Abnormal purine and pyrimidine nucleotide content in primary astroglia cultures from hypoxanthine-guanine phosphoribosyltransferase-deficient transgenic mice

Lesch-Nyhan syndrome is a pediatric metabolic-neurological syndrome caused by the X-linked deficiency of the purine salvage enzyme hypoxanthine-guanine phosphoribosyltransferase (HGPRT). The cause of the metabolic consequences of HGPRT deficiency has been clarified, but the connection between the enzyme deficiency and the neurological manifestations is still unknown. In search for this connection, in the present study, we characterized purine nucleotide metabolism in primary astroglia cultures from HGPRT-deficient transgenic mice. The HGPRT-deficient astroglia exhibited the basic abnormalities in purine metabolism reported before in neurons and various other HGPRT-deficient cells. The following abnormalities were found: absence of detectable uptake of guanine and of hypoxanthine into intact cell nucleotides; 27.8% increase in the availability of 5-phosphoribosyl-1-pyrophosphate; 9.4-fold acceleration of the rate of de novo nucleotide synthesis; manyfold increase in the excretion into the culture media of hypoxanthine (but normal excretion of xanthine); enhanced loss of label from prelabeled adenine nucleotides (loss of 71% in 24 h, in comparison with 52.7% in the normal cells), due to 4.2-fold greater excretion into the media of labeled hypoxanthine. In addition, the HGPRT-deficient astroglia were shown to contain lower cellular levels of ADP, ATP, and GTP, indicating that the accelerated de novo purine synthesis does not compensate adequately for the deficiency of salvage nucleotide synthesis, and higher level of UTP, probably due to enhanced de novo synthesis of pyrimidine nucleotides. Altered nucleotide content in the brain may have a role in the pathogenesis of the neurological deficit in Lesch-Nyhan syndrome.     

Characterization of the Alterations in Purine Nucleotide Metabolism in Hypoxanthine-Guardne Phosphoribosyltransferase-Deficient Rat Neuroma Cell Line

Abstract: A rat neuroma cell line (B103 4C), deficient of hypoxanthine-guanine phosphoribosyltransferase (HGPRT), was utilized as a model tissue in search for the biochemical basis of the Lesch-Nyhan syndrome (LNS). The HGPRT-deficient neurons exhibited the following properties: an almost complete absence of uptake of guanine and of hypoxanthine into intact cell nucleotides (0.92% and 0.69% of normal, respectively); a significant increase in the availability of 5'-phosphoribosyl-1-pyrophosphate; a three- to fourfold acceleration of the rate of de novo nucleotide synthesis; a normal excretion of xanthine, but 15-fold increase in the excretion of hypoxanthine into the culture media; a normal cellular purine nucleotide content, including the absence of 5-amino-4-imidazole carboxamide nucleotides (Z-nucleotides), but enhanced turnover of adenine nucleotides (loss of 86% of the radioactivity of the prelabeled pool in 24 h, in comparison to 73% in the normal line), and an elevated UTP content. The results suggest that, under physiological conditions, guanine salvage does not occur in the normal neurons, but that hypoxanthine salvage is of great importance in the homeostasis of the adenine nucleotide pool. The finding of the normal profile of purine nucleotides in the HGPRT-deficient neurons indicates that the lack of hypoxanthine salvage is adequately compensated by the enhanced de novo nucleotide synthesis. These results did not furnish evidence in support of the possibility that GTP or ATP depletion, or Z-nucleotide accumulation, occurs in HGPRT-deficient neurons and that these are etiological factors causing the neurological abnormalities in LNS. On the other hand, the results point to the possibility that elevated hypoxanthine concentration in the brain may have an etiological role in the pathogenesis of LNS.     

