Biosynthetic potential of sesquiterpene synthases: product profiles of Egyptian Henbane premnaspirodiene synthase and related mutants.

The plant terpene synthase (TPS) family is responsible for the biosynthesis of a variety of terpenoid natural products possessing diverse biological functions. TPSs catalyze the ionization and, most commonly, rearrangement and cyclization of prenyl diphosphate substrates, forming linear and cyclic hydrocarbons. Moreover, a single TPS often produces several minor products in addition to a dominant product. We characterized the catalytic profiles of Hyoscyamus muticus premnaspirodiene synthase (HPS) and compared it with the profile of a closely related TPS, Nicotiana tabacum 5-epi-aristolochene synthase (TEAS). The profiles of two previously studied HPS and TEAS mutants, each containing nine interconverting mutations, dubbed HPS-M9 and TEAS-M9, were also characterized. All four TPSs were compared under varying temperature and pH conditions. In addition, we solved the X-ray crystal structures of TEAS and a TEAS quadruple mutant complexed with substrate and products to gain insight into the enzymatic features modulating product formation. These informative structures, along with product profiles, provide new insight into plant TPS catalytic promiscuity.

Structural insights into methanol-stable variants of lipase T6 from Geobacillus stearothermophilus.

Enzymatic production of biodiesel by transesterification of triglycerides and alcohol, catalyzed by lipases, offers an environmentally friendly and efficient alternative to the chemically catalyzed process while using low-grade feedstocks. Methanol is utilized frequently as the alcohol in the reaction due to its reactivity and low cost. However, one of the major drawbacks of the enzymatic system is the presence of high methanol concentrations which leads to methanol-induced unfolding and inactivation of the biocatalyst. Therefore, a methanol-stable lipase is of great interest for the biodiesel industry. In this study, protein engineering was applied to substitute charged surface residues with hydrophobic ones to enhance the stability in methanol of a lipase from Geobacillus stearothermophilus T6. We identified a methanol-stable variant, R374W, and combined it with a variant found previously, H86Y/A269T. The triple mutant, H86Y/A269T/R374W, had a half-life value at 70 % methanol of 324 min which reflects an 87-fold enhanced stability compared to the wild type together with elevated thermostability in buffer and in 50 % methanol. This variant also exhibited an improved biodiesel yield from waste chicken oil compared to commercial Lipolase 100L® and Novozyme® CALB. Crystal structures of the wild type and the methanol-stable variants provided insights regarding structure-stability correlations. The most prominent features were the extensive formation of new hydrogen bonds between surface residues directly or mediated by structural water molecules and the stabilization of Zn and Ca binding sites. Mutation sites were also characterized by lower B-factor values calculated from the X-ray structures indicating improved rigidity.

An interfacial and comparative in vitro study of gastrointestinal lipases and Yarrowia lipolytica LIP2 lipase, a candidate for enzyme replacement therapy.

Lipolytic activities of Yarrowia lipolytica LIP2 lipase (YLLIP2), human pancreatic (HPL) and dog gastric (DGL) lipases were first compared using lecithin-stabilized triacylglycerol (TAG) emulsions (Intralipid) at various pH and bile salt concentrations. Like DGL, YLLIP2 was able to hydrolyze TAG droplets covered by a lecithin monolayer, while HPL was not directly active on that substrate. These results were in good agreement with the respective kinetics of adsorption on phosphatidylcholine (PC) monomolecular films of the same three lipases, YLLIP2 being the most tensioactive lipase. YLLIP2 adsorption onto a PC monolayer spread at the air/water interface was influenced by pH-dependent changes in the enzyme/lipid interfacial association constant (KAds) which was optimum at pH 6.0 on long-chain egg PC monolayer, and at pH 5.0 on medium chain dilauroylphosphatidylcholine film. Using substrate monolayers (1,2-dicaprin, trioctanoin), YLLIP2 displayed the highest lipolytic activities on both substrates in the 25-35 mN m(-1) surface pressure range. YLLIP2 was active in a large pH range and displayed a pH-dependent activity profile combining DGL and HPL features at pH values found in the stomach (pH 3-5) and in the intestine (pH 6-7), respectively. The apparent maximum activity of YLLIP2 was observed at acidic pH 4-6 and was therefore well correlated with an efficient interfacial binding at these pH levels, whatever the type of interfaces (Intralipid emulsions, substrate or PC monolayers). All these findings support the use of YLLIP2 in enzyme replacement therapy for the treatment of pancreatic exocrine insufficiency, a pathological situation in which an acidification of intestinal contents occurs.

