Circular dichroism studies of the coenzyme environment in the active sites of mutant forms of the beta-subunit in the tryptophan synthase alpha 2 beta 2 complex.

The circular dichroism has been used to evaluate the effect of mutation on the environment of the pyridoxal phosphate coenzyme in the active site of the beta-subunit in the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium. Seven mutant forms of the alpha 2 beta 2-complex with single amino acid replacements at residues 87, 109, 188, 306, and 350 of the beta-subunit have been prepared by site-directed mutagenesis, purified to homogeneity, and characterized by absorption and circular dichroism spectroscopy. Since the wild type and mutant alpha 2 beta 2 complexes all exhibit positive circular dichroism in the coenzyme absorption band, pyridoxal phosphate must bind asymmetrically in the active site of these enzymes. However, the coenzyme may have an altered orientation or active site environment in five of the mutant enzymes that display less intense ellipticity bands. The mutant enzyme in which lysine 87 is replaced by threonine has very weak ellipticity at 400 nm. Since lysine 87 forms a Schiff base with pyridoxal phosphate in the wild type enzyme, our results demonstrate the importance of the Schiff base linkage for rigid or asymmetric binding. Although the mutant enzymes display spectra in the presence of L-serine that differ from that of the wild type enzyme, addition of alpha-glycerol 3-phosphate converts the spectra of two of the mutant enzymes to that of the wild type enzyme. We conclude that this alpha-subunit ligand may produce a conformational change in the alpha-subunit that is transmitted to the mutant beta-subunits and partially corrects conformational alterations in the mutant enzymes.     

Mechanism of mutual activation of the tryptophan synthase alpha and beta subunits. Analysis of the reaction specificity and substrate-induced inactivation of active site and tunnel mutants of the beta subunit

The origin of reaction and substrate specificity and the control of activity by protein-protein interaction are investigated using the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium. We have compared some spectroscopic and kinetic properties of the wild type beta subunit and five mutant forms of the beta subunit that have altered catalytic properties. These mutant enzymes, which were engineered by site-directed mutagenesis, have single amino acid replacements in either the active site or in the wall of a tunnel that extends from the active site of the alpha subunit to the active site of the beta subunit in the alpha 2 beta 2 complex. We find that the mutant alpha 2 beta 2 complexes have altered reaction and substrate specificity in beta-elimination and beta-replacement reactions with L-serine and with beta-chloro-L-alanine. Moreover, the mutant enzymes, unlike the wild type alpha 2 beta 2 complex, undergo irreversible substrate-induced inactivation. The mechanism of inactivation appears to be analogous to that first demonstrated by Metzler's group for inhibition of two other pyridoxal phosphate enzymes. Alkaline treatment of the inactivated enzyme yields apoenzyme and a previously described pyridoxal phosphate derivative. We demonstrate for the first time that enzymatic activity can be recovered by addition of pyridoxal phosphate following alkaline treatment. We conclude that the wild type and mutant alpha 2 beta 2 complexes differ in the way they process the amino acrylate intermediate. We suggest that the wild type beta subunit undergoes a conformational change upon association with the alpha subunit that alters the reaction specificity and that the mutant beta subunits do not undergo the same conformational change upon subunit association.     

Optimization of conformational stability and catalytic efficiency in chondroitinase ABC Ι by protein engineering methods

Chondroitinase ABC Ι can promote the recovery of spinal cord injuries by depolimerization of glycosaminoglycans. However, low thermal stability is one of the limitations regarding its clinical application. In order to increase the conformational stability of the enzyme, Leu⁶⁷⁹ at the starting point of a short helix located at the C‐terminal domain of the protein was replaced by serine (L679S mutant) and aspartic acid (L679D mutant). Theoretical and spectroscopic studies showed that the stability of enzyme increased upon mutation. Based on the activity measurements, the catalytic efficiency of L679S was improved in comparison with the wild‐type protein; while that of L679D (a more stabilized protein) was not changed. According to the structural and kinetic data, we proposed a model in which a higher conformational stability results in a slower rate of the formation of the open conformation. On the other hand, a higher flexibility slows down the rate of the formation and holding of the closed conformation. Therefore, the L679S mutant, which is structurally stable relative to the wild‐type protein and is destabilized compared to the L679D mutant, exhibited the best catalytic efficiency. However, it was also found that the L679D mutant was more suitable for long‐term storage of the enzyme.     

