Esterase-16 (ES-16) of the rat (Rattus norvegicus): Identification and genetic characterization

Esterase-16, an esterase present in lung and other tissues of the laboratory rat, has been characterized by its biochemical properties (electrophoretic mobility, substrate pattern, sensitivity to inhibitors) and genetic variation in 107 inbred strains and substrains including 14 RI strains. It was classified as a carboxylesterase (EC 3.1.1.1). The phenotype ES-16A (BN/Han and 63 other strains) was defined as a narrow electrophoretic band migrating between ES-1A and ES-13A, ES-16B (LEW/Han and 42 other strains) exhibited the same electrophoretic mobility as ES-16A but was distinguished by its extremely weak activity. Segregation of ES-16 in RI strains and backcrosses indicated linkage to linkage group V (LGV). The Es-16 locus was tentatively placed into esterase cluster 2 and homology with Es-7 of the house mouse is proposed.     

Lymph esterases of the house mouse (Mus musculus)--II. The role of esterase-2 in fat resorption

1. Intralipid infusion into the duodenum of Mus musculus was accompanied by changes in lymph and serum concentrations of two esterase isozymes, ES-1 and ES-2. Whereas ES-1 levels declined in both lymph and serum, ES-2 levels increased 5-fold in lymph within 120 min, and fell to a plateau 3- to 4-fold the fasting level; serum levels of ES-2 increased continually. 2. The changes in lymph ES-2 concentrations were paralleled by lymph triglyceride concentration during Intralipid infusion. Genetically determined differences in the concentration of two allozymes, ES-2B and ES-2D, were reflected in differences in lymph triglyceride levels. The lymph triglyceride concentration was strongly correlated with approximately the cube root of the lymph ES-2 concentration for both allozymes. 3. The source of lymph ES-2 during fat resorption was probably an intracellular jejunal pool; serum ES-2 also re-entered the lymph but this fraction was not influenced by fat resorption. 4. Purified chylomicrons possessed no esterase activity; however, it was postulated that ES-2 plays an essential role in fat resorption and is extruded with the primary chylomicrons from the enterocyte.     

Lymph esterases of the house mouse (Mus musculus)--I. Identification and possible origins of abdominal lymph esterases

1. Abdominal lymph was obtained from Mus musculus by cannulation of the thoracic duct: lymph esterases were identified by polyacrylamide gel electrophoresis. Seven known esterases (ES-1, ES-2, ES-5, ES-27, SE-I, SE-II and SE-III) and a newly described activity (SE-IV) were demonstrated, all of which were also present in serum. 2. Electrophoretic staining intensities indicated that the lymph esterases were less concentrated than the corresponding activities in serum, with the single exception of ES-2. This finding was supported by quantitative immunoelectrophoresis of ES-1 and ES-2 (two allozymes each). 3. The jejunum appeared to be the origin of lymph ES-2 by a comparison of organ distribution of the allozymes ES-2B and ES-2D and by monitoring the re-appearance of ES-2 in several organs, serum and lymph after total inhibition in vivo by bis-p-nitrophenyl phosphate.     

Esterase-18 (ES-18) of the house mouse (Mus musculus): Biochemical characterization and genetics of an allozyme system linked to chromosome 19

This study describes the biochemical characterization, genetic variation, and linkage of a codominantly inherited murine esterase, termed ES-18. The enzyme was identified by isoelectric focusing of supernatants obtained after centrifugation of tissue homogenates and subsequent staining for esterase using either alpha-naphthyl acetate or 4-methylumbelliferyl elaidate as substrate. ES-18 exhibited an organ-specific variation of the intensity pattern of bands as seen in kidney, spleen, and macrophages, respectively. Its activity was highly sensitive to inhibition by 1 mmol.liter-1 p-chloromercuriphenylsulfonate but was resistant to bis-p-nitrophenyl phosphate. Four allozymes could be distinguished in kidney supernatants obtained from the inbred strains C57BL/10Sn (ES-18A), MOLF/Ei (ES-18B), WLL/BrA (ES-18C), and CAST/Ei (ES-18D). The enzyme is shown to be controlled by a structural locus, Es-18, which resides on chromosome 19. The gene order Ly-1 - Got-1 - 4.7 +/- 1.6 - Es-18 is suggested.     

