(Received for publication, September 3, 1996, and in revised form, November 22, 1996)
From the Cornell University, Division of Nutritional
Sciences, Ithaca, New York 14853 and the § Centre de
Recherché, Hotel-Dieu de Montreal, H2W 1T8 Quebec, Canada
The metabolic role of 5-formyltetrahydrofolate is not known; however, it is an inhibitor of several folate-dependent enzymes including serine hydroxymethyltransferase. Methenyltetrahydrofolate synthetase (MTHFS) is the only enzyme known to metabolize 5-formyltetrahydrofolate and catalyzes the conversion of 5-formyltetrahydrofolate to 5,10-methenyltetrahydrofolate. In order to address the function of 5-formyltetrahydrofolate in mammalian cells, intracellular 5-formyltetrahydrofolate levels were depleted in human 5Y neuroblastoma by overexpressing the human cDNA encoding MTHFS (5YMTHFS cells). When cultured with 2 mM exogenous glycine, the intracellular serine and glycine concentrations in 5YMTHFS cells are elevated approximately 3-fold relative to 5Y cells; 5YMTHFS cells do not contain measurable levels of free methionine and display a 30-40% decrease in cell proliferation rates compared with 5Y cells. Medium supplemented with pharmacological levels of exogenous folinate or methionine ameliorated the glycine induced growth inhibition. Analysis of the folate derivatives demonstrated that 5-methyltetrahydrofolate accounts for 30% of total cellular folate in 5Y cells when cultured with 5 mM exogenous glycine. 5YMTHFS cells do not contain detectable levels of 5-methyltetrahydrofolate under the same culture conditions. These results suggest that 5-formyltetrahydrofolate inhibits serine hydroxymethyltransferase activity in vivo and that serine synthesis and homocysteine remethylation compete for one-carbon units in the cytoplasm.
5-CHO-H4PteGlu1 normally
accounts for 3-10% of total intracellular folate in mammalian cells;
however, its metabolic function in cells has not been elucidated.
5-CHO-H4PteGlu is synthesized from
5,10-CH+-H4PteGlu by both the mitochondrial and
cytoplasmic isozymes of SHMT in vitro, and Escherichia
coli lacking SHMT activity do not contain intracellular
5-CHO-H4PteGlu, suggesting that SHMT catalyzes this
reaction in vivo (1). The only enzyme known to metabolize 5-CHO-H4PteGlu is MTHFS, an enzyme that catalyzes the
ATP-dependent and irreversible conversion of
5-CHO-H4PteGlu to
5,10-CH+-H4PteGlu. In rabbit liver, MTHFS is
located in the cytoplasm (2), whereas human liver contains 85% of the
MTHFS activity in the cytoplasm and 15% in the mitochondria (3).
The combined enzymatic activities of MTHFS and SHMT constitute a futile
cycle that may buffer cellular 5-CHO-H4PteGlu
concentrations and regulate SHMT activity (Scheme 1)
(4).
Cytoplasmic one-carbon metabolism is responsible for the synthesis of purines, thymidylate, and methionine and numerous subsequent S-adenosylmethionine-dependent methylation reactions (Scheme 1). There is accumulating evidence that mitochondrial folate metabolism is primarily responsible for the generation of formate and that mitochondrial derived formate is the source of one-carbon units required for cytoplasmic folate-dependent anabolic reactions (5) (Scheme 1). The major source of one-carbon units in the form of formate are generated from serine in a reaction catalyzed by mSHMT, but formate can also be generated in the mitochondria from glycine in cells that contain a GCS. Recently, it has been demonstrated that glycine is the major source of one-carbon units in kidney proximal tubules, cells that also contain a GCS (6). The role of mitochondria in generating one-carbon units for cytoplasmic folate metabolism suggests that cSHMT may not play a major role in the generation of one-carbon units. In fact, there is accumulating evidence that cSHMT is not an efficient source of one-carbon units for cytoplasmic metabolism (Scheme 1). Recent studies of Chinese hamster ovary cells (CHO) that lack mSHMT activity have demonstrated that CHO cells deficient in mSHMT activity accumulate 15-fold increased intracellular serine concentrations over wild type CHO cells, and CHO cells lacking mSHMT activity are auxotrophic for glycine. Despite the accumulation of intracellular serine, the net metabolic flux through the cSHMT enzyme in CHO cells deficient in mSHMT activity is in the direction of serine synthesis (7). Therefore, the primary role of cSHMT may not be to generate glycine or one-carbon units but instead may have other metabolic functions including the synthesis of 5-CHO-H4PteGlu.
