Next Article in Journal
Egg and Egg-Derived Foods: Effects on Human Health and Use as Functional Foods
Previous Article in Journal
Maltol, a Food Flavoring Agent, Attenuates Acute Alcohol-Induced Oxidative Damage in Mice
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

13C-Enrichment of Urinary Uric Acid after l-[Ring-2-13C]Histidine Dose in Adult Humans

Department of Nutrition Sciences, University of Alabama at Birmingham, Birmingham, AL 35294, USA
*
Author to whom correspondence should be addressed.
Submission received: 13 November 2014 / Revised: 6 January 2015 / Accepted: 15 January 2015 / Published: 20 January 2015

Abstract

:
We determined whether ring-2 carbon of histidine is folate-dependently transferred to carbons 8 (C8) and/or 2 (C2) in urinary uric acid in humans. Two adults collected each urine void for four days. Aliquots of urine for the first day were used for baseline values; then the subjects ingested 0.7 g (3.3 mmol) of l-[ring-2-13C]histidine and collected urine for three experimental days. Aliquots were analyzed for percentage 13C-content at C2 and C8 by a liquid-chromatography-mass spectrometry method. Percentage enrichment was determined by subtracting time-of-day paired baseline percentage 13C-content from experimental percentage 13C-content for each void. C2 was predominantly 13C-enriched in the majority of voids. The percentage enrichments at C2 for two subjects were 0.14 (±0.028 [SEM], n = 26) and 0.18 (±0.049, n = 21), whereas at C8, they were 0.008 (±0.006) and −0.005 (±0.008), respectively. The mean C2-enrichments were significantly greater than zero (p < 0.01), whereas those of C8 were not (p > 0.2). The enrichment had a diurnal rhythm peaking in the morning. Our results may be useful in the estimation of the timing for the administration of drugs that interfere with purine nucleotide biosynthesis in the treatment of cancer and autoimmune disease.

1. Introduction

Purine nucleotide biosynthesis de novo is an essential process in producing building blocks of DNA and RNA [1]. Two folate-dependent enzymes, glycinamide ribotide (GAR) and aminoimidazole carboxamide ribotide (AICAR) transformylases, are involved in the process for the transfer of one-carbon units into the positions 8 (C8) and 2 (C2) of the purine ring, respectively (Figure 1). Uric acid is the final catabolic product of purines in humans and is excreted in urine, and this catabolism does not alter the positions of carbons in the ring [1]. Using a liquid-chromatography-mass spectrometry (LC/MS/MS) method [2,3], it is possible to independently measure the 13C-enrichment at the C2 and C8 positions of urinary uric acid after an oral dose of 13C-labeled sources, which include formate, 2-glycine, 3-serine and ring-2-histidine. Among those one-carbon sources, only histidine is considered to be essential in humans [4].
Figure 1. Metabolic pathway of 10-formyltetrahydrofolate (10-HCO-H4folate) formed from tetrahydrofolate (H4folate) and [ring 2-carbon]histidine, [3-carbon]serine, [2-carbon]glycine, and formate. Enzymes include: (1) 5-formiminotetrahydrofolate transferase-cyclodeaminase; (2) glycine-cleavage system; (3) serine hydroxylmethyltransferase; and (4) 10-HCO-H4folate synthetase. 10-HCO-H4folate is incorporated into the carbons 2 (C2) and 8 (C8) of the purine ring by AICAR and GAR transformylases, respectively.
Figure 1. Metabolic pathway of 10-formyltetrahydrofolate (10-HCO-H4folate) formed from tetrahydrofolate (H4folate) and [ring 2-carbon]histidine, [3-carbon]serine, [2-carbon]glycine, and formate. Enzymes include: (1) 5-formiminotetrahydrofolate transferase-cyclodeaminase; (2) glycine-cleavage system; (3) serine hydroxylmethyltransferase; and (4) 10-HCO-H4folate synthetase. 10-HCO-H4folate is incorporated into the carbons 2 (C2) and 8 (C8) of the purine ring by AICAR and GAR transformylases, respectively.
Nutrients 07 00697 g001
In our previous studies, the 13C-enrichment independently at the C2 and C8 positions of urinary uric acid was measured after an oral dose of 13C-formate and [2-13C]-glycine, and these enriched mainly C2 and only C8 (+C5) of urinary uric acid, respectively [3]. In the present study, we determined whether l-[ring-2-13C]histidine furnishes a one-carbon to C8 and/or C2. To our knowledge, such a fundamental human study using the ring-2-histidine as a tracer has never been reported.

