BioFiles Volume 5, Number 6 — Cancer

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Folic Acid Metabolism: A Role in Cancer's Cause and Cure

The mammalian folic acid cycle is a highly complex but crucial process for the transfer of one-carbon units to amino acids, nucleotides, and other biomolecules. Folic acid cannot be synthesized but is obtained through diet, primarily fruits, vegetables, and fortified grains. Dietary folic acid is the starting material for the cycle's fundamental molecule tetrahydrofolic acid (tetrahydrofolate, THF). Folic acid is enzymatically reduced by dihydrofolate reductase (DHFR, EC 1.5.1.3) either partially to the intermediate dihydrofolate (DHF) or completely to tetrahydrofolate. THF is subsequently processed through a variety of oxidative enzymatic modifications that subsequently function as one-carbon donors (see Figure 1). Residual dihydrofolate may be recycled to tetrahydrofolate. While folic acid and tetrahydrofolate contribute to a myriad of processes, two of these metabolic pathways have been of interest for cancer chemotherapy (see Figure 2).

 

BioFiles Volume 5 Number 6 - Cancer Figure 1 Enzymes
1.4.4.2
1.5.1.3
1.5.1.5
1.7.99.5
2.1.1.13
2.1.1.45
2.1.2.1
2.1.2.2
2.1.2.3
2.1.2.5
2.1.2.10
3.5.1.10
3.5.4.9
4.3.1.4
6.3.4.3
6.3.3.2
Glycine dehydrogenase (decarboxylating)
Dihydrofolate reductase
Methylene-THF dehydrogenase (NADP+)
5,10-Methylene-THF reductase (FADH2)
5-Methyl-THF-homocysteine S-methyltransferase
Thymidylate synthase
Glycine hydroxymethyltransferase
Phosphoribosylglycinamide formyltransferase
Phosphoribosylamidoimidazole-carboxamide formyltransferase
Glutamate formiminotransferase
Aminomethyltransferase
Formyl-THF deformylase
Methenyl-THF cyclohydrolase
Formimino-THF cyclodeaminase
5-Formyl-THF cyclo-ligase
Formate-tetrahydrofolate ligase
Figure 1. The metabolic cycling and regeneration of tetrahydrofolate. As implied by the image, THF metabolism is not linear but may shift to create one-carbon-donating substrates as needed for particular cellular processes. The one-carbon donor molecules are colored red in the illustrated structures.

 

BioFiles Volume 5 Number 6 - Cancer Figure 2
Figure 2. Some of the reactions in which THF metabolites function as carbon donors. The illustration corresponds to the Formic Acid C1 pool indicated on the Nicholson Metabolic Pathways map available through the Sigma-Aldrich website (sigma.com/pathways). The reactions of interest discussed in this review are highlighted.

One function of folic acid metabolism is the support of DNA synthesis and repair through the generation of nucleic acid building blocks. This metabolic process is the de novo synthesis of deoxythymidine monophosphate (dTMP, 5-CH2-dUMP) from deoxyuridine monophosphate (dUMP) through addition of a methyl group by the enzyme thymidylate synthase (EC 2.1.1.45), with subsequent phosphorylation to the deoxynucleotide triphosphate. Thymidine triphosphate (dTTP) is one of the four deoxyribonucleic acids essential for DNA synthesis and repair, and cellular levels of thymidine triphosphate are limiting for DNA synthesis.

Other folic acid metabolic pathways that are important to DNA synthesis and modification are those maintained by the enzymes phosphoribosylglycinamide formyltransferase (glycinamide ribonucleotide transformylase, GAR, EC 2.1.2.2) and phosphoribosylaminoimidazolecarboxamide formyltransferase (5-aminoimidazole-4- carboxamide ribonucleotide transformylase, AICAR, EC 2.1.2.3). These two enzymes support de novo purine synthesis processes, generating precursors to adenine and guanine, the nucleotide bases required for the synthesis of deoxyadenoside triphosphate (dATP) and deoxyguanosine triphosphate (dGTP), two additional DNA building blocks.

