Three-dimensional structure of endo-1,4-beta-xylanase II from Trichoderma reesei: two conformational states in the active site.

The three-dimensional structure of endo-1,4-beta-xylanase II (XYNII) from Trichoderma reesei has been determined by X-ray diffraction techniques and refined to a conventional R-factor of 18.3% at 1.8 A resolution. The 190 amino acid length protein was found to exist as a single domain where the main chain folds to form two mostly antiparallel beta-sheets, which are packed against each other in parallel. The beta-sheet structure is twisted, forming a large cleft on one side of the molecule. The structure of XYNII resembles that of Bacillus 1,3-1,4-beta-glucanase. The cleft is an obvious suggestion for an active site, which has putative binding sites for at least four xylose residues. The catalytic residues are apparently the two glutamic acid residues (Glu86 and Glu177) in the middle of the cleft. One structure was determined at pH 5.0, corresponding to the pH optimum of XYNII. The second structure was determined at pH 6.5, where enzyme activity is reduced considerably. A clear structural change was observed, especially in the position of the side chain of Glu177. The observed conformational change is probably important for the mechanism of catalysis in XYNII.     

A de novo designed N-terminal disulphide bridge stabilizes the Trichoderma reesei endo-1,4-beta-xylanase II

We have successfully engineered a disulphide bridge into the N-terminal region of Trichoderma reesei endo-1,4-beta-xylanase II (XYNII) by substituting Thr-2 and Thr-28 with cysteine. The T2C:T28C mutational changes increased the half-life in thermal inactivation of this mesophilic enzyme from approximately 40 s to approximately 20 min at 65 degrees C, and from less than 10 s to approximately 6 min at 70 degrees C. Therefore, the N-terminal disulphide bridge enables the use of XYNII at substantially higher temperatures than permitted by its native mesophilic counterpart. Altogether, thermostability increased by about 15 degrees C. The kinetic properties of the mutant XYNII were maintained at the level of the wild type enzyme. Our findings demonstrated that a properly designed disulphide bridge, here within the N-terminal region of XYNII, can be very effective in resisting thermal inactivation.     

Irreversible thermal denaturation of Trichoderma reesei endo-1,4-beta-xylanase II and its three disulfide mutants characterized by differential scanning calorimetry

Kinetic as well as energetic aspects of the thermal denaturation of Trichoderma reesei endo-1,4-beta-xylanase II (TRX II) and its three thermostable disulfide mutants were characterized by means of differential scanning calorimetry (DSC) in different solution conditions. The calorimetric transitions were strongly scan-rate dependent, characteristic for an irreversible, kinetically controlled protein denaturation. The DSC-determined T*-values (the temperature at which the denaturation rate constant equals 1min(-1)), and the activation free energies for the transitions are consistent with the apparent transition temperatures of TRX II determined earlier by mass spectrometry. Protein aggregation, connected with the irreversibility of the transitions, was present in all cases but was less pronounced with the mutants as well as highly dependent on experimental conditions.     

瑞氏木霉木糖醇脱氢酶基因的分离与鉴定

将在木聚糖上生长的瑞氏木霉(Trichoderma reesei)RutC-30的cDNA文库全部质粒转化已携带有毕赤氏酵(Pithia stipitis)木糖还原酶基因的重组酿酒酵母(Saccharomycescerevisiae)菌株H475,在H475中构建了瑞氏木霉的cDNA表达亚文库。在以木糖为唯一碳源的选择性酵母合成培养基上,从该亚文库中筛选到瑞氏木霉木糖醇脱氢酶cDNA基因．该基因片段长为1．3kb。Southern、Norhern印迹杂交分析和蛋白质凝胶电泳结果表明该基因确实来源于瑞氏木霉,所编码蛋白质分子量约为40kDa。携带有毕赤氏酵母木糖还原酶和瑞氏木霉木糖醇脱氢酶基因的重组酵母能够在以木糖为唯一碳源的培养基上生长,并能将90％以上的木糖转化为木糖醇、乙醇和其它副产品。     

Mode of action and properties of the beta-xylosidases from Talaromyces emersonii and Trichoderma reesei

