Short-term treatment with a peroxisome proliferator-activated receptor α agonist influences plasma one-carbon metabolites and B-vitamin status in rats

Authors: Vegard Lysne ^aff001; Bodil Bjørndal ^aff002; Mari Lausund Grinna ^aff002; Øivind Midttun ^aff003; Per Magne Ueland ^aff002; Rolf Kristian Berge ^aff002; Jutta Dierkes ^aff005; Ottar Nygård ^aff001; Elin Strand ^aff002
Authors place of work: Centre for Nutrition, Department of Clinical Science, University of Bergen, Bergen, Norway ^aff001; Department of Clinical Science, University of Bergen, Bergen, Norway ^aff002; Bevital A/S, Bergen, Norway ^aff003; Department of Heart Disease, Haukeland University Hospital, Bergen, Norway ^aff004; Centre for Nutrition, Department of Clinical Medicine, University of Bergen, Bergen, Norway ^aff005; Mohn Nutrition Research Laboratory, Centre for Nutrition, University of Bergen, Bergen, Norway ^aff006; Laboratory Medicine and Pathology, Haukeland University Hospital, Bergen, Norway ^aff007
Published in the journal: PLoS ONE 14(12)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0226069

Summary

Introduction

Peroxisome proliferator-activated receptors (PPARs) have been suggested to be involved in the regulation of one-carbon metabolism. Previously we have reported effects on plasma concentrations of metabolites along these pathways as well as markers of B-vitamin status in rats following treatment with a pan-PPAR agonist. Here we aimed to investigate the effect on these metabolites after specific activation of the PPARα and PPARγ subtypes.

Methods

For a period of 12 days, Male Wistar rats (n = 20) were randomly allocated to receive treatment with the PPARα agonist WY-14.643 (n = 6), the PPARγ agonist rosiglitazone (n = 6) or placebo (n = 8). The animals were sacrificed under fasting conditions, and plasma concentration of metabolites were determined. Group differences were assessed by one-way ANOVA, and planned comparisons were performed for both active treatment groups towards the control group.

Results

Treatment with a PPARα agonist was associated with increased plasma concentrations of most biomarkers, with the most pronounced differences observed for betaine, dimethylglycine, glycine, nicotinamide, methylnicotinamide, pyridoxal and methylmalonic acid. Lower levels were observed for flavin mononucleotide. Fewer associations were observed after treatment with a PPARγ agonist, and the most notable was increased plasma serine.

Conclusion

Treatment with a PPARα agonist influenced plasma concentration of one-carbon metabolites and markers of B-vitamin status. This confirms previous findings, suggesting specific involvement of PPARα in the regulation of these metabolic pathways as well as the status of closely related B-vitamins.

Keywords:

blood plasma – Glycine – Serine – Metabolites – Cobalamins – Oxidation – Metabolic pathways – Cholines

Introduction

The choline oxidation pathway consists of the metabolic reactions converting choline, originating from endogenous synthesis or from the diet, to glycine via the intermediate metabolites betaine, dimethylglycine (DMG) and sarcosine. Glycine may also be reversibly synthesized from serine via serine-hydroxymethyltransferase. The choline oxidation pathway is closely related to the homocysteine-methionine cycle, through the enzyme betaine-homocysteine methyl transferase (BHMT) [1]. In this reaction a methyl group is transferred from betaine to homocysteine, producing methionine and DMG. The other homocysteine remethylation pathway is catalyzed by methionine synthase (MS), where the methyl group is transferred from 5’-methyltetrahydrofolate (mTHF) via the MS bound cofactor methylcobalamin (vitamin B12) forming methionine. Alternatively to remethylation, homocysteine may be irreversibly catabolized through the transsulfuration pathway, by the enzymes cystathionine-β-synthase and cystathionine-γ-lyase (Fig 1) [2]. Plasma and urinary concentration of metabolites in this pathway, including choline [3–5], betaine [5–7], DMG [8–10], sarcosine [11, 12], glycine and serine [13–15], have been linked to risk of major lifestyle diseases such as diabetes, cancer and cardiovascular disease.

**Fig. 1. Overview of metabolic pathways discussed.**
The numbers indicate enzymes, and the black boxes indicate enzymes of which gene expression have been previously shown to be down regulated by PPARα activation. The figure indicates where the enzymatic reactions occur (within/outside mitocondria). DMG indicates dimethylglycine; Hcy, homocysteine; Met, methionine; mTHF, 5’-methyltetrahydrofolate and THF, tetrahydrofolate.

