Folate-dependent enzymes in cultured Chinese hamster ovary cells: evidence for mutant forms of folylpolyglutamate synthetase

A Chinese hamster ovary auxotroph requiring glycine + adenosine + thymidine (CHO AUXB1) was shown by us previously to lack several folylpolyglutamate synthetase (FPGS) type activities. Two revertants of AUXB1 (one spontaneous and one Pt(S0₄)₂ induced) have been isolated and found to contain altered forms of this enzyme. The revertant enzymes are more sensitive to heat inactivation (37 °C, pH 7.4 or 9.0) than the parent CHO enzyme. Increased sensitivity of revertant FPGS is observed irrespective of whether one assays the specific catalysis of radioactive tetrahydropteroyldi- or tetraglutamate synthesis. ATP and MgCl₂ protect both revertant and parent CHO FPGS against rapid heat denaturation at pH 9.0, but not at pH 7.4. A genetically related auxotroph (CHO AUXB3) contains one-fifth the parent amount of FPGS. AUXB3 FPGS shows a normal sensitivity to 37 °C heat inactivation, but it has an altered substrate saturation and specificity pattern when assayed for tetrahydropteroyldi[U-¹⁴C]glutamate synthesis. Also, unlike the FPGS from parent CHO and a genetically unrelated mutant requiring only glycine (CHO AUXB2), the AUXB3 enzyme specifically lacks tetrahydropteroyltetra[U-¹⁴C]glutamate synthetase activity. These findings and polyethylene glycol fusion data with AUXB2 indicate that AUXB1 and AUXB3 each carry a mutation in the structural gene for a CHO FPGS that catalyzes tetrahydropteroyldi- as well as tetraglutamate formation. The altered form of FPGS in AUXB3 is responsible for its glycine + adenosine auxotrophy under standard culture conditions.     

Isolation and biochemical characterization of folate deficient mutants of Chinese hamster cells

This article describes the selection of auxotrophic mutants of Chinese Hamster Ovary (CHO) cells and the genetic and biochemical characterization of two mutant lines. AUXB1 is auxotrophic for glycine, adenosine, and thymidine (GAT-), whereas AUXB3 requires only glycine and adenosine (GA-). These mutants do not complement since hybrid cells formed between them are also auxotrophic. Experiments concerned with the reversion of AUXB1 to prototrophy suggest that a single genetic lesion is responsible for the multiple auxotrophy. Biochemical analysis indicates that the multiple auxotrophy of both AUXB1 and AUXB3 is a result of low levels of intracellular folates in mutant cells. Phenotypic reversion to complete or partial prototrophy can be accomplished by growing these cells in high concentrations of folic or folinic acids. However, neither the folate transport nor the dihydrofolate reductase are defective in mutant cells. Chromatographic analysis of intracellular folate derivatives indicates that while folates extracted from wild type cells exist almost exclusively as polyglutamyl derivates (primarily pentaglutamates), AUXB1 cells contain primarily folate derivates in monoglutamyl form and AUXB3 cells contain mono-, di-, and perhaps some triglutamates. This observation suggests that the enzyme responsible for linking glutamate residues onto intracellular folate derivates is the site of the biochemical lesion in the mutant cells. Our results also suggest that a possible function of polyglutamyl residues is to aid cellular retention of folates.     

A mutation inactivating the mitochondrial inner membrane folate transporter creates a glycine requirement for survival of chinese hamster cells

