Crystallographic and activity‐based evidence for thumb flexibility and its relevance in glycoside hydrolase family 11 xylanases

Enzyme intramolecular mobility and conformational changes of loops in particular play a significant role in biocatalysis. In this respect, the highly conserved thumb loop of glycoside hydrolase family (GH) 11 xylanases is an intriguing and characteristic structural element, of which the true dynamic nature and function in catalysis is still unknown. Crystallographic analysis of the structure of a Bacillus subtilis xylanase A mutant, found as a dimer in an asymmetric unit, revealed that the thumb region can adopt an extended conformation, which is stabilized in the crystal lattice through intermolecular contacts. In contrast to the closed thumb conformation of GH11 xylanases and the previously observed small conformational changes upon substrate binding, a relocation of the tip of the thumb of more than 15 Å was observed. Site‐directed mutagenesis of five thumb residues, including putative hinge point residues, and enzyme kinetics assays showed that Arg112, Asn114, and Thr126 play a role in the open‐close thumb movement. Replacement of Arg112 by glycine or proline caused a strong decrease of turnover numbers and elevated Michaelis constants on xylan. Mutant N114P hindered thumb movement, provoking a fourfold decrease of turnover numbers and a sharp rise in Michaelis constants, whereas the proline mutant of Thr126 displayed an increase in specific activity. The observation that extensive thumb opening is possible combined with the kinetic data suggests that the thumb plays a crucial role in both binding of substrate and release of product from the active site. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Characterization of temperature dependent and substrate-binding cleft movements in Bacillus circulans family 11 xylanase: A molecular dynamics investigation

Background

Xylanases (EC 3.2.1.8) hydrolyze xylan, one of the most abundant plant polysaccharides found in nature, and have many potential applications in biotechnology.

Methods

Molecular dynamics simulations were used to investigate the effects of temperature between 298 to 338 K and xylobiose binding on residues located in the substrate-binding cleft of the family 11 xylanase from Bacillus circulans (BcX).

Results

In the absence of xylobiose the BcX exhibits temperature dependent movement of the thumb region which adopts an open conformation exposing the active site at the optimum catalytic temperature (328 K). In the presence of substrate, the thumb region restricts access to the active site at all temperatures, and this conformation is maintained by substrate/protein hydrogen bonds involving active site residues, including hydrogen bonds between Tyr69 and the 2′ hydroxyl group of the substrate. Substrate access to the active site is regulated by temperature dependent motions that are restricted to the thumb region, and the BcX/substrate complex is stabilized by extensive intermolecular hydrogen bonding with residues in the active site.

General significance

These results call for a revision of both the “hinge-bending” model for the activity of group 11 xylanases, and the role of Tyr69 in the catalytic mechanism.     

木聚糖酶与XIP型木聚糖酶抑制蛋白相互作用分子机制的研究进展

Xylanase inhibitor protein (XIP)型木聚糖酶抑制蛋白对大部分GH10、GH11家族的真菌木聚糖酶具有抑制作用,但是却不能抑制细菌来源和植物自身所产生的木聚糖酶。XIP型木聚糖酶抑制蛋白对木聚糖酶的抑制作用主要是通过模拟底物接触酶的活性位点,迅速阻塞底物进入活性位点区域的通道。然而,在对XIP型木聚糖酶抑制蛋白具有抗性的GH10和GH11木聚糖酶晶体结构中,连接二级结构的Loop构象严重阻碍了XIP型木聚糖酶抑制蛋白的抑制功能。与对XIP型木聚糖酶抑制蛋白敏感的木聚糖酶相比,氨基酸残基的插入突变导致抗性木聚糖酶的Loop具有明显的凸出构象;而在GH11家族抗性木聚糖酶中,"拇指"结构中部分氨基酸的替换致使XIP型木聚糖酶抑制蛋白与"拇指"结构无法形成稳固的氢键和疏水建,从而削弱XIP的抑制作用。     

Importance of Arg-599 of β-galactosidase (Escherichia coli) as an anchor for the open conformations of Phe-601 and the active-site loop