Peroxisome proliferator-activated receptors (PPARs) are a family of nuclear receptors involved in the regulation of a variety of metabolic functions, including different aspects of energy metabolism [16, 17]. Recent studies in animals have implicated PPARs, in particular the PPARα subtype, in the regulation of one-carbon metabolism pathways. Down regulation of the genes encoding DMG dehydrogenase (DMGDH), sarcosine dehydrogenase (SARDH) and glycine-N-methyltransferase (GNMT) of the choline oxidation pathway [18], as well as both enzymes of the transsulfuration pathway [18, 19], have been observed after PPARα activation in rats. Down regulation on the protein level of BHMT, DMGDH, SARDH and GNMT have also been observed in rats and mice [20, 21].

Treatment of humans with fibrates, which are PPARα agonists, have consistently been associated with increased plasma total homocysteine (tHcy) [22, 23], and also decreased plasma betaine concentrations [24, 25] and increased urinary output of choline, betaine and DMG [24–27]. In animals, PPARα activation has been associated with increased plasma DMG [28] as well as increased glycine and serine [18, 28–31]. PPARα activation in animals have also been linked to altered status of several B-vitamins, such as increased plasma concentrations of riboflavin [31], nicotinamide (NAM) and N¹-methylnicotinamide (mNAM) [28, 31], the vitamin B6 indices pyridoxal (PL) and pyridoxal-5’-phosphate (PLP) [28] and the functional marker of cobalamin deficiency, methylmalonic acid (MMA) [28], and reduced plasma folate [28]. Reduced folate has also been reported in humans by some [32], but not all [33]. Increased urinary output of NAM and mNAM have been consistently reported in rodents [18, 28, 31, 34, 35].

In a previous study of male Wistar rats [28], we demonstrated that long-term treatment with the pan-PPAR agonist tetradecylthioacetic acid (TTA) was associated with alteration in the plasma concentration of several metabolites along the choline oxidation pathway as well as markers of B-vitamin status. However, as TTA is a pan-PPAR agonist we could not conclude whether this was a result of PPARα-activation, activation of other PPAR subtypes or PPAR-independent effects of the TTA treatment.

In the current study, we aim to extend on our previous findings and clarify the role of PPAR-activation on plasma concentration of one-carbon metabolites, as well as the status of related B-vitamins. We measured these metabolites in plasma from animals treated with specific PPARα and PPARγ agonists.

Materials and methods

Animals and study design

The current study is a substudy of an experiment aiming to explore the role of short-term activation of PPARs on lipid and fatty acid composition in liver and heart, and the experimental setup has been described in detail elsewhere [36].

Briefly, a total of 20 male Wistar rats (Taconic Europe A/S, Ry, Denmark), aged 8 weeks and with a body weight of 200-225g, were randomized into three groups: 1) Control (n = 8), 2) PPARα agonist (PPARα, n = 6); and 3) PPARγ agonist (PPARγ, n = 6). During 12 days of intervention, the animals received standard low-fat chow diet, and the daily treatments were given as 300 μl of muffin dough as vehicle, containing the active agent or placebo. The control group received pure vehicle, the PPARα group received 20 mg/kg/day of WY-14.643 (Tocris Bioscience, Bristol, UK) and the PPARγ group received 10 mg/kg/day Rosiglitazone (Sigma-Aldrich, St. Louis, MO). The muffin dough vehicle contained eggs, sugar, gluten free flour, vanilla sugar, milk and butter.

The animals were housed 2–3 per cage, and had free access to chow diet and tap water during the full study period. Prior to the study, the animals were habituated to the cage conditions and experimental handling, and introduced to the muffin dough vehicle. Animals in the same cage belonged to the same experimental group, but were taken out of the cages to receive treatment to ensure equal dosing. Cage placement, sequence of animal handling and termination were block randomized. After 12 days, the animals were sacrificed under fasting conditions, by cardiac puncture and exsanguination after receiving anesthesia with 2% isoflurane (Schering-Plough, Kent, UK).

