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Candida antarctica lipase B (CALB) and C. antarctica lipase B fused to a cellulose-binding domain (CBD-CALB) were expressed functionally in the methylotrophic yeast Pichia pastoris. The cellulose-binding domain originates from cellulase A of the anaerobic rumen fungus Neocallimastix patriciarum. The genes were fused to the alpha-factor secretion signal sequence of Saccharomyces cerevisiae and placed under the control of the alcohol oxidase gene (AOX1) promoter. The recombinant proteins were secreted into the culture medium reaching levels of approximately 25 mg/L. The proteins were purified using hydrophobic interaction chromatography and gel filtration with an overall yield of 69%. Results from endoglycosidase H digestion of the proteins showed that CALB and CBD-CALB were N-glycosylated. The specific hydrolytic activities of recombinant CALB and CBD-CALB were identical to that reported for CALB isolated from its native source. The fusion of the CBD to the lipase resulted in a greatly enhanced binding toward cellulose for CBD-CALB compared with that for CALB.

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The optimal selection of patients for adjuvant therapy, avoiding overtreatment and undertreatment, of disease is a significant challenge in the management of early breast cancers. Population-based cohorts in Denmark and in two Swedish health care regions were investigated to identify patients with breast cancer who have a sufficiently low risk of recurrence without adjuvant therapy. Published data on different calcification patterns were also included from the randomized Swedish mammography two-county study. The Danish Breast Cancer Group's population-based registry revealed that patients with lymph node-negative and estrogen receptor- or progesterone receptor-positive cancers of histological grade I that were less than 20 mm in size had a 5-year survival rate similar to age-matched groups without breast cancer. Data from the Stockholm Breast Cancer Group identified a similar risk group (no information on cancer grade) with an approximate 10% risk of dying from breast cancer after 10 years without any adjuvant therapy. In women older than 50 years, approximately 20% died of other causes. Mammographically and lymph node-negative-detected cancers that are less than 15 mm in size generally have an excellent survival outcome, excluding patients with casting calcifications. Patients who have lymph node-negative breast cancers that are less than 20 mm in size, combined with estrogen receptor positivity, can be identified as a low-risk group. The vast majority of these patients are unlikely to benefit from the addition of conventional chemotherapy, but some of them may. The dilemma is that we cannot identify these patients prospectively because of the lack of relevant predictive factors for chemotherapy.

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The alpha/beta-hydrolase fold family of enzymes is rapidly becoming one of the largest group of structurally related enzymes with diverse catalytic functions. Members in this family include acetylcholinesterase, dienelactone hydrolase, lipase, thioesterase, serine carboxypeptidase, proline iminopeptidase, proline oligopeptidase, haloalkane dehalogenase, haloperoxidase, epoxide hydrolase, hydroxynitrile lyase and others. The enzymes all have a Nucleophile-His-Acid catalytic triad evolved to efficiently operate on substrates with different chemical composition or physicochemical properties and in various biological contexts. For example, acetylcholine esterase catalyzes the cleavage of the neurotransmitter acetylcholine, at a rate close to the limits of diffusion of substrate to the active site of the enzyme. Dienelactone hydrolase uses substrate-assisted catalysis to degrade aromatic compounds. Lipases act adsorbed at the water/lipid interface of their neutral water-insoluble ester substrates. Most lipases have their active site buried under secondary structure elements, a flap, which must change conformation to allow substrate to access the active site. Thioesterases are involved in a multitude of biochemical processes including bioluminiscence, fatty acid- and polyketide biosynthesis and metabolism. Serine carboxypeptidases recognize the negatively charged carboxylate terminus of their peptide substrates. Haloalkane dehalogenase is a detoxifying enzyme that converts halogenated aliphatics to the corresponding alcohols, while haloperoxidase catalyzes the halogenation of organic compounds. Hydroxynitrile lyase cleaves carbon-carbon bonds in cyanohydrins with concomitant hydrogen cyanide formation as a defense mechanism in plants. This paper gives an overview of catalytic activities reported for this family of enzymes by discussing selected examples. The current state of knowledge of the molecular basis for catalysis and substrate specificity is outlined. Relationships between active site anatomy, topology and conformational rearrangements in the protein molecule is discussed in the context of enzyme mechanism of action.

