Purification and characterization of cytosolic 6-phosphogluconate dehydrogenase isozymes from maize

Cytosolic isozymes of 6-phosphogluconate dehydrogenase were purified from roots of maize (Zea mays L.). The final preparation contained two 55-kD proteins. Affinity-purified dehydrogenases from a maize line that is null for both cytosolic 6-phosphogluconate dehydrogenase isozymes (Pgd1-null, Pgd2-null) lacked the 55-kD proteins. The substrate kinetics of the purified enzyme were determined.     

Specific accumulation of GFP in a non-acidic vacuolar compartment via a C-terminal propeptide-mediated sorting pathway

The aim of this work was to examine the extent to which the oxidative steps of the pentose phosphate pathway in the cytosol contribute to the provision of reductant for biosynthetic reactions. Maize (Zea mays L.) contains at least two loci (pgd1 and pgd2) that encode 6-phosphogluconate dehydrogenase. Ten genotypic combinations of wild-type (Pgd1+3.8;Pgd2+5) and null alleles of pgd1 and pgd2 were constructed in the B73 background. The maximum catalytic activity of 6-phosphogluconate dehydrogenase in the roots of seedlings of these lines correlated with the number of functional pgd1 and pgd2 alleles. Enzyme activity in the double-null homozygote (pgd1-null;pgd2-null) was 32% of that in B73 wild-type suggesting the presence of at least one other isozyme of 6-phosphogluconate dehydrogenase in maize. Subcellular fractionation studies and latency measurements confirmed that the products of pgd1 and pgd2 are responsible for the vast majority, if not all, of the cytosolic 6-phosphogluconate dehydrogenase activity in maize roots. Essentially, all of the residual activity in the double-null homozygote was confined to the plastids. Low concentrations (0.1–0.5 mM) of sodium nitrite stimulated ¹⁴CO₂ production by detached root tips of both wild-type and 6-phosphogluconate dehydrogenase-deficient maize seedlings fed [U-¹⁴C]glucose. Analysis of the ratio of ¹⁴CO₂ released from [1–¹⁴C]glucose relative to [6–¹⁴C]glucose (C1/C6 ratio) showed that stimulation of the oxidative pentose phosphate pathway by nitrite correlated with the dosage of wild-type alleles of pgd1 and pgd2. The failure of 6-phosphogluconate dehydrogenase-deficient lines to respond to nitrite indicates that perturbation of the cytosolic oxidative pentose phosphate pathway can influence the provision of reductant in the plastid. We conclude that the plastidic and cytosolic oxidative pentose phosphate pathways are able to co-operate in the provision of NADPH for biosynthesis.     

Duplicated chromosome segments in maize (Zea mays L.): further evidence from hexokinase isozymes

Summary The genetic control of hexokinase isozymes (ATP: d-hexose-6-phosphotransferase, E.C. 2.7.7.1, HEX) in maize (Zea mays L.) was studied by starch gel electrophoresis. Genetic analysis of a large number of inbred lines and crosses indicates that the major isozymes observed are encoded by two nuclear loci, designated Hex1 and Hex2. Five active allozymes and one null variant are associated with Hex1, while Hex2 has nine active alleles in addition to a null variant. Alleles at both loci govern the presence of single bands, with no intragenic or intergenic heteromers visible, suggesting that maize HEX's are active as monomers. Organelle preparations demonstrate that the products of both loci are cytosolic. All alleles, including the nulls, segregate normally in crosses. Vigorous and fertile plants were synthesized that were homozygous for null alleles at both loci, suggesting that other hexosephosphorylating enzymes exist in maize that are undetected with our assay conditions. Linkage analyses and crosses with B-A translocation stocks place Hex1 on the short arm of chromosome 3, 27 centimorgans from Pgd2 (phosphogluconate dehydrogenase) and Hex2 on the long arm of chromosome 6, approximately 45 centimorgans from Pgd1. It is suggested that the parallel linkages among these two pairs of duplicated genes reflects an evolutionary history involving chromosome segment duplication or polyploidy.Paper No. 10170 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC     

Genetic mapping of isozyme loci in Secale cereale L.

