Genetics,ontogeny, and testosterone inducibility of aldehyde oxidase isozymes in the mouse: Evidence for two genetic loci (Aox-1 and Aox-2) closely linked on chromosome 1

Null-activity and low-activity variants for the liver supernatant isozymes of aldehyde oxidase (designated AOX-1 and AOX-2) were observed in inbred strains and in Harwell linkage testing stocks of Mus musculus. The genetic loci determining the activity of these isozymes (designated Aox-1 and Aox-2, respectively) are closely linked on chromosome 1 near Id-1 (encoding the soluble isozyme of isocitrate dehydrogenase). Linkage data of Aox-1 with Id-1 and Dip-1 (encoding a kidney peptidase) demonstrated that this gene coincides with or is closely linked to Aox (Watson et al., 1972). Ontogenetic analyses demonstrated that liver AOX-1 appeared just before birth and increased in activity during postnatal development, whereas liver AOX-2 was observed only during postnatal development. Adult male livers exhibited higher AOX-1 and AOX-2 activities than adult female livers. Both isozymes were significantly reduced in activity by castration of adult males and increased following testosterone administration to castrated males and normal female mice.     

Aldehyde oxidase and alcohol dehydrogenase genetics in the mouse. New alleles for the Aox-2 and Adh-3 loci

The genetic variability of one of the liver isozymes of aldehyde oxidase (AOX-B₂ or AOX-2) and the stomach isozyme of alcohol dehydrogenase (ADH-C₂) has been examined among strains of mice. Evidence is presented for a fourth allele of Aox-2 and a third allele of Adh-3 . The hybrid allozyme pattern for mouse liver AOX was consistent with a dimeric subunit structure for this enzyme.     

Sorbitol dehydrogenase genetics in the mouse: A ';null' mutant in a ';European' C57BL strain

A ';null' activity variant phenotype for sorbitol dehydrogenase (SDH) was observed in C57BL/LiA mice and used to examine the genetics of this enzyme. Linkage studies of the locus ( Sdh-1 ) with non-agouti (a) and a biochemical Iocus encoding liver L-α-hydroxyacid oxidase ( Hao-1 ) demonstrated that it is coincident with or closely linked to the structural locus, previously localized on chromosome 2. Alcohol dehydrogenase (ADH) isozymes were also examined, since the liver A₂ isozyme exhibited some activity as a sorbitol dehydrogenase on cellulose acetate zymograms. It is apparent that SDH activity is not ';essential' in this mouse strain.     

Genetics of peroxisomal enzymes in the mouse: Nonlinkage of d-amino acid oxidase locus (Dao) to catalase (Cs) and l-α-hydroxyacid oxidase (Hao-1) loci on chromosome 2

An electrophoretic polymorphism of the peroxisomal enzyme D-amino acid oxidase was observed in NZC strain Mus musculus. F1 (NZC X BALB/c) mice showed a codominant allcle two-banded phenotype which is inconsistent with the dimeric subunit structure reported for this enzyme in other species. The enzyme locus (Dao) was shown to segregate independently of Hao-1, encoding the peroxisomal enzyme hydroxyacid oxidase (liver on A4 isozyme). Thus Dao is not linked to previously mapped peroxisomal enzyme loci, Hao-1 and Cs, closely localized on chromosome 2.     

Origin of the triosephosphate isomerase isozymes in humans: genetic evidence for the expression of a single structural locus.

A genetic approach is used to ascertain that a single structural locus for triosephosphate isomerase (TPI) (E.C.5.3.1.1.) is expressed in rapidly dividing human lymphoblasts. This approach is made possible through the identification of a rare electrophoretic variant of human TPI. The variant phenotype is expressed by the TPI-B isozyme in both erythrocytes and peripheral lymphocytes. The variant phenotype is also expressed in the thermostability and electrophoretic pattern of the TPI-A isozyme in mitogen-stimulated lymphoblasts, indicating that TPI-A and TPI-B are products of the same structural locus. These findings are in contrast to the recent conclusions of Yuan et al. based upon structural analysis, suggesting that the TPI-A and TPI-B isozymes are products of distinct structural loci.     

