Characterization and affinity purification of juvenile hormone esterase from Bombyx mori

Juvenile hormone esterase (JHE) from hemolymph of the silkworm moth Bombyx mori was characterized for substrate specificity and inhibitor sensitivity. B. mori JHE hydrolyzed the juvenile hormone surrogate substrate methyl n-heptylthioacetothioate (HEPTAT) more efficiently than p-nitrophenyl acetate and 1-naphthyl acetate substrates widely used to assay total carboxylesterase activity. B. mori JHE was sensitive to 3-octylthio-1,1,1-trifluoro-2-propanone (OTFP), which was developed as a selective inhibitor for lepidopteran JHE, and relatively insensitive to diisopropyl fluorophosphate (DFP), an inhibitor of serine esterases but not of all JHEs. Affinity purification with a trifluoromethyl ketone ligand was more efficient for purification of B. mori JHE than DEAE ion exchange chromatography.     

Characterization of hemolymph juvenile hormone esterase from Lymantria dispar

A major peak of juvenile hormone esterase (JHE) activity approaching 330 nmol JH III hydrolyzed/min/ml of hemolymph was observed during the last larval growth stage in Lymantria dispar. A smaller peak of JHE occurred 3–5 days after pupation. The gypsy moth JHE was purified from larval hemolymph using a classical approach. A specific activity of 766 units per mg of protein and a K_m of 3.6 × 10⁻⁷ M for racemic JH III and the (10R, 11S) enantiomer of JH II was determined for the purified enzyme. The 62 kDa esterase was insensitive to inhibition by O,O-diisopropyl phosphorofluoridate (DFP), or by phenylmethylsulfonyl fluoride (PMSF). Two forms of JHE isolated by RP-HPLC were indistinguishable by HPLC tryptic peptide mapping and share an identical N-terminal amino acid sequence. Polyclonal antisera raised against gypsy moth enzyme cross-reacted with JHE from Trichoplusia ni but not with JHE from Manduca sexta. A weak cross-reactivity was observed with JHE from Heliothis virescens. Forty amino acid residues of the N-terminus were placed in sequence. The N-terminal sequence of JHE from L. dispar showed little homology to the sequence of JHE from H. virescens. The immunological and structural data support the conclusion that markedly different esterases, which catalyze the hydrolysis of juvenile hormone, are present in the hemolymph of different Lepidoptera.     

Only one esterase of Drosophila melanogaster is likely to degrade juvenile hormone in vivo

Previously we identified juvenile hormone esterase (JHE) from Drosophila melanogaster by the criteria that it showed both appropriate developmental expression and kinetics for juvenile hormone (JH). We also noted three further esterases of D. melanogaster with some JHE-like characteristics, such as a GQSAG active site motif, a particular amphipathic helix, or close phylogenetic relationship with other JHEs. In this study, these JHE-like enzymes were expressed in vitro and their kinetic parameters compared with those of the previously identified JHE. Despite considerable phylogenetic distance between some of the esterases, they could all hydrolyse racemic JHIII. However, only the previously identified JHE had kinetic parameters (K(M) and k(cat)) towards various forms of JH (racemic or individual isomers of JHIII, JHII, JHI, and methyl farnesoate) consistent with a physiological role in JH regulation. Furthermore, only this JHE showed a preference for artificial substrates with acyl chain lengths similar to that of JH. This suggests that there is probably only one physiologically functional JHE in D. melanogaster but multiple esterases with JH esterase activity. Genomic comparisons of the selective JHE across 11 other Drosophila species showed a single orthologue in 10 of them but Drosophila willistoni has 16 full-length copies, five of them with the GQSAG motif and amphipathic helix.     

Distinctive structural and kinetic properties of an unusual juvenile hormone-hydrolyzing esterase

The insect juvenile hormone specific esterases (JHEs), related to acetylcholinesterases but exhibiting substrate specificity for juvenile hormone (JH), are essential enzymes for normal insect development, making them attractive targets for biorationally designed, environmentally safe pesticides. We examine here a new enzyme, JHER, related to, but yet structurally, biochemically, and kinetically distinct from, the classical JHE. Both classical JHE and baculovirus-expressed JHER hydrolyze JH show disproportionately higher catalytic rates at higher substrate concentrations (in contrast to substrate inhibition reported for acetylcholinesterase) and are similarly inhibited by an organophosphate. However, JHER, which possesses an unusual cysteine residue at +1 to the catalytic serine, is less sensitive to trifluoromethyl ketone transition state analogs designed around the structure of JH. We propose a model in which JHER is expressed just prior to metamorphosis for hydrolysis of a JH-like substrate with hydrophobic backbone, a proximal ester, and a terminal expoxide or related substitution.     