Genetic identification of non-specific esterases of the mouse cauda epididymidis and description of esterase-28, a new carboxylesterase isoenzyme (EC 3.1.1.1)

Twenty-five (25) electrophoretic bands with esterase activity were distinguished in supernatants of cauda epididymidis of DBA/2J mice. Twenty (20) of these were assigned to 10 genetically defined esterases (ES-1, ES-2, ES-3, ES-6, ES-7, ES-11, ES-14, ES-17, ES-19, ES-22) which were already known from investigations of other mouse tissues. Furthermore, ES-10 was identified in cauda supernatants after isoelectric focussing. A hitherto genetically undefined esterase was assigned to locus Es-28 which was expressed solely in the epididymis. Three phenotypes were distinguished: ES-28A was present in the majority of the inbred strains examined. ES-28B was observed in AKR/Han mice and ES-28C was found in SEG/1 mice.     

Esterase-26 (ES-26): Characterization and genetic location on chromosome 3 of an eserine-sensitive esterase of the house mouse (Mus musculus)

Genetic variation of a codominantly inherited esterase, designated ES-26, has been discovered in the house mouse using isoelectric focusing in polyacrylamide gels. The ES-26A phenotype (pI 8.2) was found in C57BL/10Sn. A/J showed the ES-26B phenotype (pI 7.8-7.9). A third phenotype, ES-26C (double-banded: pI's 8.1 and 8.3), was observed in SJL/J. ES-26 was detected only in liver, stomach, and small intestine. The enzyme was shown to be controlled by the presumed structural locus Es-26, located on chromosome 3. From a four-point cross, the gene order Car-2--6.2 +/- 2.7--Es-16--21.0 +/- 4.5--Es-26--13.6 +/- 3.8--Amy-1 was established.     

Esterase-23 (ES-23): Characterization of a new carboxylesterase isozyme (EC 3.1.1.1) of the house mouse,genetically linked to ES-2 on chromosome 8

Genetic variation of a carboxylesterase isozyme (EC 3.1.1.1) of the house mouse, designated ES-23, is described. ES-23 was found in kidney, liver, and intestine. The isozyme was resistant to inhibition by 10(-3) mol/liter eserine and was stained using alpha-naphthyl butyrate or 5-bromoindoxyl acetate as substrate. Five different phenotypes, ES-23A to ES-23E, could be distinguished by disc electrophoresis and by isoelectric focusing. ES-23 is controlled by a structural locus situated within the esterase gene cluster 2 on chromosome 8. An analysis of allele distribution among different strains suggested a separate structural locus for the isozyme, Es-23e, which is closely linked to the loci Es-2, Es-5, Es-7, and Es-11. Of the five phenotypes, only ES-23B was expressed in lung. This variation is apparently controlled by a cis-acting regulatory element, presumably a temporal locus, Es-23t, closely linked to the presumed structural locus Es-23e.     

Microsomal long-chain acyl-CoA thioesterase (carboxylesterase ES-4) is regulated by thyroxine

Long chain acyl-CoA thioesterase activity is mainly located in microsomes after subcellular fractionation of liver from untreated rats. The physiological function and regulation of expression of this activity is not known. In the present study we have investigated the effect of thyroxine on expression of carboxylesterase ES-4, the major acyl-CoA thioesterase of liver microsomes. Thyroidectomy of rats decreased the palmitoyl-CoA thioesterase activity to about 25% of normal activity. This decrease was accompanied by similar decreases at the protein and mRNA levels (31% and 57%, respectively, of controls). Treatment with thyroxine completely reversed the effect of thyroidectomy and resulted in elevated levels in both thyroidectomized and control rats. For reasons of comparison we also studied the possibility that ES-10 and ES-2, two other members of the same gene family, are affected by thyroxine. ES-10 was not changed at the protein or mRNA level by any of the treatments, while ES-2 expression in liver was decreased by thyroxine treatment. The data shows that changes in activity and expression of ES-4 correlate to thyroxine status in the rat suggesting a physiological regulatory role by this hormone. Since thyroxine regulates the expression of lipogenic enzymes, these results are consistent with a function for this microsomal acyl-CoA thioesterase in fatty acid synthesis and/or secretion, rather than in oxidative degradation of fatty acids.     

