Genetic control of two esterases of rat plasma (Rattus norvegicus)

Three electrophoretic variants of plasma esterase in the albumin zone, presumably carboxylesterase, have been demonstrated in 250 rats representing a laboratory population of Wistar rats. Electrophoretic variants of the enzyme are believed to be controlled by two codominant alleles at the autosomal locus referred to as Es-2. The variant of carboxylesterase represented by a fast-migrating single band on starch gel electrophoresis is determined by the gene named Es-2 ^a, whereas the slow-migrating variant, represented by two bands, is under control of the allelic gene Es-2 ^b. Animals with Es-2 ^a/Es-2 ^b genotype have three bands of carboxylesterase in the albumin zone. Genetically determined polymorphism of plasma esterase, presumably carboxylesterase, in the prealbumin zone was shown in both laboratory and wild populations of rats. Breeding tests suggest that the gene referred to as Es-1 ^a, responsible for the presence of carboxylesterase in the prealbumin zone, is inherited dominantly, whereas animals homozygous for the allele Es-1 ^b locked this esterase fraction.     

Esterase polymorphisms in Microtus ochrogaster: interaction and linkage

Three polymorphic loci have been identified in the prairie vole, Microtus ochrogaster. Together they control a group of plasma esterases which can be separated using starch gel electrophoresis. A structural locus, Es-1, produces an enzyme which from genetic evidence appears to be a dimer. The allele Es-1 ^a produces a wholly active subunit, and homozygotes give a single enzyme band. The product of the second allele, Es-1 ^o, cannot form active enzyme on its own but will dimerize with the Es-1 ^a subunit, giving a hybrid enzyme with a slower electrophoretic mobility than the pure Es-1 ^a enzyme. The third allele, Es-1 ^–, has no detectable product. A second structural locus, Es-2, is linked to Es-1. The allele Es-2 ^a produces a single enzyme band, but the second allele Es-2 ^– has no detectable product. A modifier locus, Me, changes the mobility of the Es-1 enzymes. Me ^f is dominant over me ^s, and in homozygotes for me ^s the mobility is reduced.This work was supported by National Science Foundation Grant GB6273.This is contribution No. 869 from that Department.     

Es-6, a further polymorphic esterase in the rat

A further polymorphic rat esterase with broad tissue expression and restricted substrate specificity is described and tentatively called Es-6. Inbred rat strains have either fixed allele Es-6^F or fixed allele Es-6^S. Es-6 is not linked to the established esterase cluster consisting of the eight esterase loci Es-1, Es-2, Es-3M, Es-4M, Es-4W, Es-5 (=Es-3W), Es-7, and Es-8 in LG V of the rat or to RT1, Gc, c, a, and h. Esterases with apparently identical biochemical and genetical characteristics are Es-17 of the mouse and Es-A4 of humans.Supported by the Deutsche Forschungsgemeinschaft (Be 352/13 and Gu 105).     

Esterase 13, a new mouse esterase locus with recessive expression and its genetic location on chromosome 9

A new esterase locus (Es-13) has been identified in Mus musculus. Strains AEJ/GnRk, LG/J, SJL/J, and SWR/J carry a recessive allele, Es-13 ^b, for a locus possibly involved in the posttranslational modification of a kidney esterase. All other strains observed carried the dominant Es-13 ^a allele. Es-13 was mapped on Chr 9 by recombinant inbred lines and by conventional backcrossing experiments. Backcross data produced the following gene order and map distances: Lap-1 (31.6±7.5 cM) Es-13 (2.6±2.6 cM) Mod-1.     

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.     