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[reaction: see text] We have found that two Geotrichum candidum lipase isozymes have remarkably different abilities to differentiate between enantiomers of ethyl 2-methyldecanoate. By rational recombination of selected portions of the two isozymes, we have created a novel lipase with an enantioselectivity superior to that of the best wild-type parent isozyme. Site-directed mutagenesis identified two key amino acid residues responsible for the improved enantioselectivity without compromised total activity of the reengineered enzyme.

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Despite immense progress in our comprehension of lipase structure and function during the past decade, the basis for lipase acyl specificities has remained poorly understood. This review summarizes some recent advances in the understanding at the molecular-level of substrate acyl recognition by two members in a group of large (Mw approximately 60 kDa) microbial lipases. Two aspects of acyl specificity will be focused upon. (i) The unique preference of a fungal Geotrichum candidum lipase for long-chain cis (delta-9) unsaturated fatty acid moieties in the substrate. Mutational analysis of this lipase identified residues essential for its anomalous acyl preference. This information highlighted for the first time parts in the lipase molecule involved in substrate acyl differentiation. These results are discussed in the context of the 3D-structure of a G. candidum lipase isoenzyme and structures of the related Candida rugosa lipase in complex with inhibitors. (ii) The mechanism by which the yeast C. rugosa lipase discriminates between enantiomers of a substrate with a chiral acyl moiety. Molecular modeling in combination with substrate engineering and kinetic analyses, identified two alternative substrate binding models. This allowed for the proposal of a molecular mechanism explaining how long-chain alcohols can act as enantioselective inhibitors of this enzyme. A picture is thus beginning to emerge of the interplay between lipase structure and fatty acyl specificity.

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The fungus Geotrichum candidum produces two lipase isoenzymes, GCL I and GCL II, with distinct differences in substrate specificity despite their 86% identical primary structure. GCL I prefers ester substrates with long-chain cis (delta-9) unsaturated fatty acid moieties, whereas GCL II also accepts medium-length (C8-C14) acyl moieties in the substrate. To reveal structural elements responsible for differences in substrate differentiating ability of these isoenzymes, we designed, expressed, and characterized 12 recombinant lipase variants. Three chimeric lipases containing unique portions of the N-terminal and the C-terminal part of GCL I and GCL II, respectively, were constructed and enzymatically characterized. Activities were measured against mixed triglyceride-poly(dimethyl siloxane) particles. Our results indicate that residues within sequence positions 349-406 are essential for GCL I's high triolein/trioctanoin activity ratio of 20. The substitution of that segment in the specific GCL I to the corresponding residues in the nonspecific GCL II resulted in an enzyme with a triolein/trioctanoin activity ratio of 1.4, identical to that of GCL II. The reverse mutation in GCL II increased its specificity for triolein by a factor of 2, thus only in part restoring the high specificity seen with GCL I. In further experiments, the point mutations at the active site entrance of the GCL I, Leu358Phe and Ile357Ala/Leu358Phe, lowered the triolein/trioctanoin activity ratio from 20 to 4 and 2.5, respectively. The substitutions Cys379Phe/Ser380Tyr at the bottom of the active site cavity of GCL I decreased its specificity to a value of 3.6. Measurements of lipase activity with substrate particles composed of pure triglycerides or ethyl esters of oleic and octanoic acids resulted in qualitatively similar results as reported above. Our data reveal for the first time the identity of residues essential for the unusual substrate preference of GCL I and show that the anatomy, both at the entrance and the bottom of the active site cavity, plays a key role in substrate discrimination.