2. Subjects and Methods

This study was approved by the Institutional Review Board for Human Use at the University of Alabama at Birmingham (F060417002 approved in 2006), and written informed consent was obtained. For a total of four days, two healthy adult males collected and measured the volume of each urine void after each urine void was thoroughly mixed. The subjects were two healthy adults with no history of major illness, who were consuming normal diet without folic acid supplementation. Their serum and red-cell folate concentrations are within normal range. Serum vitamin B-12 and plasma pyridoxal 5′-phosphate concentrations were also normal, and their genotype of 5,10-methylenetetrahydrofolate reductase was the normal variant (677 CC). Aliquots of each void for the first 24-h period were used for analysis for baseline values. Subsequently, the subjects ingested 0.7 g (3.3 mmol) of l-histidine-[ring-2-13C]∙HCl∙H2O (98%, Cambridge Isotope Laboratories, Andover, MA, USA) with 50-mL water at 12:00–16:00 hour and continued collection of each urine void for three experimental days. Samples of all urine voids were analyzed for percentage 13C-content at C2 and C8 of urinary uric acid by a LC/MS/MS method [2,3]. Percentage enrichment was determined by subtracting time-of-day paired baseline percentage 13C-content from experimental percentage 13C-content for each void in both subjects. Significance of the mean percentage enrichment above zero was determined by the paired-t-test independently for C2 and C8 of urinary uric acid. Since values in urine voids reflect in vivo metabolic events hours earlier, and voids were not equally spaced in time, these data were not suitable for traditional circadian analysis. However, the large variation in the percentage 13C-enrichment at C2 suggested the use of the runs-above- and below-the-median test that assumes no mathematical model [5].

3. Results

After an oral ingestion of l-[ring-2-13C]histidine, C2 was predominantly 13C-enriched in the majority of urine voids collected for three experimental days (Figure 2). The mean (±SEM) percentage enrichments at C2 for two subjects (I and II) were 0.14 (±0.028, n = 26) and 0.18 (±0.049, n = 21), whereas at C8 they were 0.008 (±0.006) and -0.005 (±0.008), respectively. Mean C2-enrichments were significantly greater than zero (p < 0.01), whereas those of C8 were not (p > 0.2). There was no significant correlation between uric acid excretion and percentage 13C enrichment at C2 in each void, because about one third of the urine voids had little or no enrichment. Based on the previous study [3], any enrichment less than 0.004% was not considered significantly greater than zero. Subjects ingested histidine at different times, and voids are not spaced equally in time. Therefore, there is not a perfect overlap of the enrichments in Figure 2.
Figure 2. Percentage 13C-enrichment at C2 and C8 of uric acid in urine voids after ingesting 2-13C-histidine. Subjects I and II had 26 and 21 urine voids, respectively. Closed bars represent percentage 13C-enrichment at C2, and open bars represent percentage 13C-enrichment at C8. Note that the scales on the y-axes are different between C2 and C8.
Figure 2. Percentage 13C-enrichment at C2 and C8 of uric acid in urine voids after ingesting 2-13C-histidine. Subjects I and II had 26 and 21 urine voids, respectively. Closed bars represent percentage 13C-enrichment at C2, and open bars represent percentage 13C-enrichment at C8. Note that the scales on the y-axes are different between C2 and C8.
Nutrients 07 00697 g002
In our subjects I and II, the uric acid excretion was 9.1 and 9.8 mmol per three days, respectively. The uric acid content in each void varied from 8% to 16% of the total daily uric acid excretion during the period. The fraction of the dose of histidine excreted as uric acid was 0.39% and 0.54% in three days, respectively.
Diurnal rhythm was detected by the runs-above- and below-the-median test [5]. The results indicated eight runs each for subjects I and II (p < 0.01). This was less than expected indicating the presence of rhythmicity. As shown in Figure 3, the mean percentage 13C-enrichment at C2 during 8:00–12:00 h of 0.37 (±0.034, n = 12) was significantly higher than that during 20:00–24:00 h plus 00:00–04:00 h of 0.035 (±0.014, n = 12, p < 0.01).
Figure 3. Diurnal changes in mean percentage 13C-enrichment at C2 after ingesting 2-13C-histidine. These are based on the data at six 4-h periods (Figure 2). Each column from left to right includes data from 6, 6, 12, 11, 6, and 6 urine voids. Vertical line represents SEM. In order to make the figure more compact, the top of this error bar (08:00–12:00) was cut off.
Figure 3. Diurnal changes in mean percentage 13C-enrichment at C2 after ingesting 2-13C-histidine. These are based on the data at six 4-h periods (Figure 2). Each column from left to right includes data from 6, 6, 12, 11, 6, and 6 urine voids. Vertical line represents SEM. In order to make the figure more compact, the top of this error bar (08:00–12:00) was cut off.
Nutrients 07 00697 g003