Although little is known about the regulation of 5-CHO-H4PteGlu, it has been reported that valproic acid treatment lowers the intracellular concentration of 5-CHO-H4PteGlu in fetuses (8). In humans, valproic acid treatment is also associated with an increased incidence of neural tube defects, a disorder associated with folic acid status and elevated plasma homocysteine (9). 5-CHO-H4PteGlu is a potent inhibitor of several folate-dependent enzymes including phosphoribosylaminoimidazole carboxamide formyltransferase and SHMT and may regulate folic acid-dependent metabolic pathways (4). 5-CHO-H4PteGlu polyglutamates are slow tight binding inhibitors of SHMT and therefore may have a significant physiological relevance because slow binding inhibitors are generally more effective enzyme inhibitors in vivo (10). Inhibition of SHMT in vivo may be a mechanism whereby cells regulate not only folate-dependent glycine synthesis but also the supply of one-carbon units required for purine and thymidylate synthesis as well as homocysteine remethylation.
In order to determine the influence of 5-CHO-H4PteGlu depletion on folic acid-mediated one-carbon metabolism and SHMT activity, we have overexpressed the human MTHFS cDNA in 5Y neuroblastoma and determined its effects on cell proliferation, intracellular serine, glycine and methionine concentrations, and the relative distribution of the folic acid one-carbon derivatives.
(6S)-[3H]Folinic acid (40 Ci/mmol) was obtained
from New England Nuclear. 5-CHO-H4PteGlu, MES, HEPES, and
ATP were purchased from Sigma. Other chemicals were
reagent grade. Fetal bovine serum, minimal essential medium (MEM), and
its alpha modification (MEM) lacking sodium bicarbonate, ribosides,
ribotides, deoxyribosides, and deoxyribotides were obtained from
Hyclone Laboratories, Inc. Geneticin was obtained from Life
Technologies, Inc.
The full-length human MTHFS cDNA was subcloned into the XhoI/XbaI site of pcDNA3 (11). The pcDNA3 vector (Invitrogen) utilizes the human cytomegalovirus major intermediate early promoter/enhancer and the bovine growth hormone polyadenylation signal. A neomycin resistance marker expressed from the SV40 early promoter allows for selection of stable transformants in the presence of G418 sulfate.
Cell Lines and MediaThe human SH-SY5Y neuroblastoma, a
subline of the SK-N-SH neuroblastoma, were obtained from Dr. June
Biedler (Fordham University) (12). The cells are nearly diploid, have
biochemical and morphological properties of fetal noradrenergic
neurons, and have been demonstrated to have a functional glycine
cleavage system (13). The defined culture medium (MEM) lacks
glycine, serine, methionine, hypoxanthine, thymidine, and folate and
allows variation in the concentration of nutrients with relevance to
folate-dependent one-carbon metabolism. For all
experiments, the fetal bovine serum was depleted of folic acid and
other small molecules by dialysis at 4 °C over a 24-h period against
a 12-fold excess of phosphate-buffered saline (PBS) with buffer changes
every 4 h. The serum was then charcoal-treated to remove any
remaining folic acid. G418 sulfate was supplemented into the medium for
selection of stable cell colonies that integrated the MTHFS
construction.
The MTHFS construction (15 µg) was linearized with PvuI and transfected into 1 × 107 5Y neuroblastoma by electroporation (0.22 kV, 950 microfarad, Bio-Rad Gene Pulser II). Cells were cultured in MEM with
10% dialyzed fetal bovine serum for 24-48 h prior to the addition of
500 µg/ml G418 sulfate for selection of stable integrants. The cells
were incubated in a 5% CO2 enriched, 37 °C incubator until single stable colonies formed. Over 20 colonies formed and exhibited resistance to G418 sulfate, and 6 were isolated and passaged
until a stable line was generated.
The relative distribution of the
one-carbon forms of H4PteGlu was performed by modification
of previously reported procedures (14-16). Cells were passaged through
three population doublings in MEM without folate and supplemented
with 200 µM glycine, 20 µM hypoxanthine,
and 10 µM thymidine to deplete intracellular folate.
