Glutamate oxalate transaminase (GOT) genetics in Mus musculus: Linkage,polymorphism, and phenotypes of the Got-2 and Got-1 loci

A comparison of electrophoretic patterns of F₁ and backcross progeny of two inbred strains of mice has revealed a new autosomal variant of the mitochondrial form of GOT. The loci controlling the production of the soluble and mitochondrial forms of GOT have been designated Got-1 and Got-2, respectively. The two alleles of the Got-2 locus have been designated Got-2 ^a and Got-2 ^b, which represent the slow- and fast-migrating electrophoretic forms. Twenty-seven inbred strains of mice have been classified for Got-2 ^a and Got-2 ^b. It has been demonstrated that the polymorphism of Got-2 is widely distributed in feral mice. Got-2 was shown to be linked to Es-1, and evidence is also presented for linkage between Got-2 and Es-2, Es-5, and oligosyndactyly (Os). The absence of linkage of Got-2 to seven other loci has also been demonstrated. GOT was expressed in vitro in cell lines derived from human and mouse tissues.     

Chromosomal location of soluble glutamic-pyruvic transaminase-1 (Gpt-1) in the mouse

Three alleles at the Gpt-1 (glutamic-pyruvic transaminase-1) locus in the mouse, as identified by electrophoresis on cellulose acetate, and their distribution among inbred mouse strains and wild stocks are described. The Gpt-1 locus was shown to control the soluble form of the enzyme. Three-point linkage analysis established the location of Gpt-1 on chromosome 15 between uw and bt. In addition, a new staining procedure is described that allows the visualization of GPT activity on gels by the deposition of formazan. This is an improvement over previous methods that produced bands of nonfluorescence against a fluorescent background.This investigation was supported in part by Research Grant GM 20919 from the National Institute of General Medical Sciences, and by contract NO1-ES-4-2159 with the National Institute of Environmental Health Sciences. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

Genetic control of two electrophoretic variants of glucosephosphate isomerase in the mouse (Mus musculus)

The autosomal variation and the genetic control of GPI has been determined by a comparison of electrophoretic patterns of F₁ and backcross progeny of three inbred strains of mice. The locus controlling the production of GPI in the mouse has been designated Gpi-1. Two alleles at this locus have been described and designated Gpi-1 ^a and Gpi-1 ^b, which represent, respectively, the slow and fast electrophoretic forms. Twenty-seven inbred strains of mice have been classified for these two alleles. The absence of close linkage of Gpi-1 to seven other genetic loci has been determined. It has been demonstrated that the polymorphism of Gpi-1 is widely distributed in feral mice. GPI was expressed in vitro and in four types of malignant tumors.Supported by U.S. Public Health Service Grants GM-09966, from General Medical Sciences, and GY 4193.     

Assignment of the gene locus for the sixth component (C6) of complement in mice to chromosome 15

A structural locus (C-6) for the sixth component of complement in mice is assigned to chromosome 15. Three-point linkage analysis indicated that the order of loci is C-6, Gpt-1, Gdc-1, and that the map distances are 25.9±4.9 between C-6 and Gpt-1, and 36.4±5.5 between C-6 and Gdc-1. Since Gdc-1 is more distal than Gpt-1, and C-6 is 26 cM away from Gpt-1, it is estimated that the C-6 is proximal to the centromere. In addition, a new C6 form found in AKR mice is described. We propose the designation C6B for it and C-6 ^b for the allele encoding C6B.Abbreviations used in this paper IEF isoelectric focusing - GPT glutamic-pyruvic transaminase - GDC L-glycerol 3-phosphate dehydrogenase - cM centimorgan     

Mapping of theHox-3.1 andMyc-1.2 genes on chromosome 15 of the mouse by restriction fragment length variations