Structural and kinetic data show that Arg-599 of β-galactosidase plays an important role in anchoring the "open" conformations of both Phe-601 and an active-site loop (residues 794-803). When alanine was substituted for Arg-599, the conformations of Phe-601 and the loop shifted towards the "closed" positions because interactions with the guanidinium side chain were lost. Also, Phe-601, the loop, and Na+, which is ligated by the backbone carbonyl of Phe-601, lost structural order, as indicated by large B-factors. IPTG, a substrate analog, restored the conformations of Phe-601 and the loop of R599A-β-galactosidase to the open state found with IPTG-complexed native enzyme and partially reinstated order. ?-Galactonolactone, a transition state analog, restored the closed conformations of R599A-β-galactosidase to those found with ?-galactonolactone-complexed native enzyme and completely re-established the order. Substrates and substrate analogs bound R599A-β-galactosidase with less affinity because the closed conformation does not allow substrate binding and extra energy is required for Phe-601 and the loop to open. In contrast, transition state analog binding, which occurs best when the loop is closed, was several-fold better. The higher energy level of the enzyme?substrate complex and the lower energy level of the first transition state means that less activation energy is needed to form the first transition state and thus the rate of the first catalytic step (k2) increased substantially. The rate of the second catalytic step (k3) decreased, likely because the covalent form is more stabilized than the second transition state when Phe-601 and the loop are closed. The importance of the guanidinium group of Arg-599 was confirmed by restoration of conformation, order, and activity by guanidinium ions.     

Crystal structure of the complex between 4-hydroxybutyrate CoA-transferase from Clostridium aminobutyricum and CoA

Clostridium aminobutyricum ferments 4-aminobutyrate (γ-aminobutyrate, GABA) to ammonia, acetate and butyrate via 4-hydroxybutyrate that is activated to the CoA-thioester catalyzed by 4-hydroxybutyrate CoA-transferase. Then, 4-hydroxybutyryl-CoA is dehydrated to crotonyl-CoA, which disproportionates to butyryl-CoA and acetyl-CoA. Cocrystallization of the CoA-transferase with the alternate substrate butyryl-CoA yielded crystals with non-covalently bound CoA and two water molecules at the active site. Most likely, butyryl-CoA reacted with the active site Glu238 to CoA and the mixed anhydride, which slowly hydrolyzed during crystallization. The structure of the CoA is similar but less stretched than that of the CoA-moiety of the covalent enzyme-CoA-thioester in 4-hydroxybutyrate CoA-transferase from Shewanella oneidensis. In contrast to the structures of the apo-enzyme and enzyme-CoA-thioester, the structure described here has a closed conformation, probably caused by a flip of the active site loop (residues 215–219). During turnover, the closed conformation may protect the anhydride intermediate from hydrolysis and CoA from dissociation from the enzyme. Hence, one catalytic cycle changes conformation of the enzyme four times: free enzyme—open conformation, CoA+ anhydride 1—closed, enzyme-CoA-thioester—open, CoA + anhydride-2—closed, free enzyme—open.     

Cysteines Introduced into Extracellular Loops 1 and 4 of Human P-Glycoprotein That Are Close Only in the Open Conformation Spontaneously Form a Disulfide Bond That Inhibits Drug Efflux and ATPase Activity

P-glycoprotein (P-gp) is an ATP-binding cassette drug pump that protects us from toxic compounds and confers multidrug resistance. The protein is organized into two halves. The halves contain a transmembrane domain (TMD) with six transmembrane segments and a nucleotide-binding domain (NBD). The drug- and ATP-binding sites reside at the TMD1/TMD2 and NBD1/NBD2 interfaces, respectively. ATP-dependent drug efflux involves changes between the open inward-facing (NBDs apart, extracellular loops (ECLs) close together) and the closed outward-facing (NBDs close together, ECLs apart) conformations. It is controversial, however, whether the open conformation only exists transiently in intact cells because of the presence of high levels of ATP. To test for the presence of an open conformation in intact cells, reporter cysteines were placed in extracellular loops 1 (A80C, N half) and 4 (R741C, C half). The rationale was that cysteines A80C/R741C would only come close enough to form a disulfide bond in an open conformation (6.9 Å apart) because they are separated widely (30.4 Å apart) in the closed conformation. It was observed that the mutant A80C/R741C cross-linked spontaneously (>90%) when expressed in cells. In contrast to previous reports showing that trapping P-gp in a closed conformation highly activated ATPase activity, here we show that A80C/R741C cross-linking inhibited ATPase activity and drug efflux. Both activities were restored when the cross-linked mutant was treated with a thiol-reducing agent. The results show that an open conformation can be readily detected in cells and that cross-linking of cysteines placed in ECLs 1 and 4 inhibits activity.     

