GENETIC CONTROL OF CYTODIFFERENTIATION

The cells of the anterior region of the larval fatbody of Drosophila melanogaster accumulate kynurenine at the end of the third larval instar, whereas the cells of the posterior region are involved in pteridine metabolism. Through a series of transplantation experiments it has been demonstrated that the anterior fat cells synthesize kynurenine. The mutant vermilion lacks kynurenine, and the anterior fat cells of this mutant strain lack the autofluorescence characteristic of kynurenine. When the non-allelic suppressor gene is combined with vermilion, the synthesis of kynurenine is restored in the anterior fat cells, and some of the cells of the posterior region contain kynurenine as well. A similar extension in the number of cells containing kynurenine can be induced in the normal Ore-R strain by feeding the precursor tryptophan. It has been concluded that the absence of a physiological process in a differentiated cell does not necessarily represent a loss of the genetic potential for that process. The normal allele at the suppressor locus inhibits the occurrence of kynurenine in the posterior fat cells, whereas the mutant allele su²-s allows the expression of this potential. An inducer such as tryptophan can overcome this inhibition in the normal strain, and as a result the cells which are normally differentiated as "isoxanthopterin cells" may produce kynurenine as well.     

2,6-Dichlorophenolindophenol is a competitive inhibitor for xanthine oxidase and is therefore not usable as an electron acceptor in the fluorometric assay.

Xanthine oxidase has been recognized as an important source of oxygen free radicals in ischemia-reperfusion injury. In order to study this enzyme in biological tissues, the conversion of pterin (2-amino-4-hydroxypteridine) to isoxanthopterin provides the basis for a very sensitive fluorometric assay. Xanthine oxidase is typically assayed in the presence of pterin only, while an electron acceptor which replaces NAD+ is used to determine the combined xanthine dehydrogenase plus xanthine oxidase activity. 2,6-Dichlorophenol-indophenol has been used as an electron acceptor in this assay. However, it was found in this study that it acts as an effective competitive inhibitor for xanthine oxidase. We concluded that methylene blue is the electron acceptor of choice in the fluorometric assays for xanthine oxidase.     

MUTANT GENES REGULATING THE INDUCIBILITY OF KYNURENINE SYNTHESIS

Alterations in the cellular synthesis of kynurenine in the larval fatbody of Drosophila melanogaster may be obtained by feeding the precursor tryptophan or by changing the genotype. In the wild type Ore-R strain, autofluorescent kynurenine globules normally occur in the cells in the anterior regions of the fatbody designated as regions 1, 2, and 3. When tryptophan is included in the larval diet, kynurenine will develop throughout the entire fatbody, thus extending to the cells in regions 4, 5, and 6. In the fatbodies of both the sepia mutant strain and the mutant combinations of the suppressible vermilion alleles with the suppressor gene (su²-s, v¹ and su²-s, v²), kynurenine is found in the cells from region 1 through region 4. This involvement of additional cells in the synthesis of kynurenine occurs under the usual culture conditions for Drosophila. When sepia larvae are fed tryptophan, kynurenine appears in all of the cells of the fatbody. However, dietary tryptophan does not induce kynurenine production in cells in regions 5 and 6 in the mutant combination su²-s, v¹ or su²-s, v². In the latter strains, an increase in the quantity of kynurenine in the fatbody is detected, but this increase remains limited to the same cells in which kynurenine production is found under normal feeding conditions. When the v^36f allele is combined with the su²-s allele, an extremely faint autofluorescence characteristic of kynurenine is found in some of the anteriormost fat cells of regions 1 and 2. This autofluorescence becomes intensified when tryptophan is fed to su²-s, v^36f larvae. The genetic control of kynurenine synthesis in the cells of the fatbody of Drosophila melanogaster has been previously demonstrated. The present observations establish genetic regulation of the ability to induce kynurenine production within a cell through the administration of the inducer tryptophan. Kynurenine production has been considered as a unit function of the cell as a whole rather than of the enzyme alone, and it has been concluded that even though cells in different parts of the body perform this same function (kynurenine production), the gene loci regulating this function may be different for cells in different regions of the body. A phenomenon of overlapping domains of gene actions at the cellular level offers a genetic and cellular basis for developmental and physiological homeostasis.     