Restriction endonuclease fragment length variations (RFLV) were detected by use of the cDNA probeHox-3.1 for the homeo box-3.1 gene and also thec-myc oncogene probe for exon 2. RFLV ofHox-3.1 were found inHindIII restriction patterns, and RFLV of theMyc-1.2 gene inEcoRV patterns. From the RFLV, theHox-3.1 andMyc-1.2 genes were mapped on chromosome 15. Three-point cross test data showed that the frequency of recombination is 26.4% betweenMyc-1.2 andGpt-1, 30.2% betweenGpt-1 andGdc-1, and 9.4% betweenGdc-1 andHox-3.1. The following order of these genes is proposed,Myc-1.2—Gpt-1—Gdc-1—Hox-3.1. All laboratory strains carry theHox-3.1 ^a andMyc-1.2 ^a alleles. Among strains of wild origin,domesticus strains carry only theHox-3.1 ^a andMyc-1.2 ^a alleles, as do the laboratory strains. One strain ofbrevirostris carries theHox-3.1 ^a andMyc-1.2 ^b alleles. Other wild subspecies from Europe and Asia,M. m. musculus, M. m. castaneus, M. m. molossinus, Chinese mice of wild origin, andM. m. yamashinai carry theHox-3.1 ^b andMyc-1.2 ^b alleles.     

Linkage studies on an esterase locus in the mosquito Aedes togoi

An electrophoretic survey of esterases in 7 wild-type and 10 mutant strains of the mosquito Aedes (Finlaya) togoi was undertaken using thin-layer agar gels. Three esterases (designated the Est-1, Est-2, and Est-3 loci in decreasing order of electrophoretic mobility) could be detected from fourth-instar larvae, pupae, and 2- to 5-day-old adults. Homogenates of the larvae gave the most intensely stained bands in the gels, especially for Est-3. The three esterases were designated carboxylesterases based on their response to the two esterase inhibitors, eserine and paraoxon (diethyl-p-nitrophenyl phosphate). The Est-3 locus was found to have five alleles including at least one null. The linkage results of six backcrosses suggest that Est-3 is located only 5–8 map units from the sex allele (m) and the gene arrangement is Est-3-m-s (straw-colored larva) in linkage group I.This work was supported by National Institutes of Health Grant AI 16983-01.     

Genetic control of the quantitative variation of erythrocytic glyoxalase-1 (GLO-1) in mice

Quantitative genetic variation in the glyoxalase-1 content (QGlo-1) of red cells of mice is described. Its genetic control is shown to be exerted by either the Glo-1 locus or a closely linked gene to the left of H-2K. At least six alleles, designated QGlo-1 ^a through QGlo-1 ^f, can be found in different inbred strains of mice.This work was supported in part by Grants HL 0911 and AI 15413 of the National Institutes of Health and by a grant from the Sally and Alma Solomon Foundation.     

Phosphoglucomutase electrophoretic variants in the mouse

The phosphoglucomutase (PGM) electrophoretic phenotype of the mouse (Mus musculus) consists of several distinct components which can be grouped into two major zones designated PGM-1 and PGM-2. Evidence presented here indicates that each zone is controlled by a single genetic locus denoted Pgm-1 and Pgm-2, respectively. Two variant forms segregated at the Pgm-1 locus. They were codominantly expressed and inherited as alleles at an autosomal locus. The alleles were termed Pgm-1 ^a (fast) and Pgm-1 ^b (slow). These alleles were separately fixed in a number of inbred strains of mice. Preliminary evidence based on wild mouse phenotypes indicates that variant forms also exist for PGM-2 which are inherited as alleles at an autosomal locus. Genetic linkage relationships have not been determined for these loci. PGM-1 variants and PGM-2 were expressed in mouse fibroblasts in vitro.Supported by U.S. Public Health Service grants GM-09966 and GM-07249 from General Medical Sciences and 5 F2 HD-35,531 from Child Health and Human Development; and Atomic Energy Commission contract AT(30-1)-3671.Postdoctoral Fellow of the U.S. Public Health Service.     