Deletion of a dynamic surface loop improves stability and changes kinetic behavior of phosphatidylinositol-synthesizing Streptomyces phospholipase D.

Supplementary phosphatidylinositol (PI) was shown to improve lipid metabolism in animals, thus it is interesting for pharmaceutical and nutritional applications. Homogenous PI can be produced in transphosphatidylation of phosphatidylcholine (PC) with myo-inositol catalyzed by phospholipase D (PLD). Only bacterial enzymes able to catalyze PI synthesis are Streptomyces antibioticus PLD (SaPLD) variants, among which DYR (W187D/Y191Y/Y385R) has the best kinetic profile. Increase in PI yield is possible by providing excess of solvated myo-inositol, which is achievable at high temperatures due to its highly temperature-dependent solubility. However, high-temperature PI synthesis requires the thermostable PLD. Previous site-directed combinatorial mutagenesis at the residues of DYR having high B-factor yielded the most improved variant, D40H/T291Y DYR, obtained by the combination of two selected mutations. D40 and T291 are located within dynamic surface loops, D37-G45 (termed D40 loop) and G273-T313. Thus, in this work, thermostabilization of DYR SaPLD was attempted by rational design based on deletion of the D40 loop, generating two variants, Δ37-45 DYR and Δ38-46 DYR PLD. Δ38-46 DYR showed highest thermostability as its activity half-life at 70°C proved 11.7 and 8.0 times longer than that of the DYR and Δ37-45 DYR, respectively. Studies on molecular dynamics predicted Δ38-46 DYR to have the least average RMSD change as temperature dramatically increases. At 60 and 70°C, both mutants synthesized PI in a twofold higher yield compared to the DYR, while at the same time produced less of the hydrolytic side-product, phosphatidic acid.

Phenylalanine to leucine point mutation in oxyanion hole improved catalytic efficiency of Lip12 from Yarrowia lipolytica.

In lipases, oxyanion hole has crucial role in the stabilisation of enzyme-substrate complex. Majority of lipases from Yarrowia lipolytica consist of two oxyanion hole residues viz.; Thr and Leu. However, Lip12 has Phe instead of Leu at second oxyanion hole residue. It was observed that Lip12 has lower specific activity and catalytic efficiency than other lipases of Yarrowia. In silico analysis of Phe to Leu mutation revealed improved binding energy of Lip12 for p-np palmitate. This was validated by Phe148 to Leu point mutation where, specific activity of mutant was 401U/mg on olive oil, which was two fold higher in comparison to wild-type. Kcat, remained unaltered, while decrease in Km was predominant for all the substrates used in the study. Improved catalytic efficiency of mutant was a function of chain length in case of p-np esters, with 73% improvement for p-np stearate. However, hydrolysis of triacylglycerides improved by 20%, irrespective of chain length. Decrease in activation energy for all the substrates, was observed in mutant in comparison to wild-type, indicating better stabilisation of transition state complex. Further, unaltered differential activation energy for mutant depicts that substrate specificity of enzyme remained same after mutation.

Rapid profiling of disease alleles using a tunable reporter of protein misfolding.

Many human diseases are caused by genetic mutations that decrease protein stability. Such mutations may not specifically affect an active site, but can alter protein folding, abundance, or localization. Here we describe a high-throughput cell-based stability assay, IDESA (intra-DHFR enzyme stability assay), where stability is coupled to cell proliferation in the model yeast, Saccharomyces cerevisiae. The assay requires no prior knowledge of a protein's structure or activity, allowing the assessment of stability of proteins that have unknown or difficult to characterize activities, and we demonstrate use with a range of disease-relevant targets, including human alanine:glyoxylate aminotransferase (AGT), superoxide dismutase (SOD-1), DJ-1, p53, and SMN1. The assay can be carried out on hundreds of disease alleles in parallel or used to identify stabilizing small molecules (pharmacological chaperones) for unstable alleles. As demonstration of the general utility of this assay, we analyze stability of disease alleles of AGT, deficiency of which results in the kidney stone disease, primary hyperoxaluria type I, identifying mutations that specifically affect the protein-active site chemistry.