A sensitive fluorometric assay for measuring xanthine dehydrogenase and oxidase in tissues

The conversion of xanthine dehydrogenase to a free radical producing oxidase is an important component of oxygen-mediated tissue injury. Current assays for these enzymes are of limited sensitivity, making it difficult to analyze activities in organ biopsies or cultured cells. The xanthine oxidase-catalyzed conversion of pterin (2-amino-4-hydroxypteridine) to isoxanthopterin provides the basis for a fluorometric assay which is 100-500 times more sensitive than the traditional spectrophotometric assay of urate formation from xanthine. Enzyme activity as low as 0.1 pmol min-1 ml-1 can be measured with the fluorometric pterin assay. Xanthine oxidase is assayed in the presence of pterin only, while combined xanthine dehydrogenase plus oxidase activity is determined with methylene blue which replaces NAD+ as an electron acceptor. The relative proportions and specific activities of xanthine oxidase and dehydrogenase determined by the fluorometric pterin assay are comparable with the spectrophotometric measurement of activities present in rat liver, intestine, kidney, and plasma. The assay has been successfully applied to brain, human kidney, and cultured mammalian cells, where xanthine dehydrogenase and oxidase activities are too low to detect spectrophotometrically.     

Two indirect methods for detecting ureide synthesis by nodulated legumes

Two methods were developed for the detection of altered ureide metabolism in legume nodules. Both techniques are based on the positive correlation between the presence of high xanthine dehydrogenase (EC 1.2.1.37) specific activity in nodules and the ability of those nodules to produce the ureides, allantoin and allantoic acid. In the first method, nodulated legumes are treated for 2 weeks with a soil drench of allopurinol. After allopurinol treatment, leaves of N₂-fed, ureide-producing legumes, soybean, cowpea, and lima bean, became very chlorotic. Leaves of KNO₃⁻ or NH₄Cl-fed ureide-producing legumes were unaffected by the allopurinol treatment. Leaves of the amide-producing legumes, alfalfa, clover, peak, and lupin, were unaffected by the allopurinol treatment with N₂, KNO₃, or NH₄Cl as nitrogen source. These experiments showed that long-term allopurinol treatments are useful in differentiating between ureide- and amide-producing legumes when effectively nodulated. A second method was developed for the rapid, qualitative estimation of xanthine dehydrogenase activity in legume nodules. This method utilizes pterin, an alternate substrate for xanthine dehydrogenase. Xanthine dehydrogenase hydroxylates pterin in the presence of NAD⁺ to produce isoxanthopterin. When exposed to long wave ultraviolet light (365 nanometers), isoxanthopterin emits blue fluorescence. When nodules of ureide-producing legumes were sliced in half and placed in microtiter plate wells containing NAD⁺ and pterin, isoxanthopterin was observed after 6 hours of incubation at room temperature. Allopurinol prevented isoxanthopterin production. When slices of amide-producing legume nodules were placed in wells with pterin and NAD⁺, no blue fluorescence was observed. The production of NADH by xanthine dehydrogenase does not interfere with the fluorescence of isoxanthopterin. These observations agree with the high specific activity of xanthine dehydrogenase in nodules of ureide-producing legumes and the low activity measured in amide-producing nodules. The wild soybean, Glycine soja Sieb. and Zucc., was examined for ureide synthesis. Stems of wild soybean plants had a high ureide abundance with N₂ as sole nitrogen source when nodulated with either Rhizobium fredii or Bradyrhizobium japonicum. Ureide abundance declined when nitrate or ammonium was added to the nutrient solution. Nodule slices of these plants produced isoxanthopterin when incubated with pterin. Nodule crude extracts of G. soja had high levels of xanthine dehydrogenase activity. Both Glycine max and G. soja plants were found to produce ureides when plants were inoculated with fast-growing R. fredii. The two methods described here can be used to discriminate ureide producers from amide producers as well as detect nitrogen-fixing legumes which have altered ureide metabolism. A nodulated legume that lacks xanthine dehydrogenase activity as demonstrated by the pterin assay cannot produce ureides since ureide synthesis has been shown to require xanthine dehydrogenase activity both in vivo and in vitro. A nodulated legume that remains green during allopurinol treatment also lacks ureide synthesis since the leaves of ureide-producing legumes are very chlorotic following allopurinol treatment.     