4. Discussion

In the present study, we found that the C2 position of urinary uric acid was predominantly 13C-enriched in the majority of urine voids collected for three experimental days following an oral ingestion of l-[ring-2-13C]histidine. The mean enrichments at C2 for two subjects were 0.14% and 0.18%, whereas at C8 they were 0.008% and -0.005%, respectively. In our previous study, these two subjects participated as well and ingested [13C]formate and [2-13C]glycine, which enriched mainly C2 and only C8 (+ C5) of urinary uric acid, respectively [3]. We have now determined the locations of the incorporation of all one-carbon sources with the exception of serine. It is well established that [2-13C]glycine produces [3-13C]serine by the glycine-cleavage-system reactions coupled with 13C-exchange by serine hydroxylmethyltransferase [6,7]. Therefore, we postulate that [3-13C]serine also enriches principally C8. Matthews et al. [8] reported that 54% of plasma serine was biosynthesized from glycine in 60 hours in adult males. These findings suggest that [10-13C]formyltetrahydrofolate originating from [3-13C]serine is channeled to GAR transformylase in a folate-requiring-enzyme complex containing the trifunctional folate-metabolizing enzyme and serine hydroxymetyhyltransferase [9,10], whereas ring-2-histidine and formate furnish their one carbon predominantly to AICAR transformylase. Human GAR transformylase exists as a part of a large multifunctional protein which is extended and highly flexible [11] and could allow the trifunctional folate-metabolizing enzyme and serine hydroxymetyhyltransferase to form a complex as has been observed in chicken liver enzymes [9,10]. This complex would channel one carbon from 3-serine to C8. Therefore, human GAR transformylase multifunctional protein could be used as a platform to bind other enzymes as previously suggested [11].
In order to delineate possible mechanism(s) and implication of our finding of predominant enrichments at the C2 position after a l-[ring-2-13C]histidine load, it might be worth to note the following. Aminoimidazolecarboxamide (AICA), a metabolite of AICAR, is normally found in urine of healthy humans. Therefore, purine nucleotide biosynthesis is likely being blocked at this step to a certain extent at all times [3,12]. AICAR transformylase, not associated with a folate-requiring-enzyme complex that utilizes a non-essential amino acid, may be more sensitive than GAR transformylase to changes in folate-coenzyme pools and in the ability of folates to acquire a one carbon that is destined for C2. We postulate that GAR transformylase has a metabolic advantage over AICAR transformylase in acquiring a one carbon, because GAR transformylase precedes AICAR transformylase in purine nucleotide biosynthesis and utilizes the non-essential glycine and serine from diet as well as from their biosynthesis. In contrast, AICAR transformylase may have to depend on low in vivo pools of formate and the essential amino acid, histidine. Dietary histidine is required for protein biosynthesis and other homeostatic processes; therefore, it may seem metabolically wasteful to catabolize it to the non-essential glutamic acid via folate-dependent enzymes, formiminotransferase-cyclodeaminase [13]. However, if ring-2-histidine is important as a one-carbon source for C2, this seemingly wasteful catabolism of histidine may be essential. The catabolism of histidine must be important especially early in life, because the deficiency of formiminotransferase is manifested by growth retardation and neurological abnormalities [14]. In patients with this defect, more urinary AICA excretion is observed with and without an oral AICA load compared to healthy individuals [15]. This indicates that folate-dependent histidine catabolism to produce 10-formyltetrahydrofolate (formed from 5-formiminotetrahydrofolate) is apparently limiting the supply of a one carbon to AICAR transformylase. Furthermore, [ring-2-14C]-histidine was reported to label purines much more efficiently than serine or the methyl groups of choline in rats, clearly suggesting that this one carbon is destined for purine nucleotide biosynthesis rather than supplying the general one-carbon pool [16].
As to the importance of histidine in purine biosynthesis, there is a unique article in the literature. Cooperman and Lopez [17] reported that an oral histidine load alone in folate-deficient adult patients resulted in an 18-fold increase in reticulocyte formation in five days. The reticulocyte response is what would be expected if folic-acid therapy had been initiated. Therefore, it is likely that the excess histidine supplies its one carbon for DNA and RNA synthesis in the erythropoietic system; hence correcting the anemia due to folate deficiency in these patients. This could also suggest that the one carbon from ring-2-histidine is used in both purine and thymine nucleotide biosyntheses. However, the exact mechanism explaining these findings remains unknown. It may be that formiminotransferase-cyclodeaminase could be associated with AICAR transformylase in bone marrow favoring the incorporation of a one carbon from ring-2-histidine into C2. The association of histidine catabolism with purine nucleotide biosynthesis in humans has largely been neglected, and further research in this area is warranted.
The 13C-enrichment at C2 after the doses of histidine or formate [11] had a diurnal rhythm in humans, which may reflect diurnal changes in AICAR, GAR, folate, histidine and formate pools as well as AICAR transformylase activity. In addition, the size of purine nucleotide pool may regulate this enrichment [18]. Since the urine voids reflect metabolic events hours earlier, the diurnal rhythm may indicate more active metabolic use of histidine and formate for purine nucleotide biosynthesis during the night-time than daylight hours resulting in enhanced C2 enrichment of uric acid in the morning. Our results may provide important information in deciding the timing for the administration of drugs that interfere with purine nucleotide biosynthesis (e.g., antifolates) in the treatment of cancer and autoimmune disease. In fact, it has been established that methotrexate efficacy for certain cancers is increased when the drug is given during the evening and night hours [19,20].
A limitation of the study is that the number of subjects in this study is only 2. Therefore, our results should be considered preliminary. However, the use of the specific l-[ring-2-13C]histidine tracer and the specific method to independently determine the 13C-enrichment by LC/MS/MS yielded consistent results in both subjects. We used 3.3 mmol of l-[ring-2-13C]histidine as a tracer, and this amount was close to the estimated daily dietary intake of 4.5 mmol [21]. Therefore, we believe that our data represent the typical metabolism of histidine and purine in the general adult population.