Enzymatic hydrolysis of arabinoxylan is an important prerequisite for the utilization of hemicellulose for ethanol fermentation or for making the low calorie sweetener xylitol by catalytic hydrogenation of the generated xylose. This study focus on cloning and characterization of two industrial relevant beta-xylosidases (1,4-beta-D-xylan xylohydrolase, EC 3.2.1.37) from Talaromyces emersonii (betaXTE) and Trichoderma reesei (betaXTR) and a comparison of these in relation to hemicellulose hydrolysis using an industrial relevant substrate. Both beta-xylosidases were expressed in A. oryzae and subsequently purified. During the enzymatic hydrolysis of xylobiose, the reaction product of both enzymes was found to be beta-D-xylose proving that the hydrolysis is proceeding via a retaining reaction mechanism. Based on sequence similarities and glycosyl hydrolases family membership, the active site residues of betaXTE and betaXTR are predicted to be Asp 242 and Glu 441, and Asp 264 and Glu 464, respectively. The involvement in catalysis of these carboxyls was examined by modification using the carbodiimide-nucleophile procedure resulting in a complete inactivation of both enzymes. The degree of xylose release from vinasse, an ethanol fermentation by-product, by betaXTE and betaXTR was 12.1% and 7.7%, respectively. Using the beta-xylosidases in combination with the multicomponent enzyme product Ultraflo L, resulted in 41.9% and 40.8% release of xylose, respectively indicating a strong synergistic effect between the exo-acting beta-xylosidases and the endo-1,4-beta-xylanases and alpha-L-arabinofuranosidase in Ultraflo L. There seems to be no measurable differences between the two beta-xylosidases when used in this specific application despite the differences in specific activity and kinetic properties.     

Insight of Endo-1,4-Xylanase II from Trichoderma reesei: Conserved Water-Mediated H-Bond and Ion Pairs Interactions

Endo-1,4-Xylanase II is an enzyme which degrades the linear polysaccharide beta-1,4-xylan into xylose. This enzyme shows highest enzyme activity around 55 °C, even without being stabilized by the disulphide bridges. A set of nine high resolution crystal structures of Xylanase II (1.11–1.80 Å) from Trichoderma reesei were selected and analyzed in order to identify the invariant water molecules, ion pairs and water-mediated ionic interactions. The crystal structure (PDB-id: 2DFB) solved at highest resolution (1.11 Å) was chosen as the reference and the remaining structures were treated as mobile molecules. These structures were then superimposed with the reference molecule to observe the invariant water molecules using 3-dimensional structural superposition server. A total of 37 water molecules were identified to be invariant molecules in all the crystal structures, of which 26 invariant molecules have hydrogen bond interactions with the back bone of residues and 21 invariant water molecules have interactions with side chain residues. The structural and functional roles of these water molecules and ion pairs have been discussed. The results show that the invariant water molecules and ion pairs may be involved in maintaining the structural architecture, dynamics and function of the Endo-1,4-Xylanase II.     

Characterization of an unglycosylated low molecular weight 1,4-β-glucan-glucanohydrolase of Trichoderma reesei

A low molecular weight endoglucanase (1,4-beta-glucan glucanohydrolase E.C.3.2.1.4) was purified to homogeneity by a two-step procedure from 7 day old culture filtrates of Trichoderma reesei. The endoglucanase was obtained by BioGel A 0.5 m gel chromatography followed by preparative PAGIF. The purified endoglucanase was homogeneous upon titration curve separation. Enzyme characteristics were: Mr 25 kDa, pI 7.5. The amino acid composition is predominantly neutral (mainly glycine). The N-terminus is arginine. The pH-optimum for this endoglucanase was 5.8 and its optimal temperature was at 52 degrees C. The activity of this endoglucanase gave a strong increase in CMC-fluidity with only a small release of reducing sugars. The endoglucanase was 0.2% of total culture medium protein content. The reducing sugars upon CMC digestion were G1-G4. The enzyme had no specificity towards crystalline cellulose (Avicel) or xylan. The endoglucanase is not a glycoprotein.     

Hypocrea jecorina (Trichoderma reesei) Cel7A as a molecular machine: A docking study

Hypocrea jecorina (formerly Trichoderma reesei) Cel7A has a catalytic domain (CD) and a cellulose-binding domain (CBD) separated by a highly glycosylated linker. Very little is known of how the 2 domains interact to degrade crystalline cellulose. Based on the interaction energies and forces on cello-oligosaccharides computationally docked to the CD and CBD, we propose a molecular machine model, where the CBD wedges itself under a free chain end on the crystalline cellulose surface and feeds it to the CD active site tunnel. Enzyme-substrate interactions produce the forces required to pull cellulose chains from the surface and also to help the enzyme move on the cellulose chain for processive hydrolysis. The energy to generate these forces is ultimately derived from the chemical energy of glycosidic bond breakage.     