Purine nucleobase transport in human erythrocytes. Reinvestigation with a novel "inhibitor-stop" assay

A novel "inhibitor-stop" method for the determination of initial rates of purine nucleobase transport in human erythrocytes has been developed, based on the addition of seven assay volumes of cold 19 mM papaverine to terminate influx. In view of our finding that the initial velocities of adenine, guanine, and hypoxanthine influx into human erythrocytes were linear for only 4-6 s at 37 degrees C, the present method has been used to reexamine the kinetics of purine nucleobase transport in these cells. Initial influx rates of all three purine nucleobases were shown to be the result of concurrent facilitated and nonfacilitated diffusion. The nonfacilitated influx rates could be estimated either from the linear concentration dependence of nucleobase influx at high concentrations of permeant or from residual influx rates which were not inhibited by the presence of co-permeants. Appropriate corrections for nonfacilitated diffusion were made to the influx rates observed at low nucleobase concentrations. Kinetic analyses indicated that adenine (Km = 13 +/- 1 microM, n = 7), guanine (Km = 37 +/- 2 microM, n = 5), and hypoxanthine (Km = 180 +/- 12 microM, n = 6) were mutually competitive substrates for transport. The Ki values obtained with each nucleobase as an inhibitor of the influx of the other nucleobases were similar to their respective Km values for influx. Furthermore, the transport of the purine nucleobases was not inhibited by nucleosides (uridine, inosine) or by inhibitors of nucleoside transport (6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine, dilazep, dipyridamole). It is concluded that all three purine nucleobases share a common facilitated transport system in human erythrocytes which is functionally distinct from the nucleoside transporter.     

A comprehensive model of purine uptake by the malaria parasite Plasmodium falciparum: identification of four purine transport activities in intraerythrocytic parasites

Plasmodium falciparum is incapable of de novo purine biosynthesis, and is absolutely dependent on transporters to salvage purines from the environment. Only one low-affinity adenosine transporter has been characterized to date. In the present study we report a comprehensive study of purine nucleobase and nucleoside transport by intraerythrocytic P. falciparum parasites. Isolated trophozoites expressed (i) a high-affinity hypoxanthine transporter with a secondary capacity for purine nucleosides, (ii) a separate high-affinity transporter for adenine, (iii) a low-affinity adenosine transporter, and (iv) a low-affinity/high-capacity adenine carrier. Hypoxanthine was taken up with 12-fold higher efficiency than adenosine. Using a parasite clone with a disrupted PfNT1 (P. falciparum nucleoside transporter 1) gene we found that the high-affinity hypoxanthine/nucleoside transport activity was completely abolished, whereas the low-affinity adenosine transport activity was unchanged. Adenine transport was increased, presumably to partly compensate for the loss of the high-affinity hypoxanthine transporter. We thus propose a model for purine salvage in P. falciparum, based on the highly efficient uptake of hypoxanthine by PfNT1 and a high capacity for purine nucleoside uptake by a lower affinity carrier.     

Genetic and physiological characterization of Bacillus subtilis mutants resistant to purine analogs.

Bacillus subtilis mutants defective in purine metabolism have been isolated by selecting for resistance to purine analogs. Mutants resistant to 2-fluoroadenine were found to be defective in adenine phosphoribosyltransferase (apt) activity and slightly impaired in adenine uptake. By making use of apt mutants and mutants defective in adenosine phosphorylase activity, it was shown that adenine deamination is an essential step in the conversion of both adenine and adenosine to guanine nucleotides. Mutants resistant to 8-azaguanine, pbuG mutants, appeared to be defective in hypoxanthine and guanine transport and normal in hypoxanthine-guanine phosphoribosyltransferase activity. Purine auxotrophic pbuG mutants grew in a concentration-dependent way on hypoxanthine, while normal growth was observed on inosine as the purine source. Inosine was taken up by a different transport system and utilized after conversion to hypoxanthine. Two mutants resistant to 8-azaxanthine were isolated: one was defective in xanthine phosphoribosyltransferase (xpt) activity and xanthine transport, and another had reduced GMP synthetase activity. The results obtained with the various mutants provide evidence for the existence of specific purine base transport systems. The genetic lesions causing the mutant phenotypes, apt, pbuG, and xpt, have been located on the B. subtilis linkage map at 243, 55, and 198 degrees, respectively.     