Genetic variation of some aldehyde-oxidizing enzymes in the mouse

• 1 Twenty-six strains of mice were surveyed by starch gel electrophoresis for genetic variation of four liver enzymes; aldehyde dehydrogenase, aldehyde oxidase, xanthine oxidase and formaldehyde dehydrogenase.
• 2 A variant of aldehyde dehydrogenase was found in strains ICFW, IS/Cam, NZB, NZW, Simpson and Schneider. A variant of aldehyde oxidase was found in CE. A possible variant of xanthine oxidase was found in SF/Cam.
• 3 The gene determining the electrophoretic variant of aldehyde oxidase is either the same as, or very closely linked to, the Aox gene which determines aldehyde oxidase activity.

     

Electrophoretic analyses of alcohol dehydrogenase, aldehyde dehydrogenase, aldehyde reductase, aldehyde oxidase and xanthine oxidase from horse tissues

Cellulose acetate zymograms of alcohol dehydrogenase (ADH), aldehyde dehydrogenase (AHD), aldehyde reductase (AHR), aldehyde oxidase (AOX) and xanthine oxidase (XOX) extracted from horse tissues were examined. Five ADH isozymes were resolved: three corresponded to the previously reported class I ADHs (EE, ES and SS) (Theorell, 1969); a single form of class II ADH (designated ADH-C2) and of class III ADH (designated ADH-B2) were also observed. The latter isozyme was widely distributed in horse tissues whereas the other enzymes were found predominantly in liver. Four AHD isozymes were differentially distributed in subcellular preparations of horse liver: AHD-1 (large granules); AHD-3 (small granules); and AHD-2, AHD-4 (cytoplasm). AHD-1 was more widely distributed among the horse tissues examined. Liver represented the major source of activity for most AHDs. A single additional form of NADPH-dependent AHR activity (identified as hexonate dehydrogenase), other than the ADHs previously described, was observed in horse liver. Single forms of AOX and XOX were observed in horse tissue extracts, with highest activities in liver.     

An RFLP linkage map for loblolly pine based on a three-generation outbred pedigree

A genetic linkage map for loblolly pine (Pinus taeda L.) was constructed using segregation data from a three-generation outbred pedigree consisting of four grandparents, two parents, and 95 F₂ progeny. The map was based predominantly on restriction fragment length polymorphism (RFLP) loci detected by cDNA probes. Sixty-five cDNA and three genomic DNA probes revealed 90 RFLP loci. Six polymorphic isozyme loci were also scored. One-fourth (24%) of the cDNA probes detected more than 1 segregating locus, an indication that multigene families are common in pines. As many as six alleles were observed at a single segregating locus among grandparents and it was not unusual for the progeny to segregate for three or four alleles per locus. Multipoint linkage analysis placed 73 RFLP and 2 isozyme loci into 20 linkage groups; the remaining 17 RFLP and 4 isozyme loci were unlinked. The mapped RFLP probes provide a new set of codominant markers for genetic analyses in loblolly pine.     

Gene markers for alcohol-metabolizing enzymes among recombinant inbred strains of mice with differential behavioural responses towards alcohol

The genetic variability of alcohol dehydrogenase (C2 isozyme), aldehyde dehydrogenase (A2 isozyme) and aldehyde oxidase (A2 isozyme) has been examined among recombinant inbred strains of mice which have been previously studied concerning their differential behavioural responses towards alcohol. The results showed no correlation between biochemical phenotype for these loci and behavioural response.     

Chinook salmon NADP+-dependent cytosolic isocitrate dehydrogenase: Electrophoretic and genetic dissection of a complex isozyme system and geographic patterns of variation