Small angle neutron scattering reveals pH-dependent conformational changes in Trichoderma reesei cellobiohydrolase I: implications for enzymatic activity

Cellobiohydrolase I (Cel7A) of the fungus Trichoderma reesei (now classified as an anamorph of Hypocrea jecorina) hydrolyzes crystalline cellulose to soluble sugars, making it of key interest for producing fermentable sugars from biomass for biofuel production. The activity of the enzyme is pH-dependent, with its highest activity occurring at pH 4-5. To probe the response of the solution structure of Cel7A to changes in pH, we measured small angle neutron scattering of it in a series of solutions having pH values of 7.0, 6.0, 5.3, and 4.2. As the pH decreases from 7.0 to 5.3, the enzyme structure remains well defined, possessing a spatial differentiation between the cellulose binding domain and the catalytic core that only changes subtly. At pH 4.2, the solution conformation of the enzyme changes to a structure that is intermediate between a properly folded enzyme and a denatured, unfolded state, yet the secondary structure of the enzyme is essentially unaltered. The results indicate that at the pH of optimal activity, the catalytic core of the enzyme adopts a structure in which the compact packing typical of a fully folded polypeptide chain is disrupted and suggest that the increased range of structures afforded by this disordered state plays an important role in the increased activity of Cel7A through conformational selection.     

Engineering of multiple arginines into the Ser/Thr surface of Trichoderma reesei endo-1,4-beta-xylanase II increases the thermotolerance and shifts the pH optimum towards alkaline pH

We studied the effects of increase in the number of surface arginines on the enzyme activity and stability of Trichoderma reesei endo-1,4-beta-xylanase II. The number of arginines was increased in two mutant series. The first set contained six arginines on different sides of the protein surface. These arginines had no significant effect on the thermostability. However, the optimal pH region became narrower. Another series of five arginines was engineered into the 'Ser/Thr surface', formed of part of the double-layered beta-sheet located on one side of the 'right-hand-like' xylanase. These mutations shifted the activity profile to the alkaline region by approximately 0.5-1.0 pH units. In addition, the arginines on the Ser/Thr surface increased the enzyme activity at high temperature, although the enzyme stability in the absence of substrate decreased significantly at 50-55 degrees C. In the presence of the substrate, the thermostability increased 4-5-fold at 60-65 degrees C. Thus, the substrate neutralized the destabilizing effect of Ser/Thr surface arginines and revealed a stabilizing effect of the same mutations. The stabilizing effect of arginines at high temperatures was seen clearly only when five arginines were introduced into the Ser/Thr surface.     

Isolation and properties of a low molecular mass endoglucanase from Trichoderma reesei

Abstract Optimal culture conditions for obtaining low molecular mass endoglucanase (EG) from culture fluids of Trichoderma reesei were determined. The purification of this unglycosylated EG in a two-step procedure is described. In contrast to most cellulases, this EG did not bind to ConA-affinity columns. The unglycosylated fraction of the culture fluid proteins was further purified by preparative isoelectric focusing. Conditions relevant to an enzyme assay for this EG were determined (pH optimum 5.8, temperature optimum 52°C).     

Mechanical response and conformational changes of alpha-actinin domains during unfolding: a molecular dynamics study

Alpha-actinin is a cytoskeleton-binding protein involved in the assembly and regulation of the actin filaments. In this work molecular dynamics method was applied to investigate the mechanical behaviour of the human skeletal muscle α-actinin. Five configurations were unfolded at an elongation speed of 0.1 nm/ps in order to investigate the conformational changes occurring during the extension process. Moreover, a sensitivity analysis at different velocities was performed for one of the R2–R3 spectrin-like repeat configuration extracted in order to evaluate the effect of the pulling speed on the mechanical behaviour of the molecule. Two different behaviours were recognized with respect to the pulling speed. In particular, at speed higher than 0.025 nm/ps a continuous rearrangement without evident force peaks was obtained, on the contrary at lower speed evident peaks in the range 500–750 pN were detected. R3 repeat resulted more stable than R2 during mechanical unfolding, due to the lower hydrophobic surface available to the solvent. The characterization of the R2–R3 units can be useful for the development of cytoskeleton network models based on stiffness values obtained by analyses performed at the molecular level.     