Cells were labeled with [3H]folinic acid by plating at
mid to late log phase (4 × 107 cells) on 100-mm
dishes containing 3 ml of
MEM supplemented with 50 nM
[3H]folinic acid (20 Ci/mmol) for 24-36 h. Following
incubation, cell monolayers were washed with PBS until the wash
contained less than 500 cpm/ml. Cells were harvested in buffer
containing 10 mM HEPES, 2 mM ascorbate, 10 mM 2-mercaptoethanol, pH 7.5. Cell extracts were boiled for
5 min, cooled to 4 °C, and centrifuged to remove cellular debris.
Folate polyglutamates were converted to monoglutamates by incubation
with rat serum at pH 7.0 for 3 h (15). H4PteGlu,
10-CHO-H4PteGlu, 5-CHO-H4PteGlu, and
5-CH3-H4PteGlu standards were added to the
sample prior to HPLC analysis. The various folate derivatives were
separated using a Shimadzu HPLC equipped with a diode-array
spectrophotometric detector using a C18 column (3.9 × 300 mm, 10 mm) and tetrabutylammonium phosphate/ethanol gradient as
described previously (15), and 1-ml fractions were collected into
scintillation vials. The fractions containing radioactivity were
identified by comparison with the diode-array chromatogram and the
absorbance spectra of the internal standards. The elution times were:
p-aminobenzylglutamate, 9 min; 10-CHO-H4PteGlu,
17 min; H4PteGlu, 24 min; 5-CHO-H4PteGlu,
36 min; and 5-CH3-H4PteGlu, 42 min.
The MTHFS enzyme activities were quantified by measuring the increase in absorbance at 360 nm due to the formation of 5,10-CH+-H4PteGlu. The assay was initiated by incubating 300 µl of cell extract with 700 µl of reaction buffer (100 mM MES, 0.5% Triton X-100, 14 mM 2-mercaptoethanol, 100 mM ATP, 150 mM MgCl2, 0.2 mM (6R,6S)-5-CHO-H4PteGlu, pH 6.3). Protein concentrations were determined by the method of Lowry.
Growth StudiesGrowth studies were performed to determine
the effects of glycine, methionine, and folic acid on 5Y and
5YMTHFS cell proliferation rates. Cells were grown in
MEM/dialyzed fetal bovine serum lacking folate and passaged for
three population doublings to deplete cells of intracellular folate.
Following folate depletion, 1 × 105 cells were seeded
into 15-mm wells at various glycine, methionine, and folate
concentrations. Cells were harvested every 2 days and counted using a
hemocytometer until at least three population doublings were observed.
Cell viability was assessed by the ability of cells to exclude trypan
blue.
Free amino acids were isolated by a modification of a previously described procedure (17). The medium was removed, and the cell monolayers were washed three times with 10 ml of PBS. The cells were harvested from 100-mm plates using a cell scraper after the addition of 300 µl of 5% trichloroacetic acid. Cell extracts were transferred to microcentrifuge tubes and vortexed to ensure complete cell lysis. After centrifugation at 12,000 × g for 20 min, the supernatants were transferred to new microcentrifuge tubes, and the trichloroacetic acid was removed by extraction with water-saturated diethyl ether. The aqueous solution containing the free amino acids was vacuum dried overnight. The free amino acids were derivatized with o-phthaldialdehyde, and the amino acid concentrations were determined at the Cornell Biotechnology Analytical/Synthesis Facility. Amino acid concentrations were determined relative to cell number, protein concentration, and intracellular valine concentrations. All methods gave similar relative results.
Western Analysis5Y and 5YMTHFS cell pellets were suspended and lysed by sonication then incubated at 100 °C for 10 min in buffer containing 2% SDS, 100 mM dithiothreitol, 60 mM Tris, pH 6.8. SDS-polyacrylamide gel electrophoresis was carried out using a 5% stacking gel and a 8% separating gel in a slab gel apparatus (Hoefer, San Francisco, CA) with the discontinuous buffer system of Laemmli. Proteins were transferred overnight to a polyvinylidene difloride membrane (Millipore) in a Bio-Rad Transblot apparatus at 30 V with a limit of 0.2 mA. The membrane was rinsed with 0.1% Tween 20 in PBS and blocked for 10 h with 1% nonfat dry milk, 0.1% Nonidet P-40 in PBS. Sheep anti-human MTHFS antiserum was generated from Chiron Mimotopes (San Diego, CA) using synthetic peptides representing amino acids 2-28 in the human MTHFS protein. The serum was diluted 1:10,000 in blocking buffer, and the membrane was incubated in the buffer for 15 h at 4 °C. The membrane was rinsed six times with 0.1% Tween 20 in PBS and incubated for 23 h with blocking buffer containing horseradish peroxidase-conjugated mouse anti-sheep IgG antibody in a 1:6000 dilution. The membrane was visualized using the SuperSignalTM chemiluminescent horseradish peroxidase substrate system from Pierce.