Effects of site-directed mutagenesis on structure and function of recombinant rat liver S-adenosylhomocysteine hydrolase. Crystal structure of D244E mutant enzyme

A site-directed mutagenesis, D244E, of S-adenosylhomocysteine hydrolase (AdoHcyase) changes drastically the nature of the protein, especially the NAD(+) binding affinity. The mutant enzyme contained NADH rather than NAD(+) (Gomi, T., Takata, Y., Date, T., Fujioka, M., Aksamit, R. R., Backlund, P. S., and Cantoni, G. L. (1990) J. Biol. Chem. 265, 16102-16107). In contrast to the site-directed mutagenesis study, the crystal structures of human and rat AdoHcyase recently determined have shown that the carboxyl group of Asp-244 points in a direction opposite to the bound NAD molecule and does not participate in any hydrogen bonds with the NAD molecule. To explain the discrepancy between the mutagenesis study and the x-ray studies, we have determined the crystal structure of the recombinant rat-liver D244E mutant enzyme to 2.8-A resolution. The D244E mutation changes the enzyme structure from the open to the closed conformation by means of a approximately 17 degrees rotation of the individual catalytic domains around the molecular hinge sections. The D244E mutation shifts the catalytic reaction from a reversible to an irreversible fashion. The large affinity difference between NAD(+) and NADH is mainly due to the enzyme conformation, but not to the binding-site geometry; an NAD(+) in the open conformation is readily released from the enzyme, whereas an NADH in the closed conformation is trapped and cannot leave the enzyme. A catalytic mechanism of AdoHcyase has been proposed on the basis of the crystal structures of the wild-type and D244E enzymes.     

Substrate-induced DNA Polymerase β Activation

DNA polymerases and substrates undergo conformational changes upon forming protein-ligand complexes. These conformational adjustments can hasten or deter DNA synthesis and influence substrate discrimination. From structural comparison of binary DNA and ternary DNA-dNTP complexes of DNA polymerase β, several side chains have been implicated in facilitating formation of an active ternary complex poised for chemistry. Site-directed mutagenesis of these highly conserved residues (Asp-192, Arg-258, Phe-272, Glu-295, and Tyr-296) and kinetic characterization provides insight into the role these residues play during correct and incorrect insertion as well as their role in conformational activation. The catalytic efficiencies for correct nucleotide insertion for alanine mutants were wild type ∼ R258A > F272A ∼ Y296A > E295A > D192A. Because the efficiencies for incorrect insertion were affected to about the same extent for each mutant, the effects on fidelity were modest (<5-fold). The R258A mutant exhibited an increase in the single-turnover rate of correct nucleotide insertion. This suggests that the wild-type Arg-258 side chain generates a population of non-productive ternary complexes. Structures of binary and ternary substrate complexes of the R258A mutant and a mutant associated with gastric carcinomas, E295K, provide molecular insight into intermediate structural conformations not appreciated previously. Although the R258A mutant crystal structures were similar to wild-type enzyme, the open ternary complex structure of E295K indicates that Arg-258 stabilizes a non-productive conformation of the primer terminus that would decrease catalysis. Significantly, the open E295K ternary complex binds two metal ions indicating that metal binding cannot overcome the modified interactions that have interrupted the closure of the N-subdomain.     

Investigation by MD simulation of the key residues related to substrate-binding and heme-release in human ferrochelatase

Molecular dynamics (MD) simulations of three models based on the crystal structure of the E343K variant of human ferrochelatase were performed in this study. The “open” and “closed” conformations of the enzyme obtained by simulations are in agreement with the corresponding crystal structures. The snapshots and the structure analysis indicate that alterations of the hydrogen bonds and the positions of E347 and E351 lead to a conformational change in the π-helix. The hydrogen bonded form of residue R164 could be regarded as a signal indicating alteration of the active site conformation. When R164 forms a hydrogen bond with D95, the active site is closed, and when a hydrogen bond is formed with E171, the active site is open. Interestingly, the protoporphyrin with Fe²⁺ is observed to move noticeably out of the enzyme while the protoporphyrin lacking Fe²⁺ remains almost fixed. Alterations of the hydrogen bonds between the propionate of the heme and R115, K118 and S303 trigger movement of the heme out of the active site. Residues E347 and E351, which are located on the π-helix and form an acidic path leading to a salt bridge interaction with the propionate of the heme, accelerate the release process.     