A mutant Chinese hamster ovary cell line, glyB, that required exogenous glycine for survival and growth was reported previously (Kao, F., Chasin, L., and Puck, T. T. (1969) Proc. Natl. Acad. Sci. U. S. A. 64, 1284-1291). We now report that the defect in glyB cells causative of this phenotype is a point mutation in an inner mitochondrial membrane protein required for transport of folates into mitochondria. The CHO mitochondrial folate transporter (mft) was sequenced and compared with that from glyB cells. The hamster sequence was nearly identical to that of the recently reported human mitochondrial folate transporter. The corresponding cDNA from glyB cells contained a single nucleotide change that introduced a glutamate in place of the glycine in wild-type hamster MFT at codon 192 in a predicted transmembrane domain. Transfection of the wild-type hamster cDNA into glyB cells allowed cell survival in the absence of glycine and the accumulation of folates in mitochondria, whereas transfection of the Glu-192 cDNA did not. Genomic sequence analysis and fluorescence in situ hybridization demonstrated a single mutated allele of the mft gene in glyB cells, whereas there were two alleles in CHO cells. We conclude that we have defined the cause of the glyB auxotrophy and that the glyB mft mutation identified a region of this mitochondrial folate carrier vital to its transport function.     

Functional analysis of folate polyglutamylation and its essential role in plant metabolism and development

Cellular folates function as co-enzymes in one-carbon metabolism and are predominantly decorated with a polyglutamate tail that enhances co-enzyme affinity, subcellular compartmentation and stability. Polyglutamylation is catalysed by folylpolyglutamate synthetases (FPGSs) that are specified by three genes in Arabidopsis, FPGS1, 2 and 3, which reportedly encode plastidic, mitochondrial and cytosolic isoforms, respectively. A mutational approach was used to probe the functional importance of folate polyglutamylation in one-carbon metabolism and development. Biochemical analysis of single FPGS loss-of-function mutants established that folate polyglutamylation is essential for organellar and whole-plant folate homeostasis. However, polyglutamylated folates were still detectable, albeit at lower levels, in organelles isolated from the corresponding isozyme knockout lines, e.g. in plastids and mitochondria of the fpgs1 (plastidial) and fpgs2 (mitochondrial) mutants. This result is surprising given the purported single-compartment targeting of each FPGS isozyme. These results indicate redundancy in compartmentalised FPGS activity, which in turn explains the lack of anticipated phenotypic defects for the single FPGS mutants. In agreement with this hypothesis, fpgs1 fpgs2 double mutants were embryo-lethal, fpgs2 fpgs3 mutants exhibited seedling lethality, and fpgs1 fpgs3 mutants were dwarfed with reduced fertility. These phenotypic, metabolic and genetic observations are consistent with targeting of one or more FPGS isozymes to multiple organelles. These data confirm the importance of polyglutamylation in folate compartmentation, folate homeostasis and folate-dependent metabolic processes, including photorespiration, methionine and pantothenate biosynthesis.     

Folate metabolism in plants: an Arabidopsis homolog of the mammalian mitochondrial folate transporter mediates folate import into chloroplasts

The distribution of folates in plant cells suggests a complex traffic of the vitamin between the organelles and the cytosol. The Arabidopsis thaliana protein AtFOLT1 encoded by the At5g66380 gene is the closest homolog of the mitochondrial folate transporters (MFTs) characterized in mammalian cells. AtFOLT1 belongs to the mitochondrial carrier family, but GFP-tagging experiments and Western blot analyses indicated that it is targeted to the envelope of chloroplasts. By using the glycine auxotroph Chinese hamster ovary glyB cell line, which lacks a functional MFT and is deficient in folates transport into mitochondria, we showed by complementation that AtFOLT1 functions as a folate transporter in a hamster background. Indeed, stable transfectants bearing the AtFOLT1 cDNA have enhanced levels of folates in mitochondria and can support growth in glycine-free medium. Also, the expression of AtFOLT1 in Escherichia coli allows bacterial cells to uptake exogenous folate. Disruption of the AtFOLT1 gene in Arabidopsis does not lead to phenotypic alterations in folate-sufficient or folate-deficient plants. Also, the atfolt1 null mutant contains wild-type levels of folates in chloroplasts and preserves the enzymatic capacity to catalyze folate-dependent reactions in this subcellular compartment. These findings suggest strongly that, despite many common features shared by chloroplasts and mitochondria from mammals regarding folate metabolism, the folate import mechanisms in these organelles are not equivalent: folate uptake by mammalian mitochondria is mediated by a unique transporter, whereas there are alternative routes for folate import into chloroplasts.     

