Linkage of the Dao-1 gene for D-amino-acid oxidase to the pgm-1 gene for phosphoglucomutase-1 on the mouse chromosome 5

Linkage of the Dao-1 gene controlling D-amino-acid oxidase to the Pgm-1 gene controlling phosphoglucomutase-1 on the mouse chromosome 5 was examined. Mutant ddY/DAO- mice carrying a null Dao-1c allele had a Pgm-1a allele. Mutant mice were crossed to C3H/HeN and NZB/Kl mice carrying the Dao-1+ and Pgm-1b alleles. The hybrid F1 mice were backcrossed to the ddY/DAO- and their progeny were examined for alleles for D-amino-acid oxidase and phosphoglucomutase-1. In both backcrosses, the progeny with recombinant-type combinations of the alleles were significantly less than the progeny with the parental-type combinations, indicating the linkage of the Dao-1 and Pgm-1 genes. The recombination frequency between these loci was estimated to be 19.8 +/- 4.0%.     

A single-base-pair substitution abolishes D-amino-acid oxidase activity in the mouse.

Mutant ddY/DAO- mice lacking D-amino-acid oxidase (DAO) activity were examined for the cause of their lack of enzyme activity. Total RNA was extracted from the kidney of the ddY/DAO- mice and cDNA was synthesized. After cDNA encoding DAO was amplified by the polymerase chain reaction it was cloned into a plasmid and sequenced. Comparison of the DAO cDNA sequence with that of normal BALB/c mice revealed the presence of a single-base substitution (G----A) which causes a Gly-181----Arg substitution in the middle of the enzyme molecule. The mutant DAO cDNA was inserted into an expression vector and was expressed in transfected COS-1 cells. The transfected cells synthesized the DAO mutant protein, but they did not show DAO activity. In contrast, when cells were transfected with an expression vector carrying wild-type DAO cDNA, where the substituted base-pair was replaced by a normal base-pair, they showed DAO activity. These results indicate that the single base-pair substitution is the cause of the loss of DAO activity in the ddY/DAO- mice.     

Lack of D-amino-acid oxidase activity causes a specific renal aminoaciduria in the mouse

Thin-layer chromatography and amino acid analysis showed that urine of mutant ddY/DAO- mice lacking D-amino-acid oxidase activity contained more serine, proline, alanine and methionine than that of normal ddY/DAO+ mice. Among these four, an increase in alanine was conspicuous. However, the urinary levels of 11 other amino acids and glucose were not different between the ddY/DAO- and ddY/DAO+ mice. Amino acid analysis showed that the plasma levels of serine, proline and methionine were not elevated in the ddY/DAO- mice, though a slight increase in alanine was observed. Genetic crosses showed that aminoaciduria and lack of D-amino-acid oxidase activity were concomitantly transmitted as a set through generations. These results indicated that the lack of enzyme activity caused a specific renal aminoaciduria. Whether this enzyme merely diminishes the D-amino acid load presented for reabsorption, or actually participates catalytically in the reabsorption process, remains undetermined.     

Brain and Kidney d-Amino Acid Oxidases Are Coded by a Single Gene in the Mouse

Mutant mice (ddY/DAO-) lacking D-amino acid oxidase in the kidney also lacked this enzyme in the brain. Genetic cross experiments showed that the inheritance of the enzyme in the brain was the same as that in the kidney. The deficiency in the enzyme in the brain could not be separated from that in the kidney. The brain and kidney enzymes showed similar substrate specificities. These results suggest that brain and kidney D-amino acid oxidases are coded by the same gene in the mouse.     