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We describe the heterologous high-level expression of the two Geotrichum candidum lipase (GCL) isoenzymes from strain ATCC 34614 in the methylotrophic yeast Pichia pastoris. The lipase cDNAs were placed under the control of the methanol-inducible alcohol oxidase promoter. The lipases expressed in P. pastoris were fused to the alpha-factor secretion signal peptide of Saccharomyces cerevisiae and were secreted into the culture medium. Cultures of P. pastoris expressing lipase accumulated active recombinant enzyme in the supernatant to levels of approximately 60 mg/L virtually free from contaminating proteins. This yield exceeds that previously reported with S. cerevisiae by a factor of more than 60. Recombinant GCL I and GCL II had molecular masses of approximately 63 and approximately 66 kDa, respectively, as determined by SDS-PAGE. The result of endoglucosidase H digestion followed by Western blot analysis of the lipases suggested that the enzymes expressed in P. pastoris received N-linked high-mannose-type glycosylation to an extent, 6-8% (w/w), similar to that in G. candidum. The specific activities and substrate specificities of both recombinant lipases were determined and were found to agree with what has been reported for the enzymes isolated from the native source.

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A Care Multidisciplinary Action Plan was developed at a 300-bed rural medical center in 1994. Once a potential organ donor is identified and referred to the organ procurement organization and the family has consented to donation, the ICU nurse initiates the Care Multidisciplinary Action Plan, which is based on an 8-hour time frame for ICU care that may be adjusted as needed. The first hour includes prompts for coroner notification, billing changes, and completion of hospital-specific death notice forms. The remaining hours are spent administering tests and preparing the donor for organ retrieval. Collaborative issues such as donor family support also are addressed. ICU nurses who used the donor care Multidisciplinary Action Plan were interviewed to determine its effectiveness.

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The importance of Glu87 and Trp89 in the lid of Humicola lanuginosa lipase for the hydrolytic activity at the water/lipid interface was investigated by site-directed mutagenesis. It was found that the effect on the hydrolytic activity upon the replacement of Trp89 with Phe, Leu, Gly or Glu was substrate dependent. The Trp89 mutants displayed an altered chain length specificity towards triglycerides, with a higher relative activity towards triacetin and trioctanoin compared with tributyrin. Trp89 was shown to be less important in the hydrolysis of vinyl esters compared with ethyl esters and triglycerides. An exclusive effect on the acylation reaction rate by the mutation of Trp89 was consistent with the data. It is suggested that Trp89 is important in the process of binding the acyl chain of the substrate into the active site for optimal acylation reaction rate. The Trp89Phe mutation resulted in an increased hydrolytic activity towards 2-alkylalkanoic acid esters. This is suggested to be due to reduction of unfavourable van der Waals contacts between Trp89 and the 2-substituent of the substrate. Thus, in contrast to natural substrates, Trp89 has a negative impact on the catalytic efficiency when substrates with bulky acyl chains are used. In contrast to the Trp89 mutations, the effect on the hydrolytic activity of the Glu87Ala mutation was almost substrate independent, 35-70% activity of wild-type lipase. A reduction of both the acylation and deacylation reaction was consistent with the data.

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Molecular modeling showed that the enantiomers of heptyl 2-methyldecanoate are productively bound to the active site of Candida rugosa lipase in quite different conformations. The fast-reacting S-enantiomer may well occupy the previously identified acyl-binding tunnel in the active site of the lipase. By contrast, the slow-reacting R-enantiomer must be bound to the active site, leaving the tunnel empty to allow the formation of two catalytically essential hydrogen bonds between His 449 of the catalytic triad and the transition state of the catalyzed reaction. This information enables us to propose a molecular mechanism explaining how long-chain aliphatic alcohols act as enantioselective inhibitors of this lipase in the resolution of 2-methyldecanoic acid. Long-chain aliphatic alcohols may coordinate to the acyl-binding tunnel of the C. rugosa lipase, thereby selectively inhibiting the turnover of the fast-reacting S-enantiomer, thus resulting in a lowered enantioselectivity in the resolution.