Pyruvate Formate-lyase,Evidence for an Open Conformation Favored in the Presence of Its Activating Enzyme

Pyruvate formate-lyase-activating enzyme (PFL-AE) activates pyruvate formate-lyase (PFL) by generating a catalytically essential radical on Gly-734 of PFL. Crystal structures of unactivated PFL reveal that Gly-734 is buried 8 Å from the surface of the protein in what we refer to here as the closed conformation of PFL. We provide here the first experimental evidence for an alternate open conformation of PFL in which: (i) the glycyl radical is significantly less stable; (ii) the activated enzyme exhibits lower catalytic activity; (iii) the glycyl radical undergoes less H/D exchange with solvent; and (iv) the T_m of the protein is decreased. The evidence suggests that in the open conformation of PFL, the Gly-734 residue is located not in its buried position in the enzyme active site but rather in a more solvent-exposed location. Further, we find that the presence of the PFL-AE increases the proportion of PFL in the open conformation; this observation supports the idea that PFL-AE accesses Gly-734 for direct hydrogen atom abstraction by binding to the Gly-734 loop in the open conformation, thereby shifting the closed ↔ open equilibrium of PFL to the right. Together, our results lead to a model in which PFL can exist in either a closed conformation, with Gly-734 buried in the active site of PFL and harboring a stable glycyl radical, or an open conformation, with Gly-734 more solvent-exposed and accessible to the PFL-AE active site. The equilibrium between these two conformations of PFL is modulated by the interaction with PFL-AE.     

Structural basis for the altered activity of Gly794 variants of Escherichia coli beta-galactosidase

The open-closed conformational switch in the active site of Escherichia coli beta-galactosidase was studied by X-ray crystallography and enzyme kinetics. Replacement of Gly794 by alanine causes the apoenzyme to adopt the closed rather than the open conformation. Binding of the competitive inhibitor isopropyl thio-beta-D-galactoside (IPTG) requires the mutant enzyme to adopt its less favored open conformation, weakening affinity relative to wild type. In contrast, transition-state inhibitors bind to the enzyme in the closed conformation, which is favored for the mutant, and display increased affinity relative to wild type. Changes in affinity suggest that the free energy difference between the closed and open forms is 1-2 kcal/mol. By favoring the closed conformation, the substitution moves the resting state of the enzyme along the reaction coordinate relative to the native enzyme and destabilizes the ground state relative to the first transition state. The result is that the rate constant for galactosylation is increased but degalactosylation is slower. The covalent intermediate may be better stabilized than the second transition state. The substitution also results in better binding of glucose to both the free and the galactosylated enzyme. However, transgalactosylation with glucose to produce allolactose (the inducer of the lac operon) is slower with the mutant than with the native enzyme. This suggests either that the glucose is misaligned for the reaction or that the galactosylated enzyme with glucose bound is stabilized relative to the transition state for transgalactosylation.     

Molecular Dynamics Simulation Studies of dTTP Binding and Catalysis Mediated by YhdE Dimerization

YhdE is a Maf-like (multicopy associated filamentation) protein that primarily acts as dTTPase to hydrolyze dTTP into dTMP and two phosphate molecules in cell metabolism pathway. Two crystal structures of YhdE have been previously determined, representing the open and closed active site conformations, respectively. Based on the structures, we have carried out molecular dynamics simulations and free energy calculations to investigate dTTP binding to and hydrolysis by YhdE. Our results suggest that YhdE closed state is structurally more compact than its open state at room temperature. YhdE open state is a favorable conformation for dTTP binding and closed state is a structurally favorable conformation for catalytic reaction. This observation is supported by the structure of YhdE homolog in complex with a nucleotide analog. Free energy calculations reveal that YhdE dimerization occurs preferentially in dTTP binding and is favorable for successive cooperative reaction. The key residues R11, R12 and K80, are found to contribute to the substrate stabilization. Further, YhdE dimerization and binding of dTTP induce the cooperative effect through a direct allosteric communication network in YhdE from the dTTP binding sites in the catalytic center to the intermolecular β-strand in YhdE dimer.     

Molecular dynamics studies on HIV-1 protease: a comparison of the flap motions between wild type protease and the M46I/G51D double mutant

The emergence of drug-resistant mutants of HIV-1 is a tragic effect associated with conventional long-treatment therapies against acquired immunodeficiency syndrome. These mutations frequently involve the aspartic protease encoded by the virus; knowledge of the molecular mechanisms underlying the conformational changes of HIV-1 protease mutants may be useful in developing more effective and longer lasting treatment regimes. The flap regions of the protease are the target of a particular type of mutations occurring far from the active site. These mutations modify the affinity for both substrate and ligands, thus conferring resistance. In this work, molecular dynamics simulations were performed on a native wild type HIV-1 protease and on the drug-resistant M46I/G51D double mutant. The simulation was carried out for a time of 3.5 ns using the GROMOS96 force field, with implementation of the SPC216 explicit solvation model. The results show that the flaps may exist in an ensemble of conformations between a “closed” and an “open” conformation. The behaviour of the flap tips during simulations is different between the native enzyme and the mutant. The mutation pattern leads to stabilization of the flaps in a semi-open configuration.     