Distribution of the C1473G polymorphism in tryptophan hydroxylase 2 gene in laboratory and wild mice

The neurotransmitter serotonin is implicated in the regulation of various forms of behavior, including aggression, sexual behavior and stress response. The rate of brain serotonin synthesis is determined by the activity of neuronal‐specific enzyme tryptophan hydroxylase 2. The missense C1473G substitution in mouse tryptophan hydroxylase 2 gene has been shown to lower the enzyme activity and brain serotonin level. Here, the C1473G polymorphism was investigated in 84 common laboratory inbred strains, 39 inbred and semi‐inbred strains derived from wild ancestors (mostly from Eurasia) and in 75 wild mice trapped in different locations in Russia and Armenia. Among all the classical inbred strains studied, only substrains of BALB/c, A and DBA, as well as the IITES/Nga and NZW/NSlc strains were homozygous for the 1473G allele. In contrast to laboratory strains, the 1473G allele was not present in any of the samples from wild and wild‐derived mice, although the wild mice varied substantially in the C1477T neutral substitution closely linked to the C1473G polymorphism. According to these results, the frequency of the 1473G allele in natural populations does not exceed 0.5%, and the C1473G polymorphism is in fact a rare mutation that is possibly eliminated by the forces of natural selection.     

The mouse Rn locus: S allele of the renin regulator gene results from a single structural gene duplication.

Inbred strains of mice have been divided into two distinct phenotypic groups having different levels of renin activity regulated by androgen in the submaxillary gland (SMG). Strains carrying the Rnrs allele of the renin gene regulator, located on chromosome 1, have a high level of renin activity; strains carrying the Rnrb allele have a low level of renin activity. The level of SMG renin activity correlates with the level of renin mRNA. We have analyzed, by Southern blot hybridization, the organization of renin genes in both strains. Strains carrying the Rnrb allele, such as BALB/c or C57 Bl/6, or CH3 mice, have one renin structural gene per haploid genome, while those having the Rnrs allele, such as AKR or Swiss mice, have two renin genes. We have also identified renin genes in mice belonging to different biochemical groups: Mus spretus has one renin gene while M. vrania and M. musculus brevirostris have two renin genes.     

Determination of free D-proline and D-leucine in the brains of mutant mice lacking D-amino acid oxidase activity.

A new procedure to accurately measure a trace amount of d-proline in biological samples has been developed. This D-amino acid was derivatized with 4-fluoro-7-nitro-2,1,3-benzoxadiazole and was determined by a column-switching HPLC system, a combination of a micro-ODS column and a chiral column. The detection limit for D-proline spiked in a mouse cerebrum sample is 1 fmol (injection amount, S/N = 3). Within-day precision and day-to-day precision obtained for spiked d-proline (10 fmol) are 2.14 and 5.35% (RSD), respectively. Using the new method, the amount of free D-proline in eight brain regions and sera of mutant ddY/DAO- mice, lacking D-amino acid oxidase activity, and control ddY/DAO+ mice was determined. The amount of free D-leucine was also investigated. The amount and distribution of D-proline in the brains of ddY/DAO+ mice and ddY/DAO- mice are almost the same, and relatively high amounts of D-proline have been observed in the pituitary gland and in the pineal gland. On the other hand, the amount of D-leucine is different between the two strains. In the brains of ddY/DAO+ mice, a relatively high amount of D-leucine has been observed in the pineal gland compared with other regions. In the brains of ddY/DAO- mice, D-leucine amounts are approximately 10 times higher than those obtained in ddY/DAO+ mice and regional difference has not been observed, while the amounts of L-proline and L-leucine are not significantly different between the two strains. In the serum, the amounts of both free D-proline and d-leucine are significantly higher in the ddY/DAO- mice than those obtained in ddY/DAO+ mice.     