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The dynamics of the cationic, bioelectrical and secretory responses to formycin A were monitored in pancreatic islet cells in order to assess whether this adenosine analogue, which is known to be converted to formycin A 5'-triphosphate in isolated islets, triggers the same sequence of ionic events as that otherwise involved in the process of nutrient-stimulated insulin release and currently attributed to an increase in adenosine 5'-triphosphate (ATP) generation rate. Unexpectedly, formycin A first increased 86Rb outflow, decreased 45Ca outflow and inhibited insulin release from prelabelled islets perifused at physiological or higher concentrations of D-glucose. This early inhibitory effect of formycin A upon insulin release coincided, in perforated patch whole-cell recordings, with an initial transient increase of ATP-sensitive K+ channel activity. A positive secretory response to formycin A, still not associated with any decrease in K+ conductance, was only observed either immediately after formycin A administration to islets already exposed to glibenclamide or during prolonged exposure to the adenosine analogue. This coincided with an increase of cytosolic Ca2+ concentration in intact B-cells and a greater increase of membrane capacitance in response to depolarization in B-cells examined in the perforated patch whole-cell configuration. The latter stimulation of exocytotic activity could not be attributed, however, to any increase in peak or integrated Ca2+ current. Thus, the mode of action of formycin A, or its 5'-triphosphate ester, in islet cells obviously differs from that currently ascribed to endogenous ATP in the process of nutrient-stimulated insulin release.

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The interfacial activation of Candida antarctica lipase A (CALA) and B (CALB) has been investigated and compared with that of Humicola lanuginosa lipase (HLL). CALB displayed no interfacial activation towards p-nitrophenyl butyrate (PNPB) when exceeding the solubility limit of the substrate. No activation was observed towards p-nitrophenyl acetate (PNPA) at the addition of sodium dodecyl sulfate (SDS) nor in the presence of a solid polystyrene surface. The catalytic action of CALB was very different from that of Humicola lanuginosa lipase, which showed a pronounced interfacial activation with the same substrates. The basis for the anomalous behaviour of CALB is proposed to be due to the absence of a lid that regulates the access to the active site. In contrast to CALB, CALA expressed interfacial activation, but the activation was not as prominent as for Humicola lanuginosa lipase (HLL). The structural basis for the activation of CALA is unknown.

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To reveal the functional role of Glu87 and Trp89 in the lid of Humicola lanuginosa lipase, site-directed mutagenesis at Glu87 and Trp89 was carried out. The catalytic performance of wild-type and mutated lipases was studied in transesterification reactions in cyclohexane at a controlled water activity. Two different acyl donors were used in the investigation: tributyrin, a natural substrate for a lipase, and vinyl butyrate, an activated ester suitable for fast and efficient lipase-catalyzed transformations in preparative organic synthesis. As acyl acceptor 1-heptanol was used. The Glu87Ala mutation decreased the Vmax,app value with tributyrin and vinyl butyrate by a factor of 1.5 and 2, respectively. The Km,app for tributyrin was not affected by the Glu87Ala mutation, but the Km,app for vinyl butyrate increased twofold compared to the wild-type lipase. Changing Trp89 into a Phe residue afforded an enzyme with a 2.7- and 2-fold decreased Vmax,app with the substrates tributyrin and vinyl butyrate, respectively, compared to the wild-type lipase. No significant effects on the Km,app values for tributyrin or vinyl butyrate were seen as a result of the Trp89Phe mutation. However, the introduction of a Glu residue at position 89 in the lid increased the Km,app for tributyrin and vinyl butyrate by a factor of > 5 and 2, respectively. The Trp89Glu mutated lipase could not be saturated with tributyrin within the experimental conditions (0-680 mM) studied here. With vinyl butyrate as a substrate the Vmax,app was only 6% of that obtained with wild-type enzyme.