Species in the genus Oncorhynchus express complicated isocitrate dehydrogenase (IDHP) isozyme patterns in many tissues. Subcellular localization experiments show that the electrophoretically distinct isozymes of low anodal mobility expressed predominantly in skeletal and heart muscle are mitochondrial forms (mIDHP), while the more anodal, complex isolocus isozyme system predominant in liver and eye is cytosolic (sIDHP). The two loci encoding sIDHP isozymes are considered isoloci because the most common allele at one of these loci cannot be separated electrophoretically from the most common allele of the other. Over 12 electrophoretically detectable alleles are segregating at the two sIDHP* loci in chinook salmon. Careful electrophoretic comparisons of the sIDHP isozyme patterns of muscle, eye, and liver extracts of heterozygotes reveal marked differences between the tissues with regard to both relative isozyme staining and the expression of several common alleles. Presumed single-dose heterozygotes at the sIDHP isolocus isozyme system exhibit approximate 9:6:1 ratios of staining intensity in liver and eye, while they exhibit approximate 1:2:1 ratios in skeletal muscle. The former proportions are consistent with the equal expression of two loci (isolocus expression), while the latter are consistent with the expression of a single locus. Screening of over 10,000 fish from spawning populations and mixed-stock fishery samples revealed that certain variant alleles (*127, *50) are detectable only in liver and eye, while other alleles (*129, *94, and *74) are strongly expressed in muscle, eye, and liver. The simplest explanation for these observations is that the "isolocus" sIDHP system of chinook salmon (and that of steelhead and rainbow trout) results from the expression of two distinct loci (sIDHP-1* and sIDHP-2*) that have the same common allele (as defined by electrophoretic mobility). IDHP expression in skeletal muscle is due to the nearly exclusive expression of the sIDHP-1* locus, while IDHP expression in eye and liver tissues is due to high levels of expression of both sIDHP-1* and sIDHP-2*--giving rise to the isolocus situation in these latter tissues. Direct inheritance studies confirm this model of two genetically independent (disomic) loci encoding sIDHP in chinook salmon. Extensive geographic surveys of chinook salmon populations from California to British Columbia reveal marked differences in allele frequencies at both sIDHP-1* and sIDHP-2* and considerably more interpopulation differentiation than was recognized previously when sIDHP was treated as an isolocus system with only five recognized alleles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Genetics and development of ocular oxidases in the mouse: evidence for a new locus (Eox-l) closely linked with the aldehyde oxidase loci on chromosome 1

Summary. Isoelectric focusing (IEF) and histochemical techniques were used to examine the genetics, postnatal development and biochemical properties of ocular oxidases (EOXs) among inbred strains of mice. The designation as EOX was made on a provisional basis, since the 'natural' substrate(s) for this enzyme have not been identified. Five major forms were resolved from adult animals, which exhibited high activity in murine lens and low activity in the cornea. An additional ocular oxidase was observed in neonatal animals. Genetic analyses demonstrated that one of these enzymes (EOX-1) is encoded by a locus (Eox-1) which is closely linked with, but distinct from, the aldehyde oxidase (Aox) gene complex on chromosome one of the mouse. These results support the proposal that ocular oxidases are distinct from the major liver AOXs in this organism.     

A genetic linkage map of rat chromosome 9 with a new locus for variant activity of liver aldehyde oxidase.

A genetic linkage map of rat chromosome 9 consisting of five loci including a new biochemical marker representing a genetic variation of the activity of the liver aldehyde oxidase, (Aox) was constructed. Linkage analysis of the five loci among 92 backcross progeny of (WKS/Iar x IS/Iar)F1 x WKS/Iar revealed significant linkages between these loci. Minimizing crossover frequency resulted in the best gene order: Aox-D9Mit4-Gls-Cryg-Tp53l1. The homologues of the Cryg, Gls, and Aox genes have been mapped on mouse chromosome 1 and human chromosome 2q. The present findings provide further evidence for the conservation of synteny among these regions of rat, mouse, and human chromosomes.     

Mutations affecting phenol oxidase activity inDrosophila: quicksilver andtyrosinase-1

