Purine nucleoside phosphorylase (Np) in the mouse: Linkage relationship of Np-2 to esterase-10 (Es-10) and Np-1 on chromosome 14

An improved method for detecting four Np-1 (purine nucleoside phosphorylase) alleles in mouse erythrocytes by cellulose acetate electrophoresis is described. The previous linkage of Np-1 and Es-10 (esterase-10) was confirmed, with a map distance of 13.0±2.6 cM. Np-2 was detected by either specific activity assay or starch gel electrophoresis and shown to be linked to Es-10, 15.9 ± 3.1 cM, on chromosome 14. No recombinants between Np-1 and Np-2 were observed in 52 offspring, indicating either that these loci are either closely associated or that Np-2 represents simply a property of existing allelic products of the Np-1 locus.This research was supported by Medical Research Council of Canada grants to F.G.B. and F.F.S.     

Liver-specific lysosomal acid phosphatase deficiency (Apl) on mouse chromosome 17

Summary Apl, a gene involved in the processing of lysosomal acid phosphatase in mouse liver, has been mapped on Chromosome 17. The gene order and map distances in per cent recombination of the loci studied are T (20.6±3.4) Pgk-2 (7.4±2.2) Apl. Thus, Apl is at least 7 cM distal to H-2 on this chromosome. In addition, strain-specific allelic variants for Apl have been demonstrated on cellulose acetate gels, a quick and inexpensive method of electrophoresis.This work was supported by Contract NO1-ES42159 with the National Institute of Environmental Health Sciences, Grant 1–476 from the National Foundation, March of Dimes, and Grant GM 20919 from the National Institute of General Medical Sciences. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care     

Linkage of the locus for conversion of albumin (Acf-1)in the house mouse,Mus musculus

The linkage of the locus for conversion of albumin (Acf-1) has been established on chromosome 1 with the following gene order and recombination percentages: Id-1 19.3±5.2% Acf-1 4.2±1.7% Dip-1 18.4±4.2% Lp.This work was supported by NIH Postdoctoral Fellowship 1F32 GM0527701, Grant BMS75-03397 from the National Science Foundation, Grant ACS VC-17-R from the American Cancer Society, and Contract NO1-ES42159 from the National Institute of Environmental Health Sciences. The Jackson Laboratory is fully accredited by the American Association for the Accreditation of Laboratory Animal Care.     

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.     

Comparative Autosomal Linkage in Mammals: Genetics of Esterases in MUS MUSCULUS and RATTUS NORVEGICUS

Recombination between Esterase-4 and Esterase-2 in the rat was not observed in 278 backcross offspring. Es-4 is thus included within the "esterase cluster" in Linkage group V. A new map of this region was constructed and the relationship of the four esterase loci was found to be: Es-4-(9.6+/-1.6 cM)-Es-2, Es-4-(1.5+/-0.7cM)-Es-3. Homology of this region with a region of Linkage Group XVIII (Chromosome 8) of the mouse was proposed on the basis of tissue distribution, subcellular localization and response of enzymes to inhibiotrs. Specifically, rat Es-1 was suggested as the homolog of mouse Es-6. An autosomal segment comprising at least 15cM of the rat and mouse genomes appears to have remained relatively intact with respect to genetic content during rodent speciation. In addition, a new polymorphism for mouse esterase was described. The locus was designated Esterase-10 (Es-10) and proposed as the mouse homolog of human Esterase D. Linkage of Es-10 with nucleoside phosphorylase-1-(Np-1) on Chromosome 14 was established.     