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To determine whether Trp89 located in the lid of the lipase (EC 3.1.1.3) from Humicola lanuginosa is important for the catalytic property of the enzyme, site-directed mutagenesis at Trp89 was carried out. The kinetic properties of wild type and mutated enzymes were studied with tributyrin as substrate. Lipase variants in which Trp89 was changed to Phe, Leu, Gly or Glu all showed less than 14% of the activity compared to that of the wild type lipase. The Trp89Glu mutant was the least active with only 1% of the activity seen with the wild type enzyme. All Trp mutants had the same binding affinity to the tributyrin substrate interface as did the wild type enzyme. Wild type lipase showed saturation kinetics against tributyrin when activities were measured with mixed emulsions containing different proportions of tributyrin and the nonionic alkyl polyoxyethylene ether surfactant, Triton DF-16. Wild type enzyme showed a Vmax = 6000 +/- 300 mmol.min-1.g-1 and an apparent Km = 16 +/- 2% (vol/vol) for tributyrin in Triton DF-16, while the mutants did not show saturation kinetics in an identical assay. The apparent Km for tributyrin in Triton DF-16 was increased as the result of replacing Trp89 with other residues (Phe, Leu, Gly or Glu). The activities of all mutants were more sensitive to the presence of Triton DF-16 in the tributyrin substrate than was wild type lipase. The activity of the Trp89Glu mutant was decreased to 50% in the presence of 2 vol% Triton DF-16 compared to the activity seen with pure tributyrin as substrate.(ABSTRACT TRUNCATED AT 250 WORDS)

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The homologous lipases from Rhizomucor miehei and Humicola lanuginosa showed approximately the same enantioselectivity when 2-methyldecanoic acid esters were used as substrates. Both lipases preferentially hydrolyzed the S-enantiomer of 1-heptyl 2-methyldecanoate (R. miehei: ES = 8.5; H. lanuginosa: ES = 10.5), but the R-enantiomer of phenyl 2-methyldecanoate (ER = 2.9). Chemical arginine specific modification of the R. miehei lipase with 1,2-cyclohexanedione resulted in a decreased enantioselectivity (ER = 2.0), only when the phenyl ester was used as a substrate. In contrast, treatment with phenylglyoxal showed a decreased enantioselectivity (ES = 2.5) only when the heptyl ester was used as a substrate. The presence of guanidine, an arginine side chain analog, decreased the enantioselectivity with the heptyl ester (ES = 1.9) and increased the enantioselectivity with the aromatic ester (ER = 4.4) as substrates. The mutation, Glu 87 Ala, in the lid of the H. lanuginosa lipase, which might decrease the electrostatic stabilization of the open-lid conformation of the lipase, resulted in 47% activity compared to the native lipase, in a tributyrin assay. The Glu 87 Ala mutant showed an increased enantioselectivity with the heptyl ester (ES = 17.4) and a decreased enantioselectivity with the phenyl ester (ER = 2.5) as substrates, compared to native lipase. The enantioselectivities of both lipases in the esterification of 2-methyldecanoic acid with 1-heptanol were unaffected by the lid modifications.

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Molecular dynamics simulations for the lid covering the active site of Rhizomucor miehei lipase [EC 3.1.1.3] postulated that, among other interactions, Arg86 in the lid stabilized the open-lid conformation of the protein by multiple hydrogen bonding to the protein surface. Chemical modification of arginine residues in R. miehei lipase with 1,2-cyclohexanedione or phenylglyoxal resulted in residual activities in the hydrolysis of tributyrin of 66 and 46%, respectively. Tryptic maps of native and phenylglyoxal-reacted R. miehei lipase showed that Arg86 was the residue modified most, when the lipase was inhibited to the greatest extent. Guanidine, a structural analog to an arginine side chain, inhibited both the native enzyme and the arginine-modified enzymes, resulting in residual activities of 26% as compared to the native enzyme. The inhibition was not an effect of enzyme denaturation. The native enzyme was also inhibited by 1-ethylguanidine, benzamidine and urea, but to a lesser degree than by guanidine. Lipases from Humicola lanuginosa and porcine pancreas in 100 mM guanidine showed residual activities of 88 and 70%, respectively. The lipases from Candida antarctica, C. rugosa, Pseudomonas cepacia and P. fluorescens were not inhibited by guanidine. The inhibition of R. miehei lipase by structural analogs of the arginine side chain and after chemical modification of arginine residues suggest a role of an arginine residue in stabilizing the active open-lid conformation of the enzyme.

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