Summary The genetics and linkage relationships of several isozymatic and morphological markers have been investigated in different cultivars of rye (Secale cereale L.). The inheritance and the variability among cultivars of three new isozymatic zones are described: GOT2 and LAP, each of them under the control of a two-allele single locus, namely Got2 and Lap, respectively; and 6PGD1 controlled by two loci, 6Pgd1a and 6Pgd1b, which have alleles in common. Four linkage groups have been found: Acp2-Acp3, Got3-Mdh2-Lper4, Mdh1-6Pgd2-Pgi2, and Pgm-Eper2-[Eper1-Eper3]. The assignment of these four groups to the chromosomes 7R, 3R, 1R, and 4R is discussed.     

Murine liver arylsulfatase B processing influenced by region on chromosome 17

SM/J liver arylsulfatase B has a more rapid electrophoretic mobility and occurs as a series of more acidic isozymes following electrofocusing in narrow pH gradients than the liver enzyme from C57BL/6J mice. The SM/J and C57BL/6J electrofocusing patterns were both converted to a single isozyme with similar isoelectric points by pretreatment with neuraminidase, suggesting that the SM/J and C57BL/6J isozymes differed with respect to their sialic acid content. Arylsulfatase B electrofocusing and thermostability phenotypes segregated independently among progeny of SM/J×C57BL/6J crosses, suggesting that the electrofocusing phenotypes were not determined by different alleles at As-1, the putative structural locus for arylsulfatase B. Comparison of the joint segregation of hepatic acid phosphatase electrophoretic patterns and liver arylsulfatase B electrofocusing profiles revealed that the electrofocusing profiles may be determined by a region on chromosome 17 near or identical to Apl. Kidney, brain, and spleen arylsulfatase B electrofocusing patterns did not appear to differ between SM/J and C57BL/6J mice.This research was supported in part by Biomedical Sciences Research Support Grant RR-07030, by NIGMS Grant 1-RO1GM27707-01, and by Grant 1–570 from the National Foundation/March of Dimes.     

Genetic variation in cultivars of diploid ryegrass,Lolium perenne andL. multiflorum,at five enzyme systems

Summary Samples of approximately 100 plants from each of 22 populations ofLolium perenne representing 15 cultivars, and from 13 populations ofLolium multiflorum representing six cultivars were scored for iso-zyme variants in five enzyme systems, PGI, GOT, ACP, PGM and 6-PGD. From the individual banding patterns a genetic interpretation of the variation was formulated and population studies of the resulting six polymorphic enzyme loci were performed. No strong indications of partial selfing was found since at four of the six loci,Pgi 2, Got 3, Pgm 1 andPgd 1, the genotypic proportions were in correspondence with the Hardy-Weinberg expectations. This indicated, further, that the genetical interpretations of the banding patterns might be correct. Deviations from Hardy-Weinberg proportions forAcp 1 andGot 2 indicated presumably selection working on the linkage group including these loci. Gametic phase disequilibrium was observed betweenPgi 2 andPgd 1 for populations of one cultivar. These results were discussed in relation to the variation expected within a cultivar.     

A valine-resistant mutant ofArabidopsis thaliana displays an acetolactate synthase with altered feedback control