Genetic variation and biochemical properties of esterase-18 (ES-18) in the laboratory rat (Rattus norvegicus): A new locus of esterase cluster 2 in linkage group V

A new liver-specific rat carboxylesterase isozyme (EC 3.1.1.1) designated esterase-18 (ES-18) is described. Genetic variation of ES-18 was examined in 93 inbred strains and substrains and a structural locusEs-18 was suggested, coding for either the presence (Es-18 ^a) or the absence (Es-18 ^b) of the isozyme. Linkage studies involving two backcross series revealed thatEs-18 resides in cluster 2 of LGV. No recombination betweenEs-18 and other cluster 2 loci was found in 19 lines of two RI strain sets or in the backcross series.R. K. was supported by the Sonderforschungsbereich 146 (Versuchstierforschung). O.D. was supported by the Deutsche Forschungsgemeinschaft (De 315/2). This is communication No. 65 of a research program devoted to the cellular distribution, regulation, and genetics of nonspecific esterases.     

Genetics of formamidase-5 (brain formamidase) in the mouse: Localization of the structural gene on chromosome 14

A single formamidase, which is different from the formamidases found in other tissues, occurs in the brains of mice. This enzyme is here called formamidase-5 and the gene symbol is designated For-5. Two alleles are recognized on the basis of their differential heat sensitivity: For-5 ^b is relatively heat stable and is present in strain C57BL/6J, while For-5 ^d is relatively heat sensitive and is present in strain DBA/2J. The heat sensitivity of formamidase-5 in 44 other inbred strains and substrains was tested and found to resemble that of C57BL/6J or DBA/2J. Thirty-six recombinant inbred strains derived from progenitors that differed at For-5 were studied to test for single-gene inheritance and linkage with other loci. Complete concordance was found with the esterase-10 locus (Es-10), indicating close linkage. The 99% upper confidence limit of the distance between For-5 and Es-10 is 3.7 centimorgans (cM). Es-10 is located on chromosome 14 about 19 cM from the centromere. An independent demonstration of linkage of For-5 with Es-10 and another chromosome 14 marker, hairless (hr), is provided by the finding that the HRS/J strain, which has been sibmated for 60 generations with forced heterozygosity at the hr locus, is cosegregating at For-5 and Es-10. A survey of 32 inbred strains and substrains revealed that the For-5 ^d allele is associated with the Es-10 ^b allele, and that the For-5 ^b allele is associated with Es-10 ^a and Es-10 ^c. Formamidase-5 segregates as expected in the F₂ generation of crosses between strains bearing For-5 ^b and For-5 ^d alleles. It is possible that this unique formamidase of the brain is involved in the metabolism of a neurotransmitter substance.This research was sponsored in part by the Department of Energy under contract with the Union Carbide Corporation and in part by NIH Research Grant GM-18684 from the National Institute of General Medical Sciences. J. C. F. is a predoctoral Fellow supported by Grant CA 09104 from the National Cancer Institute. The Biology Division of Oak Ridge National Laboratory and the Jackson Laboratory are fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

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.     

Identification of a new allele of Es-1 segregating in an inbred strain of mice

A new allele of Es-1, designated Es-1 ^e, has been identified in the mouse. This allele was discovered segregating among the progeny of a strain DBA/2J male and is apparently the result of a spontaneous mutation within this strain. Genetic analyses have shown that this mutation is heritable and, further, that both heterozygous and homozygous progeny are viable and fertile. To date, no discernible deleterious effects have been identified as associated with this mutation.     

Esterase-29 (ES-29): Biochemical characterization and control by two independent gene loci of a testosterone-dependent mouse serum esterase

Biochemistry and genetics of a testosterone-dependent murine serum esterase designated esterase-29 (ES-29) are described. The enzyme was identified after disc electrophoresis and subsequent staining for esterase using -naphthyl acetate as the substrate. It was inhibited by bis-p-nitrophenyl phosphate and was resistant top-chlorophenylsulphonate and hence was classified as carboxylesterase EC 3.1.1.1. The molecular mass was estimated to be about 130 kDa. It was shown that ES-29 is under the control of two independent genes. The first, termed Es-29, is suggested to be a structural locus, linked to the cluster-2 esterase loci on chromosome 8. Three alleles atEs-29, Es-29 ^a, Es-29^b, andEs-29 ^care distinguished, which determine absence (SEG/1), strong activity (BALB/cJ), and low activity (MOLH/Fre), respectively. The second locus, termedMse-1 (serum esterase modifying factor), was found to be closely linked toPre-2 on chromosome 12 and is suggested to be a modifying or regulatory gene. Two alleles were distinguished,Mse-1 ^a(BALB/cJ) andMse-1 ^m(MOL3/JA, CasBgr), which determine whether ES-29 appears as a single band or a double band, respectively.Mse-1 ^mis dominant toMse-1 ^a.This work was supported by the Deutsche Forschungsgemeinschaft. This is communication No. 70 of a research program devoted to the cellular distribution, genetics, and regulation of nonspecific esterases.     

