Regulation of 6-hydroxy-2,4,5-triaminopyrimidine synthesis by riboflavin and iron in riboflavin-deficient mutants of Pichia guilliermondii yeast.

The effect of riboflavin and iron on 6-hydroxy-2,4,5-triaminopyrimidine synthesis rate was investigated in the cultures of the yeast Pichia guilliermondii (rib2 mutants) with the blocked second reaction to flavinogenesis. It was shown that riboflavin inhibited the 6-hydroxy-2,4,5-triaminopyrimidine synthesis rate in iron-rich and iron-deficient cells of mutants with low riboflavin requirements. Cycloheximide did not prevent the stimulation of 6-hydroxy-2,4,5-triaminopyrimidine synthesis caused by riboflavin starvation. 7-methyl-8-trifluoromethyl-10-(1'-D-ribityl)isoalloxazine strongly inhibited the 6-hydroxy-2,4,5-triaminopyrimidine synthesis, while 7-methyl-8-trifluoro-methyl-10-(beta-hydroxyethyl)izoalloxazine and galactoflavin exerted only a slight effect on this process. The 6-hydroxy-2,4,5-triaminopyrimidine synthesis rate in iron-deficient cells was significantly higher than in iron-rich cells. The 2,2'-dipyridyl treatment of iron-rich cells caused the stimulation of 6-hydroxy-2,4,5-triaminopyrimidine synthesis and cycloheximide abolished this effect. The results suggest that the activity of the first enzyme of flavinogenesis (guanylic cyclohydrolase) is under the control of feedback inhibition by flavins and the biosynthesis of this enzyme is regulated by iron.     

Genetic control of riboflavin biosynthesis in Pichia guilliermondii yeasts. The detection of a new regulator gene RIB81

The properties of mutants resistant to 7-methyl-8-trifluoromethyl-10-(1'-D-ribityl)-isoalloxazine (MTRY) were studied. The mutants were isolated from a genetic line of Pichia guilliermondii. Several of them were riboflavin overproducers and had derepressed flavinogenesis enzymes (GTP cyclohydrolase, 6.7-dimethyl-8-ribityllumazine synthase) in iron-rich medium. An additional derepression of these enzymes as well as derepression of riboflavin synthase occurred in iron-deficient medium. The characters "riboflavin oversynthesis" and "derepression of enzymes" were recessive in mutants of the 1st class, or dominant in those of the 2nd class. The hybrids of analogue-resistant strains of the 1st class with previously isolated regulatory mutants ribR (novel designation rib80) possessed the wild-type phenotype and were only capable of riboflavin overproduction under iron deficiency. Complementation analysis of the MTRY-resistant mutants showed that vitamin B2 oversynthesis and enzymes' derepression in these mutants are caused by impairment of a novel regulatory gene, RIB81. Thus, riboflavin biosynthesis in P. guilliermondii yeast is regulated at least by two genes of the negative action: RIB80 and RIB81. The meiotic segregants which contained rib80 and rib81 mutations did not show additivity in the action of the above regulatory genes. The hybrids of rib81 mutants with natural nonflavinogenic strain P. guilliermondii NF1453-1 were not capable of riboflavin oversythesis in the iron-rich medium. Apparently, the strain NF1453-1 contains an unaltered gene RIB81.     

Effect of rib83 mutation on riboflavin biosynthesis and iron assimilation in Pichia guilliermondii]

The monogenic rib83 mutation blocked riboflavin oversynthesis in the yeast Pichia guilliermondii and lowered iron acquisition by cells, their ferric reductase activity, and the growth rate in iron-deficient media. Mutants with the combined mutations of rib83 with rib80 and rib81 (the last two mutations impair the negative control of riboflavin synthesis and thus cause its oversynthesis) were unable to depress the enzymes of flavinogenesis (GTP cyclohydrolase and riboflavin synthase) and to overproduce riboflavin in both iron-deficient and iron-sufficient media. This suggests that the rib83 mutation is epistatic with respect to the rib80 and rib81 mutations. The RIB83 gene may positively control both riboflavin synthesis and iron acquisition in the yeast P. guilliermondii.     