5-CHO-H4PteGlu is the only derivative of H4PteGlu that does not have a known metabolic function. In order to determine the role of 5-CHO-H4PteGlu in mammalian metabolism and the metabolic consequences associated with its depletion in the cell, the human MTHFS cDNA was overexpressed in 5Y neuroblastoma. Over 20 neomycin-resistant colonies formed, and six colonies were isolated and passaged until stable cell populations were obtained. All transformants have remained viable for over 1 year. The MTHFS enzyme activity was determined for each transformant. The MTHFS activity in the 5YMTHFS cell extracts ranged from 175 to 584 pmol 5,10-CH+-H4PteGlu formed/min/mg total protein, whereas the MTHFS activity was undetectable in 5Y cells (<5 pmol 5,10-CH+-H4PteGlu/min/mg) (Table I). All of the MTHFS activity was localized to the cytoplasmic fraction, suggesting that the previously reported MTHFS cDNA does not encode a mitochondrial MTHFS enzyme. However, we cannot rule out the possibility that mitochondrial MTHFS has been increased because we were not able to detect any MTHFS activity in isolated mitochondria from either 5Y or 5YMTHFS cells.
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MTHFS overexpression was verified by Western blot analysis using the 5Y
and 5YMTHFS6 cell lines (Fig. 1). While
varying molecular masses have been reported for the MTHFS enzyme
ranging from 19 to 32 kDa, the human cDNA is expected to express an
enzyme with a molecular mass of 23 kDa (11). Although MTHFS protein was not detected in the 5Y cells consistent with the low levels of enzyme
activity found in these cells, 5YMTHFS6 cell extracts
contain a strong immunoreactive band present at 26 kDa, consistent with the expression of the MTHFS cDNA (11). A second uncharacterized 33-kDa immunoreactive band is present at equal intensity in both 5Y and
5YMTHFS cells.
Amino Acid Concentrations
Overexpression of the MTHFS cDNA in the cytoplasm would be expected to lower cytoplasmic 5-CHO-H4PteGlu levels and perhaps activate cSHMT activity and influence intracellular serine and glycine metabolism. In order to determine if 5-CHO-H4PteGlu depletion influenced cytoplasmic one-carbon metabolism, intracellular amino acid concentrations were determined for the 5Y and 5YMTHFS6 cells cultured in the presence and the absence of exogenous glycine (Table II). When cultured without glycine, serine and glycine concentrations were elevated approximately 60% in 5YMTHFS6 cells compared with 5Y cells; however, the glycine/serine ratio and intracellular methionine concentrations were unchanged. When cultured with exogenous glycine (2 mM), the intracellular glycine concentrations in 5YMTHFS6 cells were elevated nearly 3-fold compared with 5Y cells, whereas intracellular serine concentrations were elevated greater than 3-fold relative to 5Y cells. Additionally, no methionine was detected in the 5YMTHFS6 cells when cultured with 2 mM exogenous glycine. These results suggest that intracellular 5-CHO-H4PteGlu influences intracellular serine, glycine, and methionine concentrations and that these changes are associated with changes in SHMT activity in the cytoplasm.
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There is accumulating evidence that cells
contain a greater number of folic acid-dependent enzymes
than folic acid coenzymes and that folic acid metabolism is highly
compartmentalized (5, 18). Evidence for channeling of the folic acid
cofactor has also been suggested in a number of studies. This suggests
that the purine, serine, and thymidylate synthesis, as well as
homocysteine remethylation pathways are not saturated with folate and
that these pathways compete for the limited supply of one-carbon units carried by folic acid cofactors. Initial studies of the
5YMTHFS cells suggested that all transfectants were growth
inhibited in the presence of elevated exogenous glycine. In order to
determine if overexpression of the MTHFS cDNA in 5Y cells disrupted
cytoplasmic one-carbon metabolism, growth studies were performed to
determine if the 5YMTHFS cells had additional nutrient
requirements. Both 5Y and 5YMTHFS cells require exogenous
glycine for maximum cell proliferation rates with growth rates reaching
their optimum between 0.2 and 0.5 mM glycine (Fig.