Phosphoglucomutase isozymes of red cells in Mus musculus: Additional polymorphism at PGM-1 compared by two electrophoretic systems

Phosphoglucomutase (PGM) of red cells was examined in 15 inbred strains of mice, using two different starch gel electrophoretic buffer systems. Two new alleles, Pgm-1 ^c and Pgm-1 ^d, were discovered at the Pgm-1 locus. Pgm-1 ^c was first identified in strain C3H/HeNWe and Pgm-1 ^d in 129/ReWl. No variation was observed at the Pgm-2 locus.Supported in part by USPHS Pre-doctoral Fellowship No. 5 F1 GM-32,680, USPHS Research Resources Grant No. 5-PO6 RR 00343-05, USPHS (National Cancer Institute) Chemotherapy Contract 71-2010, and Biomedical Sciences Support Grant FR 07037 to the University of Kansas.     

Genetics and ontogeny of alcohol dehydrogenase isozymes in the mouse: Evidence for a cis-acting regulator gene (Adt-1) controlling C2 isozyme expression in reproductive tissues and close linkage of Adh-3 and Adt-1 on chromsome 3

An electrophoretic variant previously reported for the stomach isozyme of alcohol dehydrogenase (ADH-C2) in inbred strains of Mus musculus (Holmes, 1977) has been used to localize the gene encoding this enzyme (Adh-3) on chromosome 3 near Va (varitint) (9.6 ± 3.6% recombinants). Genetic variation of ADH-C2 activity in male and female reproductive tissues among inbred strains and Harwell linkage testing stocks was also observed. Reproductive tissue ADH-C2 phenotypes were inherited in a normal Mendelian fashion among F₂ progeny of an F₁ (LII × C57BL/Go) × C57BL/Go backcross as though controlled by a single cis-acting regulator locus (designated Adt-1) with two alleles: Adt-1 ^a (presence of ADH-C2) and Adt-1 ^b (absence or low activity of ADH-C2). No recombinants were observed among 73 progeny or among 13 inbred strains and six Harwell linkage testing stocks of mice, indicating that Adh-3 and Adt-1 are closely linked or identical genes. A single recombinant phenotype was observed in Peru-Coppock mice, suggesting that they are separate genes. Ontogenetic analyses demonstrated that ADH-B₂ is present throughout development from late fetal stages in stomach, liver, and kidney; similar results were found for ADH-C2 in developing kidney and stomach extracts, whereas ADH-A2 exhibited high activity in liver extracts after 3 weeks of age in both sexes and in male kidney extracts after 6 weeks.     

Comparison of glucokinase in C3H/He and C58 mice that differ in their hepatic activity

Partially purified preparations of the hepatic glucokinase from C3H/He and C58 inbred mice have been used to explore the molecular basis for the observed twofold difference in activity between the strains. The single codominant gene that appears to regulate activity, the alleles of which are designated Gk^a and Gk^b, respectively, for the two strains, could represent a structural gene change. This now seems unlikely because the mouse enzyme, although showing small differences from rat glucokinase, appeared to be identical in the two strains with respect to thermal stability, electrophoretic mobility in agarose gels, and kinetic properties such as the apparent K _m values for MgATP^2– and glucose and the unique cooperative interaction with the latter substrate. The enzymes also reacted identically in a range of immunological tests (double-diffusion, immunoelectrophoresis, immune precipitation and immune inhibition assays) and ELISA immune inhibition assays indicated that the twofold difference in activity was due to a similar difference in antigenically active enzyme. Genetic control over the physiologically significant regulation of enzyme amount is therefore probable.This work has been supported in part by a grant from the British Diabetic Association and a Training Studentship to PAJ from the Medical Research Council (U.K.).     

Genetic control of LDH isozymes in the house fly,Musca domestica

Electrophoretic variations in lactate dehydrogenase from adult whole body homogenates are described for three laboratory strains of house fly, Musca domestica. Several crosses between different electrophoretic forms provided evidence that the observed variations are due to segregation of alleles at two distinct loci (designated as A and B loci) and that the LDH isozymes of house flies are dimers formed by a random association of subunits controlled by the two loci.     