ABRUPT CLINE FOR SEX CHROMOSOMES IN A HYBRID ZONE BETWEEN TWO SPECIES OF MICE

We compared the patterns of movement of sex chromosomal and autosomal loci along a 160 km transect across a zone of hybridization between M. domesticus and M. musculus in southern Germany and western Austria using seven genetic markers. These included one Y-specific DNA sequence (YB10), two X-specific loci (DXWas68 and DXWas31), and four autosomal isozyme loci (Es-10, Es-1, Mpi-1, and Np-1). Random effects logistic regression analysis enabled us to examine the relationship between M. domesticus allele frequency and geographic distance from the western edge of the hybrid zone and allowed statistical evaluation of differences in cline midpoint and width among loci. More limited movement was observed for all three sex chromosomal markers across the zone compared with three of the four autosomal markers. If differential movement reflects fitness differences of specific alleles (or alleles at closely linked loci) on a hybrid background, then alleles that move to a limited extent across a hybrid zone may contribute to hybrid breakdown between two species. The limited flow of both X- and Y-specific alleles suggest that sex chromosomes have played an important role in Mus speciation.     

Biochemical genetics of Es-14 (formerly Es-Si) and a new esterase variation,Es-15, of the laboratory rat (Rattus norvegicus): Biochemistry,tissue expression,and linkage to Es-1 in linkage group V

The segregation of rat esterases controlled by loci residing in linkage group V (LGV) has been studied in two backcross series, (LEW/Han × BN/Han)F₁ × LEW/Han and (LEW/Han × LE/Han)F₁ × LEW/Han. Es-14 (formerly Es-Si) was shown to be closely linked to Es-1. A new esterase locus, Es-15, was described which codes for a liver isozyme. The distribution pattern of three alleles at the Es-15 locus is presented for 52 independent inbred strains. Close linkage of Es-15 to Es-14 and to Es-1 was established, proposing the following gene order: [Es-2, Es-10]—[ES-1, ES-14, ES-15]. The esterase loci on LGV are thus separated into two gene clusters, cluster 1 and cluster 2. These conclusions are supported by the strain distribution patterns of the two RI strain series, LXB and DXE.Otto von Deimling was supported by the Deutsche Forschungsgemeinschaft (De 315/2-1, communication No. 56).     

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.     

An acid phosphatase locus expressed in mouse kidney (Apk) and its genetic location on chromosome 10

A genetic locus controlling the electrophoretic mobility of an acid phosphatase in mouse kidney is described. This locus, called acid phosphatase-kidney (Apk), is not expressed in erythrocytes, liver, spleen, heart, lung, brain, skeletal muscle, stomach, or testes. The product of Apk hydrolyzes the substrate naphthol AS-MX phosphoric acid but is not active on a-naphthylphosphate or 4-methylumbelliferylphosphate. It is not inactivated by 50 C for 1 hr, nor is its electrophoretic mobility altered by incubation with neuraminidase. The locus is invariant among 31 inbred strains (Apk ^a), with a variant allele (Apk ^m) observed only in Mus musculus molossinus. Codominant expression was observed in F₁ hybrids of M. m. molossinus and inbred strains. Apk was mapped on Chr 10, near the neurological mutant waltzer (v).This work was supported by Contract NO1-ES42159 from the National Institute of Environmental Health Sciences and by Grant 1-476 from the National Foundation—March of Dimes. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

Histidine decarboxylase phenotypes of inbred mouse strains: A regulatory locus (Hdc) determines kidney enzyme concentration

Mouse kidney histidine decarboxylase (HDC) provides a model system to study genetic control of a hormone-regulated enzyme (inducible by estrogen and thyroxine; repressible by testosterone). Five major HDC phenotypes scored on the basis of (i) enzyme activity and (ii) the difference in activity between the sexes (females usually higher than males) have been discovered by screening 38 strains of mice. One genetic difference between high-activity strains (DBA/2 and C3H/He) and low-activity strains (C57BL/6 and C57BL/10) has been examined in detail. The phenotypic difference segregates as a single gene in both conventional crosses and between recombinant inbred (RI) strains. Immunoprecipitation has shown that the activity difference is due to an alteration in the number of enzyme molecules. The phenotypic difference between high and low strains can therefore be attributed to different alleles of a single regulatory locus, Hdc; the alleleHdc ^d determines low HDC concentration, and the allele Hdc ^d high concentration. Hdc has been mapped to chromosome 2 using data from both comparisons of strain distribution patterns of previously mapped loci within RI strains and a conventional three-point cross. The probable gene order is B2m-pa-Hdc, with map distances of 3.1±1.7 and 2.0±1.4 cM, respectively.This work was supported by an MRC project grant to Grahame Bulfield, an SERC research studentship to S. A. M. Martin, and NIH Research Grant GM 18684 from the National Institute of General Medical Sciences to B. A. Taylor. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory animal care.     