Dynamic reorganization of the motor domain of myosin subfragment 1 in different nucleotide states.

Atomic models of the myosin motor domain with different bound nucleotides have revealed the open and closed conformations of the switch 2 element [Geeves, M.A. & Holmes, K.C. (1999) Annu. Rev. Biochem.68, 687-728]. The two conformations are in dynamic equilibrium, which is controlled by the bound nucleotide. In the present work we attempted to characterize the flexibility of the motor domain in the open and closed conformations in rabbit skeletal myosin subfragment 1. Three residues (Ser181, Lys553 and Cys707) were labelled with fluorophores and the probes identified three fluorescence resonance energy transfer pairs. The effect of ADP, ADP.BeFx, ADP.AlF4- and ADP.Vi on the conformation of the motor domain was shown by applying temperature-dependent fluorescence resonance energy transfer methods. The 50 kDa lower domain was found to maintain substantial rigidity in both the open and closed conformations to provide the structural basis of the interaction of myosin with actin. The flexibility of the 50 kDa upper domain was high in the open conformation and further increased in the closed conformation. The converter region of subfragment 1 became more rigid during the open-to-closed transition, the conformational change of which can provide the mechanical basis of the energy transduction from the nucleotide-binding pocket to the light-chain-binding domain.     

Mutations at subsite −3 in cyclodextrin glycosyltransferase from <Emphasis Type="Italic">Paenibacillus macerans</Emphasis> enhancing α-cyclodextrin specificity

A major disadvantage of cyclodextrin production is the limited cyclodextrin product specificity of cyclodextrin glycosyltransferase (CGTase). Here, we described mutations of Asp372 and Tyr89 at subsite −3 in the CGTase from Paenibacillus macerans strain JFB05-01. The results showed that Asp372 and Tyr89 played important roles in cyclodextrin product specificity of CGTase. The replacement of Asp372 by lysine and Tyr89 by aspartic acid, asparagine, lysine, and arginine resulted in a shift in specificity towards the production of α-cyclodextrin, which was most apparent for the mutants D372K and Y89R. Furthermore, the changes in cyclodextrin product specificity for the single mutants D372K and Y89R could be combined in the double mutant D372K/Y89R, which displayed a 1.5-fold increase in the production of α-cyclodextrin, with a concomitant 43% decrease in the production of β-cyclodextrin when compared to the wild-type CGTase. Thus, the D372K and Y89R single and double mutants were much more suitable for the industrial production of α-cyclodextrin than the wild-type enzyme. The enhanced α-cyclodextrin specificity of these mutants might be a result of stabilizing the bent conformation of the intermediate in the cyclization reaction.     

Engineering E. coli Alkaline Phosphatase Yields Changes of Catalytic Activity,Thermal Stability and Phosphate Inhibition

To investigate the function of aspartic acid residue 101 and arginine residue 166 in the active site of Escherichia coli alkaline phosphatase (EAP), two single mutants D101S (Asp 101 &#77 Ser) and R166K (Arg 166 &#77 Lys) and a double mutant D101S/R166K of EAP were generated through site-directed mutagenesis based on over-lap PCR method. Their enzymatic kinetic properties, thermal stabilities and possible reaction mechanism were explored. In the presence of inorganic phosphate acceptor, 1 M diethanolamine buffer, the k cat for D101S mutant enzyme increased 10-fold compared to that of wild-type EAP. The mutant R166K has a 2-fold decrease of k cat relative to the wild-type EAP, but the double mutant D101S/R166K was in the middle of them, indicative of an additive effect of these two mutations. On the other hand, the catalytic efficiencies of mutant enzymes are all reduced because of a substantial increase of K m values. All three mutants were more resistant to phosphate inhibitor than the wild-type enzyme. The analysis of the kinetic data suggests that (1) the D101S mutant enzyme obtains a higher catalytic activity by allowing a faster release of the product; (2) the R166K mutant enzyme can reduce the binding of the substrate and phosphate competitive inhibitor; (3) the double mutant enzyme has characteristics of both quicker catalytic turnover number and decreased affinity for competitive inhibitor. Additionally, pre-steady-state kinetics of D101S and D101S/R166K mutants revealed a transient burst followed by a linear steady state phase, obviously different from that of wild-type EAP, suggesting that the rate-limiting step has partially change from the release of phosphate from non-covalent E-Pi complex to the hydrolysis of covalent E-Pi complex for these two mutants.     