Esterase-17 (ES-17): Characterization and genetic location on chromosome 9 of a bis-p-nitrophenyl phosphate-resistant esterase of the house mouse (Mus musculus)

Genetic variation of a new codominantly inherited esterase, designated ES-17, has been discovered in the house mouse using isoelectric focusing in polyacrylamide gels. The ES-17 A phenotype (three bands; isoelectric points, betweenpH 5.55 andpH 5.90) was found in C57 BL/10Sn. LP/J possessed the Es-17B phenotype (three bands; isoelectric points,pH 5.05–5.55). ES-17 was present in all tissues examined, except for hemolysate and serum, and was most clearly expressed in the small intestine. Because of its reaction toward various substrates and inhibitors, ES-17 has tentatively been classified as acetyl esterase (EC 3.1.1.6). ES-17 was shown to be controlled by the structural locusEs-17, located on chromosome 9. From test-cross data, a gene order ofEs-17-8.7±2.5 map units-Mpi-1-10.2±2.7 map units-Mod-1 was established. This work was supported by the Deutsche Forschungsgemeinschaft (SFB 46). This is communication No. 35 of a research program devoted to the cellular distribution and genetics of nonspecific esterases.     

Microsomal long-chain acyl-CoA thioesterase (carboxylesterase ES-4) is regulated by thyroxine.

Long chain acyl-CoA thioesterase activity is mainly located in microsomes after subcellular fractionation of liver from untreated rats. The physiological function and regulation of expression of this activity is not known. In the present study we have investigated the effect of thyroxine on expression of carboxylesterase ES-4, the major acyl-CoA thioesterase of liver microsomes. Thyroidectomy of rats decreased the palmitoyl-CoA thioesterase activity to about 25% of normal activity. This decrease was accompanied by similar decreases at the protein and mRNA levels (31% and 57%, respectively, of controls). Treatment with thyroxine completely reversed the effect of thyroidectomy and resulted in elevated levels in both thyroidectomized and control rats. For reasons of comparison we also studied the possibility that ES-10 and ES-2, two other members of the same gene family, are affected by thyroxine. ES-10 was not changed at the protein or mRNA level by any of the treatments, while ES-2 expression in liver was decreased by thyroxine treatment. The data shows that changes in activity and expression of ES-4 correlate to thyroxine status in the rat suggesting a physiological regulatory role by this hormone. Since thyroxine regulates the expression of lipogenic enzymes, these results are consistent with a function for this microsomal acyl-CoA thioesterase in fatty acid synthesis and/or secretion, rather than in oxidative degradation of fatty acids.     

Biochemical and genetic characterization of esterase-27 (ES-27), the major plasma cholinesterase of the house mouse (Mus musculus)

Esterase-27A (ES-27A) was characterized in strain A/WySnA by a cascade of seven bands seen after disc electrophoresis of serum and subsequent staining for esterase. ES-27A catalyses the hydrolysis of thiocholine butyrate and is strongly inhibited by 100 microM tetraisopropyl pyrophosphamide (isoOMPA). Hence, the enzyme was concluded to be a cholinesterase EC 3.1.1.8. A heat-labile form termed ES-27B was represented by strain AKR/Han. From a three-point cross (AKR/Han, A/Wy) and a five-point cross (AKR/Han, SEG/1), the gene order on chromosome 3 was concluded to be centromere-Car-2-Es-26-Es-27-Amy-1-Adh-1.     