5. Conclusions

Our findings presented here can be summarized as follows: (a) C2 of urinary uric acid was predominantly 13C-enriched after a l-[ring-2-13C]histidine dose; (b) this enrichment showed a diurnal rhythm; and (c) folate-dependent histidine catabolism to glutamic acid may be essential for purine nucleotide biosynthesis. These results together with those in our previous study [3] are the first to document the independent detection of 13C-enrichment at C2 and C8 of urinary uric acid after ingestion of 13C-labeled formate, 2-glycine and ring-2-histidine in the same individuals. It is important to stress that the roles of folate coenzymes and one-carbon sources in purine nucleotide biosynthesis de novo described in general textbooks, have been obtained in uricotelic animals and microorganisms, where it was found or assumed that one-carbon sources from its precursors are equally incorporated into C2 and C8 of the purine ring. However, our results indicate that the above findings cannot be extrapolated to human metabolism. Our non-invasive method using 13C-labeled tracers and the LC/MS/MS method should lead to a better understanding of the purine biosynthesis in future human studies. Although our results represent a small sample size and should be considered preliminary, we hope that our findings stimulate the interest of researchers in the area of histidine metabolism and purine nucleotide biosynthesis in humans.

Acknowledgments

This study was in part supported by a grant from National Institute of Health (DK064174).

Author Contributions

Both authors participated equally in study concept and design, acquisition, analysis and interpretation of data, and writing of the manuscript.

Conflicts of Interest

The authors have no conflicts of interest to declare.