Assignment of the gene for adenine phosphoribosyltransferase on the genetic map of mouse chromosome 8

Two electrophoretic variants of adenine phosphoribosyltransferase (APRT) were identified in a population of wild mice (Mus musculus bactrianus). Breeding tests demonstrated that the APRT variants are under the control of two alleles at an autosomal locus designatedAprt. We have examined the linkage relationships betweenAprt and the markers of chromosome 8 including esterase-1 and the centromere. The recombination distance between the centromere andAprt is 44 ± 7 cM, and that betweenEs-1 andAprt is 25 ± 2 cM, i.e., the probable order of the markers examined is cen-Es-1-Aprt on chromosome 8.     

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.     

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.     

Biochemical polymorphism in the rat,Rattus norvegicus: Genetic study of four markers

The linkage of the hemoglobin (Hbb) and albino (c) loci has been determined from backcross progeny of the mating (WAG/Orl × Long Evans/Orl)F ₁ × WAG/Orl. The data give 9.1 ± 1.8% recombination. The backcross (August/Orl × WAG/Orl)F ₁ × August/Orl segregating for Hbb and pink-eyed yellow (p) shows 21.5±4.2% recombination. The proposed gene order on linkage group I is p-c-Hbb. Linkage of the seminal vesicle protein (Svp-1) and the nonagouti (a) loci has been determined from backcross progeny of the mating (August/Orl × Long Evans/Orl)F ₁ × Long Evans/Orl. The data show 7.1±3.4% recombination. Svp-1 thus represents an additional marker in linkage group V. Two new autosomal variants have been reported: The locus which controls a plasma protein's polymorphism has been designated Gl-1 with two codominant alleles Gl-1a and Gl-1b. The other locus, controlling a testis esterases polymorphism, has been assigned the symbol Es-3 and has two codominant alleles Es-3a and Es-3b. The absence of linkage of Gl-1 and Es-3 to each other and to five different loci has also been reported. Rat and mouse analogy with respect to these markers and established linkages is discussed.     

Biochemical genetics of rat esterases: Polymorphism,tissue expression,and linkage of four loci

Two alleles at each of four esterase loci in Rattus norvegicus are described with regard to tissue expression, electrophoretic characterization, and genetic linkage. A previously described dominant gene for prealbumin serum esterase is demonstrated to exist as two codominant alleles in the genetically determined absence of the characteristic albumin esterase. The allelic composition of 16 inbred strains for four esterase genes is provided, and the heretofore ambiguous nomenclature of rat esterase genetics is standardized. Linkage of Es-1, Es-2, and Es-3 is demonstrated. Es-2 and Es-3 are tightly linked in that no recombination has been observed in 55 offspring. The same offspring demonstrated 9% recombination between Es-1 and the other two loci.This work was supported by a grant from the Brown-Hazen Fund of Research Corporation.     

Assignment of Lap-1 to linkage group I of the rat (Rattus norvegicus)

Genetic analysis of backcross progeny from previously characterized rat inbred strains revealed that the biochemical marker Lap-1 is localized in linkage group I (LG I). Lap-1 codes for leucine arylaminopeptidase (EC 3.4.11). The distances of Lap-1 to c, RT6, and Hbb, based on recombination frequencies, are 3.1±1.5, 8.3±4.0, and 11.4±2.8 cM, respectively. Acon-1 codes for aconitase (EC 4.2.1.3). The calculated distances of Acon-1 to c and Hbb are 30.1±5.0 and 36.1±5.3 cM, respectively. This suggests that Acon-1 is also in LG I, but the observed high frequency of double crossovers requires further confirmation of this linkage. Ahd-2, Es-6, and Gdc-1 are linked neither to markers of LG I nor to one another.     