Drug resistance in HIV-1 protease: Flexibility-assisted mechanism of compensatory mutations

The emergence of drug-resistant variants is a serious side effect associated with acquired immune deficiency syndrome therapies based on inhibition of human immunodeficiency virus type 1 protease (HIV-1 PR). In these variants, compensatory mutations, usually located far from the active site, are able to affect the enzymatic activity via molecular mechanisms that have been related to differences in the conformational flexibility, although the detailed mechanistic aspects have not been clarified so far. Here, we perform multinanosecond molecular dynamics simulations on L63P HIV-1 PR, corresponding to the wild type, and one of its most frequently occurring compensatory mutations, M46I, complexed with the substrate and an enzymatic intermediate. The quality of the calculations is established by comparison with the available nuclear magnetic resonance data. Our calculations indicate that the dynamical fluctuations of the mutated enzyme differ from those in the wild type. These differences in the dynamic properties of the adducts with the substrate and with the gem-diol intermediate might be directly related to variations in the enzymatic activity and therefore offer an explanation of the observed changes in catalytic rate between wild type and mutated enzyme. We anticipate that this "flexibility-assisted" mechanism might be effective in the vast majority of compensatory mutations, which do not change the electrostatic properties of the enzyme.     

Exon grafting yields a "two active-site" lysozyme

The design of enzymes with enhanced stability and activity has long been a goal in protein engineering. We report a strategy to engineer an additional active site for human lysozyme, grafted the entire human lysozyme exon 2, which encodes the catalytically competent domain, into the gene at a position corresponding to an exposed loop region in the translated protein. Exon 2 grafting created a novel lysozyme with twice the activity of the wild type enzyme, equal activity came from each of the two active sites. We dissected the contributions of each active site using site-directed mutagenesis of the catalytic doublets of (E35A/D53A), circular dichroism, fluorescence spectra, and molecular modeling. Temperature and pH stability of the "two active-site" enzyme were similar to those of wild-type lysozyme. Thus, we provide a novel strategy for engineering the active site of enzymes.     

The acidic triad conserved in type IA DNA topoisomerases is required for binding of Mg(II) and subsequent conformational change

The acidic residues Asp-111, Asp-113, and Glu-115 of Escherichia coli DNA topoisomerase I are located near the active site Tyr-319 and are conserved in type IA topoisomerase sequences with counterparts in type IIA DNA topoisomerases. Their exact functional roles in catalysis have not been clearly defined. Mutant enzymes with two or more of these residues converted to alanines were found to have >90% loss of activity in the relaxation assay with 6 mM Mg(II) present. Mg(II) concentrations (15-20 mM) inhibitory for the wild type enzyme are needed by these double mutants for maximal relaxation activity. The triple mutant D111A/D113A/E115A had no detectable relaxation activity. Mg(II) binding to wild type enzyme resulted in an altered conformation detectable by Glu-C proteolytic digestion. This conformational change was not observed for the triple mutant or for the double mutant D111A/D113A. Direct measurement of Mg(II) bound showed the loss of 1-2 Mg(II) ions for each enzyme molecule due to the mutations. These results demonstrate a functional role for these acidic residues in the binding of Mg(II) to induce the conformational change required for the relaxation of supercoiled DNA by the enzyme.     