Tissue nonspecific alkaline phosphatase is activated via a two-step mechanism by zinc transport complexes in the early secretory pathway.

A number of enzymes become functional by binding to zinc during their journey through the early secretory pathway. The zinc transporters (ZnTs) located there play important roles in this step. We have previously shown that two zinc transport complexes, ZnT5/ZnT6 heterodimers and ZnT7 homo-oligomers, are required for the activation of alkaline phosphatases, by converting them from the apo- to the holo-form. Here, we investigated the molecular mechanisms of this activation. ZnT1 and ZnT4 expressed in chicken DT40 cells did not contribute to the activation of tissue nonspecific alkaline phosphatase (TNAP). The reduced activity of TNAP in DT40 cells deficient in both ZnT complexes was not restored by zinc supplementation nor by exogenous expression of other ZnTs that increase the zinc content in the secretory pathway. Moreover, we showed that expression of ZnT5/ZnT6 heterodimers reconstituted with zinc transport-incompetent ZnT5 mutant failed to restore TNAP activity but could stabilize the TNAP protein as the apo-form, regardless of zinc status. These findings demonstrate that TNAP is activated not simply by passive zinc binding but by an elaborate two-step mechanism via protein stabilization followed by enzyme conversion from the apo- to the holo-form with zinc loaded by ZnT complexes in the early secretory pathway.

AnhE, a metallochaperone involved in the maturation of a cobalt-dependent nitrile hydratase.

Acetonitrile hydratase (ANHase) of Rhodococcus jostii RHA1 is a cobalt-containing enzyme with no significant sequence identity with characterized nitrile hydratases. The ANHase structural genes anhA and anhB are separated by anhE, predicted to encode an 11.1-kDa polypeptide. An anhE deletion mutant did not grow on acetonitrile but grew on acetamide, the ANHase reaction product. Growth on acetonitrile was restored by providing anhE in trans. AnhA could be used to assemble ANHase in vitro, provided the growth medium was supplemented with 50 microM CoCl(2). Ten- to 100-fold less CoCl(2) sufficed when anhE was co-expressed with anhA. Moreover, AnhA contained more cobalt when produced in cells containing AnhE. Chromatographic analyses revealed that AnhE existed as a monomer-dimer equilibrium (100 mm phosphate, pH 7.0, 25 degrees C). Divalent metal ions including Co(2+), Cu(2+), Zn(2+), and Ni(2+) stabilized the dimer. Isothermal titration calorimetry studies demonstrated that AnhE binds two half-equivalents of Co(2+) with K(d) of 0.12 +/- 0.06 nM and 110 +/- 35 nM, respectively. By contrast, AnhE bound only one half-equivalent of Zn(2+) (K(d) = 11 +/- 2 nM) and Ni(2+) (K(d) = 49 +/- 17 nM) and did not detectably bind Cu(2+). Substitution of the sole histidine residue did not affect Co(2+) binding. Holo-AnhE had a weak absorption band at 490 nM (epsilon = 9.7 +/- 0.1 m(-1) cm(-1)), consistent with hexacoordinate cobalt. The data support a model in which AnhE acts as a dimeric metallochaperone to deliver cobalt to ANHase. This study provides insight into the maturation of NHases and metallochaperone function.

Adopting selected hydrogen bonding and ionic interactions from Aspergillus fumigatus phytase structure improves the thermostability of Aspergillus niger PhyA phytase.