Activation of the proto-oncogene p60c-src by point mutations in the SH2 domain.

To investigate the importance of a conserved region spanning residues 137 to 241 in the noncatalytic domain of p60c-src (SH2 region), we used oligonucleotide-directed mutagenesis to change residues that are highly conserved in this region. Chicken embryo fibroblasts infected with a p60c-src variant containing arginine instead of tryptophan at residue 148 (W148R) appeared more rounded than cells overexpressing a normal c-src gene, and they formed colonies in soft agar. p60c-src variants containing serine instead of arginine at residue 155 (R155S) or isoleucine instead of glycine at residue 170 (G170I) also appeared transformed and were anchorage independent, but to a lesser extent than W148R. Mutation of residue 201 from histidine to leucine (H201L) had no observable effect. The in vitro kinase activity of cells infected with W148R or G170I was elevated twofold. Expression of p60W148R (or, to a lesser extent, of p60G170I) increased the number of proteins phosphorylated on tyrosine in infected cells. All of the mutants were phosphorylated in vivo on Tyr-527, instead of Tyr-416 as observed for p60v-src. Immunoprecipitated p60W148R and p60G170I were found to be associated with a phosphatidylinositol kinase activity, a factor which appears to be necessary for transformation by tyrosine-specific protein kinases. These results show that a single point mutation in the SH2 region of the cellular src gene can activate its transforming potential. This type of activation is in a new category of alterations at the amino terminus that activate but do not cause a shift in phosphorylation at the carboxy terminus.     

Characterization and analysis of novel carboxyl/cholinesterase genes possessing the Thr-316 motif in the silkworm, Bombyx mori

Juvenile hormone esterases (JHEs) function in juvenile hormone (JH) degradation. In the silkworm, Bombyx mori, we have characterized authentic JHE (Bmjhe) and five other carboxyl/cholinesterase (CCE) genes (Bmcce-1 to -5) with GQSAG, a motif sequence of JHE. But none of the genes appeared to function in vivo as a JHE, except for Bmjhe. Recently it was reported that the GQSAG motif might be dispensable, and that the Thr-316 residue has functional significance for JHE activity. On the basis of these findings, we identified two novel JHE candidates, Bmcce-6 and Bmcce-7, that lack GQSAG but possess Thr-316. In the CCE phylogenetic tree, BmCCE-6 was close to the lepidopteran JHE cluster, while BmCCE-7 constituted the same cluster as pheromone-degrading esterases. The developmental expression profiles were different among Bmjhe, Bmcce-6, and Bmcce-7. None of the proteins hydrolyzed JH in vitro. Our results suggest that only one CCE (BmJHE) functions as JHE in the silkworm.     

Improved insecticidal efficacy of a recombinant baculovirus expressing mutated JH esterase from Manduca sexta

Juvenile hormone esterase (JHE), a member of the carboxylesterase family (EC 3.1.1.1), metabolizes JH that is found in juvenile insects. A highly conserved amphipathic alpha helix is found on the surface of known JHEs. This helix is implicated in receptor-mediated binding and endocytosis of JHE by the pericardial cells resulting in the clearance of JHE activity from the hemolymph. In this study, Lys-204 and Arg-208 of the amphipathic alpha helix of the JHE of Manduca sexta (MsJHE) were mutated to histidine residues generating MsJHE-HH. Pharmacokinetic studies following the injection of MsJHE-HH into the hemocoel of larval M. sexta, Heliothis virescens, and Agrotis ipsilon indicated that MsJHE-HH and wild type MsJHE are cleared at similar rates. The infectivity (lethal concentration and lethal time) of a recombinant baculovirus, AcMsJHE-HH, expressing MsJHE-HH was not significantly different than that of a recombinant baculovirus, AcMsJHE, expressing MsJHE in first instars of H. virescens and A. ipsilon. However, the mass of AcMsJHE-HH-infected larvae was 40–50% lower than that of larvae infected with AcMsJHE, and 70–90% lower than that of wild type AcMNPV-infected larvae.     