Mapping of the MouseLy-6, Xp-14, andGdc-1 loci to chromosome 15

TheLy-6 locus is now regarded as a gene complex consisting of at least five closely linked loci (Ly-6A-Ly-6E) whose polymorphic products are identified by monoclonal antibodies and distinguished by different tissue distributions.Ly-6 has been assigned by other investigators to chromosome (Chr) 9 (linked toThy-1 or to Chr 2. We report that theLy-6 gene complex, together with theXp-14 andGdc -1 loci, is situated on Chr 15 linked toGpt1. These new linkage data are derived from four sources: (1) three separate crosses that failed to demonstrate linkage ofLy-6 to eitherThy-4 on Chr 9 or to any of five genes present on Chr 2; (2) the NXSM recombinant inbred strains, which suggested the linkage ofLy-6 andXp-14 toGpt-1 on Chr 15; (3) severalGpt-1 andGdc-1 congenic strains that confirmed the assignment ofLy-6 andXp-14 to Chr 15; and (4) backcrosses that further confirmed the linkage ofLy-6, Gpt-1, Gdc-4, andXp-14, the probable gene order beingGpt-11/Ly-6 Xp-14-Gdc-1.     

Glk: A locus controlling galactokinase activity in the mouse

Inbred strains of mice exhibit significant variation in whole blood galactokinase (GALK) activity. Activities tend to cluster into two classes, one class having approximately twice the activity of the other. Hybrids (F₁) between high and low strains have activity intermediate between the parental activities. Two sets of recombinant inbred (RI) lines were developed by brother-sister mating, beginning with F₂ generations of crosses between different pairs of high and low GALK activity strains. The RI lines segregated in terms of GALK activity, indicating single gene inheritance; this galactokinase locus has been designated Glk. The strain distribution patterns of both RI series agreed closely with esterase-3 (Es-3) alleles of the respective parental strains (31/34 independently derived strains were concordant for Es-3 and Glk genotypes), a finding consistent with a map distance between loci of 2.5 cM. Es-3 has been located on the distal end of chromosome 11. Glk, with its alleles Glk ^a (lower activity) and Glk ^b (higher activity), is therefore assigned to the same region.This project was supported by NIH Grants GM-02138 and GM-18684 from the National Institute of General Medical Sciences and HD-04861 and HD-00588 from the National Institute of Child Health and Human Development, and by a grant from the Clark Foundation, New York City. The Jackson Laboratory is fully certified by the American Association for Accreditation of Laboratory Animal Care.This work was carried out while J. D. M. was enrolled in the Summer Program for College, Graduate, and Medical Students at the Jackson Laboratory.     

Polymorphism of esterase 11 in Mus musculus,a further esterase locus on chromosome 8

A further esterase, esterase 11, which exhibits a polymorphism detectable by electrophoresis, has been observed in the house mouse, Mus musculus. In 15 inbred strains and two outbred strains, the ES-11A phenotype has been found, composed of two bands of enzyme activity of greater anodal electrophoretic mobility than the two bands of the ES-11B phenotype found in one inbred strain, one wild stock, and 101 wild mice. In F₁ hybrids (IS/Cam×C57 BL/Gr), the phenotype shown corresponds to a mixture of the two parental phenotypes. In backcrosses, ES-11 segregates as an autosomal gene, designated Es-11, closely linked to Es-2 and Es-5 on chromosome 8.This work was supported by the Medical Research Council.     

Electrophoretic heterogeneity of mouse erythrocyte peptidases

Starch gel electrophoresis in conjunction with a specific staining method revealed the occurrence of five distinct peptidases in mouse red blood cells. These enzymes can be distinguished on the basis of substrate specificity and electrophoretic mobility. They have been designated peptidases A, B, C, D, and E to correspond with the nomenclature adopted for human peptidases with which the mouse enzymes appear to be homologous. Genetically determined variants of peptidase C are described. The phenotype Pep C1 occurs in C57BL/Gr mice and the phenotype Pep C2 in CBA/Gr and Strong A/Gr mice. These phenotypes and the presumed heterozygote, Pep C2-1, appear to be due to the occurrence of codominant autosomal alleles which have been designated Pep-C ¹ and Pep-C ². F₁ and F₂ crosses show segregation in the expected Mendelian ratios. F₂ embryos and their placentae show the same electrophoretic pattern for peptidase C. The occurrence of a separate locus controlling the structure of each distinct peptidase is postulated.     