Although it has been widely used as a feed supplement to reduce manure phosphorus pollution of swine and poultry, Aspergillus niger PhyA phytase is unable to withstand heat inactivation during feed pelleting. Crystal structure comparisons with its close homolog, the thermostable Aspergillus fumigatus phytase (Afp), suggest associations of thermostability with several key residues (E35, S42, R168, and R248) that form a hydrogen bond network in the E35-to-S42 region and ionic interactions between R168 and D161 and between R248 and D244. In this study, loss-of-function mutations (E35A, R168A, and R248A) were introduced singularly or in combination into seven mutants of Afp. All seven mutants displayed decreases in thermostability, with the highest loss (25% [P<0.05]) in the triple mutant (E35A R168A R248A). Subsequently, a set of corresponding substitutions were introduced into nine mutants of PhyA to strengthen the hydrogen bonding and ionic interactions. While four mutants showed improved thermostability, the best response came from the quadruple mutant (A58E P65S Q191R T271R), which retained 20% greater (P<0.05) activity after being heated at 80 degrees C for 10 min and had a 7 degrees C higher melting temperature than that of wild-type PhyA. This study demonstrates the functional importance of the hydrogen bond network and ionic interaction in supporting the high thermostability of Afp and the feasibility of adopting these structural units to improve the thermostability of a homologous PhyA phytase.

Stabilization of hyperactive dihydrofolate reductase by cyanocysteine-mediated backbone cyclization.

Stabilization of an enzyme while maintaining its activity has been a major challenge in protein chemistry. Although it is difficult to simultaneously improve stability and activity of a protein by amino acid substitutions due to the activity-stability trade-off, backbone cyclization by connecting the N and C termini with a linker is promising as a general method of stabilizing a protein without affecting its activity. Recently, we created a hyperactive, methionine- and cysteine-free mutant of dihydrofolate reductase from Escherichia coli, called ANLYF, by introducing seven amino acid substitutions, which, however, destabilized the protein. Here we show that ANLYF is stabilized without a loss of its high activity by a novel backbone cyclization method for unprotected proteins. The method is based on the in vitro cyanocysteine-mediated intramolecular ligation reaction, which can be conducted with relatively high efficiency by a simple procedure and under mild conditions. We also show that the reversibility of thermal denaturation is highly improved by the cyclization. Thus, activity and stability of the protein can be separately improved by amino acid substitutions and backbone cyclization, respectively. We suggest that the cyanocysteine-mediated cyclization method is complementary to the intein-mediated cyclization method in stabilizing a protein without affecting its activity.

Structural mobility in human manganese superoxide dismutase.

Human manganese superoxide dismutase (MnSOD) is a homotetramer of 22 kDa subunits, a dimer of dimers containing dimeric and tetrameric interfaces. We have investigated conformational mobility at these interfaces by measuring amide hydrogen/deuterium (H/D) exchange kinetics and 19F NMR spectra, both being excellent methods for analyzing local environments. Human MnSOD was prepared in which all nine tyrosine residues in each subunit are replaced with 3-fluorotyrosine. The 19F NMR spectrum of this enzyme showed five sharp resonances that have been assigned by site-specific mutagenesis by replacing each 3-fluorotyrosine with phenylalanine; four 19F resonances not observed are near the paramagnetic manganese and extensively broadened. The temperature dependence of the line widths and chemical shifts of the 19F resonances were used to estimate conformational mobility. 3-Fluorotyrosine 169 at the dimeric interface showed little conformational mobility and 3-fluorotyrosine 45 at the tetrameric interface showed much greater mobility by these measures. In complementary studies, H/D exchange mass spectrometry was used to measure backbone dynamics in human MnSOD. Using this approach, amide hydrogen exchange kinetics were measured for regions comprising 78% of the MnSOD backbone. Peptides containing Tyr45 at the tetrameric interface displayed rapid exchange of hydrogen with deuterium while peptides containing Tyr169 in the dimeric interface only displayed moderate exchange. Taken together, these studies show that residues at the dimeric interface, such as Tyr169, have significantly less conformational freedom or mobility than do residues at the tetrameric interface, such as Tyr45. This is discussed in terms of the role in catalysis of residues at the dimeric interface.