Induced reversion of a Chinese hamster ovary triple auxotroph. Validation of the system with several mutagens

A Chinese hamster ovary triple auxotroph (CHO AUXB1) requires glycine, adenosine, and thymidine (GAT) for growth and survival due to a defect in the structural gene for folylpolyglutamate synthetase (FPGS). This auxotroph and others like it contain less than 3% of the parental amounts of FPGS activity. In order to develop a reverse mutation assay with CHO AUXB1, we determined the optimal conditions for measuring reversion and characterized some of the revertants. We also obtained quantitative mutagenicity data for several direct-acting mutagens for comparison to the parental CHO-S/HGPRT locus. Induced revertants appear in the culture immediately following 20-22 h exposures in +GAT complete medium, indicative of dominant genetic changes. They are maximally expressed after 2 population doublings and can be conveniently selected after 44-48 h of expression growth by plating 1 X 10(6) cells/100-mm dish into -GAT-deficient medium and incubating 12-13 days. Plating reconstruction experiments show that the cloning efficiencies of revertants in -GAT medium are not influenced by the presence of up to 1 X 10(6) CHO AUXB1 cells. Dose-dependent increases above the spontaneous revertant frequency (average = 5 X 10(7)) are induced with cis-Pt(NH3)2Cl2 (14-fold) (but not trans-Pt(NH3)2Cl2), PtCl4(10-fold), Pt(SO4)2 (14-fold), K2CrO4 (8-fold), EMS (10-fold), 4-NQO (53-fold), ICR-191 (60-fold), and ICR-170 (30-fold). All of the revertants that have been isolated are stable to repeated subculturing in -GAT medium; 40 out of 42 that have been analyzed are characterized by an increased 72-h growth incorporation of labeled folate and their extracts contain 5-94% as much FPGS as the original, parental CHO-S line. Spontaneous and induced reversion to the GAT+ phenotype primarily reflects mutations involving the FPGS gene locus. But the re-acquisition by most of the revertants of much less than normal amounts of FPGS activity suggests that they arise from compensatory second-site mutations within this gene. Comparison of the mutagenicity patterns of the foregoing compounds as a function of the applied concentration and the relative percent survival reveals some interesting similarities, as well as differences, between the CHO AUXB1/FPGS and CHO-S/HGPRT loci. In particular, the FPGS locus is rather insensitive to EMS (or other simple alkylating agents). However, it seems to be quite susceptible to reversion by other chemicals that are known to react selectively with guanine bases in DNA. CHO AUXBI is a useful supplemental mammalian assay system for assessing quantitatively the generally weak mutagenic activities of metal compounds.     

Folate-dependent enzymes in cultured Chinese hamster cells: folypolyglutamate synthetase and its absence in mutants auxotrophic for glycine + adenosine + thymidine.