Genetic control of heat sensitivity and activity level of murine arylsulfatase B

BALB/c male mice possess twofold higher kidney p-nitrocatechol-SO4 arylsulfatase B than do A/HeJ male mice; however, their liver arylsulfatase activities are comparable. Twentyfold-purified kidney arylsulfatases B from these two strains have similar Michaelis constants, electrophoretic mobilities, pH optima, and inhibitor profiles; however, the BALB/c enzyme is more heat stable than the A/HeJ enzyme. BALB/c, C3H/HeJ, DBA/2J, and SWR/J mice share an autosomal allele, As-1a, which apparently determines the heat-stable arylsulfatase B, while A/HeJ and C57BL/6J mice possess the As-1b allele, which determines the heat-sensitive enzyme. A second autosomal locus, Asr-1, determines liver arylsulfatase B activity. C57BL/6J mice carry the Asr-1a allele, which results in high liver activities, while C3H/HeJ mice are homozygous for the low-activity allele, Asr-1b. Male mice generally have 30-40% higher kidney activities than females; however, female kidney arylsulfatase activities rise and actually surpass those of males during late pregnancy and lactation.     

''Allelic'' forms of immunoglobulin V genes in different strains of mice.

A VH gene (Ox1) has a major role in the early antibody response of several mouse strains to hapten phenyloxazolone (phOx). Antibodies that are coded by this gene are positive for idiotype 495. Idiotype-positive monoclonal antibodies originating from the early primary response of nine strains were partially sequenced (mRNA). All 21 antibodies were coded by this gene, most of them also by one VL gene, VKOx1(H3). Very few somatic mutations were found, and the germ-line sequence of the two genes in several strains can be predicted. Four 'alleles' of the VHOx1 gene have 99-99.7% sequence homology to each other. One allele was found in Igh allotype j strains CBA and C3H, another in allotype c strains DBA/2 and RF, the third in allotype f strain CE and the fourth in BALB/c, 129, A/J and RIII mice (allotypes a, e or g). The VKOx1(H3) gene has the same sequence in eight strains. RF mice do not use this gene for the anti-phOx response. Our data suggest that antibody responses are inherited to a considerable extent and that immunoglobulin V genes are as stable as other genes in evolution.     

Linkage of prion protein and scrapie incubation time genes

A single gene (Prn-i) that affects scrapie incubation period in mice has been identified. I/LnJ mice have a very long incubation period after inoculation of scrapie prions (200-385 days) and NZW/LacJ mice have a short one (113 +/- 2.8 days). (NZW X I/Ln)F1 hybrid mice had incubation times of 223 +/- 2.8 days indicating longer incubation times were dominant. Incubation periods in the backcross progeny of (NZW/LacJ X I/LnJ)F1 X NZW/LacJ segregated into two groups (64 mice, 130 +/- 1.1 d; 66 mice, 195 +/- 1.9 d) indicating single gene control. NZW/LacJ and 20 other inbred strains have the Prn-pa allele which is identified as a 3.8 kb Xbal fragment using a hamster PrP (prion protein) cDNA probe. I/LnJ and three other Prn-pb mouse strains have a 5.5 kb Xbal restriction fragment. Analysis of DNA from 66 backcross mice indicated Prn-i is tightly linked to Prn-p, the structural gene for PrP.     

Interacting Genes Control Glycerol-3-Phosphate Dehydrogenase Expression in Developing Cerebellum of the Mouse

The cerebellum of BALB/cJ mice has approximately 2.5 times as much glycerol-3-phosphate dehydrogenase (GPDH) as that of C57BL/6J mice. This difference in enzyme levels, which positively correlates with similar differences in the levels of hybridizable GPDH mRNA, is controlled by at least two unlinked regulatory loci and the structural gene, Gdc-1, located on chromosome 15. These regulatory loci, which act predominantly during the second and third weeks of postnatal cerebellar development and differentiation, have been separated from each other in the CXB recombinant inbred strains of mice. One regulatory locus, Gdcr-1, although unlinked to the structural gene, has an allele in BALB/c mice that preferentially enhances expression of the BALB/c structural allele at Gdc-1. The other locus, Gdcr-2, which may or may not be single, enhances GPDH expression at Gdc-1 irrespective of the allele present, as is commonly observed for loci acting from a distance. Measurements of GPDH mRNA in the recombinant inbred mice suggest that these regulatory genes act by modulating mRNA levels. Accordingly, the regulation of GPDH expression in the cerebellum of mice depends on a complex interaction of unlinked regulatory elements with regulatory elements near the structural gene. Furthermore, since the Gdc-1 locus is expressed in virtually every tissue of the mouse except blood and since the observed genetic variation is restricted to the cerebellum, it is likely that other tissues will have their own distinctive genetic mechanisms for modulating Gdc-1 expression.     