Treatment of cells with the angiogenic inhibitor fumagillin results in increased stability of eukaryotic initiation factor 2-associated glycoprotein, p67, and reduced phosphorylation of extracellular signal-regulated kinases.

Fumagillin, an angiogenic inhibitor, binds to methionine aminopeptidase 2, which is the same as eukaryotic initiation factor 2-associated glycoprotein, p67. p67 protects eIF2alpha from phosphorylation by its kinases. To understand the importance of fumagillin binding to p67, we measured the level of p67 in mouse C2C12 myoblasts treated with fumagillin. We show that fumagillin increases the stability of p67 by decreasing its turnover rate. The increased levels of p67 result in inhibition of phosphorylation of extracellular signal-regulated kinases 1 and 2 (ERKs 1 and 2). p67 binds to these ERKs, and the 108-480 amino acid segment is sufficient for this binding. p67's affinity to ERKs 1 and 2 also increases in fumagillin-treated myoblasts while its affinity for eIF2alpha remains unchanged. A mutant at the conserved amino acid residue D251A increases the phosphorylation of ERKs 1 and 2 without affecting the binding to p67, thus indicating the importance of this residue in the regulation of the phosphorylation of these ERKs. These results suggest that fumagillin increases the stability of p67 and its affinity to ERKs 1 and 2 and causes the inhibition of the phosphorylation of ERKs 1 and 2.

Nitric oxide synthase (NOS2) mutation in Dahl/Rapp rats decreases enzyme stability.

The pathogenesis of salt-sensitive hypertension remains poorly defined, but a role for nitric oxide (NO) has been suggested. The Dahl/Rapp salt-sensitive rat possesses a defect in NO synthesis that is overcome by supplementation with L-arginine, which increases NO and cGMP production and prevents salt-sensitive hypertension. An S714P mutation of inducible NO synthase (NOS2) was subsequently identified. The current report examined the functional significance of an S714P mutation in NOS2. COS-7 cells were transiently transfected with cDNA of wild-type NOS2 and S714P and S714A mutants of NOS2, and enzyme function was determined. Whereas steady-state mRNA levels did not differ, immunoblot analysis demonstrated decreased levels of NOS2 protein. Metabolic labeling experiments confirmed a reduced half-life of the S714P mutation. Nitrite production, which was dependent on the concentration of L-arginine in the medium, was diminished in cells transfected with the S714P mutant, compared with the wild type and the S714A mutant. These data provide a biochemical explanation of the physiological abnormalities of NOS2 in the Dahl/Rapp salt-sensitive rat and suggest that a posttranslational mechanism involving the proteasome may be responsible for the diminished NO production observed in response to increased dietary salt intake in these animals.

Role of enzyme-ribofuranosyl contacts in the ground state and transition state for orotidine 5'-phosphate decarboxylase: a role for substrate destabilization?

The crystal structure of yeast orotidine 5'-monophosphate decarboxylase (ODCase) complexed with the inhibitor 6-hydroxyuridine 5'-phosphate (BMP) reveals the presence of a series of strong interactions between enzyme residues and functional groups of this ligand. Enzyme contacts with the phosphoribofuranosyl moiety of orotidine 5'-phosphate (OMP) have been shown to contribute at least 16.6 kcal/mol of intrinsic binding free energy to the stabilization of the transition state for the reaction catalyzed by yeast ODCase. In addition to these enzyme-ligand contacts, active site residues contributed by both subunits of the dimeric enzyme are positioned to form hydrogen bonds with the 2'- and 3'-OH groups of the ligand's ribosyl moiety. These involve Thr-100 of one subunit and Asp-37 of the opposite subunit, respectively. To evaluate the contributions of these ribofuranosyl contacts to ground state and transition state stabilization, Thr-100 and Asp-37 were each mutated to alanine. Elimination of the enzyme's capacity to contact individual ribosyl OH groups reduced the k(cat)/K(m) value of the T100A enzyme by 60-fold and that of the D37A enzyme by 300-fold. Removal of the 2'-OH group from the substrate OMP decreased the binding affinity by less than a factor of 10, but decreased k(cat) by more that 2 orders of magnitude. Upon removal of the complementary hydroxymethyl group from the enzyme, little further reduction in k(cat)/K(m) for 2'-deoxyOMP was observed. To assess the contribution made by contacts involving both ribosyl hydroxyl groups at once, the ability of the D37A mutant enzyme to decarboxylate 2'-deoxyOMP was measured. The value of k(cat)/K(m) for this enzyme-substrate pair was 170 M(-1) s(-1), representing a decrease of more than 7.6 kcal/mol of binding free energy in the transition state. To the extent that electrostatic repulsion in the ground state can be tested by these simple alterations, the results do not lend obvious support to the view that electrostatic destabilization in the ground state enzyme-substrate complex plays a major role in catalysis.