New polymorphisms of esterase 7 and esterase 8 in inbred strains of rats: Tissue expression and linkage studies

Two new esterase polymorphisms (Es-7 and Es-8) were identified in the testis homogenate of laboratory rats, Rattus norvegicus, by using discontinuous gradient polyacrylamide gel electrophoresis. Es-7 expressed two phenotypes: ES-7A (fast) and ES-7B (slow). Es-8, which migrated in the cathodal region rather than the ES-7 region, also expressed two phenotypes: ES-8A (fast) and ES-8B (slow). Linkage tests among Es-2, Es-7, and Es-8 were made from backcross progeny of the mating (LEJ/Hkm × T/Hok)F₁ × LEJ/Hkm. One recombinant in 51 progeny tested was observed between Es-2 and Es-7; however, recombination between Es-2 and Es-8 was not observed in the same progeny. In addition, we show that the esterase polymorphisms of Es-5 in liver homogenate and Es-3 in small intestine homogenate are identical.     

A biochemical and ecological study of plasma esterase polymorphism in natural populations of the field vole,Microtus agrestis L.

Starch gel electrophoresis of plasma from wild individuals of Microtus agrestis L., the field vole, has revealed widespread polymorphism for the presence or absence of a particular esterase, referred to as E₁. The active forms of the enzyme hydrolyze a wide range of substrates and are resistant to inhibition by eserine, the organophosphate Diazinon, and to appropriate heat treatment. Breeding tests suggest four alleles: Es-1 ^o which, when homozygous, results in complete absence of enzyme activity; Es-1 ^a andEs-1 ^b which control equal activity but differences in electrophoretic mobility; and Es-1 ^c which has double the activity of either Es-1 ^a or Es-1 ^b ,but the same mobility as Es-1 ^a .A sensitive method has been developed of measuring E₁ activity in free solution, with interfering effects of other esterases being eliminated by differential inhibition. Quantitative estimates of activity in laboratory-reared voles of known ages and genotype showed that homozygotes and heterozygotes can be separated with a fair degree of confidence. There is a small but significant negative regression of activity on age. No sex differences have been detected. There is evidence of residual variation in activity of uncertain origin. Comparison of phenotype frequency in widely separated Scottish populations suggests that the polymorphism is balanced. Phenotypic frequencies have been systematically studied in natural populations in relation to ecology, season of the year, and the cycle of population density. There is strong evidence of a population-density-dependent selection in favor of animals without E₁ enzyme activity, judged by the difference in frequency before and after the peak density. There is also evidence of selection in the opposite direction due to differences in survival during the winter. These opposing selective pressures are believed to contribute to the polymorphism, although other factors are not excluded.     

Heterogeneity of Es-1 esterases in the rabbit (Oryctolagus cuniculus)

Analysis of the Es-1 system in the rabbit with polyacrylamide gel electrophoresis (PAGE) revealed a high degree of individual variation. In the liver the number of esterase bands found in the Es-1 region of the gels ranged from 2 to 16. The results indicate that one locus with three alleles is responsible for all of the esterase bands in the Es-1 region. The most plausible explanation for the observed heterogeneity is that each of the alleles codes for a protein (MW 65,000±2000) that is changed by posttranslational modifications, thus giving rise to two to five monomeric enzymes with esterase activity. Polymerization of these monomers then results in 1–11 dimers. Based on similarities with mouse Es-9, chromosomal homology between rabbit Es-1 and mouse Es-9 is proposed.     