Feed intake was estimated by weighing the food provided to the cages, as well as residual feed. During the intervention, feed intake and total weight gain was somewhat higher in animals treated with PPARγ-agoinst, but liver weight was increased in rats treated with PPARα-agonist. In the PPARα-group, hepatic expression of PPARα was 61% higher, and the expression of known PPARα target genes such as Acox1 (9-fold increase), Cd36 (9-fold increase), LPL (6-fold increase) and Hmgcs2 (2-fold increase) were affected by treatment with PPARα-agonist, demonstrating activation of PPARα in the liver [36]. Further, adipose tissue expression of known PPARγ target genes, such as Fatp1 (3-fold increase) and Fabp4 (0.5-fold increase) were affected by treatment with PPARγ agonist, demonstrating activation of PPARγ [36].

Ethics statement

The animal experiments complied with the Guidelines for the Care and Use of Experimental Animal use and the study protocols were approved by the national animal research authority (FOTS, ID number 2014/6187).

Biochemical analyses

Quantification of plasma metabolites were performed at Bevital A/S (Bevital, Bergen, Norway, www.bevital.no), using gas- or liquid chromatography coupled with tandem mass spectrometry for all metabolites except cobalamin which was analyzed by microbiological assay [37–40]. For the purpose of this targeted metabolomics approach, the metabolites of interest included the metabolites of the methionine-homocysteine cycle and the transsulfuration pathway (methionine, tHcy, cystathionine and cysteine), the choline oxidation pathway (choline, betaine, DMG, glycine and serine), as well as markers of related B-vitamins (Flavin mononucleotide [FMN], NAM, mNAM, Nicotinic acid [NA], PL, PLP, 4-pyridoxic acid (PA), the PAr-index (Par, calculated as the ratio of 4-pyridoxic acid divided by the sum of pyridoxal 5'-phosphate plus pyridoxal), mTHF, cobalamin and MMA).

Statistical analyses and presentation of data

The animals were housed 2–3 per cage, but as the rats were taken out of the cages to receive the intervention, the individual rat was regarded as the experimental unit of analysis. Plasma metabolite concentrations were log-transformed, and the data are presented as geometric means (geometric standard deviation, gSD). The groups were compared by one-way ANOVA, and the proportion of variance explained by the experimental groups were assessed by calculating the η². The assumption of equal variances was assessed with Levene’s test and visually by plotting the residuals. Within-group normality was visualized by Q-Q plots of the residuals. Planned comparisons towards the control group were performed for the two intervention groups. Standardized mean difference (SMD; 95% confidence interval) were calculated and plotted to illustrate the differences from the control group. For effect sizes, Cohen’s cutoff of η² > 35% was considered a large proportion of explained variance [41], and SMD > 1 were considered a large effect size. All individual data points are presented in S1 Fig. To evaluate potential cage effects, data was also plotted treating the cages as the experimental unit (n = 2–3 per group, S2 Fig).

As no new experiments were performed for this investigation, no formal power calculation was conducted. However, the current sample size was considered sufficient for replication of the most pronounces differences previously reported (SMD > 3) [28]. At a conventional cutoff for statistical significance at p < 0.05 the current sample sizes would yield 71% power to detect a large variance explained (η² > 35%), and 80% power of detecting between-group differences of SMD > 1.65.

Statistical analyses were performed using R software version 3.5.1 [42], and the packages within the tidyverse (dplyr, broom, purrr, magrittr, rlang) and forestplot.

Results

The plasma concentration of metabolites and the SMD (95% CI) for the intervention groups versus the control group are given in Fig 2. Overall, more and larger differences were observed after treatment with PPARα agonist compared to PPARγ agonist.

**Fig. 2. Biomarker concentrations, given as geometric mean (geometric standard deviations).**
The groups were compared with one-way ANOVA, and the η2 indicates the proportion of variation explained by the model. The black lines with squares correspond to the standardized mean difference (95% CI) between the PPARα group and control, and the grey lines with circles represents PPARγ vs control. DMG indicates dimethylglycine; FMN, Flavin mononucleotide; MMA, methylmalonic acid; mNAM, N1-methylnicotinamide; mTHF, 5’-methyltetrahydrofolate; NA, nicotinic acid; NAM, nicotinamide; PA, 4-pyridoxic acid; PAr, PA/(PLP+PL); PL, pyridoxal; PLP, pyridoxal 5’-phosphate.