Developmental-stage-dependent adenine transport in Neurospora crassa.

Although germinated conidia of Neurospora crassa transport adenine through two different systems, only one of these, namely, the general purine transport system, which transports adenine, hypoxanthine, guanine, and 6-methylpurine, is present in freshly harvested conidia of the wild type. The second system develops during germination. The latter system can transport adenine and 6-methylpurine. Time course and kinetic studies of adenine transport in freshly harvested conidia of an ad-8 mutant indicated that, in contrast to the wild type, the general purine transport activity is very low in this strain and that the second adenine transport system is possibly present in the ungerminated conidia. A study of adenine and hypoxanthine uptake in ad-8 and ad-4 mutants, both of which cannot utilize hypoxanthine for growth, isolated that the two transport systems may be under different metabolic controls.     

Purine and pyrimidine transport and permeation in human erythrocytes

Time courses of the uptake of radiolabeled hypoxanthine, adenine and uracil were measured by rapid kinetic techniques over substrate ranges from 0.02 to 5000 microM in suspensions of human erythrocytes at 25 or 30 degrees C. At concentrations above 25 microM, the rate of intracellular phosphoribosylation of hypoxanthine and adenine was insignificant relative to their rates of entry into the cell and time courses of transmembrane equilibration of the substrates could be measured and analyzed by integrated rate analysis. Hypoxanthine and uracil are transported by simple facilitated carriers with directional symmetry, high capacity and Michaelis-Menten constants of about 0.2 and 5 mM, respectively. Adenine is probably transported by a carrier with similar properties but no saturability was detectable up to a concentration of 5 mM. Cytosine entered the cells much more slowly than the other three nucleobases, and its entry seems not to be mediated by a carrier. The hypoxanthine transporter resembles that of one group of mammalian cell lines, which does not exhibit any overlap with the nucleoside transporter and is resistant to inhibitors of nucleoside transport. Results from studies on the effects of the nucleobases on the influx and countertransport of each other were complex and did not allow unequivocal conclusions as to the number of independent carriers involved. At concentrations below 5 microM, radiolabel from adenine and hypoxanthine accumulated intracellularly to higher than equilibrium levels. Part of this accumulation reflected metabolic trapping, especially when the medium contained 50 mM phosphate. But part was due to an apparent concentrative accumulation of free adenine and hypoxanthine up to 3-fold at medium concentrations much less than 1 microM and when cells were incubated in phosphate-free medium. This concentrative accumulation could be due to the functioning of additional high-affinity, low-capacity, active transport systems for adenine and hypoxanthine, but other factors could be responsible, such as saturable binding to intracellular components.     

Distinction between Hypoxanthine and Xanthine Transport in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii cells consumed hypoxanthine and xanthine by means of active systems which promoted purine intracellular accumulation against a high concentration gradient. Both uptake and accumulation were also observed in mutant strains lacking xanthine dehydrogenase activity. Xanthine and hypoxanthine uptake systems exhibited very similar Michaelis constants for transport and pH values, and both systems were induced by either hypoxanthine or xanthine. However, they differed greatly in the length of the lag phase before uptake induction, which was longer for hypoxanthine than for xanthine. Cells grown on ammonium and transferred to hypoxanthine media consumed xanthine before hypoxanthine, whereas cells transferred to xanthine media did not take up hypoxanthine until 2 hours after commencing xanthine consumption. Metabolic and photosynthetic inhibitors such as 2,4-dinitrophenol, 3-(3,4-dichlorophenyl)-1,1-dimethyl urea, and carbonylcyanide m-chlorophenylhydrazone inhibited to a different extent the hypoxanthine and xanthine uptake. Similarly, N-ethylmaleimide abolished xanthine uptake but slightly affected that of hypoxanthine. Hypoxanthine consumption was inhibited by adenine and guanine whereas that of xanthine was inhibited only by urate. We conclude that hypoxanthine and xanthine in C. reinhardtii are taken up by different active transport systems which work independently of the intracellular enzymatic oxidation of these purines.     