Expression and characterization of Flavikunin: A Kunitz‐type serine protease inhibitor identified in the venom gland cDNA library of Bungarus flaviceps

Trancriptomic analysis of the venom gland cDNA library of Bungarus flaviceps revealed Kunitz‐type serine protease inhibitor as one of the major venom protein families with three groups A, B, C. One of the group B isoforms named Flavikunin, which lacked an extra cysteine residue involved in disulfide bond formation in β‐bungarotoxin, was synthesized, cloned, and overexpressed in Escherichia coli. To decipher the structure‐function relationship, the P1 residue of Flavikunin, histidine, was mutated to alanine and arginine. Purified wild‐type and mutant Flavikunins were screened against serine proteases‐thrombin, factor Xa, trypsin, chymotrypsin, plasmin, and elastase. The wild‐type and mutant Flavikunin (H?R) inhibited plasmin with an IC ₅₀ of 0.48 and 0.35 µM, respectively. The in‐silico study showed that P1 residue of wild‐type and mutant (H?R) Flavikunin interacted with S1′ and S1 site of plasmin, respectively. Thus, histidine at the P1 position was found to be involved in plasmin inhibition with mild anticoagulant activity.     

Site-specific mutagenesis of an essential histidine residue in pancreatic cholesterol esterase

The histidine residue essential for the catalytic activity of pancreatic cholesterol esterase (carboxylester lipase) has been identified in this study using sequence comparison and site-specific mutagenesis techniques. In the first approach, comparison of the primary structure of rat pancreatic cholesterol esterase with that of acetylcholinesterase and cholinesterase revealed two conserved histidine residues located at positions 420 and 435. The sequence in the region around histidine 420 is quite different between the three enzymes. However, histidine 435 is located in a 22-amino acid domain that is 47% homologous with other serine esterases. Based on this sequence homology, it was hypothesized that histidine 435 is the histidine residue essential for catalytic activity of cholesterol esterase. The role of His435 in the catalytic activity of pancreatic cholesterol esterase was then studied by the site-specific mutagenesis technique. Substitution of the histidine in position 435 with glutamine, arginine, alanine, serine, or aspartic acid abolished the ability of cholesterol esterase to hydrolyze p-nitrophenyl butyrate and cholesterol [14C]oleate. In contrast, mutagenesis of the histidine residue at position 420 to glutamine had no effect on cholesterol esterase enzyme activity. The results of this study strongly suggested that histidine 435 may be a component of the catalytic triad of pancreatic cholesterol esterase.     

Functional characterization of hypothetical proteins of Mycobacterium tuberculosis with possible esterase/lipase signature: a cumulative in silico and in vitro approach

The functional aspect of several mycobacterium proteins annotated as hypothetical are yet to be discovered. In the present investigation, in silico approaches were used to predict the biological function of some of the unknown Mtb proteins, which were further validated by wet lab experiments. After screening thousands of Mtb proteins, functionally unknown hypothetical proteins Rv0421c, Rv0519c, Rv0774c, Rv1191, Rv1592c, and Rv3591c were chosen on the basis of their importance in Mtb life cycle. All these proteins posses the α/β-hydrolase topological fold, characteristic of lipases/esterases, with serine, aspartate, and histidine as the putative members of the catalytic triad. The catalytic serine is located in pentapeptide motif “GXSXG” and oxyanion residue is in dipeptide motif HG. To further support our observation, molecular docking was performed with conventional synthetic lipolytic substrates (pNP-esterss) and specific lipase/esterase inhibitors (tetrahydrolipstatin and phenylmethanesulfonyl fluoride (PMSF)). Significant docking score and strong interaction of substrates/inhibitors with these proteins revealed that these could be possible lipases/esterases. To validate the in silico studies, these genes were cloned from Mtb genome and the proteins were over-expressed in pQE-30/Escherichia coli M15 system. The expressed proteins were purified to homogeneity and enzymatic activity was determined using pNP esters as substrate. The enzyme activity of recombinant proteins was inhibited by tetrahydrolipstatin and PMSF pre-treatment. Outcome of the present investigation provided a basic platform to analyze and characterize unknown hypothetical proteins.     