The complex enzyme phenol oxidase plays a major role in sclerotization and melanization of cuticle in insects. Production of active enzyme from the inactive proenzyme involves at least six protein components inDrosophila. We examine here the biochemical phenotype of two loci that affect phenol oxidase activity—quicksilver (qs; 1–39.5) andtyrosinase-1 (tyr-1; 2–54.5). Three mutations isolated by different procedures in three different laboratories are alleles at thequicksilver locus. The effects of these mutations have been monitored by means of enzyme assaysin vitro and in polyacrylamide gels and by measurement of catecholamine pool sizes. The activity of all three active enzyme components (A1, A2, and A3) is reduced inqs mutants. The activated enzyme of oneqs allele is thermolabile, while its activator is normal. Deletion and genetic mapping placetyr-1 nearpurple (pr; 2–54.5). Enzyme activity is reduced to 10% of normal but is not thermolabile and the activator is normal. The activity of all three A components is reduced. The diphenol oxidase activity in double mutant combinations shows that these mutations andDox-A2 (Pentzet al., 1986) affect this enzyme in different ways.B.C.B. was supported by National Institutes of Health Research Grant GM31217 and E.S.P. was supported by National Institutes of Health Research Grant GM19242 to T.R.F.W.     

Biochemical markers in rats: Linkage relationships of aconitase (Acon-1), aldehyde dehydrogenases (Ahd-2 and Ahd-c), alkaline phosphatase (Akp-1), and hydroxyacid oxidase (Hao-1)

We have examined the linkage relationships between five biochemical markers, Acon-1, Ahd-2, Ahd-c, Akp-1, and Hao-1, and 19 other genetic loci in five breeding combinations. The genetic locus that codes for a recently described aldehyde dehydrogenase in the liver (Ahd-c) has been assigned to linkage group X (LG X). Hydroxyacid oxidase is coded for by a locus (Hao-1) that is linked to genes that encode agouti coat color and seminal vesicle proteins in linkage group IV. Alkaline phosphatase (Akp-1) was linked to the locus that encodes the C6 component of complement and this association provisionally defines a new linkage group (LG XI) in the rat. The locus Acon-1 could not be positively assigned to a specific linkage group but the results from one breeding combination suggest that this locus may be included in linkage group II. No linkage relationship could be detected for the aldehyde dehydrogenase coded for by Ahd-2.This work was supported by Grant GM 32580 from the National Institutes of Health, United States Public Health Service.     

Population structure in Arabidopsis lyrata: evidence for divergent selection on trichome production

Leaf trichomes may serve several biological functions including protection against herbivores, drought, and UV radiation; and their adaptive value can be expected to vary among environments. The perennial, self-incompatible herb Arabidopsis lyrata is polymorphic for trichome production, and occurs in a glabrous and a trichome-producing form. Controlled crosses indicate that the polymorphism is governed by a single gene, with trichome production being dominant. We examined the hypothesis that trichome production is subject to divergent selection (i.e., directional selection favoring different phenotypes in different populations) by comparing patterns of variation at the locus coding for glabrousness and at eight putatively neutral isozyme loci in Swedish populations of A. lyrata. The genetic diversity (He) and allele number at isozyme loci tended to increase with population size and decreased with latitude of origin, whereas genetic diversity at the locus coding for glabrousness did not vary with population size and increased with latitude of origin. The degree of genetic differentiation at the glabrousness locus was much higher than that at isozyme loci. Genetic identity at isozyme loci was negatively related to geographic distance, suggesting isolation by distance. In contrast, there was no significant correlation between genetic identity at the glabrousness locus and at isozyme loci. The results are consistent with the hypothesis that divergent selection contributes to population differentiation in trichome production in A. lyrata.     

Alcohol dehydrogenase isozymes in the mouse: genetic regulation, allelic variation among inbred strains and sex differences of liver and kidney A2 isozyme activity

Genetic analysis of a proposed cis-acting temporal locus (Adh-3t), which regulates alcohol dehydrogenase C2 (ADH-C2) activity in mouse epididymis extracts, among F1 (ddN X BALB/c) X ddN male backcross progeny provided evidence for genetic distinctness between the structural (Adh-3) and temporal (Adh-3t) loci on chromosome 3. Genetic analysis also confirmed the close linkage of Adh-1 (encoding liver and kidney ADH-A2) and Adh-3 (encoding stomach ADH-C2) to within 0.3 centimorgans on the mouse genome. Evidence is presented for a proposed closely linked cis-acting temporal locus (designated Adh-lt) for the A2 isozyme (encoded by Adh-1) controlling the activity of this enzyme in mouse kidney extracts, but having no apparent affect on liver and intestine ADH-A2 activities. An extensive survey of the distribution of Adh-1, Adh-3 and Adh-3t alleles among 65 strains of mice is reported--with the exception of two Japanese strains (ddN and KF), linkage disequilibrium between Adh-3 and Adh-3t was observed. Sex differences in mouse liver and kidney ADH-A2 activities were observed, with male/female ratios of approximately 0.6 and 3 respectively for these tissue extracts.     