A second important folate metabolic reaction is the conversion of homocysteine to the amino acid methionine by the action of 5-methyl-THF-homocysteine S-methyltransferase (EC 2.1.1.13). Some of this regenerated methionine is subsequently transformed along with ATP by the enzyme methionine adenosyl transferase (EC 2.5.1.6) to produce S-adenosylmethionine (SAM or SAdoMet), phosphate, and diphosphate. S-Adenosylmethionine is a key substrate for methyltransferases and participates in more than 100 types of methylation reactions of biological molecules such as lipids and peptides. The methylation of DNA is an important epigenetic modification that utilizes S-adenosylmethionine as a methyl donor. Therefore, folate levels and metabolism are necessary for normal and malignant cells to synthesize and repair DNA, and to subsequently methylate DNA and other biomolecules.

Interference with folate metabolism has a greater toxic effect on rapidly dividing cells, such as red blood cells, bone marrow cells, gastrointestinal cells, and malignant cells. Because folate metabolism is required for cell replication and survival, compounds that are metabolic inhibitors have successfully been used as antitumor therapeutics, albeit with toxicity and limited application. The first antifolate drug, aminopterin, is a folic acid analog (4-aminofolic acid) that inhibits dihydrofolate reductase, preventing the reduction of folic acid and dihydrofolic acid to THF. Methoxtrexate (MTX) is another analog of folic acid still in use as an antitumor chemotherapeutic that directly inhibits dihydrofolate reductase, as well as inhibiting thymidylate synthase. In light of developed drug resistance to methotrexate, many synthetic compounds that inhibit dihydrofolate reductase and/or thymidylate synthase have been screened. Newer classical antifolates (folate structural analogs) used in cancer chemotherapy include trimetrexate, permetrexed, and raltitrexed, while non-classical antifolates have also been investigated for functionality as antitumor and antibacterial agents. Permetrexed is a multitargeted antifolate that blocks several folic acid cycle enzymes in addition to thymidylate synthase and dihydrofolate reductase.

As folate metabolism is fundamental to both cancerous and normal cells, so folate depletion and its resultant reduction of DNA synthesis and DNA methylation must be toxic to both malignant and normal cells. Studies using healthy cells show that folate deficiency can result in DNA damage, including chromosomal breaks and sequence miscoding, possibly due to insufficient levels of thymidine. Folate depletion may also contribute to reduced levels of S-adenosylmethionine, resulting in hypomethylation of DNA. One in vivo study found that folate deficiency in rats was associated with DNA strand breaks and hypomethylation of specific sequences of the p53 tumor suppressor gene.1 Researchers chose to study p53 for changes potentially associated with dietary folate deficiency as this gene is mutated in 30-50% of common human cancers.

Paradoxically, inhibition of folic acid metabolism has been used as a mechanism for successful elimination of malignant cells, but insufficient folic acid levels in normal cells have been associated with DNA damage and altered DNA methylation conditions that have been associated with malignant transformation. Interference or prevention of folic acid metabolism is then potentially both a cause of malignancy and a means to induce apoptosis or necrosis in malignant cells. The complexity of the folic acid metabolic cycle and its use in construction and modification of fundamental biomolecules of the cell allow this paradox to exist.

Folic Acid Metabolites and Enzymes



References

  1. Kim, Y.-I. et al. Folate deficiency in rats induces DNA strand breaks and hypomethylation within the p53 tumor suppressor gene. Am. J. Clin. Nutr., 65, 46–52 (1997).
  2. Gangjee, A. et al. Recent advances in classical and non-classical antifolates as antitumor and antiopportunistic infection agents: Part I. Anti-Cancer Agen. Med. Chem., 7, 524–542 (2007).
  3. Gangjee, A. et al. Recent advances in classical and non-classical antifolates as antitumor and antiopportunistic infection agents: Part II. Anti-Cancer Agen. Med. Chem., 8, 205–231 (2008).
  4. Chapter 15: Folate and folic acid, in "Vitamin and Mineral Requirements in Human Nutrition", World Health Organization, Food and Agriculture Organization of the United Nations (2004).
  5. Choi, S.-W. et al. Folate and carcinogenesis: An integrated scheme. J. Nutr., 130, 129–132 (2000).
  6. McGuire, J.J. Anticancer antifolates: Current status and future directions. Curr. Pharm. Design, 9, 2593-2613 (2003).
  7. Bertino, J.R. Cancer research: From folate antagonism to molecular targets. Best Pract. Res. Clin. Haematol., 22, 577–582 (2009).

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