Methionine (η² = 52%, p = 0.009), homocysteine (η² = 48%, p = 0.016) and cystathionine (η² = 39%, p = 0.048) were different between the groups. Planned comparisons showed that methionine (SMD = -1.5), homocysteine (SMD = -1.4) and cystathionine (SMD = -0.88) were lower after treatment with PPARγ agonist, while all metabolites were higher after treatment with PPARα agonist(SMD = 1.0, 1.0 and 0.9, respectively).

In the choline oxidation pathway, group differences were observed for betaine (η² = 68%, p < 0.001), DMG (η² = 68%, p < 0.001), glycine (η² = 81%, p < 0.001), and serine (η² = 60%, p < 0.001). The planned comparisons demonstrated higher concentrations of betaine (SMD = 2.7), DMG (SMD = 3.4), glycine (SMD = 4.4) and serine (SMD = 2.4) in the PPARα group. Lower plasma choline (SMD = -1.5), and higher serine (d = 1.9) was observed in the PPARγ group.

FMN, but not riboflavin, was different between the groups (η² = 65%, p < 0.001), and the planned comparisons revealed this to be due to lower concentrations in the PPARα group (SMD = -2.4). NAM and mNAM were different between groups (both η² > 90%, p < 0.001), and this was entirely explained by higher levels after treatment with PPARα agonist(SMD = 6.6 and 5.9, respectively). The same pattern was seen for the two vitamin B6 forms PL and PLP (η² = 74% and 48%, both p < 0.001), where higher concentrations in the PPARα agonist group explained the difference (SMD = 3.9 and 2.0, respectively). A between-group difference was observed for cobalamin (η² = 43%, p = 0.03) and its functional marker MMA (η² = 73%, p < 0.001). PPARα agonistic treatment was associated with lower plasma cobalamin (SMD = -1.8) and higher MMA (SMD = 3.0).

Discussion

This short-term study of one-carbon metabolites and B-vitamins in male Wistar rats treated with PPAR agonists demonstrated pronounced effects of PPARα agonist on the plasma concentration of metabolites of the choline oxidation pathway and markers of B-vitamin status. The largest differences were seen for plasma betaine, DMG, glycine, NAM, mNAM, PL and MMA, which were all higher, and FMN which was lower in the PPARα group. The current findings confirm our previous observations on effects of the pan-PPAR agonist TTA [28], and suggest that these biomarker alterations are due to PPARα activation.

In the PPARα group, higher plasma concentrations were observed for several metabolites of the choline oxidation pathway, including betaine, DMG, glycine and serine, with a majority of the observed variation in these variables (η² = 60–81%) being explained by the model. The increased concentrations of these metabolites may indicate increased flux through the choline oxidation pathway. Although plasma mTHF did not differ between groups, the lower cobalamin and higher MMA levels observed in the PPARα group may indicate lower cobalamin availability. This could reduce the activity of the MS-mediated homocysteine remethylation pathway, causing a compensatory increase in BHMT flux. PPARα-induced down regulation of DMGDH and SARDH may cause accumulation of their upstream metabolites, DMG and sarcosine. Unfortunately, we were not able to determine plasma concentrations of sarcosine, due to analytical interference from the EDTA in the tubes used for blood sampling. Both DMGDH and SARDH are flavoproteins and lower concentrations of FMN may indicate lower cofactor availability, potentially contributing to reduced enzyme activities.

Compared to control, plasma glycine and serine concentrations were much higher in the PPARα group, which have been consistently found in other animal studies [18, 28–31, 43]. Ericsson et al demonstrated that the increased plasma glycine levels were primarily due to increased entry into plasma, possibly reflecting increased de novo synthesis [29]. In addition to the choline oxidation pathway, glycine may originate from carnitine synthesis, threonine catabolism or from glycolysis via serine [44, 45]. Increased carnitine synthesis has been demonstrated after PPARα activation [46], in line with the known increases in β-oxidation and lowering of triglycerides. Hence, increased carnitine synthesis following PPARα activation is a likely contributor to increased plasma glycine. However, circulating concentration of carnitines were lower after PPARα agonistic treatment in the current experiment [36]. PPARα is known to increase lipid oxidation and sparing glucose [47], hence, glucose metabolism is not a likely contributor to the observed increases in plasma glycine and serine in the PPARα group. Higher plasma serine may be related to interconversion of excess glycine through serine-hydroxymethyltransferase. Upstream accumulation of glycine and serine following PPARα-induced down-regulation of GNMT is another potentially contributing factor [18]. Higher plasma serine observed after treatment with PPARγ agonist may be related to increased glycolysis, as PPARγ activation is known to increase insulin sensitivity, facilitating increased glucose utilization, as well as directly influence hepatic glucose uptake [48].