Dialyzed sonicates from Chinese hamster ovary (CHO) and V-79 lung cells catalyze the addition of l-[U-¹⁴C]glutamate to tetrahydrofolate (H₄PteGlu). Catalysis is optimal between pH 8.5 and 10.2 and is dependent on Mg²⁺ and a purine nucleotide triphosphate. Cobalamins do not stimulate the system even when the cells are grown in the absence of cyanocobalamin (CN-Cbl). Incubations with dl-H₄-[G-³H]PteGlu + l-[U-¹⁴C]glutamate show that the product routinely assayed by DEAE-cellulose chromatography is tetrahydropteroyldiglutamate (H₄PteGluGlu). Higher reduced folylpolyglutamates are formed when the standard assay level of dl-H₄PteGlu is decreased from 100 μm to 1–5 μm. Using either dialyzed extracts or a 25-fold purified enzyme fraction, dATP is 1.6 times more effective than ATP. The folyl specificity for diglutamate synthesis is H₄PteGlu > H₄-homofolate > 5-formyl-H₄PteGlu > 5-MeH₄ PteGlu. dl-5-MeH₄PteGlu is only about 15% as active as dl-H₄PteGlu. Extracts from a CHO mutant AUXB1 (requiring glycine + adenosine + thymidine) and a V-79 mutant ght-1 (requiring glycine + hypoxanthine + thymidine) have <3% of their respective parent cell amounts of H₄PteGluGlu synthetase activity. CHO AUXB1 and V-79 ght-1 extracts are also inactive with the other three reduced folyl compounds cited above and PteGlu. Twelve out of 16 revertant clones that were isolated from CHO AUXB1 in media lacking glycine + adenosine + thymidine contained 44–66% of the wild-type level of H₄PteGluGlu synthetase activity. Both parent CHO and V-79 extracts catalyzed the conversion of H₄PteGluGlu and tetrahydropteroyl triglutamate to higher glutamyl conjugates. The AUXB1 and ght-1 mutant extracts again lacked these catalytic properties. In contrast, revertants of AUXB1 with about 50% of the wild-type H₄PteGluGlu synthetase activity displayed a proportionate ability to synthesize higher polyglutamyl conjugates. From our findings and published genetic data, we conclude that in cultured hamster cells a single synthetase can successively add at least three glutamates to H₄PteGlu. Loss of its function in certain mutants is responsible for their triple auxotrophy.     

The distribution and chemical nature of radioactive folates in rat liver cells and rat liver mitochondria.

Subcellular fractionation of rat liver cells revealed that a mixture of 14C- and 3H-labelled folic acid was distributed approximately equally between the mitochondria and cytosol 2, 24, 48 and 72 h after oral administration. Subfractionation of liver mitochondria 48 h after oral administration showed that the radioactivity was mainly associated with the inner membrane (27.7%) and matrix (51.5%). Hot-ascorbate extraction of the cell cytosol, mitochondrial inner membrane and matrix showed the majority of folates were present as polyglutamates. Acid treatment of isolated folates from cytosol, inner membrane and matrix produced breakdown products consistent with scission of tetrahydrofolates. The folates isolated in the mitochondrial matrix were bound to protein that had an estimated mol. wt. of 90,000.     

Folate-dependent enzymes in cultured Chinese hamster ovary cells: induction of 5-methyltetrahydrofolate homocysteine cobalamin methyltransferase by folate and methionine.

The effects of media vitamin B₁₂(CNB₁₂), l-methionine, folic acid, dl-5-methyltetrahydrofolate (5-MeH₄folate), homocysteine, and other nutrients on four one-carbon enzymes in cultured Chinese hamster ovary (CHO) cells were examined. Excess 10 mm methionine elevates the amount of B₁₂ methyltransferase 1.8 – 2.3-fold at media folate concentrations of 0.2 – 2.0 μm. Conversely, excess 100 μm folic acid increases the amount of B₁₂ holoenzyme by 2.4 – 3.0-fold when the medium contains 0.01 – 0.1 mm methionine. These increases in B₁₂ methyltransferase promoted by 100 μm media folate and 10 mm methionine are inhibited by cycloheximide. 5-MeH₄folate will support growth and induce methyltransferase synthesis more efficiently than folic acid.Upon transfer to methionine-free media, wild-type CHO cells will survive and can be repeatedly subcultured in the absence of exogenous methionine, provided it is supplemented with 1.0 μm CNB₁₂, 0.1 mm homocysteine, and 100 μm folic acid or 10 μm dl-5-MeH₄folate. No growth occurs if homocysteine is omitted, but a requirement for added CNB₁₂ does not become evident until the cells have undergone at least two or three divisions. Survival upon transfer from 0.1 mm methionine-containing to methionine-free media is dependent upon the B₁₂ holomethyltransferase content of the cells used as an inoculum. Inoculum cells must have been previously grown in media supplemented with 1.0 μm CNB₁₂ to stabilize and convert apo- to holomethyltransferase, and 100 μm folate (or 10 μm dl-5-MeH₄folate) to induce maximal enzyme-protein synthesis. Transfer to methionine-deficient medium does not result in more than a 20–25% increase in the cellular B₁₂ enzyme content over the level already induced by 100 μm folate in 0.1 mm methionine-supplemented media. A mutant auxotroph CHO AUXB1 with a triple growth requirement for glycine + adenosine + thymidine (McBurney, M. W., and Whitmore, G. F. (1974) Cell, 2, 173) cannot survive in media lacking exogenous methionine. High concentrations of media folic acid or dl-5-MeH₄folate fail to induce elevated amounts of B₁₂ methyltransferase in this mutant. Excess 10 mm medium methionine does, however, elevate its B₁₂ enzyme as in the parent CHO cells. An additional mutant AUXB3 that requires glycine + adenosine (McBurney, M. W., and Whitmore, G. F. (1974) Cell, 2, 173) barely survives in methionine-deficient media. It has a folate-induced B₁₂ enzyme level intermediate between wild-type CHO cells and AUXB1. The level of B₁₂ methyltransferase induced by high media folate concentrations is a critical determinant of CHO cell survival in methionine-free media.     