The PD...(D/E)XK motif in restriction enzymes: a link between function and conformation

The active sites of Mg(II)-dependent nucleases feature a cluster of conserved charged residues which includes both acidic (Asp and Glu) and basic (Lys) side chains. In restriction enzymes, these side chains are part of the conserved PD...(D/E)XK functional sequence motif which has been implicated as being important in metal ion binding and catalytic steps. Recent work revealing the unusual behavior of the active site variant D58A of the representative PvuII endonuclease prompted speculation that the array of charged groups in the nuclease active site may also be linked to conformational behavior [Dupureur, C. M., and Conlan, L. H. (2000) Biochemistry 39, 10921-10927]. To address this issue, we analyzed the conformational behavior of active site variants of PvuII endonuclease using both NMR spectroscopic and thermodynamic methods. NMR spectroscopic analysis via (19)F and (1)H-(15)N HSQC experiments indicates that a number of side chain and backbone amide groups are perturbed upon Ala substitution at conserved active site residues Asp58, Glu68, and Lys70. Spectral changes are particularly pronounced for the lowest-activity mutants (D58A and K70A). These changes are accompanied by perturbations in conformational stability. Ala substitution at each of these positions results in 2-5 kcal/mol of stabilization over the wild-type enzyme at pH 7.7, changes which constitute increases in DeltaG(d)(H2O) of 20-50%. The pH dependencies of mutant enzyme stabilities are distinct from those of the wild type, results which confirm that these ionizable groups strongly influence stability. Wild-type enzyme stability is correlated with the ionization of groups shown to be important to metal ion binding and orientation. Correlations between spectral changes and conformational stability indicate that the latter measurements may prove useful in the evaluation of site-directed mutant restriction enzymes. More importantly, these results indicate that structure-function relationships in restriction enzyme active sites can be complex, and that the ensemble of conserved charged residues which mediate DNA hydrolysis in Mg(II)-dependent nucleases constitutes a critical link between function and conformation.     

Flexibility and enzyme activity of NADH oxidase from Thermus thermophilus in the presence of monovalent cations of Hofmeister series

Recently, we have shown that anions of Hofmeister series affect the enzyme activity through modulation of flexibility of its active site. The enzyme activity vs. anion position in Hofmeister series showed an unusual bell-shaped dependence. In the present work, six monovalent cations (Na(+), Gdm(+), NH(4)(+), Li(+), K(+) and Cs(+)) of Hofmeister series with chloride as a counterion have been studied in relation to activity and stability of flavoprotein NADH oxidase from Thermus thermophilus (NOX). With the exception of strongly chaotropic guanidinium cation, cations are significantly less effective in promoting the Hofmeister effect than anions mainly due to repulsive interactions of positive charges around the active site. Thermal denaturations of NOX reveal unfavorable electrostatic interaction at the protein surface that may be shielded to different extent by salts. Michaelis-Menten constants for NADH, accessibility of the active site as reflected by Stern-Volmer constants and activity of NOX at high cation concentrations (1-2 M) show bell-shaped dependences on cation position in Hofmeister series. Our analysis indicates that in the presence of kosmotropic cations the enzyme is more stable and possibly more rigid than in the presence of chaotropic cations. Molecular dynamic (MD) simulations of NOX showed that active site switches between open and closed conformations [J. Hritz, G. Zoldak, E. Sedlak, Cofactor assisted gating mechanism in the active site of NADH oxidase from Thermus thermophilus, Proteins 64 (2006) 465-476]. Enzyme activity, as well as substrate binding, can be regulated by the salt mediated perturbation of the balance between open and closed forms. We propose that compensating effect of accessibility and flexibility of the enzyme active site leads to bell-shaped dependence of the investigated parameters.     