Purification and characterization of mouse alcohol dehydrogenase from two inbred strains that differ in total liver enzyme activity

Alcohol dehydrogenase activity in mouse liver homogenate-supernatants is 1.7 times greater in the C57BL/10 strain than in the BALB/c strain, regardless of whether activity is expressed in units per gram liver, total liver, or milligram DNA. The K _m values for ethanol and NAD⁺, approximately 0.4 and 0.03mm, respectively, of enzyme purified from both strains are similar. Moreover, the K _i for NADH, 1 µm, the pH optimum for ethanol oxidation, 10.5, and the V _max for ethanol oxidation, 160 min^–1, for ADH from the C57BL/10 and BALB/c strains are similar. Therefore, the difference in ADH activity in the two strains cannot be due to differences in the catalytic properties of the enzyme. The electrophoretic and isoelectric focusing patterns and two-dimensional tryptic peptide maps of the purified enzyme from both strains are identical. Thus the amino acid sequences of enzyme from C57BL/10 and BALB/c mice must also be identical or very similar. The difference in ADH activity in the two strains is most likely the result of genetic differences in the content of ADH protein in liver.Supported by NIAAA Grant AA 04307.     

Genetics of an esterase in Aedes aegypti

Zymograms of single individuals of Aedes aegypti were obtained by means of starch gel electrophoresis, using alpha-naphthyl acetate as substrate. Inbred lines gave consistently homogeneous patterns; earlier results from random-breeding laboratory strains had shown considerable variability. Six distinct bands were observed. The furthest moving band, designated Esterase 6, showed differential migration in two inbred lines. Reciprocal crosses between these lines gave F₁ progeny showing both bands. Backcrosses of F₁ to either parental line gave a 1:1 segregation. These results are consistent with the hypothesis that the two forms of Esterase 6 are controlled by a single pair of codominant alleles at a single gene locus (Est 6 ^a and Est 6 ^b). Linkage tests with marker genes have demonstrated that Est 6 is on linkage group 2, with the following alignment: spot-abdomen (9.0±1.0) yellow-larva (17.4±1.3) Est 6. Crosses with another inbred line demonstrated a third band with intermediate mobility, designated Est 6 ^c. An additional electrophoretic variant which seems to have a simple Mendelian basis was found in esterase band 1.This work was supported by NIH Research Grant No. A1-02753.     

Enzyme Activities in Urtica dioica: Effects of Daylength and Leaf Age on Glutamate Dehydrogenase, Aspartate Aminotransferase and Alanine Aminotransferase

Enzymes, important to protein synthesis, were investigated in young and old leaves of Urtica dioica. The plants, divided into two groups, were exposed to either 18-hour or 12-hour photo-periods. One group of plants from each photoperiodic regime was subjected to an irradiance of 28 W × m^-2, and the other group of plants to 42 W × m^-2. The enzymes investigated were glutamate dehydrogenase (GDH), aspartate aminotransferase (glutamate-oxaloacetate transaminase, GOT), and alanine aminotransferase (glutamate-pyruvate transaminase, GPT), GDH and GOT were determined by means of electrophoretic separation on polyacrylamide and spectrophotometric measurements. GPT was determined only by the latter method. Plants exposed to 18-hour photoperiods showed much higher GDH activity than did those exposed to 12-hour photoperiods. The activity of GDH also increased with leaf age. Besides one uniform NAD⁺-dependent GDH, two other NAD⁺-independent enzymes, showing GDH activity, were identified on polyacryl-amide gel electrophoresis. The distribution of NADH and NAD⁺-dependent GDH activity between young and old leaves was similar under different growth conditions. The activity of GOT was insensitive to environmental changes. The results regarding GPT indicate that this enzyme responded to different photoperiods in the same way as GDH. A correlation coefficient of 0.928 was obtained for the relationship between GDH and GPT activity.     

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.