Sensitivity of insect ovarian tissues to various pteridines as tested in tissue culture

The effect of pteridine derivatives and analogues on the cell outgrowth from the ovarian explants of the waxmoth, Galleria mellonella, was examined in hanging-drop cultures and cytochemical tests were made for succinate and glucose-6-phosphate dehydrogenases. Most of the derivatives and analogues of 2-amino-4-hydroxypteridine injured to a lesser or greater extent insect ovarian tissues in vitro, depending on the drug structure and the concentration applied. Of all the pteridine derivatives and analogues tested only 2-amino-4-mercaptopteridine and its C-6,7-dimethyl derivative (10 μM) promoted cell outgrowth from the explants as did folate.     

INTRACELLULAR LOCALIZATION OF KYNURENINE IN THE FATBODY OF DROSOPHILA

Light blue fluorescent globules accumulate in the cells of the anterior region of the fatbody of Drosophila larvae near the time of pupation. This fluorescent material appears in the Ore-R wild type strain as well as mutant strains in which the synthesis of both the red and brown eye pigments is affected. The vermilion mutant, which is characterized by the absence of the brown pigment component in the eye, was the only strain among those examined which did not develop the light blue fluorescent globules. Utilizing chromatographic techniques together with the information gained by examination of the mutant strains, the fluorescent material has been identified as kynurenine. Of particular interest is the manner of appearance of the fluorescent material in the vicinity of the nuclear membrane of the fat cells.     

Germ line abnormalities InDrosophila simulans transfected with the transposable P element

A strain ofDrosophila simulans was studied 40 generations after the transposable P element had been introduced into the genome by means of transformation. The genome also contained arosy transposon consisting of the wildtype allele of therosy gene flanked by P element DNA. During the 40 generations of evolution the number of P elements had increased to the level of 8–15 and the number ofrosy transposons to the level of 4–12. Continued transpositional activity in the germ line of the strain was evidenced by deletions occurring in therosy transposon and, in two independent sublines, by the transposition of therosy transposon from the X chromosome to the autosomes. Although at 25°C gonadal development and fertility appeared normal in both sexes, at 29°C both sexes were sterile. The sterile females had morphologically normal ovaries, but the sterile males often had shrunken, dysmorphic testes containing few or no immature sperm bundles. However, the sterility found in the transfected strain may not result directly from transpositional activity of the P element. The characteristics of theD. simulans strain infected with the P element are discussed in the context of factors that influence hybrid dysgenesis inD. melanogaster.     

Nitrate reductase-deficient mutants in barley : immunoelectrophoretic characterization

Nitrate reductase-deficient barley (Hordeum vulgare L.) mutants were assayed for the presence of a functional molybdenum cofactor determined from the activity of the molybdoenzyme, xanthine dehydrogenase, and for nitrate reductase-associated activities. Rocket immunoelectrophoresis was used to detect nitrate reductase cross-reacting material in the mutants. The cross-reacting material levels of the mutants ranged from 8 to 136% of the wild type and were correlated with their nitrate reductase-associated activities, except for nar 1c, which lacked all associated nitrate reductase activities but had 38% of the wild-type cross-reacting material. The cross-reacting material of two nar 1 mutants, as well as nar 2a, Xno 18, Xno 19, and Xno 29, exhibited rocket immunoprecipitates that were similar to the wild-type enzyme indicating structural homology between the mutant and wild-type nitrate reductase proteins. The cross-reacting materials of the seven remaining nar 1 alleles formed rockets only in the presence of purified wild-type nitrate reductase, suggesting structural modifications of the mutant cross-reacting materials. All nar 1 alleles and Xno 29 had xanthine dehydrogenase activity indicating the presence of functional molybdenum cofactors. These results suggest that nar 1 is the structural gene for nitrate reductase. Mutants nar 2a, Xno 18, and Xno 19 lacked xanthine dehydrogenase activity and are considered to be molybdenum cofactor deficient mutants. Cross-reacting material was not detected in uninduced wild-type or mutant extracts, suggesting that nitrate reductase is synthesized de novo in response to nitrate.     