Esterase-16 (Es-16): Characterization,polymorphism, and linkage to chromosome 3 of a kidney esterase locus of the house mouse

A polymorphism for an isozyme of a presumed arylesterase, esterase-16 (EC 3.1.1.2), has been detected in kidney, heart, and spleen of the house mouse, Mus musculus, by means of isoelectric focusing and by disc electrophoresis. Three phenotypes can be distinguished: the ES-16A phenotype (IEP 5.9) was found in C57BL/10Sn and many other laboratory inbred strains; the ES-16B phenotype (IEP 6.1) was found in M. m. molossinus; and the ES-16C phenotype (IEP 5.9; very weak activity) was found in Peru-Coppock. Esterase-16 is strongly inhibited by 10^?3 m p-chloromercuribenzoate, but not by 2·10^?4 m bis-p-nitrophenyl phosphate or by 10^?3 m Diamox. It stains well with indoxyl acetate and other indigogenic substrates but only weakly with α-naphthyl acetate. Esterase-16 is completely insoluble in water. It is apparently governed by a structural gene locus, Es-16, with three alleles, Es-16 ^a , Es-16^b, and Es-16 ^c, respectively. Es-16 is closely linked to Car-1 and Car-2 on chromosome 3. Typing of 94 animals of the backcross (C57BL/10Sn × M. m. mol.) F₁ × M. m. mol. revealed a recombination frequency of 8.51±2.9%.     

Genetic study of pancreatic proteinase in mice (Mus musculus): Linkage of the Prt-2 locus on chromosome 8

The Prt-2 locus is linked with Es-1 and Es-2 loci on chromosome 8 (linkage group XVIII). Recombination frequencies were 8.2% between Es-1 and Es-2, 12.7% between Es-1 and Prt-2, and 4.5% between Es-2 and Prt-2. From these data, the map position of Prt-2 has been estimated on chromosome 8. The Prt-1 and Prt-3 loci, which are linked very closely on the same chromosome, were not determined.     

Restriction fragment length polymorphism and chromosome mapping of a mouse homeo box gene,Hox-2.1

Restriction endonuclease fragment length polymorphisms (RFLPs) were found using the cDNA probe Hox-2.1 for the homeo box-2.1 gene in the mouse. Polymorphism was detected in restriction patterns generated by fragments fromHindIII digestion. The great majority of laboratory strains of mice carries theHox-2.1 ^a allele. Only two laboratory strains carry theHox-2.1 ^b allele. Among strains of wild origin, the European subspecies (Mus m. domesticus, M. m. brevirostris, andM. m. musculus) and some Asian subspecies (M. m. castaneus) carry theHox-2.1 ^a allele. The subspecies from Far Eastern countries (M. m. molossinus, Chinese mice of wild origin, andM. m. yamashinai) carry theHox-2.1 ^ballele. Using the RFLP, theHox-2.1 gene was mapped on chromosome 11. Three-point cross test data showed that the recombination frequency is 29.6% between theHba and theHox-2.1 genes and 23.5% between theHox-2.1 and theEs-3 genes. The gene order ofHba-Hox-2.1-Es-3 has been confirmed.     

Polymorphism of the Hereditary Sigma Virus in Natural Populations of DROSOPHILA MELANOGASTER

Previous studies have shown that, in natural French populations of Drosophila melanogaster, 10 to 20% of the flies are infected by the noncontagious, hereditary rhabdovirus sigma responsible for CO₂ sensitivity. These populations are also polymorphic for two alleles [ref(2)P^o and ref(2)P^p] of a gene for resistance to the sigma virus. Evidence is given here that two viral genetic types, differing in their response to the ref(2)P^p allele, are present in these populations of flies; the most common type is only slightly sensitive to the ref(2)P^p allele.     