Characterization of a Chinese hamster cell with a temperature-sensitive mutation in folate metabolism

The Chinese hamster cell line, tsAUXB1, is auxotrophic for glycine, adenosine, and thymidine when grown at 38.5°C, but is prototrophic at 34°C. The evidence suggests that the temperature-sensitive lesion exists in the enzyme responsible for the addition of glutamyl residues onto intracellular folate derivatives. This enzyme appears to be synthesized constitutively in wild type cells.     

Glycine and Folate Ameliorate Models of Congenital Sideroblastic Anemia

Sideroblastic anemias are acquired or inherited anemias that result in a decreased ability to synthesize hemoglobin in red blood cells and result in the presence of iron deposits in the mitochondria of red blood cell precursors. A common subtype of congenital sideroblastic anemia is due to autosomal recessive mutations in the SLC25A38 gene. The current treatment for SLC25A38 congenital sideroblastic anemia is chronic blood transfusion coupled with iron chelation. The function of SLC25A38 is not known. Here we report that the SLC25A38 protein, and its yeast homolog Hem25, are mitochondrial glycine transporters required for the initiation of heme synthesis. To do so, we took advantage of the fact that mitochondrial glycine has several roles beyond the synthesis of heme, including the synthesis of folate derivatives through the glycine cleavage system. The data were consistent with Hem25 not being the sole mitochondrial glycine importer, and we identify a second SLC25 family member Ymc1, as a potential secondary mitochondrial glycine importer. Based on these findings, we observed that high levels of exogenous glycine, or 5-aminolevulinic acid (5-Ala) a metabolite downstream of Hem25 in heme biosynthetic pathway, were able to restore heme levels to normal in yeast cells lacking Hem25 function. While neither glycine nor 5-Ala could ameliorate SLC25A38 congenital sideroblastic anemia in a zebrafish model, we determined that the addition of folate with glycine was able to restore hemoglobin levels. This difference is likely due to the fact that yeast can synthesize folate, whereas in zebrafish folate is an essential vitamin that must be obtained exogenously. Given the tolerability of glycine and folate in humans, this study points to a potential novel treatment for SLC25A38 congenital sideroblastic anemia.     

Purification and characteristics of recombinant human folylpoly-gamma-glutamate synthetase expressed at high levels in insect cells

Folylpoly-gamma-glutamate synthetase activity is central to the operation of folate metabolism and is essential for the survival of mammalian stem cell populations but the very low levels of endogenous expression of this enzyme have greatly limited its study. We now report the expression of cytosolic folylpoly-gamma-glutamate synthetase (FPGS) cloned from human leukemic cells in baculovirus-infected insect cells at levels of 4-5% of the total soluble protein of the cells. As was the case with endogenously expressed mammalian FPGS, recombinant enzyme was quantitatively blocked at the amino terminus in spite of the large-scale production in insect cells. A three-step purification procedure resulted in an overall yield of 7-35 mg per liter of culture with a recovery of about 50% and purity approximately 95%; pure enzyme was stable to storage for extended periods. Pure protein had a specific activity of 25 micromol h(-1)mg(-1) with aminopterin as a substrate and used a broad spectrum of folates as substrates. The pure enzyme also carried out ATP hydrolysis in the absence of a folate substrate or glutamic acid; this partial reaction occurred at a k(cat) about 0.4% that of the full reaction. In vitro, this single protein added several (1-8) moles of glutamic acid per mole of folate analog, the same spectrum of folate polyglutamates as seen in vivo. The quantities of pure enzyme achievable in insect cells should allow functional and structural studies on this enzyme.     