Effect of molecular confinement on internal enzyme dynamics: frequency domain fluorometry and molecular dynamics simulation studies

The tryptophanyl emission decay of the mesophilic beta-galactosidase from Aspergillus oryzae free in buffer and entrapped in agarose gel is investigated as a function of temperature and compared to that of the hyperthermophilic enzyme from Sulfolobus solfataricus. Both enzymes are tetrameric proteins with a large number of tryptophanyl residues, so the fluorescence emission can provide information on the conformational dynamics of the overall protein structure rather than that of the local environment. The tryptophanyl emission decays are best fitted by bimodal Lorentzian distributions. The long-lived component is ascribed to close, deeply buried tryptophanyl residues with reduced mobility; the short-lived one arises from tryptophanyl residues located in more flexible external regions of each subunit, some of which are involved in forming the catalytic site. The center of both lifetime distribution components at each temperature increases when going from the free in solution mesophilic enzyme to the gel-entrapped and hyperthermophilic enzyme, thus indicating that confinement of the mesophilic enzyme in the agarose gel limits the freedom of the polypeptide chain. A more complex dependence is observed for the distribution widths. Computer modeling techniques are used to recognize that the catalytic sites are similar for the mesophilic and hyperthermophilic beta-galactosidases. The effect due to gel entrapment is considered in dynamic simulations by imposing harmonic restraints to solvent-exposed atoms of the protein with the exclusion of those around the active site. The temperature dependence of the tryptophanyl fluorescence emission decay and the dynamic simulation confirm that more rigid structures, as in the case of the immobilized and/or hyperthermophilic enzyme, require higher temperatures to achieve the requisite conformational dynamics for an effective catalytic action and strongly suggest a link between conformational rigidity and enhanced thermal stability.     

In silico analyses of substrate interactions with human serum paraoxonase 1

Human paraoxonase (HuPON1) is a serum enzyme that exhibits a broad spectrum of hydrolytic activities, including the hydrolysis of various organophosphates, esters, and recently identified lactone substrates. Despite intensive site-directed mutagenesis and other biological studies, the structural basis for the specificity of substrate interactions of HuPON1 remains elusive. In this study, we apply homology modeling, docking, and molecular dynamic (MD) simulations to probe the binding interactions of HuPON1 with representative substrates. The results suggest that the active site of HuPON1 is characterized by two distinct binding regions: the hydrophobic binding site for arylesters/lactones, and the paraoxon binding site for phosphotriesters. The unique binding modes proposed for each type of substrate reveal a number of key residues governing substrate specificity. The polymorphic residue R/Q192 interacts with the leaving group of paraoxon, suggesting it plays an important role in the proper positioning of this substrate in the active site. MD simulations of the optimal binding complexes show that residue Y71 undergoes an "open-closed" conformational change upon ligand binding, and forms strong interactions with substrates. Further binding free energy calculations and residual decomposition give a more refined molecular view of the energetics and origin of HuPON1/substrate interactions. These studies provide a theoretical model of substrate binding and specificity associated with wild type and mutant forms of HuPON1, which can be applied in the rational design of HuPON1 variants as bioscavengers with enhanced catalytic activity.     

Escherichia coli serine hydroxymethyltransferase. The role of histidine 228 in determining reaction specificity.

Serine hydroxymethyltransferase has a conserved histidine residue (His-228) next to the lysine residue (Lys-229) which forms the internal aldimine with pyridoxal 5'-phosphate. This histidine residue is also conserved at the equivalent position in all amino acid decarboxylases and tryptophan synthase. Two mutant forms of Escherichia coli serine hydroxymethyltransferase, H228N and H228D, were constructed, expressed, and purified. The properties of the wild type and mutant enzymes were studied with substrates and substrate analogs by differential scanning calorimetry, circular dichroism, steady state kinetics, and rapid reaction kinetics. The conclusions of these studies were that His-228 plays an important role in the binding and reactivity of the hydroxymethyl group of serine in the one-carbon-binding site. The mutant enzymes utilize substrates and substrate analogs more effectively for a variety of alternate non-physiological reactions compared to the wild type enzyme. As one example, the mutant enzymes cleave L-serine to glycine and formaldehyde when tetrahydropyteroylglutamate is replaced by 5-formyltetrahydropteroylglutamate. The released formaldehyde inactivates these mutant enzymes. The loss of integrity of the one-carbon-binding site with L-serine in the two mutant forms of the enzyme may be the result of these enzymes not undergoing a conformational change to a closed form of the active site when serine forms the external aldimine complex.     