Linkage analyses among five esterase loci in the laboratory rat (Rattus norvegicus)

A cluster of esterase loci has been identified on a segment of a rat linkage group V; however, the linear order of all the loci has not been established. We estimated the recombination frequencies of two locus combinations among five esterase loci (Es-1, Es-2, Es-3, Es-4, and Es-Si) and the linear order of the loci by using three sets of backcross matings: (1) (K:W × IS) × IS, (2) (K:W × IS) × IS, and (3) (SHR × W) × W). The linear order was determined to be Es-1-Es-4-Es-2-Es-3-Es-Si, although the order of Es-2 and Es-4 remains tentative. The sexinfluenced esterase (Es-Si) was demonstrated to be distinct from Es-1 and was proposed to be Es-Si locus with two alleles of Es-Si ^a (positive) and Es-Si ^b (null).This work was partly supported by Grants-in-Aid for Scientific Research, No. 339020 (1978), from the Ministry of Education, Science and Culture, Japan.     

Mechanism of Inhibition by C-terminal α-Helices of the ? Subunit of Escherichia coli FoF1-ATP Synthase

The ϵ subunit of bacterial F_oF₁-ATP synthase (F_oF₁), a rotary motor protein, is known to inhibit the ATP hydrolysis reaction of this enzyme. The inhibitory effect is modulated by the conformation of the C-terminal α-helices of ϵ, and the “extended” but not “hairpin-folded” state is responsible for inhibition. Although the inhibition of ATP hydrolysis by the C-terminal domain of ϵ has been extensively studied, the effect on ATP synthesis is not fully understood. In this study, we generated an Escherichia coli F_oF₁ (EF_oF₁) mutant in which the ϵ subunit lacked the C-terminal domain (F_oF₁^ϵΔC), and ATP synthesis driven by acid-base transition (ΔpH) and the K⁺-valinomycin diffusion potential (ΔΨ) was compared in detail with that of the wild-type enzyme (F_oF₁^ϵWT). The turnover numbers (k_cat) of F_oF₁^ϵWT were severalfold lower than those of F_oF₁^ϵΔC. F_oF₁^ϵWT showed higher Michaelis constants (K_m). The dependence of the activities of F_oF₁^ϵWT and F_oF₁^ϵΔC on various combinations of ΔpH and ΔΨ was similar, suggesting that the rate-limiting step in ATP synthesis was unaltered by the C-terminal domain of ϵ. Solubilized F_oF₁^ϵWT also showed lower k_cat and higher K_m values for ATP hydrolysis than the corresponding values of F_oF₁^ϵΔC. These results suggest that the C-terminal domain of the ϵ subunit of EF_oF₁ slows multiple elementary steps in both the ATP synthesis/hydrolysis reactions by restricting the rotation of the γ subunit.     

CONTROL OF 5S RNA SYNTHESIS DURING EARLY DEVELOPMENT OF ANUCLEOLATE AND PARTIAL NUCLEOLATE MUTANTS OF XENOPUS LAEVIS

Ribosomes of all eukaryotes contain a single molecule of 5S, 18S, and 28S RNA. In the frog Xenopus laevis the genes which code for 18S and 28S RNA are located in the nucleolar organizer, but these genes are not linked to the 5S RNA genes. Therefore the synthesis of the three ribosomal RNAs provides a model system for studying interchromosomal aspects of gene regulation. In order to determine if the synthesis of the three ribosomal RNAs are interdependent, the relative rate of 5S RNA synthesis was measured in anucleolate mutants (o/o), which do not synthesize any 18S or 28S RNA, and in partial nucleolate mutants (p^l-1/o), which synthesize 18S and 28S RNA at 25% of the normal rate. Since the o/o and p^l-1/o mutants have a complete and partial deletion of 18S and 28S RNA genes respectively, but the normal number of 5S RNA genes, they provide a unique system in which to study the dependence of 5S RNA synthesis on the synthesis of 18S and 28S RNA. Total RNA was extracted from embryos labeled during different stages of development and analyzed by polyacrylamide gel electrophoresis. Quite unexpectedly it was found that 5S RNA synthesis in o/o and p^l-1/o mutants proceeds at the same rate as it does in normal embryos. Furthermore, 5S RNA synthesis is initiated normally at gastrulation in o/o mutants in the complete absence of 18S and 28S RNA synthesis.