Human liver folylpolyglutamate synthetase: biochemical characterization and interactions with folates and folate antagonists

Folylpolyglutamate synthetase (FPGS) was isolated from human liver cytosol by 0-30% (w/v) ammonium sulfate fractionation and characterized biochemically. Using aminopterin (AMT), L-[3H]glutamate and MgATP as cosubstrates, maximal gamma-L-glutamylation activity was observed in the presence of the activators KCl and NaHCO3. ATP and 2-mercaptoethanol were each required for enzyme activity and stability. In the absence of ATP, human liver FPGS rapidly inactivated at 37 degrees C (t1/2 approximately 8 min), whereas FPGS isolated from rabbit liver was significantly more stable (t1/2 = 68 min). Both folates and antifolates were effectively polyglutamylated by the isolated human liver enzyme. Km parameters determined for AMT (Km = 4.3 microM) were similar to those determined for several reduced folates (tetrahydrofolic acid, dihydrofolic acid, and folinic acid; Km = 3-7 microM), while significantly higher Km values were observed for methotrexate (MTX) and 5-methyltetrahydrofolic acid (Km = 50-60 microM) and for folic acid (Km = 100 microM). All of the substrates examined exhibited Vmax values ranging from 30 to 90% of the AMT value (Vmax = 935 pmol product/mg/h). The order of reactivity for these substrates differed from that determined in parallel studies for FPGS isolated from rat and rabbit liver. In the case of AMT and several reduced folates, inhibition of human liver FPGS was observed at substrate concentrations at or above 50-250 microM. FPGS isolated from six individual human livers exhibited highly similar biochemical and kinetic properties, suggesting the presence of the same or at least highly similar enzyme species in each individual, with a five-fold interindividual range in specific activities observed. Comparison of MTX with its higher polyglutamates (MTX-Glu2 to MTX-Glu6) as FPGS substrates indicated a significant decrease in Vmax values with increasing glutamate chain length which was partially compensated for by a corresponding decrease in Km. Consistent with these observations, the isolated enzyme was unable to synthesize polyglutamates higher than MTX-Glu3 when MTX was supplied as substrate, raising the question as to how MTX polyglutamates containing up to five or six gamma-L-glutamate residues are formed in vivo.     

Mitochondrial one-carbon metabolism is adapted to the specific needs of yeast, plants and mammals

In eukaryotes, folate metabolism is compartmentalized between the cytoplasm and organelles. The folate pathways of mitochondria are adapted to serve the metabolism of the organism. In yeast, mitochondria support cytoplasmic purine synthesis through the generation of formate. This pathway is important but not essential for survival, consistent with the flexibility of yeast metabolism. In plants, the mitochondrial pathways support photorespiration by generating serine from glycine. This pathway is essential under photosynthetic conditions and the enzyme expression varies with photosynthetic activity. In mammals, the expression of the mitochondrial enzymes varies in tissues and during development. In embryos, mitochondria supply formate and glycine for purine synthesis, a process essential for survival; in adult tissues, flux through mitochondria can favor serine production. The differences in the folate pathways of mitochondria depending on species, tissues and developmental stages, profoundly alter the nature of their metabolic contribution.     