Purine and pyrimidine transport and phosphoribosylation and their interaction in overall uptake by cultured mammalian cells. A re-evaluation.

The zero-trans uptake of purines and pyrimidines was measured in suspensions of Novikoff rat hepatoma, mouse L, P388 mouse leukemia, and Chinese hamster ovary cells by a rapid kinetic technique which allows the determination of uptake time points in intervals as short as 1.5 s. Kinetic parameters for purine/pyrimidine transport were determined by measuring substrate influx into cells in which substrate conversion to nucleotides was negligible either due to lack of the appropriate enzymes or to depletion of the cells of ATP (5'-phosphoribosylpyrophosphate), and by computer fitting exact, integrated rate equations derived for various carrier-mediated transport models directly to zero-trans influx data. The results indicate that different carriers function in the transport of hypoxanthine/guanine, adenine, and uracil with substrate:carrier association constants (K) at 24 degrees C of 300 to 400 muM, 2 to 3 mM, and about 14 mM, respectively, for Novikoff cells. K and Vmax for hypoxanthine transport by L and P388 cells are similar to those for Novikoff cells, but the transport capacity of Chinese hamster ovary cells is much lower and K = 1500 muM. All transport systems are completely symmetrical. Hypoxanthine transport is so rapid that an intracellular concentration of free hypoxanthine (90%) close to that in the medium is attained within 20 to 50 s of incubation at 24 degrees C, at least at extracellular concentrations below K. In cells in which conversion to nucleotides is not blocked free hypoxanthine accumulates intracellularly to steady state levels with equal rapidity and thereafter the rate of hypoxanthine uptake into total cell material is strictly a function of the rate of phosphoribosylation. The low Km systems for hypoxanthine (1 to 9 muM) and adenine (0.2 to 40 muM) uptake detected previously in many types of cells reflect the substrate saturation of the respective phosphoribosyltransferases rather than of the transport system.     

Purine and pyrimidine transport by cultured Novikoff cells. Specificities and mechanism of transport and relationship to phosphoribosylation.

Adenine, guanine, and hypoxanthine were rapidly incorporated into the acid-soluble nucleotide pool and nucleic acids by wild type Novikoff cells. Incorporation followed normal Michaelis-Menten kinetics, but the following evidence indicates that specific transport processes precede the phosphoribosyltransferase reactions and are the rate-limiting step in purine incorporation by whole cells. Cells of an azaguanine-resistant subline of Novikoff cells which lacked hypoxanthine-guanine phosphoribosyltransferase activity and failed to incorporate guanine or hypoxanthine into the nucleotide pool, exhibited uptake of guanine and hypoxanthine by a saturable process. Similarly, wild type cells which had been preincubated in a glucose-free basal medium containing KCN and iodoacetate transported guanine and hypoxanthine normally, although a conversion of these purines to nucleotides did not occur in these cells. The mutant and KCN-iodoacetate treated wild type cells also exhibited countertransport of guanine and hypoxanthine when preloaded with various purines, uracil, and pyrimidine nucleosides. The cells also possess a saturable transport system for uracil although they lack phosphoribosyltransferase activity for uracil. In the absence of phosphoribosylation, none of the substrates was accumulated against a concentration gradient. Thus transport is by facilitated diffusion (nonconcentrative transport). Furthermore, the apparent Km values for purine uptake by untreated wild type and azaguanine-resistant cells were higher and the apparent Vmax values were lower than those for the corresponding phosphoribosyltransferases...     

Purine base transport in Neurospora crassa.