2). When cultured in the presence of 1.0 µM
(6R,6S)-5-CHO-H4PteGlu,
5YMTHFS6 cells did not require exogenous thymidylate,
purines, or methionine to maintain optimal growth rates. However, when
cultured in the presence of 10 nM (6R,6S)5-CHO-H4PteGlu as described
under "Materials and Methods," the 5YMTHFS6 cells were
growth inhibited relative to 5Y cells when exogenous glycine
concentrations exceeded 1 mM (Fig. 2). 5YMTHFS6
cells display a 30-40% decrease in cell proliferation rates at
glycine concentrations of 2 mM or greater relative to 5Y
cell proliferation rates. The growth inhibition was ameliorated in the
5YMTHFS6 cells by the addition of 1.0 µM
folinic acid to the culture medium (Fig. 2).
In order to determine if the glycine-induced growth inhibition of
5YMTHFS6 cells resulted in the disruption of purine,
thymidine, or methionine synthesis, the ability of methionine,
hypoxanthine, and thymidylate to ameliorate the glycine induced growth
inhibition was examined (Fig. 3). The addition of
exogenous hypoxanthine (500 µM) or thymidylate (500 µM) did not ameliorate the glycine-induced (5.0 mM) growth inhibition, whereas the addition of exogenous methionine at 1.0 mM completely ameliorated the
glycine-induced growth inhibition in the 5YMTHFS6 cells.
These results suggest that the growth inhibition exhibited by
5YMTHFS6 cells in the presence of glycine is due to
depletion of intracellular methionine and that
5-CHO-H4PteGlu depletion results in disruptions of
homocysteine remethylation.
Analysis of the Folic Acid One-carbon Derivative Distribution
The individual distribution of folic acid one-carbon forms was determined for the 5Y and 5YMTHFS6 cells in the presence and the absence of glycine (Table III). 5Y cells cultured with 0.0 or 0.2 mM exogenous glycine or 0.5 mM L-serine contain predominately 10-CHO-H4PteGlu (63-70%) and H4PteGlu (21-28%) with detectable levels of 5-CHO-H4PteGlu (3-7%) and 5-CH3-H4PteGlu (3-4%). However, when cultured in the presence of 5 mM glycine, 10-CHO-H4PteGlu (57%) and H4PteGlu (8.5%) concentrations were decreased, whereas 5-CH3-H4PteGlu levels increased markedly (31%) without affecting 5-CHO-H4PteGlu levels (3%). Cell fractionation studies suggested that all of the accumulated 5-CH3-H4PteGlu was localized to the cytoplasm. The increase in 5-CH3-H4PteGlu and decrease in H4PteGlu levels associated with 5.0 mM exogenous glycine suggests that glycine can serve as a major source of one-carbon units for cytoplasmic folate metabolism via the GCS.
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When cultured in the absence of glycine, the 5YMTHFS6 cells do not contain any 5-CHO-H4PteGlu, verifying that overexpression of MTHFS in the cytoplasm depletes intracellular 5-CHO-H4PteGlu concentrations. In all culture conditions 10-CHO-H4PteGlu (67-90%) is the predominate folate derivative in these cells, with the remaining folate present as H4PteGlu (8-32%). 5-CH3H4PteGlu was not detected (<1%) in the culture conditions listed in Table III. These results suggest that although exogenous glycine is an effective source of one-carbon units for 5-CH3-H4PteGlu synthesis in 5Y cells, 5YMTHFS6 cells are not able to accumulate 5-CH3-H4PteGlu when cultured with exogenous glycine.
In the present study, the effects of 5-CHO-H4PteGlu depletion on folate-dependent one-carbon metabolism were determined by overexpressing the MTHFS cDNA in the cytoplasm of human 5Y neuroblastoma. Previous studies of the 5Y neuroblastoma (13) have demonstrated that these cells contain both mitochondrial and cytoplasmic SHMT activities, as well as an active GCS. Analysis of the folic acid one-carbon pools demonstrated that overexpression of MTHFS in the cytoplasm depletes all cellular 5-CHO-H4PteGlu, suggesting that 5-CHO-H4PteGlu accumulates in the cell due to limiting MTHFS activity. However, although overexpression of the MTHFS cDNA resulted in accumulation of MTHFS enzyme in the cytoplasm, we cannot rule out the possibility that mitochondrial MTHFS activity was also increased because we were not able to detect any MTHFS activity in purified mitochondria from either 5Y or 5YMTHFS cells. Analysis of the intracellular free amino acid pools suggests that depletion of 5-CHO-H4PteGlu increased both intracellular serine and glycine concentrations, suggesting that 5-CHO-H4PteGlu polyglutamates do inhibit cSHMT activity in vivo, consistent with previous in vitro studies (10).