References

  1. Rowe, P.B. Folates in the biosynthesis and degradation of purines. In Folates and Pterins. Chemistry and Biochemistry of Folates; Blakley, R.L., Benkovic, S.T., Eds.; John Wiley: New York, NY, USA, 1984; Volume 1, pp. 329–344. [Google Scholar]
  2. Gorman, G.S.; Tamura, T.; Baggott, J.E. Mass spectrometric method for detecting carbon 13 enrichment introduced by folate coenzymes in uric acid. Analy. Biochem. 2003, 321, 188–191. [Google Scholar] [CrossRef]
  3. Baggott, J.E.; Gorman, G.S.; Tamura, T. 13C Enrichment of carbons 2 and 8 of purine by folate-dependent reactions after [13C]formate and [2–13C]glycine dosing in adult humans. Metabolism 2007, 56, 708–715. [Google Scholar] [CrossRef] [PubMed]
  4. Laidlaw, S.A.; Kopple, J.D. Newer concepts of the indispensable amino acids. Am. J. Clin. Nutr. 1987, 46, 593–605. [Google Scholar] [PubMed]
  5. Sokal, R.R.; Rohlf, F.J. Biometry. In the Principles and Practice of Statistics in Biological Research, 2nd ed.; W.H. Freeman: San Francisco, NC, USA, 1981; pp. 782–787. [Google Scholar]
  6. Kikuchi, G. The glycine cleavage system: Composition, reaction mechanism, and physiological significance. Mol. Cell. Biochem. 1973, 1, 169–187. [Google Scholar] [CrossRef] [PubMed]
  7. Fern, E.B.; Garlick, P.J. The specific radioactivity of the tissue free amino acid pool as a basis for measuring the rate of protein synthesis in the rat in vivo. Biochem. J. 1974, 142, 413–419. [Google Scholar] [PubMed]
  8. Matthews, D.E.; Conway, J.M.; Young, V.R.; Bier, D.M. Glycine nitrogen metabolism in man. Metabolism 1982, 30, 886–893. [Google Scholar] [CrossRef]
  9. Caperelli, C.A.; Benkovic, P.A.; Chettur, G.; Benkovic, S.J. Purification of a complex catalyzing folate cofactor synthesis and transformylation in de novo purine biosynthesis. J. Biol. Chem. 1980, 255, 1885–1890. [Google Scholar] [PubMed]
  10. Smith, G.K.; Mueller, W.T.; Wasserman, G.F.; Taylor, W.D.; Benkovic, S.J. Characterization of the enzyme complex involving the folate-requiring enzymes of de novo purine biosynthesis. Biochemistry 1980, 19, 4313–4321. [Google Scholar] [CrossRef] [PubMed]
  11. Welin, M.; Grossmann, J.G.; Flodin, S.; Nyman, T.; Stenmark, P.; Trésaugues, L.; Kotenyova, T.; Johansson, I.; Nordlund, P.; Lehtiӧ, L. Structural studies of tri-functional human GART. Nucleic Acids Res. 2010, 38, 7308–7319. [Google Scholar] [CrossRef] [PubMed]
  12. Baggott, J.E.; Gorman, G.S.; Morgan, S.L. Phenotypes and circadian rhythm in utilization of formate in purine nucleotide biosynthesis de novo in adult humans. Life Sci. 2011, 88, 688–692. [Google Scholar] [CrossRef] [PubMed]