Enhancer elements in the mouse CYP1A2 gene: a comparative sequencing among different inbred mouse strains

CYP1A2 expression is constitutively high in mouse liver and is well known for metabolizing several drugs and many procarcinogens to reactive intermediates that can cause toxicity or cancer. In the present study, the basal level of hepatic CYP1A2 activity was shown to vary among different inbred mouse strains. The highest methoxyresorufin-O-demethylase activity (261+/-52pmol/mgprotein/min) was registered in CC57BR and the lowest (82+/-11pmol/mgprotein/min) in C3H/a. We have tested the hypothesis that possible polymorphisms in regulatory elements in the 5'-upstream region of the mouse CYP1A2 gene could cause the differences in CYP1A2 enzyme activity among different inbred strains. We have performed a study on the CYP1A2 gene by sequencing the regulatory region from -4675 to -4204 where two enhancer elements were recently identified. The absence of mutation prescribing the phenotype in the CYP1A2 gene was found. The region studied seems to be a highly conserved in mice and not to be associated with interstrain differences in constitutive CYP1A2 enzyme activity.     

Early embryonic lethality caused by targeted disruption of the 3-hydroxy-3-methylglutaryl-CoA reductase gene

The endoplasmic reticulum (ER) enzyme 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, which converts HMG-CoA to mevalonate, catalyzes the ratelimiting step in cholesterol biosynthesis. Because this mevalonate pathway also produces several non-sterol isoprenoid compounds, the level of HMG-CoA reductase activity may coordinate many cellular processes and functions. We used gene targeting to knock out the mouse HMG-CoA reductase gene. The heterozygous mutant mice (Hmgcr+/-) appeared normal in their development and gross anatomy and were fertile. Although HMG-CoA reductase activities were reduced in Hmgcr+/- embryonic fibroblasts, the enzyme activities and cholesterol biosynthesis remained unaffected in the liver from Hmgcr+/- mice, suggesting that the haploid amount of Hmgcr gene is not rate-limiting in the hepatic cholesterol homeostasis. Consistently, plasma lipoprotein profiles were similar between Hmgcr+/- and Hmgcr+/+ mice. In contrast, the embryos homozygous for the Hmgcr mutant allele were recovered at the blastocyst stage, but not at E8.5, indicating that HMG-CoA reductase is crucial for early development of the mouse embryos. The lethal phenotype was not completely rescued by supplementing the dams with mevalonate. Although it has been postulated that a second, peroxisome-specific HMG-CoA reductase could substitute for the ER reductase in vitro, we speculate that the putative peroxisomal reductase gene, if existed, does not fully compensate for the lack of the ER enzyme at least in embryogenesis.     

Genetic control of glucokinase activity in mice

Inbred strains of mice were surveyed for liver glucokinase activity. Mice of all strains studied could be distributed into three groups with high, intermediate, and low levels of enzyme activity. Genetic analysis using crosses and backcrosses with prototype high (C3H/HeJ) and low (RF/J) strains revealed that glucokinase activity was controlled by a single gene. The name glucokinase and gene symbol Gk are suggested for this gene. The Gk ^a allele designates the strain with high glucokinase activity, while Gk ^b represents the allele in the strain with the low enzyme activity. The interaction of fasting and diabetes on the activity of glucokinase in these two strains is described.Supported in part by United States Public Health Service Research Grant CA 05873 from the National Cancer Institute. The Jackson Laboratory is fully accredited by the American Association for the Accreditation of Laboratory Animal Care.     