In these studies, we have demonstrated that 5Y cells do not accumulate 5-CH3-H4PteGlu in the cytoplasm in the absence of exogenous glycine, whereas 5-CH3-H4PteGlu accounts for 31% of total folate in 5Y cells cultured with 5 mM exogenous glycine. This suggests that glycine is an effective one-carbon source for the synthesis of 5-CH3-H4PteGlu and subsequent homocysteine remethylation (Scheme 1). 5Y cells overexpressing MTHFS in the cytoplasm do not accumulate either free methionine or 5-CH3-H4PteGlu when cultured with elevated exogenous glycine, suggesting that glycine is no longer an effective source of one-carbon units for homocysteine remethylation. The observation that glycine is no longer an effective one-carbon source for homocysteine remethylation in 5YMTHFS cells suggests that 5-CHO-H4PteGlu plays a critical role in regulating the activity of cSHMT and the relative distribution of the one-carbon forms of folic acid.
When cultured with exogenous glycine, 5YMTHFS6 cells appear to accumulate serine, whereas methionine pools are depleted. These results suggest that there are two reactions competing for one-carbon units in the form of 5,10-CH2-H4PteGlu: serine synthesis catalyzed by cSHMT and 5-CH3-H4PteGlu synthesis catalyzed by the enzyme methylenetetrahydrofolate reductase (Scheme 1). The combined activation of cSHMT resulting from 5-CHO-H4PteGlu depletion and the availability of exogenously supplied glycine inhibits the flow of one-carbon units from 10-CHO-H4PteGlu to 5-CH3H4PteGlu due to an increase in serine synthesis by cSHMT. In the absence of exogenous glycine, depletion of 5-CHO-H4PteGlu does not affect cell proliferation rates in 5YMTHFS cells. However, when cultured with 10 nM folinate, exogenous glycine (2 mM) inhibits 5YMTHFS cell proliferation 30-40% relative to 5Y cell proliferation rates. This suggests that both cSHMT activation and a source of exogenous glycine is required to deplete 5-CH3-H4PteGlu and thereby inhibit homocysteine remethylation.
We have also attempted to overexpress the human MTHFS cDNA in human MCF-7 cells and CHO cells.2 These cell lines do not contain a GCS and require serine as the major source of one-carbon units. We were not able to obtain stable cell lines that overexpressed MTHFS in the CHO cells, suggesting that MTHFS overexpression may be lethal in these cells. We were only able to obtain two stable MCF-7 cell transfectants that overexpressed the MTHFS cDNA. In the MCF-7 transfectants, MTHFS activity was elevated less than 6-fold, suggesting that increases in MTHFS activity in MCF-7 cells may also be lethal.2
The low levels of 5-CHO-H4PteGlu in the cell do play a role in folic acid-dependent one-carbon metabolism. 5-CHO-H4PteGlu is required to keep cytoplasmic folate metabolism in homeostasis by mediating the flow of one-carbon units in the cytoplasm through either the homocysteine remethylation or serine synthesis pathways. The need for folate-dependent serine synthesis in the cytoplasm is not clearly understood because serine synthesis from glycolytic intermediates also occurs in the cytoplasm. However, these studies suggest that the slow tight binding inhibitor 5-CHO-H4PteGlu regulates cSHMT activity and folate-dependent serine synthesis. This may be a mechanism used by cells to prevent accumulation of intracellular folate as 5-CH3-H4PteGlu and thereby regenerate H4PteGlu for purine biosynthesis. This notion is supported by previous in vitro kinetic studies that have demonstrated substrate channeling of THF polyglutamate cofactor from cSHMT to 10-formyltetrahydrofolate synthetase during the cSHMT catalyzed conversion of glycine to serine (19).
Finally, it is also of interest that increased availability of either methionine or folinate can ameliorate the glycine-induced growth inhibition of 5YMTHFS cells. It has been well established that disruptions in folate-dependent homocysteine remethylation can result in incomplete closure of the neural tube during development (9). The ability of 5-CHO-H4PteGlu to influence 5-CH3-H4PteGlu concentrations and homocysteine remethylation suggests that regulation of the 5-CHO-H4PteGlu futile cycle may be critical to maintain one-carbon homeostasis especially during rapid proliferative stages in development.