Fungal Metabolism of trans-2-Octenoic Acid

Juvenile hormone esterases (JHEs) function in juvenile hormone (JH) degradation. In the silkworm, Bombyx mori, we have characterized authentic JHE (Bmjhe) and five other carboxyl/cholinesterase (CCE) genes (Bmcce-1 to -5) with GQSAG, a motif sequence of JHE. But none of the genes appeared to function in vivo as a JHE, except for Bmjhe. Recently it was reported that the GQSAG motif might be dispensable, and that the Thr-316 residue has functional significance for JHE activity. On the basis of these findings, we identified two novel JHE candidates, Bmcce-6 and Bmcce-7, that lack GQSAG but possess Thr-316. In the CCE phylogenetic tree, BmCCE-6 was close to the lepidopteran JHE cluster, while BmCCE-7 constituted the same cluster as pheromone-degrading esterases. The developmental expression profiles were different among Bmjhe, Bmcce-6, and Bmcce-7. None of the proteins hydrolyzed JH in vitro. Our results suggest that only one CCE (BmJHE) functions as JHE in the silkworm.     

An aromatic side chain is required at residue 8 of SU for fusion of ecotropic murine leukemia virus

The surface glycoprotein (SU) of most gammaretroviruses contains a conserved histidine at its amino terminus. In ecotropic murine leukemia virus SU, replacement of histidine 8 with arginine (H8R) or deletion of H8 (H8del) abolishes infection and cell-cell fusion but has no effect on binding to the cellular receptor. We report here that an aromatic ring side chain is essential to the function of residue 8. The size of the aromatic ring appears to be important, as does its ability to form a hydrogen bond. In addition, infection by all of the nonaromatic amino acid substitutions could be partially rescued by the addition of two suppressor mutations (glutamine 227 to arginine [Q227R] and aspartate 243 to tyrosine [D243Y]) or by exposure to chlorpromazine, an agent that induces fusion pores in hemifusion intermediates to complete fusion, suggesting that, like the previously described H8R mutant, the mutants reported here also arrest membrane fusion at the hemifusion state. We propose that H8 is a key switch-point residue in the conformation changes that lead to membrane fusion and present a possible mechanism for how its substitution arrests fusion at the hemifusion state.     

Fluorescent inhibitors for the qualitative and quantitative analysis of lipolytic enzymes

We report on the determination of active enzyme components in pure and crude lipases, using fluorescent inhibitors for covalent modification and visualization of the enzymatically active proteins. Lipase-specific compounds are triacylglycerol analogs, namely 1,2(2, 3)-di-O-alkylglyceroalkylphosphonic acid-p-nitrophenyl esters, containing a fluorescent substituent bound to the omega-end of an alkyl chain. Inhibitors derived from single-chain alcohols, such as p-nitrophenyl esters of fluorescent alkyl phosphonates, react with lipases and esterases. The p-nitrophenyl ester bond is susceptible toward nucleophilic attack by the active serine of the lipolytic enzyme. This reaction is stoichiometric, specific, and irreversible. Stable lipid-protein complexes are formed which can be analyzed on the basis of their fluorescent signal. From fluorescence intensity the moles of active serine (enzyme) were accurately determined. A lipase-specific inhibitor was used for the analysis of a commercial lipase preparation from Rhizomucor miehei. After incubation of the enzyme with the fluorescent lipid, a single fluorescence band was observed after SDS-gel electrophoresis, indicating the presence of a single lipase in the crude enzyme material. A linear correlation was obtained between fluorescence intensity and the amount of enzyme. Using a combination of different inhibitors, we were able to discriminate between lipases and esterases.     