结构修饰提高酶稳定性、活性

酶因其特异性和可持续性而成为广泛应用的绿色催化剂，其稳定性和催化活性是决定酶适用性的关键因素。为满足实际应用需求，通过蛋白质结构修饰赋予其所需的催化特性是当前的研究热点。提高热稳定性的策略有：引入非共价/共价相互作用（疏水相互作用、氢键、盐桥、芳香环相互作用、二硫键）、环截短、C端和N端工程，及增加脯氨酸/减少甘氨酸的数目等；获得具有高效性和多样性的生物催化剂的策略有：降低空间位阻、拓宽催化口袋、增加底物亲和力及调节活性位点灵活性等。然而，在稳定性或催化功能改造的过程中，新突变的引入会削弱其他功能，致使进化过程中稳定性和催化活性相互制约。因此，采用基于理性计算优选突变热点、基于多重蛋白质稳定性或活性改造策略的共进化，以及基于高度稳定的蛋白质骨架创造或/和优化蛋白质功能等多种策略克服酶稳定性-活性之间的权衡。本综述重点阐述了结构修饰方法在提高酶稳定性或/和催化活性方面的应用，并展望了该领域的未来发展前景。     

Effect of mutations in the qa gene cluster of Neurospora crassa on the enzyme catabolic dehydroquinase.

Catabolic dehydroquinase, which functions in the inducible quinic acid catabolic pathway of Neurospora crassa, has been purified from wild type (74-A) and three mutants in the qa gene cluster. The mutant strains were: 105c, a temperature-sensitive constitutive mutant in the qa-1 regulatory locus; M-16, a qa-3 mutant deficient in quinate dehydrogenase activity; and 237, a leaky qa-2 mutant which possess very low levels of catabolic dehydroquinase activity. The enzymes purified from strains 74-A, 105c, and M-16 are identical with respect to behavior during purification, specific activity, electrophoretic behavior, stability, molecular weight, subunit structure, immunological cross-reactivity, and amino acid content. The mutant enzyme from strain 237 is 1,500-fold less active and appears to have a slightly different amino acid content. It is identical by a number of the other criteria listed above and is presumed to be a mutant at or near the enzyme active site. These data demonstrate that the qa-1 gene product is not involved in the posttranslational expression of enzyme activity. The biochemical identity of catabolic dehydroquinase isolated from strains 105c and M-16 with that from wild type also demonstrates that neither the inducer, quinic acid, nor other enzymes encoded in the qa gene cluster are necessary for the expression of activity. Therefore the combined genetic and biochemical data on the qa system continue to support the hypothesis that the qa-1 regulatory protein acts as a positive initiator of qa enzyme synthesis.     

Large-scale conformational dynamics of the HIV-1 integrase core domain and its catalytic loop mutants

HIV-1 integrase is one of the three essential enzymes required for viral replication and has great potential as a novel target for anti-HIV drugs. Although tremendous efforts have been devoted to understanding this protein, the conformation of the catalytic core domain around the active site, particularly the catalytic loop overhanging the active site, is still not well characterized by experimental methods due to its high degree of flexibility. Recent studies have suggested that this conformational dynamics is directly correlated with enzymatic activity, but the details of this dynamics is not known. In this study, we conducted a series of extended-time molecular dynamics simulations and locally enhanced sampling simulations of the wild-type and three loop hinge mutants to investigate the conformational dynamics of the core domain. A combined total of >480 ns of simulation data was collected which allowed us to study the conformational changes that were not possible to observe in the previously reported short-time molecular dynamics simulations. Among the main findings are a major conformational change (>20 A) in the catalytic loop, which revealed a gatinglike dynamics, and a transient intraloop structure, which provided a rationale for the mutational effects of several residues on the loop including Q(148), P(145), and Y(143). Further, clustering analyses have identified seven major conformational states of the wild-type catalytic loop. Their implications for catalytic function and ligand interaction are discussed. The findings reported here provide a detailed view of the active site conformational dynamics and should be useful for structure-based inhibitor design for integrase.     