Effect of the rib83Mutation on Riboflavin Synthesis and Iron Acquisition in the Yeast Pichia guilliermondii

Abstract–Monogenicrib83mutation blocked riboflavin oversynthesis in the yeast Pichia guilliermondiiand lowered iron acquisition by cells, their ferric reductase activity, and the growth rate in iron-deficient media. Mutants with the combined mutations of rib83with rib80and rib81(the last two mutations impair the negative control of riboflavin synthesis and thus cause its oversynthesis) were unable to depress the enzymes of flavinogenesis (GTP cyclohydrolase and riboflavin synthase) or overproduce riboflavin in both iron-deficient and iron-sufficient media. This suggests that rib83mutation is epistatic with respect to rib80and rib81mutations. The RIB83gene may positively control both riboflavin synthesis and iron acquisition in the yeast P. guilliermondii.     

Nature of riboflavin precursors in Pichia guilliermondi yeasts]

Thirty-nine riboflavin-deficient mutants have been isolated from three yeast strains of Pichia guilliermondii (ATSS 9058, VKM Y-1256, VKM Y-1257) and F5-121 mutant which is capable of production of large amounts of riboflavin in the presence of iron in the medium. All mutants were divided into five groups according to the nature of precursors accumulated in the medium and growth reaction in media with 6,7-dimethyl-8-ribityllumasine and diacetyl. The mutants of the first group did not accumulate specific precursors of riboflavin either in the cells or in the medium. The mutants of the second, third and fourth groups accumulated, after the incubation with diacetyl, 2-amino-4-hydroxy-6,7-dimethylpteridine, 2-amino-4-hydroxy-6,7-dimethyl-8-ribitylpteridine and 6,7-dimethyl-8-ribityllumasine; therefore, they synthesized the following precursors of riboflavin: 2,4,5-triamino-6-hydroxy-pyrimidine, 2,5-diamino-6-hydroxy-4-ribitylaminopyrimidine and 2,6-dihydroxy-5-amino-4-ribitylaminopyrimidine. The mutants of the fifth group accumulated 6,7-dimethyl-8-ribityllumasine in the medium and lacked riboflavin synthetase activity, as was confirmed by enzymatic studies.     

Regulation of synthesis of GTP-cyclohydrolase participating in yeast falvinogenesis by iron

Pichia guilliermondii, Schwanniomyces occidentalis, Torulopsis candida and several riboflavin-dependent mutants of Torulopsis candida were grown in a medium with a low concentration of iron. In these conditions, the activity of GTP-cyclohydrolase which catalyzes the first step of flavinogenesis increases. The activity of the enzyme increases also when the cells of T. candida and P. guilliermondii with a high content of iron are incubated with alpha, alpha'-dipyridyl which induces overproduction of riboflavin; this action of alpha, alpha'-dipyridyl is eliminated by cycloheximide. Therefore, iron deficiency in the cells of these yeasts causes derepression of GTP-cyclohydrolase participating in riboflavin biosynthesis. The activity of the enzyme is inhibited by FAD but not by FMN and riboflavin.     

Regulation of the activity and synthesis of enzymes participating in the formation of 6,7-dimethyl-8-ribityllumazine, a riboflavin precursor in yeast

The properties of two flavinogenesis enzymes--synthase of the aliphatic precursor of riboflavin (APR-synthase) and 6.7-dimethyl-8-ribityllumazinesynthase (DMRL-synthase) of Pichia guilliermondii. It is established that DMRL-synthase, uses APR as a substrate which contains, evidently, a phosphate group. The value of Km for APR is equal to 0.7.10(-5) M, for 2.4-dihydroxy-5-amino-6-ribitylaminopyrimidine--1.25.10(-5) M. It is riboflavin but not FAD that inhibits the activity of DMRL-synthase; the value (I)0.5 is equal to 2.10(-5) M. DMRL, riboflavin, flavin mononucleotide and FAD do not affect the APR-synthase activity. In iron-deficient cells of P. guilliermondii, Torulopsis candida, Debaryomyces kl?ckeri and Schwanniomyces occidentalis realizing the oversynthesis of riboflavin there occurs derepression of DMRL-synthase and APR-synthase.     