A valine-resistant mutant line, VAL-2, ofArabidopsis thaliana (L.) Heynh. was identified by screening M 2 populations of ethylmethane-sulfonate-mutagenized seeds. The resistance was found to be due to a single, dominant, nuclear gene mutation. Assay of acetolactate synthase (ALS) indicated that the valine resistance in this mutant is caused by decreased sensitivity of ALS to the branched-chain amino acids, valine, leucine andisoleucine. A two fold decrease in apparentK _m value for pyruvate of the mutant ALS enzyme was detected compared with that of the wild type. The sensitivity of the ALS enzyme to sulfonylurea, imidazolinone and triazolopyrimidine herbicides was not altered in the mutant. At the plant growth level the mutant was also resistant to valine plus leucine, but was sensitive to leucine orisoleucine alone. The mutant gene,var1, maps, or is very closely linked, toCSR1, the gene encoding acetolactate synthase inArabidopsis.Abbreviations ALS acetolactate synthase - BCAA branched-chain amino acid - CS chlorsulfuron - IM imidazolinone - SU sulfonylurea - TP triazolopyrimidine We thank Dr. George W. Haughn for providing Arabidopsis lines MSU12, MSU15, MSU21, MSU22 and MSU23. This work was supported by a Research Grant from the Natural Sciences and Engineering Research Council of Canada to J.K., K.W. is grateful for a University of Saskatchewan Graduate Scholarship.     

Genetic relationships between the multiple alcohol dehydrogenases of maize

There are three electrophoretically separable sets of alcohol dehydrogenase isozymes in maize. Previous work has shown that two of these isozymes (Sets I and II) share a subunit in common, since mutations in one of the Adh genes, Adh ₁, alter both isozymes. A mutation in the second Adh gene, Adh ₂, has now been induced and recovered. This mutant allele also alters two of the three isozymes—Sets III and II. Adh ₁ and Adh ₂ appear to segregate independently. Gel filtration data show that all ADH isozymes are indistinguishable in size. These findings support the hypothesis that the two Adh genes specify promoters which homo- and heterodimerize, yielding three types of ADH isozymes.This research was supported by National Science Foundation Grant GB 25594. M.F. is a recipient of Public Health Service Genetics Training Grant GM 82-12.     

Abnormal Mammary Development in 129:STAT1-Null Mice is Stroma-Dependent

Female 129:Stat1-null mice (129S6/SvEvTac-Stat1^tm1Rds homozygous) uniquely develop estrogen-receptor (ER)-positive mammary tumors. Herein we report that the mammary glands (MG) of these mice have altered growth and development with abnormal terminal end buds alongside defective branching morphogenesis and ductal elongation. We also find that the 129:Stat1-null mammary fat pad (MFP) fails to sustain the growth of 129S6/SvEv wild-type and Stat1-null epithelium. These abnormalities are partially reversed by elevated serum progesterone and prolactin whereas transplantation of wild-type bone marrow into 129:Stat1-null mice does not reverse the MG developmental defects. Medium conditioned by 129:Stat1-null epithelium-cleared MFP does not stimulate epithelial proliferation, whereas it is stimulated by medium conditioned by epithelium-cleared MFP from either wild-type or 129:Stat1-null females having elevated progesterone and prolactin. Microarrays and multiplexed cytokine assays reveal that the MG of 129:Stat1-null mice has lower levels of growth factors that have been implicated in normal MG growth and development. Transplanted 129:Stat1-null tumors and their isolated cells also grow slower in 129:Stat1-null MG compared to wild-type recipient MG. These studies demonstrate that growth of normal and neoplastic 129:Stat1-null epithelium is dependent on the hormonal milieu and on factors from the mammary stroma such as cytokines. While the individual or combined effects of these factors remains to be resolved, our data supports the role of STAT1 in maintaining a tumor-suppressive MG microenvironment.     

New isozyme systems for maize (Zea mays L.): Aconitate hydratase,adenylate kinase,NADH dehydrogenase,and shikimate dehydrogenase