The effects of genetic variation in N-acetyltransferases on 4-aminobiphenyl genotoxicity in mouse liver

Inbred, congenic and transgenic strains of mice were characterized for acetylation of p-aminobenzoic (PABA) and the carcinogen 4-aminobiphenyl (4ABP). C57Bl/6 mice have the NAT2*8 allele, A/J mice have NAT2*9 and congenic B6.A mice have NAT2*9 on the C57Bl/6 background. The first transgenic strain with human NAT1, the functional equivalent of murine NAT2, was also tested. The murine NAT2*9 allele correlated with a slow phenotype measured with the murine NAT2 selective substrate PABA. The two strains having this allele also had a lower capacity to acetylate 4ABP. A line with five copies of the human NAT1 transgene was bred for at least five generations with either C57Bl/6 or A/J mice. There was no significant change in PABA NAT activity on the C57Bl/6 background but a 2.5-fold increase was seen in hNAT1:A/J compared with A/J. The effect of variation in NATs on 4ABP genotoxicity was assessed in these strains. Twenty-four hours after exposure to a single oral dose of 120 mg 4ABP/kg, hepatic 4ABP-DNA adducts were detected by immunofluoresence in all strains. Nuclear fluorescence intensities (mean+/-S.D.) were 41.1+/-3.6 for C57Bl/6, 37.9+/-1.11 for A/J and 36.3+/-2.44 for B6.A. There was no correlation between murine NAT2 alleles and 4ABP-DNA adduct levels. Similar results were seen with the transgenic strains. The data indicate that the range of variation present in these strains of mice was insufficient to alter susceptibility to 4ABP genotoxicity. The impact of these relatively modest differences in the acetylation of the activation of 4ABP may be masked by other competing biotransformation reactions since 4ABP is a substrate for both NAT1 and NAT2. Mouse models with variation in both isoforms are needed to adequately assess the role of variation in NATs in susceptibility to 4ABP genotoxicity.     

Genetic variation in androgen regulation of ornithine decarboxylase gene expression in inbred strains of mice

Previous studies have indicated that androgen regulation of certain gene products in murine kidney is genetically controlled. In the present work, the expression of renal ornithine decarboxylase (ODC) gene(s) was used as a biological marker to study androgen responsiveness of eight inbred strains of mice (A/J, C57BR/cdJ, 129/J, C57L/J, BALB/cJ, SM/J, RF/J, and C57BL/6J). Kidneys of untreated females from these strains did not have significantly different basal ODC activities or ODC mRNA concentrations. However, renal enzyme concentrations in intact male mice exhibited marked strain-dependent variation; three strains (RF/J, SM/J, and C57BR/cdJ) had 5- to 20-fold higher activities than the other five strains. Renal ODC mRNA content showed similar genetic variability in the male mice; animals with highest enzyme activity had higher mRNA levels than those with low activity. These results could not be explained by differences in either serum testosterone levels or renal nuclear androgen receptor content, suggesting that the animals were differentially sensitive to endogenous androgens. To evaluate further the androgen regulation of ODC gene expression, female mice were treated with testosterone-releasing implants for 5-7 days. The two strains (A/J and C57BL/6J) that had low enzyme activity in response to endogenous testosterone in male mice also showed blunted responses to exogenous androgen administration, as measured by the induction of ODC and its mRNA. The relative distribution of the two mRNA species coding for ODC (2.2 and 2.7 kb in size) exhibited strain-dependent variation that did not, however, correlate with the androgen responsiveness. Studies of the mRNA levels in reciprocal F1 hybrids of C57BR/cdJ and C57BL/6J mice suggested that androgen sensitivity of ODC gene expression, at least in these crosses, was inherited in an autosomal dominant manner.     