Generation of up-regulated allosteric variants of potato ADP-glucose pyrophosphorylase by reversion genetics.

Mutagenesis of the large subunit (LS) of the potato ADP-glucose pyrophosphorylase generated an enzyme, P52L, that was insensitive to 3-phosphoglycerate (3-PGA). To identify additional residues involved in 3-PGA interaction, we subjected P52L LS DNA to a second round of mutagenesis and identified second-site revertants by their ability to restore glycogen accumulation as assessed by iodine (I2) staining. Enzymes from class I revertants with normal I2-staining had an 11- to 49-fold greater affinity for the activator 3-PGA compared with the P52L mutant and a decreased sensitivity to the inhibitor orthophosphate. Sequence analysis of these class I revertants identified a P66L mutation in R4, an E38K mutation in R20, and a G101N mutation in R10 and R32. These mutations appear to restore 3-PGA binding by counteracting the effect of the P52L mutation because introducing E38K or G101N into the wild-type LS led to enzyme variants with higher affinity for the activator 3-PGA and increased resistance to the inhibitor orthophosphate. The generation of these revertant enzymes provides additional structure-function information on the allosteric regulation of higher plant ADP-glucose pyrophosphorylases and validates a strategy for developing novel variants of the enzyme that may be useful in manipulating starch biosynthesis in higher plants.

PCR isolation of catechol 2,3-dioxygenase gene fragments from environmental samples and their assembly into functional genes.

A method was developed to isolate central segments of catechol 2, 3-dioxygenase (C23O) genes from environmental samples and to insert these C23O gene segments into nahH (the structural gene for C23O encoded by catabolic plasmid NAH7) by replacing the corresponding nahH sequence with the isolated segments. To PCR-amplify the central C23O gene segments, a pair of degenerate primers was designed from amino acid sequences conserved among C23Os. Using these primers, central regions of the C23O genes were amplified from DNA isolated from a mixed culture of phenol-degrading or crude oil-degrading bacteria. Both the 5' and 3' regions of nahH were also PCR-amplified by using appropriate primers. These three PCR products, the 5'-nahH and 3'-nahH segments and the central C23O gene segments, were mixed and PCR-amplified again. Since the primers for the amplification of the central C23O gene segments were designed so that the 20 nucleotides at both ends of the segments are identical to the 3' end of the 5'-nahH segment and the 5' end of the 3'-nahH segment, respectively, the central C23O gene segments could anneal to both the 5'- and 3'-nahH segments. After the second PCR, hybrid C23O genes in the form of (5'-nahH segment-central C23O gene segment-3'-nahH segment) were amplified to full length. The resulting products were cloned into a vector and used to transform Escherichia coli. This method enabled divergent C23O sequences to be readily isolated, and more than 90% of the hybrid plasmids expressed C23O activity. Thus, the present method is useful to create, without isolating bacteria, a library of functional hybrid genes.

Monomeric human cathepsin E.

Cathepsin E is a homodimer, consisting of two monomers linked by an inter-molecular disulphide bond. The cysteine residue involved is located near to the N-terminus of the mature proteinase. By mutating this residue to alanine, a monomeric form of human cathepsin E was engineered and purified. The activity of the resultant enzyme was not altered significantly (in terms of its ability to hydrolyse two chromogenic peptide substrates; and its susceptibility to inhibition by pepstatin). However, the stability of the mutant enzyme to alkaline pH and to temperature was markedly reduced.