Mutation of active site residues of insulin-degrading enzyme alters allosteric interactions

The active site glutamate (Glu(111)) and the active site histidine (His(112)) of insulin-degrading enzyme (IDE) were mutated. These mutant enzymes exhibit, in addition to a large decrease in catalytic activity, a change in the substrate-velocity response from a sigmoidal one seen with the native enzyme (Hill coefficient > 2), to a hyperbolic response. With 2-aminobenzoyl-GGFLRKHGQ-N-(2,4-dinitrophenyl)ethylenediamine as substrate, ATP and triphosphate increase the reaction rate of the wild type enzyme some 50-80-fold. This effect is dampened with glutamate mutants to no effect or less than a 3-fold increase in activity and changed to inhibition with the histidine mutants. Sedimentation equilibrium shows the IDE mutants exhibit a similar oligomeric distribution as the wild type enzyme, being predominantly monomeric, with triphosphate having little if any effect on the oligomeric state. Triphosphate did induce aggregation of many of the IDE mutants. Thus, the oligomeric state of IDE does not correlate with kinetic properties. The His(112) mutants were shown to bind zinc, but with a lower affinity than the wild type enzyme. The glutamate mutants displayed an altered cleavage profile for the peptide beta-endorphin. Wild type IDE cleaved beta-endorphin at Leu(17)-Phe(18) and Phe(18)-Lys(19), whereas the glutamate mutants cleaved at these sites, but in addition at Lys(19)-Asn(20) and at Met(5)-Thr(6). Thus, active site mutations of IDE are suggested to not only reduce catalytic activity but also cause local conformational changes that affect the allosteric properties of the enzyme.     

Selective metal binding to Cys-78 within endonuclease V causes an inhibition of catalytic activities without altering nontarget and target DNA binding

T4 endonuclease V is a pyrimidine dimer-specific DNA repair enzyme which has been previously shown not to require metal ions for either of its two catalytic activities or its DNA binding function by virtue of its ability to function in the presence of metal-chelating agents. However, we have investigated whether the single cysteine within the enzyme was able to bind metal salts and influence the various activities of this repair enzyme. A series of metals (Hg2+, Ag+, Cu+) were shown to inactivate both endonuclease Vs pyrimidine dimer-specific DNA glycosylase activity and the subsequent apurinic nicking activity. The binding of metal to endonuclease V did not interfere with nontarget DNA scanning or pyrimidine dimer-specific binding. The Cys-78 codon within the endonuclease V gene was changed by oligonucleotide site-directed mutagenesis to Thr-78 and Ser-78 in order to determine whether the native cysteine was directly involved in the enzyme's DNA catalytic activities and whether the cysteine was primarily responsible for the metal binding. The mutant enzymes were able to confer enhanced ultraviolet light (UV) resistance to DNA repair-deficient Escherichia coli at levels equal to that conferred by the wild type enzyme. The C78T mutant enzyme was purified to homogeneity and shown to be catalytically active on pyrimidine dimer-containing DNA. The catalytic activities of the C78T mutant enzyme were demonstrated to be unaffected by the addition of Hg2+ or Ag+ at concentrations 1000-fold greater than that required to inhibit the wild type enzyme. These data suggest that the cysteine is not required for enzyme activity but that the binding of certain metals to that amino acid block DNA incision by either preventing a conformational change in the enzyme after it has bound to a pyrimidine dimer or sterically interfering with the active site residue's accessibility to the pyrimidine dimer.     