Association between Tph2 gene polymorphism, brain tryptophan hydroxylase activity and aggressiveness in mouse strains

The brain neurotransmitter serotonin is involved in the regulation of aggressive behavior. The main factor determining the brain serotonin level is the activity of the rate-limiting enzyme in the biosynthesis of the neurotransmitter--tryptophan hydroxylase isoform (TPH) 2 encoded by the Tph2 gene. Recently the C1473G single-nucleotide polymorphism in the Tph2 gene was reported. Here we study the C1473G polymorphism in 10 inbred mouse strains (C57BL/6J, AKR/J, DD/He, C3H/HeJ, YT/Y, BALB/cJLac, CC57BR/Mv and A/He) and demonstrate the association of the polymorphism with brain TPH activity and intermale aggressiveness. TPH activity in the midbrain of mice homozygous for the 1473C allele was higher than that in mice carrying 1473G alleles. A close association of the 1473C allele with increased number of attacks towards another male was found. The results support a link between the C1473G polymorphism in Tph2 gene, tryptophan hydroxylase activity and intensity of intermale aggression.     

A false note of DNA polymerase iota in the choir of genome caretakers in mammals

DNA polymerase iota (Pol iota) of mammals is a member of the Y family of DNA polymerases. Among many other genome caretakers, these enzymes are responsible for maintaining genome stability. The members of the Y-family DNA polymerases take part in translesion DNA synthesis, bypassing some DNA lesions, and are characterized by low fidelity of DNA synthesis. A unique ability of Pol iota to predominantly incorporate G opposite T allowed us to identify the product of this enzyme among those synthesized by other DNA polymerases. This product can be called a "false note" of Pol iota. We measured the enzyme activity of Pol iota in crude extracts of cells from different organs of five inbred strains of mice (N3H/Sn, 101/H, C57BL/6, BALB/c, 129/J) that differed in a number of parameters. The "false note" of Pol iota was clearly sounding only in the extracts of testis and brain cells from four analyzed strains: N3H/Sn, 101/H, C57BL/6, BALB/c. In mice of 129/J strain that had a nonsense mutation in the second exon of the pol iota gene, the Pol iota activity was reliably detectable only in the extracts of brain. The data show that the active enzyme can be formed in some cell types even if they carry a nonsense mutation in the pol iota gene. This supports tissue-specific regulation of pol iota gene expression through alternative splicing. A semiquantitative determination of pol iota activity in mice strains different in their radiosensitivity suggests a reciprocal correlation between the enzyme activity of pol iota in testis and the resistance of mice to radiation.     

Genetic control of glycolipid expression

A polymorphic variation of sialic acid species of sialosyllactosylceramide was found in dog erythrocytes. The analysis of the glycolipids in the erythrocytes of the individual dogs in a family of a Japanese breed of dog, Shiba-Inu, showed that the expression of sialosyllactosylceramide containing N-glycolylneuraminic acid was an autosomal dominant trait over the expression of that containing N-acetylneuraminic acid. Polymorphic variations of major liver gangliosides were also found in various strains of inbred mice. The strains were classified into three groups; the first group possessed only II3 NeuGc-LacCer, the second group possessed II3NeuGc-GgOse3Cer in addition to II3NeuGc-LacCer and the third group possessed II3NeuGc-GgOse4Cer and II3NeuGc,IV3NeuGc-GgOse4Cer as well as the above two gangliosides. By subjecting mice of these three groups to genetic analysis, the strain of the first group (WHT/Ht mice) was demonstrated to be a recessive homozygote which had a single autosomal defective gene making it unable to express N-acetylgalactosaminyltransferase activity to produce II3NeuGc-GgOse3Cer. The strains of the second group (BALB/c and C57BL/10 mice) were also demonstrated to be recessive homozygotes which had a single autosomal defective gene making them unable to express high enough level of galactosyltransferase activity to produce II3NeuGc-GgOse4Cer. By the analysis of gangliosides and the enzyme activity of H-2 congenic mice and mice produced by a mating, this defective gene controlling the expression of II3NeuGc-GgOse4-Cer through the regulation of the transferase activity was demonstrated to be linked to H-2 complex on chromosome 17.