In situ autoradiographic detection of folylpolyglutamate synthetase activity

The enzyme folylpolyglutamate synthetase (FPGS) catalyzes the conversion of folate (pteroylmonoglutamate) to the polyglutamate forms (pteroylpolyglutamates) that are required for folate retention by mammalian cells. A rapid in situ autoradiographic assay for FPGS was developed which is based on the folate cofactor requirement of thymidylate synthase. Chinese hamster AUX B1 mutant cells lack FPGS activity and are unable to accumulate folate. As a result, the conversion of [6-3H]deoxyuridine to thymidine via the thymidylate synthase reaction is impaired in AUX B1 cells and no detectable label is incorporated into DNA. In contrast, FPGS in wild-type Chinese hamster CHO cells causes folate retention and enables the incorporation of [6-3H]deoxyuridine into DNA. Incorporation may be detected by autoradiography of monolayer cultures or of colonies replica plated onto polyester discs. Introduction of Escherichia coli FPGS into AUX B1 cells restores the activity of the thymidylate synthase pathway and demonstrates that the E. coli FPGS enzyme can provide pteroylpolyglutamates which function in mammalian cells.     

Subcellular localization of gamma-glutamyl carboxypeptidase and of folates.

The subcellular distributions of glutamyl carboxypeptidase, folate specific activities, and radioactive metabolites of injected [3H] folic acid were studied in rat liver. The specific activity of glutamyl carboxypeptidase in the lysosomal fraction was near or greater than four times that in the other subcellular fractions. The specific activity of folates was highest in the soluble fraction (102 ng folate/mg protein) and lowest in the microsomal fraction (22 ng folate/mg protein). Nuclear, mitochondrial, and lysosomal folates were 95% folate polyglutamates, and microsomal and soluble folates were 85--90% folate polyglutamates. Injected [3H] folic acid was initially concentrated in the microsomal fraction, as measured by 3h cpm per ng folate. Initially, injected [3H] folic acid was found converted to folate penta- and hexaglutamates in all fractions to a similar extent except in the microsomes where the percentage conversion was much less, as measured by the percentage of total 3H cpm determined to be [3H] folate penta- and hexaglutamates. At 24 h, the conversion of [3H] folates to penta- and hexaglutamates in each fraction was less than that found for the endogenous folates. Injected [3H] folic acid after 2h was found to consist of 94% reduced folates in the soluble fraction, 56% in the mitochondrial, 55% in the nuclear, 20% in the lysosomal, and 15% in the microsomal fraction.     

Subcellular localization of γ-glutamyl carboxypeptidase and of folates

The subcellular distributions of glutamyl carboxypeptidase, folate specific activities, and radioactive metabolites of injected [³H] folic acid were studied in rat liver. The specific activity of glutamyl carboxypeptidase in the lysosomal fraction was near or greater than four times that in the other subcellular fractions.The specific activity of folates was highest in the soluble fraction (102 ng folate/mg protein) and lowest in the microsomal fraction (22 ng folate/mg protein). Nuclear, mitochondrial, and lysosomal folates were 95% folate polyglutamates, and microsomal and soluble folates were 85–90% folate polyglutamates.Injected [³H] folic acid was initially concentrated in the microsomal fraction, as measured by ³H cpm per ng folate.Initially, injected [³H] folic acid was found converted to folate penta- and hexaglutamates in all fractions to a similar extent except in the microsomes where the percentage conversion was much less, as measured by the percentage of total ³H cpm determined to be [³H] folate penta- and hexaglutamates. At 24 h, the conversion of [³H] folates to penta- and hexaglutamates in each fraction was less than that found for the endogenous folates.Injected [³H] folic acid after 2 h was found to consist of 94% reduced folates in the soluble fraction, 56% in the mitochondrial, 55% in the nuclear, 20% in the lysosomal, and 15% in the microsomal fraction.     