Electrophoretic variation and inheritance of four novel enzyme systems were studied in maize (Zea mays L.). A minimum of 10 genetic loci collectively encodes isozymes of aconitate hydratase (ACO; EC 4.2.1.3.), adenylate kinase (ADK; EC 2.7.4.3), NADH dehydrogenase (DIA; EC 1.6.99.—), and shikimate dehydrogenase (SAD; EC 1.1.1.25). At least four loci are responsible for the genetic control of ACO. Genetic data for two of the encoding loci,Aco1 andAco4, demonstrated that at least two maize ACOs are active as monomers. Analysis of organellar preparations suggests that ACO1 and ACO4 are localized in the cytosolic and mitochondrial subcellular fractions, respectively. Maize ADK is encoded by a single nuclear locus,Adk1, governing monomeric enzymes that are located in the chloroplasts. Two cytosolic and two mitochondrial forms of DIA were electrophoretically resolved. Segregation analyses demonstrated that the two cytosolic isozymes are controlled by separate loci,Dia1 andDia2, coding for products that are functional as monomers (DIA1) and dimers (DIA2). The major isozyme of SAD is apparently cytosolic, although an additional faintly staining plastid form may be present. Alleles atSad1 are each associated with two bands that cosegregate in controlled crosses. Linkage analyses and crosses with B-A translocation stocks were effective in determining the map locations of six loci, including the previously described but unmapped locusAcp4. Several of these loci were localized to sparsely mapped regions of the genome.Dia2 andAcp4 were placed on the distal portion of the long arm of chromosome 1, 12.6 map units apart.Dia1 was localized to chromosome 2, 22.2 centimorgans (cM) fromB1. Aco1 was mapped to chromosome 4, 6.2 cM fromsu1. Adk1 was placed on the poorly marked short arm of chromosome 6, 8.1 map units fromrgd1. Less than 1% recombination was observed betweenGlu1 (on chromosome 10) andSad1. In contrast to many other maize isozyme systems, there was little evidence of gene duplication or of parallel linkage relationships for these allozyme loci. This work was supported by grants from Pioneer Hi-Bred International, Inc., of Johnston, Iowa, the National Institute of Health (Research Grant GM11546), and the United States Department of Agriculture (Competitive Research Grant 83-CRCR-1-1273). This is Paper No. 11372 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh.     

Genetics of allozyme variation in Gossypium arboreum L. and Gossypium herbaceum L. (Malvaceae)

Summary Seed protein extracts from 90 accessions of Gossypium arboreum and 70 accessions of Gossypium herbaceum were electrophoretically analyzed for isozyme variation. Eighteen enzyme systems were resolved, ten of which were polymorphic among accessions. No within accession isozyme variation was observed within these highly inbred lines. A minimum of 24 genes encode the isozymes resolved and data is presented for codominant inheritance at 13 loci. Tests for non-random joint segregation in 63 of the 78 possible two-locus combinations from the 13 characterized loci give evidence for four pairs of linked genes (Lap2/Me1 [r=0.160+/-0.027], Lap2/Pgi1 [r= 0.285+/-0.055], Mdh6/Tpi1 [r= 0.197+/-0.028], and 6Pgd2/6Pgd3[r 0.000]. Numerous presumptive duplicate isozyme loci were observed and these were usually expressed as patterns of nonsegregating heteromultimers within accessions. Single gene expression was also observed at several loci. The observed results are in agreement with those of previous cytological investigations which have proposed the polyploid origin of the diploid Old World Gossypiums.     

The responses of wild-type and ABA mutant Arabidopsis thaliana plants to phosphorus starvation

The growth patterns of plants subjected to phosphorus starvation resemble those caused by treatment with ABA, suggesting that ABA could mediate the response of the plant to phosphorus starvation. We examined the role of ABA in phosphorus stress by comparing growth and biochemical responses of Arabidopsis thaliana ABA mutants aba-1 and abi2-1 to those of wild-type plants. We first characterized acid phosphatase production of wild-type Arabidopsis in response to phosphorus starvation. We found that several acid phosphatase isozymes are present in roots and shoots, but only a subset of these isozymes are induced by phosphorus stress, and they are induced in both organs. Production of acid phosphatase in response to phosphorus stress was not affected by the aba-1 or abi2-1 mutations. Low phosphorus also resulted in decreased growth of both wild-type and ABA mutant plants, and the root-to-shoot ratio was increased in both wild type and mutants. Anthocyanins accumulated in response to phosphorus stress in both wild-type and mutant plants, but the increase was reduced in the aba-1 mutant. Thus, two different ABA mutants responded normally in most respects to phosphorus stress. Our data do not support a major role for ABA in coordinating the phosphorus-stress response.     