Eremothecium ashbyii mutants resistant to 8-azaguanine. II. Mutants with different degrees of resistance to 8-azaguanine]

Guanine, unlike adenine and hypoxanthine, can not eliminate the inhibitory effect of adenine analogues on the growth and flavinogenesis of Eremothecium ashbyii. Guanine does not restore riboflavin synthesis inhibited with 5-10(-3) M 8-azaguanine. Low adenine concentrations (10(-4)-3-10(-4) M), which do not influence the inhibitory effect of 5.-10(-3) M 8-azaguanine, restore the riboflavin synthesis in combination with guanine. On the basis of the data obtained as well as the data of biochemical analysis it is concluded that the riboflavin producer studied lacks guanosinemonophosphate reductase. The mutants resistant to various concentrations of 8-azaguanine have been obtained. In all mutants resistant to 8-azaguanine the efficiency of the incorporation of 14C-guanine and 14C-adenine into mycelium is decreased as compared with the susceptible strain. The mutant Azg-R 10 resistant to high (3-10(-3) M) concentrations of 8-azaguanine, 8-azaadenine and 2,6-diaminopurine secretes inosine-like compounds when grown in a synthetic medium. The stepwise increase of the mutant resistance to 8-azaguanine from 10(-4) M TO 3-10(-3) M did not result in further enhancement of riboflavin synthesis.     

First reaction of riboflavin biosynthesis —Catalysis by a guanosine triphosphate cyclohydrolase from yeast

An enzyme that uses GTP as a substrate for the formation of formate and a 2.4.5-triamino-6-hydroxypyrimidine derivative has been determined in the riboflavin overproducing yeast Pichia guilliermondii. In rib 1 mutants this enzyme is absent. This implies an involvement of the enzyme in the riboflavin biosynthesis and indicates that GTP is a purine precursor of riboflavin. Some properties of the GTP cyclohydrolase (substrate specificity, pH and temperature optima, activators and inhibitors, molecular weight, stability) were studied using a partly purified enzyme preparation. Cells grown under riboflavin overproducing conditions (iron deficiency) have 20–40-fold increased enzyme activity as compared with non-overproducing cultures (supplemented with iron).Non-Standard Abbreviations RF riboflavin - DHRiboyslAP £ 2.5-diamino-6-hydroxy-4-(1-d-ribosylamino)pyrimidine-5-phosphate - DHRibitylAP 2.5-diamino-6-hydroxy-4-(1-ribitylamino)pyrimidine - neopterin 6-(trihydroxypropyl)pterin - DMP 6.7-dimethylpterin - Fe iron deficient condition - +Fe supplemented with iron     

Genetic classification of riboflavin-dependent mutants of Pichia guilliermondii yeasts]

114 riboflavinless mutants were selected from the genetic line of Pichia guilliermondii yeast. By means of accumulation test the mutants were divided into five biochemical groups. In genetic experiments seven complementation classes were found among 106 mutants. The strains of the I biochemical group, accumulating no specific products, corresponded to complementation class rib1; II group, accumulating 2,4,5-triaminopyrimidine - to the class rib2; III group, accumulating 2,6-dihydroxy-4-ribitylaminopyrimidine - to the class rib3; the mutants of the IV group, accumulating 2,6-dihydroxy-5-amino-4-ribitylaminopyrimidine, were divided into three complementation classes rib4, rib5 and rib6; the mutants of the V group, acculumating 6,7-dimethyl-8-ribityllumazine, corresponded to the class rib7. Two mutants of the IV biochemical group within complementation classes rib4 and rib5 were detected could not grow in the medium with diacetyl without riboflavin. Intragenic complementation was found within classes rib6 and rib7. No linkage between mutations of different complementation classes was detected.     

The red mutations impair the regulation of flavinogenesis and metal homeostas in yeast Pichia guilliermondii

A method of positive selection of mutants with impaired regulation of flavinogenesis and metal homeostasis in yeast Pichia guilliermondii was developed. This positive selection system was based on the isolation of pseudo-wild-type revertants (the Rib+ phenotype) in riboflavin-dependent rib1-86 mutant (the Rib- phenotype) of yeast P. guilliermondii. Mutation rib1-86 blocks activity of the GTP cyclohydrolase II catalyzing the first step in riboflavin (RF) biosynthesis. Study of a collection of spontaneous Rib+ revertants allowed the identification of a considerably large number of genetic loci responsible for the suppression of rib1-86, which include both previously identified three loci (rib80, rib81, and hit1) and six new loci designated red1-red6 (reduction). A comparative analysis of the wild-type strain and red mutants revealed that these mutants had higher activity levels of GTP cyclohydrolase and RF-synthase, elevated levels of RF biosynthesis, enhanced Fe/Cu reductase activity and higher total iron content in cells and that they are characterized by enhanced sensitivity to transition metals (Fe(III), Cu(II), Cd(II), Co(II), Zn(II), Ag(I), and to H2O2. The metal hypersensitivity of mutant cells can be prevented by an increased amount of extracellular iron ions. Mutations red1 and red6 synergistically interact with the locus rib81 in the course of RF biosynthesis. Obviously, each RED gene plays an important role in the regulation of both flavinogenesis and metal homeostasis in P. guilliermondii cells.     