A Novel Substance Localizing on the Apical Surface of the Ectodermal and the Esophageal Epithelia of Sea Urchin Embryos

A new substance (ES-1) which localizes on the ectodermal and espophageal epithelia of sea urchin embryos was identified by a monoclonal antibody, McA ES-1. McA ES-1 recognized a 175 KDa protein of fertilized and 200 KDa in proteins of unfertilized egg-cortices. By indirect fluorescent antibody staining, ES-1 was found on the plasma membrane of fertilized eggs and in the cortical region of unfertilized eggs. ES-1 was not contained in the cortical granules and remained fixed in the cortex after centrifugation of unfertilized eggs for 30 min at 20,000 g. The polarized localization of ES-1 on the apical surface of ectodermal epithelial cells continued to the metamorphosis. It disappeared from mesenchyme cells and other migrating cells of the gastrula, while ES-1 was reexpressed in the presumptive esophagus to be connected with ectodermal epithelium. This may suggest a functional significance of ES-1 in establishment of cell polarity in the epithelium of larvae. In metamorphosing larvae and adults, the apical localization of ES-1 could no longer be found, and it was found in coelomocytes. From these findings, it is concluded that ES-1 was a novel surface substance of embryos and is probably phagocytosed at metamorphosis.     

Esterase-25(Es-25): Identification and characterization of a new kidney arylesterase of the house mouse,genetically linked toLy-18 on chromosome 12

Genetic variation of a codominantly inherited kidney esterase, designated ES-25, has been discovered in the house mouse using disc electrophoresis. The ES-25A phenotype was found in A strains, AKR, and BALB/c. ES-25B was found in C57BL strains and several other laboratory strains. The enzyme was shown to be controlled by a presumed structural locus, Es-25. The high concordance in 48 RI strains of Es-25 with Ly-18 indicated the location of Es-25 on chromosome 12. The gene order Es-25-Ly-18-D12Nyul-Pre-1 was proposed.     

Esterase-30 (ES-30) of the house mouse: Biochemical characterization and genetics of a new carboxylesterase isozyme linked to cluster-2 loci on chromosome 8

A new carboxylesterase isozyme (EC 3.1.1.1), designated ES-30, is described in mouse liver. Two phenotypes were distinguished, ES-30A, a possible null type, was found in SPE/Pas and in other lines derived fromMus spretus, and ES-30B was found in BALB/cJ and other laboratory inbred strains. ES-30B is characterized by a distinct electrophoretic band when stained using 5-bromoindoxyl acetate as the substrate. After isolation and purification from other esterases by ion-exchange chromatography and molecular sieving, the molecular mass was estimated by two independent methods to be 62 and 64 kDa, respectively. The activity of ES-30B is higher in adult males than in females and can be stimulatedin vivo by testosterone. The distribution of phenotypes on the progeny of a backcross series suggests a separate locus,Es-30, with the allele a for absence andb for presence of the isozyme. LocusEs-30 is shown to be closely linked toEs-2 and toEs-7 of cluster-2 on chromosome 8. The gene orderEs-9—Got-2—(Es-2, Es-7, Es-30) is suggested. This work was supported by the Deutsche Forschungsgemeinschaft. This is communication No. 72 of a research program devoted to the cellular distribution, genetics, and regulation of nonspecific esterases.     

Biochemistry and genetics of esterase-20 (ES-20), a second trimeric carboxylesterase of the house mouse (mus musculus). II. A unique recombination reveals ES-20 as a hybrid enzyme

A unique recombination is described between (Es-1, Es-6) and (Es-9, Es-22) within gene cluster 1 of the esterase gene region on chromosome 8 of the house mouse. This recombination established the gene order Es-1--Es-6--(Es-9, Es-22)--Got-2. A further 73 recombinations, from a total of 911 backcrosses, had taken place between cluster 1 and cluster 2. A distance between the clusters of 8.01 +/- 0.90% was calculated; the genes within the clusters appeared more tightly linked than previously assumed. ES-20 behaved anomalously following the recombination within cluster 1: homozygous descendants of the recombinant expressed a new form of ES-20. In vitro incubation of purified ES-6A3 and ES-9A generated ES-20A, revealing this esterase to be a hybrid of different cluster 1 gene products, Es-9 and possibly Es-6. This result satisfactorily accounted for the genetic finding, as well as a range of biochemical properties of ES-20.     