Dictyostelium discoideum cobB mutants show reduced heavy metal accumulation associated with gene amplification

Wild-type Dictyostelium discoideum cells grow- ing on non-toxic levels of nickel chloride or cobaltous chloride accumulate 2–3.5 times as much nickel and at least 1.5 times as much cobalt as cobB mutants. The cobB trait is dominant, confers unstable cobalt and nickel resistance and is correlated with the presence of up to 50 copies of a linear extrachromosomal DNA, approximately 100?kb in length, derived from linkage group III. Independent cobB mutants can be obtained by selection on medium containing either cobalt or nickel. The amplified DNA can be transferred to wild-type strains by electroporation. Strains with mutations at a second cobalt resistance locus, cobA, accumulate the same amount of cobalt, but more nickel than wild-type strains. Our results are consistent with the cobA mutant phenotype being due to internal sequestration of cobalt, and the cobB mutant phenotype being due to reduced net uptake of cobalt and nickel. Energy-dependent nickel export was detectable in wild-type and cobB mutant strains but its role in heavy metal resistance has not yet been proved.     

FACTORS AFFECTING THE INTRACELLUALR SYNTHESIS OF KYNURENINE

Near the time of pupation, autofluorescent kynurenine globules appear in the cells in the anterior region of the fatbody of Drosophila melanogaster. It has been reported previously that kynurenine synthesis may be induced in an additional group of fat cells by feeding the precursor tryptophan to Drosophila larvae, and that this induction of kynurenine production viewed within the fat cells is correlated with an increase in tryptophan pyrrolase activity. In the present report, conditions are outlined which result in the appearance of kynurenine in all of the fat cells. The number of cells in the fatbody which contain kynurenine is influenced by the quantity of tryptophan included in the diet, as well as by the developmental stage at the time of treatment and the duration of the feeding period on the inducer. Physical barriers modifying permeability, such as the membranous layer noted surrounding the fatbody, may be a factor in the regulation of the time and nature of the cellular induction of kynurenine synthesis. Another factor to be considered is the possibility of interference with the availability of tryptophan as a substrate or inducer for this synthesis within the cell. It is suggested that the occurrence of pteridines in some of the fat cells may modify the response of these cells to produce kynurenine, since pteridines as electron acceptors can complex with tryptophan as an electron donor. Kynurenine may be produced in the fat cells under in vitro conditions when they are incubated with L-tryptophan, but kynurenine is not formed when fat cells are incubated with D-tryptophan. The in vitro studies further demonstrate that induction of kynurenine synthesis may occur in fat cells isolated from young larvae in contrast, to in vivo conditions in which inducer does not effect an earlier appearance of kynurenine in the larval fatbody.     

Larval adipose tissue of homoeotic bithorax mutants of Drosophila.

In the homoeotic bithorax mutant combination bx³$\text{pbx}\text{Ubx}{}^{105}$ of Drosophila melanogaster, the metathoracic segment is transformed to a mesothoracic segment and the adult flies have an extra pair of wings in place of the paired halteres [Lewis, E. B. (1963). Amer. Zool.3, 33–56]. The morphology of the larval fat body, the number of cells in the fat body, and the distribution pattern of kynurenine autofluorescent materials (KAF+) in this tissue were compared in the homoeotic mutant and a wild-type strain. The mutant has an additional mass of adipose cells anterior to the posterior margin of the ventral commissure of the fat body. However, the total number of adipose cells in the two strains as well as the limits of the KAF+ cell population do not differ. Therefore, the bithorax transformation in the larval fat body involves rearrangement of the same cell population as that in the normal strain. This study suggests (1) that the bithorax mutant genes affect the pattern of cell segregation and/or migration of preblastoderm nuclei during embryogenesis and (2) that the larval fat body of Drosophila has a segmental origin.     

Xanthine dehydrogenase accumulation in developing Drosophila eyes

Xanthine dehydrogenase activity is assayed by following the oxidation of pterin to isoxanthopterin by spectrofluorometry at the reaction's wavelength peaks: excitation, 344 nm; emission, 412 nm. The method is sensitive to less than 0·1 μU of activity (0·1 pmol/min) and allows the assay of Drosophila imaginal disk homogenates.While the larval eye disk contains less than 0·1 per cent of the individual's XDH, the developing eye becomes a major store, with 30 per cent of the individual's activity by the time of eye pigmentation. The data suggest a basis for the well-known non-autonomous action of the gene rosy, the structural gene for XDH: the enzyme is synthesized in an organ of primary gene expression, and transported through the haemolymph to the eye of the pupa and pharate adult.     