Protein kinase C (PKC)-induced phosphorylation of ROMK1 is essential for the surface expression of ROMK1 channels

We carried out in vitro phosphorylation assays to determine whether ROMK1 is a substrate of protein kinase C (PKC) and used the two-electrode voltage clamp method to investigate the role of serine residues 4, 183, and 201, the three putative PKC phosphorylation sites, in the regulation of ROMK1 channel activity. Incubation of the purified His-tagged ROMK1 protein with PKC and radiolabeled ATP resulted in (32)P incorporation into ROMK1 detected by autoradiography. Moreover, the in vitro phosphorylation study of three synthesized peptides corresponding to amino acids 1-16, 174-189, and 196-211 of ROMK1 revealed that serine residues 4 and 201 of ROMK1 were the two main PKC phosphorylation sites. In contrast, (32)P incorporation of peptide 174-189 was absent. In vitro phosphorylation studies with ROMK1 mutants, R1S4/201A, R1S4/183A, and R1S183/201A, demonstrated that the phosphorylation levels of R1S4/201A were significantly lower than those of the other two mutants. Also, the Ba(2+)-sensitive K(+) current in oocytes injected with green fluorescent protein (GFP)-R1S4/201A was only 5% of that in oocytes injected with wild type GFP-ROMK1. In contrast, the K(+) current in oocytes injected with GFP-ROMK1 mutants containing either serine residue 4 or 201 was similar to those injected with wild type ROMK1. Confocal microscope imaging shows that the surface expression of the K(+) channels was significantly diminished in oocytes injected with R1S4/201A and completely absent in oocytes injected with R1S4/183/201A. Furthermore, the biotin labeling technique confirmed that the membrane fraction of ROMK channels was almost absent in HEK293 cells transfected with either R1S4/201A or R1S4/183/201A. However, when serine residues 4 and 201 were mutated to aspartate, the K(+) currents and the surface expression were completely restored. Finally, addition of calphostin C in the incubation medium significantly decreased the K(+) current in comparison with that under control conditions. Biotin labeling technique further indicated that inhibition of PKC decreases the surface ROMK1 expression in human embryonic kidney (HEK) cells transfected with ROMK1. We conclude that ROMK1 is a substrate of PKC and that serine residues 4 and 201 are the two main PKC phosphorylation sites that are essential for the expression of ROMK1 in the cell surface.     

Biochemical characterization of juvenile hormone esterases from lines selected for high or low enzyme activity inGryllus assimilis

In a previous study, activity of the insect endocrine regulator juvenile hormone esterase (JHE), in the cricketGryllus assimilis, was subjected to bidirectional selection. This resulted in three pairs of high- and low-selected lines, each of which differed by 3.5-fold in JHE activity. In the present study, juvenile hormone esterases from these lines were characterized with respect to the Michaelis constant (K _m), thermostability, and inhibition. None of three high-selected JHEs differed from its respective low-selected JHE in the Michaelis constant (K _m) for juvenile hormone. Similarly, the high-selected JHEs did not differ from the low selected JHEs in thermostability or inhibition by either of two general esterase inhibitors (DFP, eserine) or a “JHE-specific” inhibitor (OTFP). Thus no evidence was obtained to suggest that the response to selection was due to allozymes or isozymes with altered kinetic or stability properties. Kinetic and stability properties were also very similar for the JHEs from the three high-selected or the three low-selected lines. Finally, none of the thermostability or inhibition profiles for any of the six JHEs exhibited sharp discontinuities, thus providing no evidence for the existence of multiple isozymes. The available evidence points to genetically variable regulators which affect the synthesis, degradation, or tissue distribution of JHE as being responsible for the divergence in JHE activity between the selected lines.     

Proton-dependent electron transfer from CuA to heme a and altered EPR spectra in mutants close to heme a of cytochrome oxidase