Biochemistry and genetics of esterase-20 (ES-20), a second trimeric carboxylesterase of the house mouse (Mus musculus). I. Purification and characterization of ES-20C1 from male kidney

ES-20 was isolated from male mouse kidney and purified 350-fold by ion-exchange chromatography, isoelectric focusing, and gel filtration. The resultant product was apparently homogeneous by the criteria of polyacrylamide gel electrophoresis and immunodiffusion and represented a major fraction of male mouse kidney esterase. Sodium dodecyl sulfate gel electrophoresis revealed the presence of a single subunit band, molecular weight 59,500; the molecular weight of the native protein was found to be 179,000. Titration of the active site yielded an equivalent weight of about 175,000. The enzyme was further characterized by its kinetic parameters for the hydrolysis of a series of 4-nitrophenyl esters and was classified as a carboxylesterase (EC 3.1.1.1). ES-20C1 bound to concanavalin A, indicating that it was a high-mannose-type glycoprotein; the role of terminal beta-N-acetylglucosamine residues in the carbohydrate side chains for stabilization of the quaternary structure of the trimer was revealed. Extensive biochemical and immunological similarities to ES-9C supported an earlier suggestion that the Es-9c gene product is a component of the ES-20C1 trimer.     

Phenylisothiocyanate and dansyl chloride precolumn derivatizations for the high-performance liquid chromatography analysis of the antitumoral agent ES-285 in dog plasma

Chromophor and fluorophor addition reactions involving phenylisothiocyanate (PITC) and dansyl chloride (DC) were optimized to adapt two high-performance liquid chromatography (HPLC) procedures designed for the accurate determination of the novel antitumoral agent ES-285 in Beagle dog plasma. ES-285 was reacted with PITC at 60 degrees C for 15 min in the presence of triethylamine. The dansyl derivative was obtained by reaction of ES-285 with dansyl chloride in a basic medium at 80 degrees C for 20 min. Both reactions also worked for ES-299, a compound structurally related to ES-285 which was used as internal standard. The treatment of ES-285 and ES-299 spiked plasma samples with a basic phosphate buffer and MeOH permitted the extraction of the drug from the matrix. The purification of the analytes was carried out by solid-phase extraction followed by precolumn derivatization with PITC and DC. The phenylisothiocyanate adducts were analyzed by isocratic HPLC with UV detection at 254 nm. The ES-285 and ES-299 derivatives were eluted from a C(18) column at approximately 6.9 and approximately 8.1 min, respectively. The eluent ACN-water (95:5, v/v) was delivered to the column at a flow-rate of 1 ml/min and the analysis was completed in 15 min. The dansyl derivatives were analysed by a two-HPLC column system with fluorescence detection and gradient elution. The column temperature was maintained at 40 degrees C. The analysis lasted 55 min with the elution of ES-285 and ES-299 derivatives at approximately 35.2 and approximately 37.9 min, respectively. The PITC- and DC-based procedures were characterized by limits of quantification of 20 and 15 ng/ml, respectively. Both procedures were validated according to the ICH and FDA guidelines. They were selective for ES-285 and provided accurate, precise and reproducible results. ES-299 was shown to be a suitable internal standard. The HPLC procedure involving derivatization with DC was more sensitive and permitted to process plasma sample volumes as low as 100 microl. On the other hand, the PITC-based procedure characterised by a quite similar LOQ permitted a higher throughput but implied the processing of a 500-microl plasma volume.     