Observations presented in this paper point to the presence of dual transport mechanisms for the base adenine in Neurospora crassa. Competition for transport, as well as growth inhibition studies using an ad-1 auxotroph, show that the purine bases adenine, guanine, and hypoxanthine share at least one transport mechanism which is insensitive to adenosine, cytosine, and a variety of other purine base analogues. On the other hand, uptake of adenine by an ad-8 mutant strain unable to transport [8-14C]hypoxanthine at any concentration was not inhibited by guanine or hypoxanthine. This observation demonstrates the existence of an adenine-specific transport system which was also found to be insensitive to inhibition by other purine base analogues, adenosine or cytosine. Recombination analysis of ad-8 by wild-type crosses showed that the inability to transport [8-14C]hypoxanthine was a consequence of the ad-8 lesion or a closely linked mutation. Saturation plots of each system gave intermediary plateaus and nonlinear reciprocal plots which, based on comparison with pure enzyme kinetic analysis, suggest that either each system consists of two or more uptake systems, at least one of which exhibits cooperativity, or that each system is a single uptake mechanism which possesses more than two binding sites where the relative affinity for the purine base first decreases and then increases as the sites are filled.     

Studies on purine transport and on purine content in vacuoles isolated from Saccharomyces cerevisiae.

The transport of purine derivatives into vacuoles isolated from Saccharomyces cerevisiae was studied. Vacuoles which conserved their ability to take up purine compounds were prepared by a modification of the method of polybase-induced lysis of spheroplasts. Guanosine greater than inosine = hypoxanthine greater than adenosine were taken up with decreasing initial velocities, respectively; adenine was not transported. Guanosine and adenosine transporting systems were saturable, with apparent Km values 0.63 mM and 0.15 mM respectively, while uptake rates of inosine and of hypoxanthine were linear functions of their concentrations. Adenosine transport in vacuoles appeared strongly dependent on the growth phase of the cell culture. The system transporting adenosine was further characterized by its pH dependency optimum of 7.1 and its sensitivity to inhibition by S-adenosyl-L-methionine. In the absence of adenosine in the external medium, [14C]adenosine did not flow out from preloaded vacuoles. However, in the presence of external adenosine, a very rapid efflux of radioactivity was observed, indicating an exchange mechanism for the observed adenosine transport in the vacuoles. In isolated vacuoles the only purine derivative accumulated was found to be S-adenosyl-L-homocysteine.     

A purine permease in Candida glabrata

Abstract Competition experiments revealed that adenine and guanine were transported by a purine permease in both Candida glabrata 4 and a C. glabrata 4 cytosine permease negative mutant. The C. glabrata 4 cytosine permease negative mutant was isolated using 5-fluorocytosine selection. This mutant no longer transported cytosine, but transported adenine and guanine. A transport system for hypoxanthine was not detected. Hence, in addition to the cytosine permease, a purine permease exists in C. glabrata . This differs from the purine cytosine permeases in Saccharomyces cereuisiae and Candida albicans which transport adenine, cytosine, guanine and hypoxanthine.     

Purine nucleobase transport in the intraerythrocytic malaria parasite

Hypoxanthine, a nucleobase, serves as the major source of the essential purine group for the intraerythrocytic malaria parasite. In this study we have measured the uptake of hypoxanthine, and that of the related purine nucleobase adenine, by mature blood-stage Plasmodium falciparum parasites isolated from their host cells by saponin-permeabilisation of the erythrocyte and parasitophorous vacuole membranes. The uptake of both [3H]hypoxanthine and [3H]adenine was comprised of at least two components; in each case there was a rapid equilibration of the radiolabel between the intra- and extracellular solutions via a low-affinity transport mechanism, and an accumulation of radiolabel (such that the estimated intracellular concentration exceeded the extracellular concentration) via a higher-affinity process. The uptake of [3H]adenine was studied in more detail. The rapid, low-affinity equilibration of [3H]adenine between the intra-and extracellular solution was independent of the energy status of the parasite whereas the higher-affinity accumulation of the radiolabel was ATP-dependent. A kinetic analysis of adenine uptake revealed that the low-affinity (equilibrative) process had a Km of approximately 1.2mM, similar to the value of 0.82 mM estimated here (using the Xenopus laevis oocyte expression system) for the Km for the transport of adenine by PfENT1, a parasite-encoded member of the 'equilibrative nucleoside/nucleobase transporter' family. The results indicate that nucleobases enter the intraerythrocytic parasite via a rapid, equilibrative process that has kinetic characteristics similar to those of PfENT1.     