不同类型杂交水稻组合及其亲本苗期同工酶位点分析

对6个杂交水稻组合及其亲本苗期14种酶的同工酶进行检测,并对其中较为清晰稳定的酶带进行了位点分析,以探讨杂种优势遗传基础。共获得了28个位点的相关资料,包括每个位点的性质、表型多态性和每个位点所编码的酶活性及酶带平均迁移率。所有供试材料在其中25个位点上均未表现出多态性,只有部分组合与其亲本在Est-4、Amy-1、Aat-2等3个位点上存在多态性,其中有81．8％的差异组合其酶带表现出共显性特征。对共显性与杂种优势的关系进行了探讨。     

The Genetics of α-Hydroxyacid Oxidase and Alcohol Dehydrogenase in the Mouse: Evidence for Multiple Gene Loci and Linkage between Hao-2 and Adh-3

Electrophoretic polymorphisms for stomach alcohol dehydrogenase (ADH-C2) and kidney L-alpha-hydroxyacid oxidase (HAOX-B4) have been identified in an Asian subspecies of mouse, Musmusculus castaneous. These variants are inherited in a normal Mendelian fashion with two alleles in each case showing codominant expression. The structural gene loci for those enzymes (Adh-3 and Hao-2, respectively) are apparently linked (17.6% recombinants) in this organism, whereas the multiple gene loci for HAOX, Hao-1 (encoding the A4 liver isozyme) and Hao-2, exhibited independent segregation and are unlinked (50% recombinants). Evidence is presented for 3 ADH loci: ADH-1, encoding liver ADH-A2 which exhibits high activity with ethanol (SELANDER, HUNT and YANG 1969; ADH-2, liver and stomach ADH-B2 using 2-hexene-1-ol as substrate; and Adh-3, stomach ADH-C2 using both benzyl alcohol and 2-hexene-1-ol as substrate.     

Isoelectric focusing studies of aldehyde dehydrogenases from mouse tissues: variant phenotypes of liver, stomach and testis isozymes

Isoelectric focusing techniques (IEF) were used to examine the tissue distribution and genetic variability of aldehyde dehydrogenases (AHDs) from inbred strains of mice. Twelve zones of AHD activity were resolved which were differentially distributed between tissues. Liver extracts exhibited highest activity for most enzymes, with the exception of isozymes found in stomach (AHD-4) and testis (AHD-4 and AHD-6). Genetic variants for AHD-1 (liver mitochondrial isozyme) and AHD-4 (stomach isozyme) were examined from inbred strains and F1 hybrid animals. The results were consistent with dimeric subunit structures (designated as A2 and D2 isozymes respectively). IEF patterns for activity variants of testis-specific AHD-6 were identical, with 3-banded phenotypes being observed. pI values for the AHD forms as well as for aldehyde oxidase and xanthine oxidase isozymes, which stain in the absence of coenzyme, were reported.     

Characterization of wheat germin (oxalate oxidase) expressed by Pichia pastoris

High-level secretory expression of wheat (Triticum aestivum) germin/oxalate oxidase was achieved in Pichia pastoris fermentation cultures as an alpha-mating factor signal peptide fusion, based on the native wheat cDNA coding sequence. The oxalate oxidase activity of the recombinant enzyme is substantially increased (7-fold) by treatment with sodium periodate, followed by ascorbate reduction. Using these methods, approximately 1 g (4x10(4) U) of purified, activated enzyme was obtained following eight days of induction of a high density Pichia fermentation culture, demonstrating suitability for large-scale production of oxalate oxidase for biotechnological applications. Characterization of the recombinant protein shows that it is glycosylated, with N-linked glycan attached at Asn47. For potential biomedical applications, a nonglycosylated (S49A) variant was also prepared which retains essentially full enzyme activity, but exhibits altered protein-protein interactions.