  13. MacKenzie, R.E.; Baugh, C.M. Tetrahydropteroylpolyglutamate derivatives as substrates of two multifunctional proteins with folate-dependent enzyme activities. Biochim. Biophys. Acta 1980, 611, 187–195. [Google Scholar] [CrossRef] [PubMed]
  14. Arakawa, T.; Tamura, T.; Ohara, K.; Narisawa, K.; Tanno, K.; Honda, Y.; Higashi, O. Familial occurrence of formiminotransferase deficiency syndrome. Tohoku J. Exp. Med. 1968, 96, 211–217. [Google Scholar] [CrossRef] [PubMed]
  15. Arakawa, T.; Wada, Y. Urinary AICA (4-amino-5-immidazolecarboxamide) following an oral dose of AICA in formiminotransferase deficiency syndrome. Tohoku J. Exp. Med. 1966, 88, 99–102. [Google Scholar] [CrossRef] [PubMed]
  16. Sprinson, D.B.; Rittenberg, D. The metabolic reactions of carbon atom 2 of l-histidine. J. Biol. Chem. 1952, 198, 655–661. [Google Scholar] [PubMed]
  17. Cooperman, J.M.; Lopez, R. The role of histidine in the anemia of folate deficiency. Exp. Biol. Med. 2002, 227, 998–1000. [Google Scholar]
  18. An, S.; Kumar, R.; Sheets, E.D.; Benkovic, S.J. Reversible compartmentalization of de novo purine biosynthetic complexes in living cells. Science 2008, 320, 103–106. [Google Scholar] [CrossRef] [PubMed]
  19. Schmiegelow, K.; Glomstein, A.; Kristinsson, J.; Salmi, T.; Schroder, H.; Bjork, O. Impact of morning versus evening schedule for oral methotrexate and 6-mercaptopurine on relapse risk for children with acute lymphoblastic leukemia. J. Pediat. Hematol. Oncol. 1997, 19, 102–109. [Google Scholar] [CrossRef]
  20. Lévi, F. From circadian rhythms to cancer chronotherapeutics. Chronobiol. Int. 2002, 19, 1–19. [Google Scholar] [CrossRef] [PubMed]
  21. Matthews, D.E. Proteins and amino acids. In Modern Nutrition in Health and Disease, 11th ed.; Ross, A.C., Caballero, B., Cousins, R.J., Tucker, K.L., Ziegler, T.R., Eds.; Wolters Kluwer: Philadelphia, PA, USA, 2004; pp. 3–35. [Google Scholar]

Share and Cite

MDPI and ACS Style

Tamura, T.; Baggott, J.E. 13C-Enrichment of Urinary Uric Acid after l-[Ring-2-13C]Histidine Dose in Adult Humans. Nutrients 2015, 7, 697-705. https://0-doi-org.brum.beds.ac.uk/10.3390/nu7010697

AMA Style

Tamura T, Baggott JE. 13C-Enrichment of Urinary Uric Acid after l-[Ring-2-13C]Histidine Dose in Adult Humans. Nutrients. 2015; 7(1):697-705. https://0-doi-org.brum.beds.ac.uk/10.3390/nu7010697

Chicago/Turabian Style

Tamura, Tsunenobu, and Joseph E. Baggott. 2015. "13C-Enrichment of Urinary Uric Acid after l-[Ring-2-13C]Histidine Dose in Adult Humans" Nutrients 7, no. 1: 697-705. https://0-doi-org.brum.beds.ac.uk/10.3390/nu7010697

Article Metrics

Back to TopTop