Acyclovir transport into human erythrocytes

The mechanism of transport of the antiviral agent acyclovir (ACV) into human erythrocytes has been investigated. Initial velocities of ACV influx were determined with an "inhibitor-stop" assay that used papaverine to inhibit ACV influx rapidly and completely. ACV influx was nonconcentrative and appeared to be rate-saturable with a Km of 260 +/- 20 microM (n = 8). However, two lines of evidence indicate that ACV permeates the erythrocyte membrane by means other than the nucleoside transport system: 1) potent inhibitors (1.0 microM) of nucleoside transport (dipyridamole, 6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine, and dilazep) had little (less than 8% inhibition) or no effect upon the influx of 5.0 microM ACV; and 2) a 100-fold molar excess of several purine and pyrimidine nucleosides had no inhibitory effect upon the influx of 1.0 microM ACV. However, ACV transport was inhibited competitively by adenine (Ki = 9.5 microM), guanine (Ki = 25 microM), and hypoxanthine (Ki = 180 microM). Conversely, ACV was a competitive inhibitor (Ki = 240-280 microM) of the transport of adenine (Km = 13 microM), guanine (Km = 37 microM), and hypoxanthine (Km = 180 microM). Desciclovir and ganciclovir, two compounds related structurally to ACV, were also found to be competitive inhibitors of acyclovir influx (Ki = 1.7 and 1.5 mM, respectively). These results indicate that ACV enters human erythrocytes chiefly via the same nucleobase carrier that transports adenine, guanine, and hypoxanthine.     

Role of the nucleoside transport function in the transport and salvage of purine nucleobases

Genetic deficiencies in the nucleoside transport function markedly altered the abilities of cultured mutant S49 T lymphoblasts to transport, incorporate, and salvage exogenous hypoxanthine. The concentrations of exogenous hypoxanthine required to reverse azaserine toxicity and replenish azaserine-depleted nucleoside triphosphate pools in AE1 cells, a nucleoside transport-deficient clone, were about 10-fold higher than those required for wild type cells. In a similar fashion, guanine could reverse mycophenolic acid toxicity in wild type but not in AE1 cells. Surprisingly, a second nucleoside transport-deficient clone, 80-5D2, which had lost 80-90% of its ability to transport nucleosides, required lower hypoxanthine concentrations than the wild type parent to reverse these azaserine-mediated effects. The addition of submicromolar concentrations of either p-nitrobenzylthioinosine or dipyridamole, two potent inhibitors of nucleoside transport, to wild type cells mimicked the phenotype of the AE1 cells with respect to hypoxanthine. AE1 cells or p-nitrobenzylthioinosine-treated wild type cells could only transport hypoxanthine at 10-25% the rate of untreated wild type cells, whereas 80-5D2 cells could transport hypoxanthine more efficiently. Adenine transport was also diminished in AE1 and FURD-80-3-6 cells, but not to sufficiently low levels to interfere with their ability to salvage adenine to overcome azaserine toxicity. These studies on S49 cells altered in their nucleoside transport capacity provide powerful genetic evidence that purine nucleobases share a common transport function with nucleosides in these mammalian T lymphoblasts.     

Uptake of AMP, ADP, and ATP in Escherichia coli W

The uptake activity ratio for AMP, ADP, and ATP in mutant (T-1) cells of Escherichia coli W, deficient in de novo purine biosynthesis at a point between IMP and 5-aminoimidazole-4-carboxiamide-1-β-D-ribofuranoside (AICAR), was 1:0.43:0.19. This ratio was approximately equal to the 5'-nucleotidase activity ratio in E. coli W cells. The order of inhibitory effect on [2-3H]ADP uptake by T-1 cells was adenine > adenosine > AMP > ATP. About 2-fold more radioactive purine bases than purine nucleosides were detected in the cytoplasm after 5 min in an experiment with [8-1?C]AMP and T-1 cells. Uptake of [2-3H]adenosine in T-1 cells was inhibited by inosine, but not in mutant (Ad-3) cells of E. coli W, which lacked adenosine deaminase and adenylosuccinate lyase. These experiments suggest that AMP, ADP, and ATP are converted mainly to adenine and hypoxanthine via adenosine and inosine before uptake into the cytoplasm by E. coli W cells.     