癌基因EJ－ras在小鼠胚胎干细胞（ES－5）中的表达及其对ES－5细胞一些特征的影响

转基因动物在研究基因的功能、医药、畜牧业等方面有重要的应用。利用胚胎干细胞（ＥＳ）制作转基因动物,比传统的显微注射法有无可比拟的优点。但是,目前、只在小鼠中建立起了ＥＳ细胞系,在其它哺乳动物（包括家畜）中尚未建成。近来,人们开始探索：改变胚胎细胞的遗传物质（如：把外源基因导入胚胎细胞）是否有利于获得ＥＳ细胞系．在各种外源基因中,癌基因是值得尝试的基因。因为：（１）ＥＳ细胞的建系是使胚胎的ＩＣＭ细胞永生化的过程;（２）在体外利用癌基因转染可使许多原代培养细胞永生化;（３）ＥＳ细胞高表达一些原癌基因。我们用癌基因ＥＪ－ｒａｓ转染小鼠ＥＳ细胞,观察其对ＥＳ－５细胞一些特性（增殖、嵌合能力）的影响,以便选择合适的癌基因用于家畜ＥＳ细胞的建系。ＥＳ－５细胞通常培养在丝裂霉素处理的小鼠胚胎成纤维细胞（ＭＥＦ）上（Ｆｉｇ．Ａ）。转染用ＥＳ－５细胞培养在无饲养层细胞的、含有大鼠肝细胞（ＢＲＬ）的条件培养液ＤＭＥＭ中。ＥＪ－ｒａｓ基因克隆在真核表达载体ＰＳＶ２ｎｅｏ的ＢａｍＨＩ位点上、使用磷酸钙法转染ＥＳ－５细胞,Ｇ－４１８法筛选阳性克隆,得到的抗性克隆仍以集落形式生长（Ｆｉｇ．Ｂ）,选取５个较好的克隆（ＥＳ－ｒａｓ１,２,     

Identification and development of a genetically closely-linked carboxylesterase family of the mouse liver

Six carboxylesterase isozymes (viz. ES-1, ES-6, ES-9, ES-20, ES-22 and ES-24), governed by esterase gene cluster 1 on chromosome 8 of the house mouse, were identified electrophoretically in liver supernatants using their biochemical, genetic and developmental characteristics. ES-1 and ES-20 were expressed as liver-specific forms. The peri- and postnatal development of the six isozymes indicated that they were individually regulated at the genetic level, although the isozymes were regulated as a group when compared to genetically unrelated esterases. The concept of evolutionary divergence following repeated gene duplication of an ancestral esterase structural gene was extended to cover divergence of the temporal (regulatory) genes associated with the multigene family. Allelic variation of the temporal genes was more limited than that of the corresponding structural genes.     

19 A solution structure of the filarial nematode immunomodulatory protein,ES-62

ES-62, a protein secreted by filarial nematodes, parasites of vertebrates including humans, has an unusual posttranslational covalent addition of phosphorylcholine to an N-type glycan. Studies on ES-62 from the rodent parasite Acanthocheilonema viteae ascribe it a dominant role in ensuring parasite survival by modulating the host immune system. Understanding this immunomodulation at the molecular level awaits full elucidation but distinct components of ES-62 may participate: the protein contributes aminopeptidase-like activity whereas the phosphorylcholine is thought to act as a signal transducer. We have used biophysical and bioinformatics-based structure prediction methods to define a low-resolution model of ES-62. Sedimentation equilibrium showed that ES-62 is a tightly bound tetramer. The sedimentation coefficient is consistent with this oligomer and the overall molecular shape revealed by small angle x-ray scattering. A 19 A model for ES-62 was restored from the small-angle x-ray scattering data using the program DAMMIN which uses simulated annealing to find a configuration of densely packed scattering elements consistent with the experimental scattering curve. Analysis of the primary sequence with the position-specific iterated basic local alignment search tool, PSI-BLAST, identified six closely homologous proteins, five of which are peptidases, consistent with observed aminopeptidase activity in ES-62. Differences between the secondary structure content of ES-62 predicted using the consensus output from the secondary structure prediction server JPRED and measured using circular dichroism are discussed in relation to multimeric glycosylated proteins. This study represents the first attempt to understand the multifunctional properties of this important parasite-derived molecule by studying its structure.