Biochemical genetics of Fundulus heteroclitus (L.). III. Inheritance of isocitrate dehydrogenase (Idh-A and Idh-B), 6-phosphogluconate dehydrogenase (6-Pgdh-A), and serum esterase (Est-S) polymorphisms

Starch gel electrophoresis has shown that natural populations of Fundulus heteroclitus have variants at four enzyme-coding loci: Idh-A, Idh-B, 6-Pgdh-A, and Est-S. Analysis of the phenotypic distribution of the F₁ generation suggests that each of the variants segregates as autosomally inherited codominant alleles. Tissue specificity and intracellular localization were also determined for the IDH and 6PGDH isozymes.This work was supported by Grants DEB 76-19877 and DEB 79-12216 from the National Science Foundation and by Grant P60-80-04 from the State of Maryland. RVB and REC were supported by NIH Training Grant GM07231 to the Department of Biology.Contribution No. 1103 from the Department of Biology, The Johns Hopkins University.     

Multiple molecular forms of xanthine dehydrogenase and related enzymes. IV. The relationship of aldehyde oxidase to xanthine dehydrogenase

Variants of the enzyme aldehyde oxidase in Drosophila melanogaster are described. In addition to electrophoretic variants, a mutant that causes low levels of the enzyme has been found by screening more than 80 strains for aldehyde oxidase levels. The locus of the mutation maps on the third chromosome near lpo and aldox. The existence of the ry, lpo, and aldox mutants and of the new mutant indicates that xanthine dehydrogenase, pyridoxal oxidase, and aldehyde oxidase are under a separate genetic control, in addition to a common genetic control by ma-l and lxd. The genetic separation is shown to be accompanied by physical separation of the enzymes with DEAE-cellulose column chromatography and (NH ₄)₂SO₄fractionation. Further data on the metabolism of aldehydes by xanthine dehydrogenase and aldehyde oxidase are presented. Although xanthine dehydrogenase requires NAD or a similar cofactor to metabolize purine and pteridine substrates, aldehyde oxidase oxidizes salicylaldehyde to salicylic acid without dissociable cofactors and with the uptake of oxygen.This work was supported in part by Research Grant GM-08202, by a Predoctoral Fellowship (J.C.) and a Genetics Training Grant (J.C. and E.D.), and by a Research Career Development Award (E.G.), all from the National Institutes of Health. Part of this work was submitted by J.C. to the University of North Carolina at Chapel Hill in partial fulfillment of the degree of Doctor of Philosophy.     

Repression of the Plastidic Isoenzymes of Aldolase, 3-Phosphoglycerate Kinase, and Triosephosphate Isomerase in the Barley Mutant "albostrians"

White leaves of the mutant line albostrians and green leaves of the wild-type cultivar Salome of barley (Hordeum vulgare L.) were screened for the presence of plastidic and cytosolic isoenzymes of sugar-phosphate metabolism. Isoenzyme separation was achieved by anion-exchange chromatography on Fractogel TSK DEAE-650(S). The mutant tissue had a markedly reduced level of plastidic 3-phosphoglycerate kinase, triosephosphate isomerase, and aldolase activity. In contrast, the activity of plastidic glucosephosphate isomerase, fructose 1,6-bisphosphatase, 6-phosphogluconate dehydrogenase, starch phosphorylase, and ADP-glucose pyrophosphorylase was in the same range as in wild-type leaf tissue. The activity of the corresponding cytosolic isoenzymes (including UDP-glucose pyrophosphorylase) showed essentially no differences in mutant and wild type. The same trend was observed in dark-grown mutant and wild-type leaves. Interestingly, the total activity levels of all isoenzymes were about the same when comparing dark-grown and light-grown mutant or wild-type plants. From these data, it is concluded that mutant leaves exhibit a selective decrease of a subgroup of plastidic isoenzymes associated with the Calvin cycle.     

