facilitate sulfur insertion, BS catalyzes the reductive cleavage of AdoMet to methionine and 5'-deoxyadenosyl radicals, which then abstract hydrogen atoms from the C6 and C9 positions of dethiobiotin. The enzyme from Escherichia coli is purified as a dimer that contains one [2Fe-2S]2+ cluster per monomer and can be reconstituted in vitro to contain an additional [4Fe-4S]2+ cluster per monomer. Since each monomer contains each type of cluster, the dimeric enzyme could contain one active site per monomer, or could contain a single active site at the dimer interface. To address these possibilities, and to better understand the manner in which biotin synthase controls radical generation and reactivity, we have examined the binding of AdoMet and DTB to reconstituted biotin synthase. We find that both the [2Fe-2S]2+ cluster and the [4Fe-4S]2+ cluster must be present for tight substrate binding. Further, substrate binding is highly cooperative, with the affinity for AdoMet increasing >20-fold in the presence of DTB, while DTB binds only in the presence of AdoMet. The stoichiometry of binding is ca. 2:1:1 AdoMet:DTB:BS dimer, suggesting that biotin synthase has a single functional active site per dimer. AdoMet binding, either in the presence or in the absence of DTB, leads to a decrease in the magnitude of the UV-visible absorption band at approximately 400 nm that we attribute to changes in the coordination environment of the [4Fe-4S]2+ cluster. Using these spectral changes as a probe, we have examined the kinetics of AdoMet and DTB binding, and propose an ordered binding mechanism that is followed by a conformational change in the enzyme-substrate complex. This kinetic analysis suggests that biotin synthase is evolved to bind AdoMet both weakly and slowly in the absence of DTB, while both the rate of binding and the affinity for AdoMet are increased in the presence of DTB. Cooperative binding of AdoMet and DTB may be an important mechanism for limiting the production of 5'-deoxyadenosyl radicals in the absence of the correct substrate.