Eukaryotic cytochrome c oxidase (CcO) and homologous prokaryotic forms of Rhodobacter and Paraccocus differ in the EPR spectrum of heme a. It was noted that a histidine ligand of heme a (H102) is hydrogen bonded to serine in Rhodobacter (S44) and Paraccocus CcOs, in contrast to glycine in the bovine enzyme. Mutation of S44 to glycine shifts the heme a EPR signal from g(z) = 2.82 to 2.86, closer to bovine heme a at 3.03, without modifying other properties. Mutation to aspartate, however, results in an oppositely shifted and split heme a EPR signal of g(z) = 2.72/2.78, accompanied by lower activity and drastically inhibited intrinsic electron transfer from CuA to heme a. This intrinsic rate is biphasic; the proportion that is slow is pH dependent, as is the relative intensity of the two EPR signal components. At pH 8, the heme a EPR signal at 2.72 is most intense, and the electron transfer rate (CuA to heme a) is 10-130 s(-1), compared to wild-type at 90,000 s(-1). At pH 5.5, the signal at 2.78 is intensified, and a biphasic rate is observed, 50% fast (approximately wild type) and 50% slow (90 s(-1)). The data support the prediction that the hydrogen-bonding partner of the histidine ligand of heme a is one determinant of the EPR spectral difference between bovine and bacterial CcO. We further demonstrate that the heme a redox potential can be dramatically altered by a nearby carboxyl, whose protonation leads to a proton-coupled electron transfer process.     

NMR analysis of site-specific mutants of yeast phosphoglycerate kinase. An investigation of the triose-binding site

Site-specific mutants of yeast phosphoglycerate kinase have been produced in order to investigate the roles of the 'basic-patch' residues, arginine 168 and histidine 170. The fully-conserved residue, arginine 168, has been replaced with a lysine (R168K) and a methionine (R168M) residue, while the non-conserved histidine 170 has been replaced with an aspartate (H170D). Comparison of the 500-MHz 1H-NMR spectra of the mutant proteins with that of wild-type phosphoglycerate kinase shows that the overall fold of the mutants remains essentially unaltered from that of the native enzyme. Results of NOE experiments indicate that there are only very minor changes in structure in the vicinity of the mutations. These mutations have also led to firm sequence-specific resonance assignments to histidines 62, 167 and 170. NMR studies of 3-phosphoglycerate binding show that decreasing the positive charge in the sequence 168-170 reduces the binding of this substrate (by about 15-fold and 4-fold for mutants R168M and H170D respectively). Mutant R168K binds 3-phosphoglycerate with an affinity about twofold less than that of the native enzyme. Significantly, the activity of mutant H170D, measured at saturating substrate concentrations, is unchanged from that of the wild-type enzyme. This indicates that this residue is not of major importance in the binding or reaction of 3-phosphoglycerate. The observation is in agreement with results obtained for the wild-type enzyme, which indicate that 3-phosphoglycerate interacts most strongly with histidine 62 and least strongly with histidine 170, as would be predicted from the X-ray crystal structure. Substitution of positively charged arginine 168 with neutral methionine (or positively charged lysine) does not cause a detectable change in the pKa values of the neighbouring histidine groups, in as much as they remain below 3. The results reported here indicate that the observed reduction in catalytic efficiency relates less to direct electrostatic effects than to the mutants' inability to undergo 3-phosphoglycerate-induced conformational changes.     

Three-dimensional structure of Erwinia chrysanthemi pectin methylesterase reveals a novel esterase active site

Most structures of neutral lipases and esterases have been found to adopt the common alpha/beta hydrolase fold and contain a catalytic Ser-His-Asp triad. Some variation occurs in both the overall protein fold and in the location of the catalytic triad, and in some enzymes the role of the aspartate residue is replaced by a main-chain carbonyl oxygen atom. Here, we report the crystal structure of pectin methylesterase that has neither the common alpha/beta hydrolase fold nor the common catalytic triad. The structure of the Erwinia chrysanthemi enzyme was solved by multiple isomorphous replacement and refined at 2.4 A to a conventional crystallographic R-factor of 17.9 % (R(free) 21.1 %). This is the first structure of a pectin methylesterase and reveals the enzyme to comprise a right-handed parallel beta-helix as seen in the pectinolytic enzymes pectate lyase, pectin lyase, polygalacturonase and rhamnogalacturonase, and unlike the alpha/beta hydrolase fold of rhamnogalacturonan acetylesterase with which it shares esterase activity. Pectin methylesterase has no significant sequence similarity with any protein of known structure. Sequence conservation among the pectin methylesterases has been mapped onto the structure and reveals that the active site comprises two aspartate residues and an arginine residue. These proposed catalytic residues, located on the solvent-accessible surface of the parallel beta-helix and in a cleft formed by external loops, are at a location similar to that of the active site and substrate-binding cleft of pectate lyase. The structure of pectin methylesterase is an example of a new family of esterases.