Purification and characterization of an extracellular endo-1,4-β-xylanase from Fusarium oxysporum f. sp. melonis

Abstract Fusarium oxysporum f. sp. melonis produces extracellular endo-1,4-β-xylanase and β-xylosidase when grown in shaken culture at 26°C in a mineral salts medium containing oat spelt xylan and glucose as carbon sources. Endo-1,4-β-xylanase was purified 251 times from 5-day-old culture filtrates, by Sephacryl S-200, ion exchange and gel filtration HPLC. The purified sample yielded a single band in SDS polyacrylamide gels with a molecular mass of 80 kDa on electrophoretic mobility and 83 kDa by gel filtration behavior. High activity of the endo-1,4-β-xylanase against xylan was observed between 5 and 8 pH, and between 40 and 60°C, the optimum pH and temperature being 5.0 and 50°C, respectively. Kinetic properties of the enzyme are similar to those of other fungal xylanases, showing high affinity towards oat spelt xylan with a K _m of 1 mM expressed as xylose equivalent.     

Molecular insight into conformational transformation of human glucokinase: conventional and targeted molecular dynamics

Abstract

Glucokinase (GK) plays a key role in the regulation of hepatic glucose metabolism. An unusual mechanism of positive cooperativity of monomeric GK containing only a single binding site for glucose is very interesting and still unclear. The activation process of GK is associated with a large-scale conformational change from the inactive to the active state. Here, conventional and targeted molecular dynamics simulations were used to study the conformational dynamics of GK in the stable configurations and in the transition from active to inactive state. Three phases of the structural reorganization of GK were detected. The first step is a transformation of GK from the active state to the intermediate structure, where the cleft between the domains is open, but alpha helix 13 is still inside the small domain. From this point, there are two alternative paths. One path leads to the inactive state through the release of helix 13 from the inside of small domain to the outside. Other path goes back to the active state. Simulation results reveal the critical role of helix 13 in the transformation of GK from the open state to inactive one and the influence of the loop 2 on the protein transformation between the open and the closed active states. Principal component analysis and covariance matrix analysis were carried out to analyze the dynamics of protein. Importance of hydrogen bonds in the stability of the closed conformation is shown. Overall, our simulations provide new information about the dynamics of GK and its structural transformation.

Communicated by Ramaswamy H. Sarma     

A spin label study of conformational changes in cytochrome c

Spin-labeled pig heart cytochromes c singly modified at Met-65, Tyr-74 and at one of the lysine residues, Lys-72 or Lys-73, were investigated by the ESR method under conditions of different ligand and redox states of the heme and at various pH values. Replacement of Met-80 by the external ligand, cyanide, was shown to produce a sharp increase in the mobility of all the three bound labels while reduction of the spin-labeled ferricytochromes c did not cause any marked changes in their ESR spectra. In the pH range 6-13, two conformational transitions in ferricytochrome c were observed which preceded its alkaline denaturation: the first with pK 9.3 registered by the spin label at the Met-65 position, and the second with pK 11.1 registered by the labels bound to Tyr-74 and Lys-72(73). The conformational changes in the 'left-hand part' of ferricytochrome c are most probably induced in both cases by the exchange of internal protein ligands at the sixth coordination site of the heme.     

Evaluation of conformational changes in diabetes‐associated mutation in insulin a chain: A molecular dynamics study

Insulin plays a central role in the regulation of metabolism in humans. Mutations in the insulin gene can impair the folding of its precursor protein, proinsulin, and cause permanent neonatal‐onset diabetes mellitus known as Mutant INS‐gene induced Diabetes of Youth (MIDY) with insulin deficiency. To gain insights into the molecular basis of this diabetes‐associated mutation, we perform molecular dynamics simulations in wild‐type and mutant (Cys^A7 to Tyr or C(A7)Y) insulin A chain in aqueous solutions. The C(A7)Y mutation is one of the identified mutations that impairs the protein folding by substituting the cysteine residue which is required for the disulfide bond formation. A comparative analysis reveals structural differences between the wild‐type and the mutant conformations. The analyzed mutant insulin A chain forms a metastable state with major effects on its N‐terminal region. This suggests that MIDY mutant involves formation of a partially folded intermediate with conformational change in N‐terminal region in A chain that generates flexible N‐terminal domain. This may lead to the abnormal interactions with other proinsulins in the aggregation process. Proteins 2015; 83:662–669. © 2015 Wiley Periodicals, Inc.     