Accessibility of Four Arginine Residues on the S4 Segment of the Bacillus halodurans Sodium Channel

The voltage-gated Na⁺ channel of Bacillus halodurans (NaChBac) is composed of six transmembrane segments (S1–S6), with a pore-forming region composed of segments S5 and S6 and a voltage-sensing domain composed of segments S1–S4. The S4 segment forms the core of the voltage sensor. We explored the accessibility of four arginine residues on the S4 segment of NaChBac, which are positioned at every third position from each other. These arginine residues on the S4 segment were replaced with cysteines using site-directed mutagenesis. Na⁺ currents were recorded using the whole-cell configuration of the patch-clamp technique. We tested the effect of the sulfhydryl reagents applied from inside and outside the cellular space in the open and closed conformations. Structural models of the voltage sensor of NaChBac were constructed based on the recently crystallized KvAP and Kv1.2 K⁺ channels to visualize arginine residue accessibility. Our results suggest that arginine accessibility did not change significantly between the open and closed conformations, supporting the idea of a small movement of the S4 segment during gating. Molecular modeling of the closed conformation also supported a small movement of S4, which is mainly characterized by a rotation and a tilt along the periphery of the pore. Interestingly, the second arginine residue of the S4 segment (R114) was accessible to sulfhydryl reagents from both sides of the membrane in the closed conformation and, based on our model, seemed to be at the junction of the intracellular and extracellular water crevices.     

The structures of Thermoplasma volcanium phosphoribosyl pyrophosphate synthetase bound to ribose-5-phosphate and ATP analogs

Phosphoribosyl pyrophosphate (PRPP) synthetase catalyzes the transfer of the pyrophosphate group from ATP to ribose-5-phosphate (R5P) yielding PRPP and AMP. PRPP is an essential metabolite that plays a central role in cellular metabolism. The enzyme from a thermophilic archaeon Thermoplasma volcanium (Tv) was expressed in Escherichia coli, crystallized, and its X-ray molecular structure was determined in a complex with its substrate R5P and with substrate analogs β,γ-methylene ATP and ADP in two monoclinic crystal forms, P2₁. The β,γ-methylene ATP- and the ADP-bound binary structures were determined from crystals grown from ammonium sulfate solutions; these crystals diffracted to 1.8 Å and 1.5 Å resolutions, respectively. Crystals of the ternary complex with ADP-Mg²⁺ and R5P were grown from a polyethylene glycol solution in the absence of sulfate ions, and they diffracted to 1.8 Å resolution; the unit cell is approximately double the size of the unit cell of the crystals grown in the presence of sulfate. The Tv PRPP synthetase adopts two conformations, open and closed, at different stages in the catalytic cycle. The binding of substrates, R5P and ATP, occurs with PRPP synthetase in the open conformation, whereas catalysis presumably takes place with PRPP synthetase in the closed conformation. The Tv PRPP synthetase forms a biological dimer in contrast to the tetrameric or hexameric quaternary structures of the Methanocaldococcus jannaschii and Bacillus subtilis PRPP synthetases, respectively.     

Structural characterization of the active and inactive states of Src kinase in solution by small-angle X-ray scattering

Src kinase plays an important role in several signaling and regulation mechanisms in vivo. Enzymatic activity is tightly regulated through the phosphorylation and dephosphorylation of tyrosine 527, which is placed at the C-terminal tail. Here, we have addressed domain rearrangements involved in the regulation mechanism of Src kinase in solution using small-angle X-ray scattering. In the phosphorylated wild-type form of Src kinase corresponding to the inactive state of the protein, a single conformation compatible with a closed crystallographic structure was found in solution. In the Y527F point mutant representing the active state, analysis of scattering data reveals an equilibrium between two differently populated conformations differing in the radius of gyration by 5 Å. The major species (85% of the total population) presents a closed conformation indistinguishable from the crystallographic structure of the inactive state. The minor species (15% of the total population) is an open conformation similar to the crystallographic structure in the active state. The latter structure has the SH3, SH2, and SH2-catalytic domain linker assembled as a pseudo-two-domain protein. The regulation model emerging from this study, including at least three different conformational states, allows the tight regulation of the enzyme without compromising fast response in the presence of natural targets.