The red Mutations Impair the Regulation of Flavinogenesis and Metal Homeostasis in Yeast Pichia guilliermondii

A method of positive selection of mutants with impaired regulation of flavinogenesis and metal homeostasis in yeast Pichia guilliermondii was developed. This positive selection system was based on the isolation of pseudo-wild-type revertants (the Rib⁺ phenotype) in riboflavin-dependent rib1-86 mutant (the Rib^– phenotype) of yeast P. guilliermondii. Mutation rib1-86 blocks activity of the GTP cyclohydrolase II catalyzing the first step in riboflavin (RF) biosynthesis. Study of a collection of spontaneous Rib⁺ revertants allowed the identification of a considerably large number of genetic loci responsible for the suppression of rib1-86, which include both previously identified three loci (rib80, rib81, andhit1) and six new loci designated red1–red6 (reduction). A comparative analysis of the wild-type strain and red mutants revealed that these mutants had higher activity levels of GTP cyclohydrolase and RF-synthase, elevated levels of RF biosynthesis, enhanced Fe/Cu reductase activity and higher total iron content in cells and that they are characterized by enhanced sensitivity to transition metals (Fe(III), Cu(II), Cd(II), Co(II), Zn(II), Ag(I)) and to H₂O₂. The metal hypersensitivity of mutant cells can be prevented by an increased amount of extracellular iron ions. Mutations red1 and red6 synergistically interact with the locus rib81 in the course of RF biosynthesis. Obviously, each RED gene plays an important role in the regulation of both flavinogenesis and metal homeostasis in P. guilliermondii cells.     

Flavinogenesis and regulation of purine biosynthesis de novo in Pichia guilliermondi mutants resiatant to 8-azaguanine]

93 mutants resistant to 8-azaguanine (AGR-mutants) were derived from the strain of Pichia guilliermondii with blocked guanine deaminase (EC 3.5.4.3.) by UV-irradiation. The mutants retained the ability to uptake 8-azaguanine and guanine but could not deaminate guanine. Some of the AGR-mutants were found to accumulate large amounts of hypoxanthine and small amounts of guanine in the cultural medium. The inhibitory effect of guanine and 8-azaguanine but not adenine on the purine biosynthesis de novo was considerably decreased. It was established observing the rates of 5 amino 4-imidazoleribotide accumulation in purine-requiring AGR-mutants in the presence of different purines. The regulation of the activity and biosynthesis of IMP-dehydrogenase (EC 1. 2. 1. 14) with guanine compounds in AGR-mutants was completely preserved. Under cultivating in iron-rich medium all the AGR-mutants accumulated more riboflavin than the strain H-101 and the wild type strain. That occured as a result of the increase of flavinogenesis velocity in AGR-mutants during late logarithmic and negative growth acceleration phases. Some of mutants also synthesized more riboflavin in iron-deficient medium. Depression of riboflavine synthetase was not observed in the iron-rich cells of AGR-mutants.     

8-azaguanine and flavinogenesis in Eremothecium ashbyii.

8-Azaguanine (10- minus 4 M) supplementation in synthetic medium inhibited flavinogenesis in Eremothecium ashbyii to far greater extent (68per cent) than the growth (25 per cent). That enzymes comprising the biosynthetic pathway of riboflavin are synthesized during early growth phase of the organism is supported by the data presented. 8-Azaguanine mediated inhibition in flavinogenesis was closely related with decreased levels of ribose-5'-phosphatase, ribose reductase and ribitol kinase, the enzymes involved in supplying ribitol for flavinogenesis. Addition of guanine and not ribitol during early growth phase to 8-azaguanine-added cultures released the inhibition of riboflavin synthesis and restored the enzyme levels in the presence of the antimetabolite.     

Prenylated flavanones from the twigs of Dorstenia mannii

Investigation of the twigs of Dorstenia mannii gave 6,8-diprenyl-5,7,3′4′-tetrahydroxyflavanone and four new prenylated flavanones, named dorsmanins E-H and characterized as 5,6-7,8-bis-(2,2-dimethylchromano)-3′,4′-dihydroxyflavanone, 7,8-[2″-(1-hydroxy-1-methylethyl)-dihydrofurano]-6-prenyl-5,3′,4′-trihydroxyflavanone, 6,7-[2″-(1-hydroxy-1-methylethyl)dihydrofurano]-8-prenyl-5,3′,4′-trihydroxyflavanone and 6-prenyl-8-(2-hydroxy-3-methylbut-3-enyl)-5,7,3′,4′-tetrahydroxyflavanone, respectively, on the basis of spectral analysis and chemical evidence for the chromano derivative.     