Site-directed mutagenesis of a family 42 β-galactosidase from an antarctic bacterium

Site directed mutagenesis was used to modify the active site of a cold active beta-galactosidase taken from an Antarctic psychrotolerant Planococcus Bacterial isolate. The goal was to modify the active site such that there would be an increase in activity on certain substrates which showed little to no activity with the wild type enzyme. A total of 5 mutant enzymes were constructed with amino acid changes based on an analysis done via homology modeling. All 5 modified enzymes were assayed using 14 different nitrophenol substrates. In most cases there was a loss of activity on substrates that showed activity with the wild type enzymes. None of the expected activity was observed with any of the mutants, possibly in part due to a decrease in hydrogen bonding between the active site and the substrates. With the substrates p-nitrophenyl-β-d-galacturonide and p-nitrophenyl-α-d-glucopyranoside we saw increased activity. With one of the mutants we measured a 320% increase in activity on p-nitrophenyl-β-d-galacturonide. Two other mutants showed activity on p-nitrophenyl-α-d-glucopyranoside, which showed no activity at all with the wild type enzyme.     

Characterization of a camptothecin-resistant human DNA topoisomerase I

Topoisomerase I purified from a camptothecin-resistant human leukemia cell line and from the parental, camptothecin-sensitive line were compared in vitro. Relaxation of supercoiled DNA by the wild type enzyme was inhibited in the presence of camptothecin, while the mutant enzyme was unimpaired. Camptothecin altered the cleavage pattern of the wild type but not of the mutant enzyme. The stability of cleavable complexes was studied at a preferred topoisomerase I-binding sequence recognized by both enzymes. Camptothecin greatly enhanced the kinetic stability of the cleavable complex formed by the wild type enzyme, whereas that of the mutant enzyme was only marginally affected. In the absence of camptothecin, the cleavable complex formed by the mutant enzyme was stabilized relative to that of the wild type by several criteria. Thus, the mutant enzyme cleaved the topoisomerase I recognition sequence with 2-fold higher efficiency than the wild type enzyme. The mutant cleavable complex had a higher kinetic stability and was less sensitive to salt dissociation than the wild type complex. Furthermore, the mutant enzyme formed cleavable complexes in the absence of divalent cations, which were required for complex formation by the wild type enzyme.     

活性部位的柔性

比较酶在变性过程中构象和活力变化,发现在活性完全丧失时尚无可察 觉的整体构象变化。排除变性剂抑制和寡聚酶解聚等可能性之后,提出了酶活性部位柔性假说。随后用多种实验方法直接证实了活性部位的构象变化先于分子整体构象变化,并与活性丧失同步,根据催化过程中活性部位构旬变化,以及限制活性部位构象变化对酶活性的影响,提出了酶活性部位柔性为酶充分表现其催化活性所必需的设想。     

Cold-active esterase from Psychrobacter sp. Ant300: gene cloning, characterization, and the effects of Gly-->Pro substitution near the active site on its catalytic activity and stability

The gene encoding an esterase (PsyEst) of Psychrobacter sp. Ant300, a psychrophilic bacterium isolated from Antarctic soil, was cloned, sequenced, and expressed in Escherichia coli. PsyEst, which is a member of hormone-sensitive lipase (HSL) group of the lipase/esterase family, is a cold-active, themolabile enzyme with high catalytic activity at low temperatures (5-25 degrees C), low activation energy (e.g., 4.6 kcal/mol for hydrolysis of p-nitrophenyl butyrate), and a t(1/2) value of 16 min for thermal inactivation during incubation at 40 degrees C and pH 7.9. A three-dimensional structural model of PsyEst predicted that Gly(244) was located in the loop near the active site of PsyEst and that substitution of this amino-acid residue by proline should potentially rigidify the active-site environment of the enzyme. Thus, we introduced the Gly(244)-->Pro substitution into the enzyme. Stability studies showed that the t(1/2) value for thermal inactivation of the mutant during incubation at 40 degrees C and pH 7.9 was 11.6 h, which was significantly greater than that of the wild-type enzyme. The k(cat)/K(m) value of the mutant was lower for all substrates examined than the value of the wild type. Moreover, this amino-acid substitution caused a shift of the acyl-chain length specificity of the enzyme toward higher preference for short-chain fatty acid esters. All of these observations could be explained in terms of a decrease in active-site flexibility brought about by the mutation and were consistent with the hypothesis that cold activity and thermolability arise from local flexibility around the active site of the enzyme.