Genetic polymorphism of the sixth component of complement (C6) in mice

Immunofixation after isoelectric focusing revealed two forms of mouse C6, C6A and C6M, both of which consist of two major protein bands and one or more acidic minor bands. They were distinguishable by their different isoelectric point (pI) ranges: C6M has more acidic pI ranges (pH < 6.2) than C6A (pH < 6.3). C6A was found in common inbred mice of Mus musculus domesticus, while C6M was found in inbred and wild mice of M. m. molossinus (Japanese wild mice, an Asian subspecies). Breeding experiments showed that these two forms of C6 were controlled by a single codominant autosomal locus. We propose the designation C-6 for this locus with two alleles, C-6 ^a and C-6 ^m , which encode for C6A and C6M, respectively. Linkage analysis indicated that the locus is not closely linked to the following loci: Idh-1, agouti, Amy-1, brown, Gpd-1, Mup-1, Pgm-2, Pgm-1, albino, Hbb, Es-1, Mod-1, Sep-1, Es-3, Igh-1, beige, Es-10, Sod-1, and C-3.     

Mapping of theEs-4 locus and linear order of esterase genes (linkage group V; LGV) in the rat

There are three different linear orders of esterase loci of linkage group V (LGV) in the rat (Rattus norvegicus). The first is Es-2-Es-3-Es-1, the second Es-3-(Es-2,Es-4)-Es-1, and the third Es-3-Es-2-Es-1-Es-4. We carried out mating experiments to define the order clearly. Linkage analyses of the four esterase loci, Es-1, Es-2, Es-3, and Es-4, were carried out using two inbred strains carrying different alleles at the four loci. Six locus combinations examined in this study were as follows: Es-1-Es-2, Es-1-Es-3, Es-1-Es-4, Es-2-Es-3, Es-2-Es-4, and Es-3-Es-4. The recombination frequencies of each combination were 6.3, 6.3, 6.3, 5.2, 1.8, and 3.4%, respectively. The first recombination between Es-2 and Es-4 was observed. We propose that the esterase loci of LGV be classified into three clusters according to distances between the loci. The linear order of the four loci is shown to be as follows: [Es-3] (cluster II)-3.4 +/- 2.4%-[Es-4-1.8 +/- 1.7%-Es-2] (cluster III)-6.3 +/- 6.1%-[Es-1] (cluster I).     

Assignment of histidase-regulating locus to chromosome 10 of the mouse

Data from four sets of recombinant inbred strains confirm that variation at a single genetic locus is responsible for the previously observed differences in the rate of histidase synthesis in inbred mice. Linkage testing stocks were used to demonstrate linkage with steel (Sl) on chromosome 10.This research was supported in part by Grants GM 21002 and GM 18684 from the National Institutes of General Medical Sciences. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.     

Evolution of mammalian carbonic anhydrase loci by tandem duplication: Close linkage of Car-1 and Car-2 to the centromere region of chromosome 3 of the mouse

Electrophoretic variants of two carbonic anhydrase enzymes, CAR-1 (CA I) and CAR-2 (CA II), have been found in the laboratory mouse, Mus musculus. These two loci are closely linked to each other and are located on chromosome 3 near its centromere. The close linkage of Car-1 and Car-2 supports the hypothesis that the present-day carbonic anhydrase loci are the result of tandem duplication of an earlier carbonic anhydrase locus with subsequent divergence. The red blood cells of mice of the subspecies M. m. casteneus have significantly reduced levels of CAR-1 and CAR-2.This research was supported in part by Research Grants GM-20919 from the National Institute of General Medical Sciences and CA-01074 from the National Cancer Institute, and by Contracts E(11-1)-3267 with the Energy Research and Development Administration and NO1-ES-4-2159 with the National Institute of Environmental Health Sciences. The Jackson Laboratory is fully certified by the American Association for Accreditation of Laboratory Animal Care.