Involvement of outer membrane proteins in enterochelin-mediated iron uptake in Escherichia coli.

Escherichia coli K-12 grown in iron-deficient media contained a large amount of outer membrane proteins O-2a, O-2b, and O-3, while cells grown in iron-supplemented media contained far smaller amounts of these proteins. The iron uptake by the iron-deficient cells was significantly stimulated in the presence of enterochelin, while that by the iron-rich cells was not. The outer membrane isolated from cells grown in the iron-deficient media showed enterochelin-stimulated binding of iron, while the outer membrane from iron-rich cells and cytoplasmic membranes from both types of cells did not show such binding activity. The amount of iron bound by the outer membrane was almost equivalent to the amount of O-2a, O2b, or O-3, irrespective of the amount of these proteins in the outer membrane, which is controlled by the amount of iron in the medium. Small particles rich in these proteins were prepared from cells by EDTA extraction. The particles were active in enterochelin-mediated iron binding and the amount of iron bound was equivalent to the amount of each of these proteins in the particles. Although the outer membrane of E. coli B was as active in iron binding as that of E. coli K-12, it did not possess an appreciable amount of O-2a. Gel electrophoretic analysis revealed that 9-2b and 9-3 were identical with the proteins missing mutants feuB and feuA, respectively.     

Oversynthesis of riboflavin by yeast Pichia guilliermondii in response to oxidative stress

The effect of oxidative stress on riboflavin (vitamin B2) biosynthesis and iron accumulation in flavinogenic yeast P. guilliermondii was investigated. Treatment of P. guilliermondii cells with superoxidgenerating agent methylviologen leads to elevated production of malondialdyhyd (MDA) which reflects the overall cellular oxidation state. Increased iron content in the cells and enhanced productivity of flavinogenesis under these conditions has been shown too. Significant increasing of MDA and riboflavin production by yeast cells under iron deficiency was observed. Riboflavin overproducing P. guilliermondii mutant strains rib80, rib81 and hit, possess high iron transport and synthesize increased quantity of MDA. The role of riboflavin overproduction and activation of iron assimilation in the P. guilliermondii antioxidant defence is discussed.     

The activity of enzymes involved in synthesis and hydrolysis of flavin adenine dinucleotide is Pichia guilliermondii studies at different levels of flavinogenesis

The activity of FAD-pyrophosphorylase and FAD-hydrolase (nucleotidepyrophosphatase) was studied in extracts of Pichia guilliermondii ATCC 9058 capable of riboflavin over-production. The specific activity of the enzymes was highest at the logarithmic growth phase (2.6 and 3.8 mcmoles of FAD per 1 min per 1 mg of protein X10(-5), respectively), and did not increase upon the induction of riboflavin overproduction. A decrease in the content of hemin compounds and a low content of flavins in the cells of Pichia guilliermondii mutants had no considerable effect on the activity of the two enzymes. When the yeast was cultivated on a medium containing hexadecane, an increase in the content of FAD in the cells was not accompanied with a rise in the activity of FAD-pyrophosphorylase. The activity of the enzyme did not change when succinate and lactate, the substrates of FAD-containing enzymes, were used as the source of carbon. The activity of FAD-pyrophosphorylase increased only when iron-deficient cells of the yeast were grown or incubated on a medium containing glycine; this stimulation was inhibited by cycloheximide.     

8-azaguanine and flavinogenesis in Eremothecium ashbyii

8-Azaguanine (10⁻⁴ M) supplementation in synthetic medium inhibited flavinogenesis in Eremothecium ashbyii to far greater extent (68%) than the growth (25%). That enzymes comprising the biosynthetic pathway of riboflavin are synthesized during early growth phase of the organism is supported by the data presented. 8-Azaguanine mediated inhibition in flavinogenesis was closely related with decreased levels of ribose-5′-phosphatase, ribose reductase and ribitol kinase, the enzymes involved in supplying ribitol for flavinogenesis. Addition of guanine and not ribitol during early growth phase to 8-azaguanine-added cultures released the inhibition of riboflavin synthesis and restored the enzyme levels in the presence of the antimetabolite.