The folylpolyglutamate synthetase plastidial isoform is required for postembryonic root development in Arabidopsis

A recessive Arabidopsis (Arabidopsis thaliana) mutant with short primary roots and root hairs was identified from a forward genetic screen. The disrupted gene in the mutant encoded the plastidial isoform of folylpolyglutamate synthetase (FPGS), previously designated as AtDFB, an enzyme that catalyzes the addition of glutamate residues to the folate molecule to form folylpolyglutamates. The short primary root of atdfb was associated with a disorganized quiescent center, dissipated auxin gradient in the root cap, bundled actin cytoskeleton, and reduced cell division and expansion. The accumulation of monoglutamylated forms of some folate classes in atdfb was consistent with impaired FPGS function. The observed cellular defects in roots of atdfb underscore the essential role of folylpolyglutamates in the highly compartmentalized one-carbon transfer reactions (C1 metabolism) that lead to the biosynthesis of compounds required for metabolically active cells found in the growing root apex. Indeed, metabolic profiling uncovered a depletion of several amino acids and nucleotides in atdfb indicative of broad alterations in metabolism. Methionine and purines, which are synthesized de novo in plastids via C1 enzymatic reactions, were particularly depleted. The root growth and quiescent center defects of atdfb were rescued by exogenous application of 5-formyl-tetrahydrofolate, a stable folate that was readily converted to metabolically active folates. Collectively, our results indicate that AtDFB is the predominant FPGS isoform that generates polyglutamylated folate cofactors to support C1 metabolism required for meristem maintenance and cell expansion during postembryonic root development in Arabidopsis.     

The effect of methotrexate on intracellular folate pools in human MCF-7 breast cancer cells. Evidence for direct inhibition of purine synthesis

This report details the effects of methotrexate on the intracellular folate pools of the MCF-7 human breast cancer cell line. To achieve this goal, we designed a high-pressure liquid chromatography system capable of separating the physiologic folates. The folate pools were quantitated following growth and equilibration in 2.25 microM radiolabeled folic acid. Each of the intracellular folates was identified by coelution with standard folates and by chemical/biochemical tests unique to each of the various folates. The 10-formyl-H4PteGlu (where H4PteGlu represents dl-tetrahydrofolic acid) pool accounted for 20.5% of the total intracellular folate pool in untreated cells, whereas 5-formyl-H4PteGlu and H4PteGlu accounted for 6.5 and 10.6%, respectively. The levels of these three folates remained stable throughout cell growth. The 5-methyl-H4PteGlu pool accounted for less than 10% in early growth phase cells but assumed greater than 60% of the total pool by the mid- and late-log phases of cell growth. When the MCF-7 cells were exposed to 1 microM methotrexate, de novo purine synthesis and de novo thymidylate synthesis were rapidly inhibited to less than 20% of control within 3 h. During this time period, rapid alterations in the folate pools also occurred such that dihydrofolic acid levels rose from less than 1% in untreated cells to greater than 30% of the total pool. This rise was accompanied by a parallel fall in 5-methyl-H4PteGlu. H4PteGlu and 5-formyl-H4PteGlu were undetectable following 2 h of methotrexate exposure, but 10-formyl-H4PteGlu, the required cosubstrate for de novo purine synthesis, was preserved at greater than 80% of pretreatment values following a 1 microM methotrexate exposure of up to 21 h. The rapid inhibition of de novo purine synthesis in these cells following methotrexate exposure coupled with a relatively preserved 10-formyl-H4PteGlu pool suggests direct inhibition of this synthetic pathway by the temporally coincident accumulation of dihydrofolic acid and/or methotrexate polyglutamates. This inhibition cannot be ascribed to depletion of the folate cofactor 10-formyl-H4PteGlu.     

The diverse members of the mitochondrial carrier family in plants

Sequencing of plant genomes allowed the identification of various members of the mitochondrial carrier family (MCF). In plants, these structurally related proteins are involved in the transport of solutes like nucleotides, phosphate, di- and tricarboxylates across the mitochondrial membrane and therefore exhibit physiological functions similar to known isoforms from animal or yeast mitochondria. Interestingly, various studies led to the recognition of MCF proteins which mediate the transport of different substrates like folates, S-adenosylmethionine, ADPglucose or ATP, ADP and AMP in plastids.