Genetic evaluation of peroxisomal and cytosolic acetoacetyl-CoA thiolase isozymes in n-alkane-assimilating diploid yeast, Candida tropicalis

The n-alkane-assimilating diploid yeast, Candida tropicalis, possesses two acetoacetyl-CoA thiolase (Thiolase I) isozymes encoded by one allele: peroxisomal and cytosolic Thiolase Is encoded by both CT-T1A and CT-T1B. To clarify the function of peroxisomal and cytosolic. Thiolase Is, the site-directed mutation leading Thiolase I ΔC6 without a putative C-terminal peroxisomal targeting signal was introduced on CT-T1A locus in the ct-t1bΔ-null mutant. The C-terminus-truncated Thiolase I was active and solely present in the cytosol. Although the ct-t1aΔ/t1bΔ-null mutants showed mevalonate auxotrophy, the mutants having the C-terminus-truncated Thiolase I did not require mevalonate for growth, as did the strains having cytosolic Thiolase I. These results demonstrated that the presence of Thiolase I in the cytoplasm is indispensable for the sterol synthesis in this yeast. It is of greater interest that peroxisomal and cytosolic Thiolase I isozymes, products of the same genes, play different roles in the respective compartments, although further investigations will be necessary to analyze how to be sorted into peroxisomes and the cytosol.     

Duplication of the autosomally inherited 6-phosphogluconate dehydrogenase gene locus in tetraploid species of cyprinid fish

Among members of the fish family Cyprinidae,a diploid—tetraploid relationship exists. The present study on electrophoretic patterns of 6-phosphogluconate dehydrogenase indicates that such diploid members as Barbus tetrazonamaintain allelic polymorphism at a single gene locus for this enzyme. Tetraploid members such as the carp and goldfish are endowed with two separate gene loci for 6-PGD. Tetraploid evolution apparently fixed two former alleles of the same locus as two separate gene loci. Furthermore, it appears that after becoming tetraploid, the carp and goldfish developed a separate regulatory mechanism for each locus; thus preferential activation of one or the other 6-PGD locus occurs in different tissues of tetraploid species. This investigation was supported in part by a grant (CA-05138) from the National Cancer Institute, U.S. Public Health Service, and in part by a research fund established in honor of General James H. Doolittle. Contribution No. 4-68, Department of Biology, City of Hope Medical Center.Dr. Bender is a recipient of International Postdoctoral Fellowship 3 F05-TW-01198-0152 from the U.S. Public Health Service.     

Degradation of Sulfhydryl Groups in Soymilk by Lipoxygenases during Soybean Grinding

The process of degradation of sulfhydryl (SH) groups in soymilk was investigated by using Glycine max var. Suzuyutaka (wild type) and the following seven mutant lines lacking lipoxygenase(s): L-1-, L-2-, L-3-, L-1,-2-, L-2,-3-, L-1,-3-, and L-1,-2,-3-null. The soymilk prepared from the L-1,-2,-3-null line of all the mutants had the highest SH content. The content of SH groups was the lowest with the L-1,-3-null line of the three double-null lines and the highest with the L-2-null line of the three single-null lines. These results show that lipoxygenases strongly participated in the degradation of SH groups in soymilk and that the L-2 isozyme had the greatest SH-degrading capability. When these soybean samples were ground under low-temperature conditions and in a nitrogen (N₂) atmosphere to inhibit the degradation of SH groups caused by lipoxygenases, SH degradation of the L-2,-3- and L-1,-3-null lines was strongly inhibited at low temperature, while that of the L-1,-2-null line was strongly inhibited in the N₂ atmosphere. In view of the strong inhibition of SH degradation in an N₂ atmosphere with Suzuyutaka (wild type), which has three L-1,-2,-3 isozymes, these results suggest that not only the L-2 isozyme but also that the L-3 isozyme of the three in Suzuyutaka played an important role in SH degradation during soybean grinding.