Model-free methods of analyzing domain motions in proteins from simulation: A comparison of normal mode analysis and molecular dynamics simulation of lysozyme

Model-free methods are introduced to determine quantities pertaining to protein domain motions from normal mode analyses and molecular dynamics simulations. For the normal mode analysis, the methods are based on the assumption that in low frequency modes, domain motions can be well approximated by modes of motion external to the domains. To analyze the molecular dynamics trajectory, a principal component analysis tailored specifically to analyze interdomain motions is applied. A method based on the curl of the atomic displacements is described, which yields a sharp discrimination of domains, and which defines a unique interdomain screw-axis. Hinge axes are defined and classified as twist or closure axes depending on their direction. The methods have been tested on lysozyme. A remarkable correspondence was found between the first normal mode axis and the first principal mode axis, with both axes passing within 3 Å of the alpha-carbon atoms of residues 2, 39, and 56 of human lysozyme, and near the interdomain helix. The axes of the first modes are overwhelmingly closure axes. A lesser degree of correspondence is found for the second modes, but in both cases they are more twist axes than closure axes. Both analyses reveal that the interdomain connections allow only these two degrees of freedom, one more than provided by a pure mechanical hinge. Proteins 27:425–437, 1997. © 1997 Wiley-Liss, Inc.     

A molecular dynamics study of reovirus attachment protein sigma1 reveals conformational changes in sigma1 structure

Molecular dynamics simulations were performed using the recently determined crystal structure of the reovirus attachment protein, sigma1. These studies were conducted to improve an understanding of two unique features of sigma1 structure: the protonation state of Asp(345), which is buried in the sigma1 trimer interface, and the flexibility of the protein at a defined region below the receptor-binding head domain. Three copies of aspartic acids Asp(345) and Asp(346) cluster in a solvent-inaccessible and hydrophobic region at the sigma1 trimer interface. These residues are hypothesized to mediate conformational changes in sigma1 during viral attachment or cell entry. Our results indicate that protonation of Asp(345) is essential to the integrity of the trimeric structure seen by x-ray crystallography, whereas deprotonation induces structural changes that destabilize the trimer interface. This finding was confirmed by electrostatic calculations using the finite difference Poisson-Boltzmann method. Earlier studies show that sigma1 can exist in retracted and extended conformations on the viral surface. Since protonated Asp(345) is necessary to form a stable, extended trimer, our results suggest that protonation of Asp(345) may allow for a structural transition from a partially detrimerized molecule to the fully formed trimer seen in the crystal structure. Additional studies were conducted to quantify the previously observed flexibility of sigma1 at a defined region below the receptor-binding head domain. Increased mobility was observed for three polar residues (Ser(291), Thr(292), and Ser(293)) located within an insertion between the second and third beta-spiral repeats of the crystallized portion of the sigma1 tail. These amino acids interact with water molecules of the solvent bulk and are responsible for oscillating movement of the head of approximately 50 degrees during 5 ns of simulations. This flexibility may facilitate viral attachment and also function in cell entry and disassembly. These findings provide new insights about the conformational dynamics of sigma1 that likely underlie the initiation of the reovirus infectious cycle.     

Heterogeneity of cellulase complexes from Trichoderma reesei: A preparative isoelectric focusing study of some extracellular hydrolases

Abstract Homogeneity of extracellular proteins of Trichoderma reesei found after isoelectric focusing (IEF) has been shown to reflect purity of a (multi)enzyme complex rather than purity of one enzyme isolated. The intention of the present study was to demonstrate to what extent distribution of (multi)enzyme complexes reflects a general concept of extracellular hydrolases in the culture fluid of T. reesei . The complete culture fluid studied by preparative IEF on the distribution of cellulases, β-glucosidase, xylanase and xylosidase confirms this view. (Macro)heterogeneity found after IEF is discussed on the basis of different charges of complexes.