Purine metabolism in human lymphocytes.

In peripheral human blood lymphocytes the uptake and metabolism of adenine, guanine, and hypoxanthine was investigated. This was achieved by incubation of purified lymphocytes with 14C-purine bases, separation of cells from the incubation medium by a rapid filtration technique, and subsequent separation of the acid soluble material by thin-layer chromatography. No perferential uptake for one of the purine bases was observed. In all cases only traces of 14C-purine bases not added originally and labeled nucleosides could be demonstrated. Approximately 2/3 of adenine and 1/2 of guanine or hypoxanthine were converted to nucleotides. Separation of formed nucleotides showed that adenine and guanine were metabolized mainly to their corresponding nucleotides; hypoxanthine was converted to a considerable amount to adenine nucleotides and only to a small proportion into its own nucleotides. These results demonstrate the predomonance of adenine nucleotide formation in normal human lymphocytes.     

Nature of 6-methylpurine inhibition and characterization of two 6-methylpurine-resistant mutants of Neurospora crassa.

6-Methylpurine, an analog of adenine, inhibits the growth of Neurospora crassa. From kinetic studies it was found that 6-methylpurine is converted to its nucleotide form by adenine phosphoribosyltransferase (EC 2.4.2.7), and inhibits the de novo purine biosynthesis. Adenine relieves the growth inhibition caused by 6-methylpurine, whereas hypoxanthine is not very effective. Studies dealing with hypoxanthine utilization in the presence of 6-methylpurine indicated a severely reduced uptake of hypoxanthine and a general slowdown in its further metabolism. Two mutants (Mepr-3 and Mepr-10) which are resistant to 6-methylpurine were characterized. Studies of purine base uptake and the in vivo and in vitro conversion to nucleotides indicated that Mepr-10 may be an adenine phosphoribosyltransferase-defective mutant, whereas Mepr-3 may be a mutant with altered feedback response to 6-methylpurine. Both mutants showed a severely lowered hypoxanthine phosphoribosyltransferase activity, but because 6-methylpurine did not have any effect on the conversion of hypoxanthine to IMP in the wild type, it was concluded that 6-methylpurine resistance in these mutants cannot be due to lowered hypoxanthine phosphoribosyltransferase activity, but rather that the lowering of enzyme activity may be a secondary effect.     

Regulation of hypoxanthine transport in Neurospora crassa.

Hypoxanthine uptake and hypoxanthine phosphoribosyltransferase activity (EC 2.4.2.8) were determined in germinated conidia from the adenine auxotrophic strains ad-1 and ad-8 and the double mutant strain ad-1 ad-8. The mutant strain ad-1 appears to lack aminoimidazolecarboximide ribonucleotide formyltransferase (EC 2.1.2.3) or inosine 5'monophosphate cyclohydrolase (EC 3.5.1.10) activities, or both, whereas the ad-8 strain lacks adenylosuccinate synthase activity (EC 6.3.4.4). Normal (or wild-type) hypoxanthine transport capacity was found to the ad-1 conidia, whereas the ad-8 strains failed to take up any hypoxanthine. The double mutant strains showed intermediate transport capacities. Similar results were obtained for hypoxanthine phosphoribosyl-transferase activity assayed in germinated conidia. The ad-1 strain showed greatest activity, the ad-8 strain showed the least activity, and the double mutant strain showed intermediate activity levels. Ion-exchange chromatography of the growth media revealed that in the presence of NH+/4, the ad-8 strain excreted hypoxanthine or inosine, the ad-1 strain did not excrete any purines, and the ad-1 ad-8 double mutant strain excreted uric acid. In the absence of NH+/4, none of the strains excreted any detectable purine compounds.