Alteration of the gene for xanthine dehydrogenase in Drosophila following treatment with wildtype DNA

Summary Microinjection of whole genome DNA into Drosophila embryos can result in a variety of changes to the host genome. In the experiments reported here, wildtype DNA is injected into mutant animals lacking xanthine dehydrogenase activity by virtue of a mutation in the structural gene for the enzyme, the rosy gene. Animals with wildtype eye pigmentation and normal levels of xanthine dehydrogenase result from the treatment. Analysis of the electrophoretic mobility of the enzyme in the altered stocks indicates, in four of five cases, that the restoration of activity coincides with changes in electrophoretic mobility. The changes which occur are consistent with acquisition of sequence from the donor DNA and, in two cases, provide evidence for recombination between homologous sequences.     

In vitro and in vivo characterization of alkyl hydroperoxide reductase mutant strains of Helicobacter hepaticus

Mutant strains in the tsaA gene encoding alkyl hydroperoxide reductase were more sensitive to O₂ and to oxidizing agents (paraquat, cumene hydroperoxide and t-butylhydroperoxide) than the wild type, but were markedly more resistant to hydrogen peroxide. The mutant strains resistance phenotype could be attributed to a 4-fold and 3-fold increase in the catalase protein amount and activity, respectively compared to the parent strain. The wild type did not show an increase in catalase expression in response to sequential increases in O₂ exposure or to oxidative stress reagents, so an adaptive compensatory mutation has probably occurred in the mutants. In support of this, chromosomal complementation of tsaA mutants restored alkyl hydroperoxide reductase, but catalase was still up-expressed in all complemented strains. The katA promoter sequence was the same in all mutant strains and the wild type. Like its Helicobacter pylori counterpart strain, a H. hepaticus tsaA mutant contained more lipid hydroperoxides than the wild type strain. Hepatic tissue from mice inoculated with a tsaA mutant had lesions similar to those inoculated with the wild type, and included coagulative necrosis of hepatocytes. The liver and cecum colonizing abilities of the wild type and tsaA mutant were comparable. Up-expression of catalase in the tsaA mutants likely permits the bacterium to compensate (in colonization and virulence attributes) for the loss of an otherwise important oxidative stress-combating enzyme, alkyl hydroperoxide reductase. The use of erythromycin resistance insertion as a facile way to screen for gene-targeted mutants, and the chromosomal complementation of those mutants are new genetic procedures for studying H. hepaticus.     

Metabolism of furazolidone by milk xanthine oxidase and rat liver 9000g supernatant: formation of a unique nitrofuran metabolite and an aminofuran derivative

In vitro metabolism of furazolidone (N-(5-nitro-2-furfuryliden)-3-amino-2-oxazolidone) was investigated by using milk xanthine oxidase and rat liver 9000g supernatant. As a result, a new type of reduction product was isolated as one of the main metabolites from the incubation mixture and it was tentatively identified as 2,3-dihydro-3-cyanomethyl-2-hydroxyl-5-nitro-1a, 2-di(2-oxo-oxazolidin-3-yl)iminomethyl-furo[2,3- b]furan. In addition, the present study demonstrated the formation of N-(5-amino-2-furfurylidene)-3-amino-2-oxazolidone as a minor metabolite of nitrofuran in a milk xanthine oxidase system. The aminofuran derivative was easily degraded by milk xanthine oxidase under aerobic, but not anaerobic, conditions. The degradation appears to be due to superoxide anion radicals, hydroxyl radicals, and/or singlet oxygen, which are produced in this enzyme system.     

Constitutive mutants for dextransucrase from Leuconostoc mesenteroides NRRL B-512F

Constitutive mutants for dextransucrase were isolated from cells of Leuconostoc mesenteroides NRRL B-512F by treatment with N-methyl-N′-nitro-N-nitrosoguanidine, growing on an agar plate containing glucose as a carbon source and overlaying a soft agar with sucrose and tetracycline. These mutants were able to produce the enzyme in a liquid media containing sugars other than sucrose, such as glucose, fructose and maltose, without simultaneous synthesis of dextran. The enzyme activity of one mutant strain, SH 3002, was 2- to 3-fold higher than that of the wild strain grown on sucrose. When the concentration of glucose in the medium was increased from 2 to 4%, a 1.7-fold increase of enzyme activity was obtained for the mutant, whereas only a slight increase of the activity was observed on sucrose for both the wild strain and the mutant.