As in our previous report we observe lower plasma levels of the vitamin B2 metabolite FMN after treatment with PPARα agonist [28]. This could reflect reduced formation of FMN from riboflavin through riboflavin kinase or increased metabolism of FMN to flavin adenine dinucleotide (FAD) by FAD synthase. Notably, FAD acts as a product inhibitor of its own synthesis [49]. Hence, increased FAD utilization may increase FAD synthesis, and thus reduce FMN and riboflavin levels. FAD acts as an electron acceptor in the first step of β-oxidation, and although speculative, this may suggest that PPARα induced increases in hepatic fatty acid oxidation may drive the conversion from FMN to FAD, by product removal. Lower plasma riboflavin and FMN may thus reflect the altered cofactor requirements following PPARα induced changes in energy metabolism.

The largest response to intervention in the current study were the higher concentrations of plasma NAM and mNAM in the PPARα group, with an excess of 90% of the observed variation being explained by the model. We [28] and others [18, 28, 31, 34, 35, 50, 51] have previously observed a marked increase in B3 vitamers in plasma, urine and liver of rodents treated with PPARα agonists. Thus, these observations fits well with the existing literature. In addition to dietary consumption, NAM may be endogenously formed from the amino acid tryptophan through the kynurenine pathway [52]. Amino-carboxymuconate semialdehyde (ACMS), a downstream metabolite of this pathway, is either catabolized by the enzyme ACMS dehydrogenase or converted to quinolinic acid and metabolized further to NAM through quinolinic acid phosphoribosyltransferase (QAPRT). PPARα activation has been shown to down regulate ACMS dehydrogenase and up regulate QAPRT [53, 54], shifting the flux towards increased niacin synthesis from tryptophan. We believe this offers a mechanistic explanation of our observations, suggesting NAM and/or mNAM as potential biomarkers of PPARα activity. This has to be examined in future studies.

Similar to our previous findings [28], we observe higher concentrations of both circulating B6 vitamers PL and PLP in the PPARα group. Vitamin B6 status is inversely associated with inflammation [55], and PLP has been suggested as a scavenger of reactive oxidative species [56]. Hence, the increased plasma concentrations of PL and PLP may be related to the anti-inflammatory and anti-oxidative properties of PPARα activation [17]. Of interest, we observe larger increases in PL compared to PLP. One possible explanation may be increased conversion from PLP to PL, a reaction catalyzed by alkaline phosphatase [56]. Increased alkaline phosphatase mRNA has been demonstrated after PPARα activation in cell culture studies [57]. Additionally, the final step in the synthesis of PLP from its precursors pyridoxine-5’-phosphate and pyridoxamine-5’-phospate is catalyzed by pyridoxamine 5’-phosphate oxidase which is a FMN-dependent protein [56, 58], and lower FMN availability may contribute to reduced PLP synthesis via this route. This is also in line with observations that fibrate treatment does not change plasma PLP concentrations in humans [33].

We observed a large increase in plasma MMA after treatment with PPARα agonist, in accordance with what we previously reported after treatment with pan-PPAR agonist [28]. Although MMA is considered a functional biomarker of vitamin B12 deficiency, much of the variation in plasma MMA is not accounted for by vitamin B12 status, suggesting that B12 independent mechanisms might also be at play [59]. Of interest, Molloy et al identified a novel genetic variant in the metabolism of branched-chain amino acids (BCAA), explaining 9.9% of the variance of circulating MMA, independent of vitamin B12 status [60].

There are several possible ways PPARα activation may contribute to increased MMA; by increasing the availability of precursors, by interfering with intracellular vitamin B12 processing or by directly interfering with the methylmalonyl-CoA mutase reaction. The precursor of methylmalonyl-CoA is propionyl-CoA, resulting from catabolism of BCAA and odd-chained fatty acids. PPARα activation is well known to stimulate hepatic fatty acid oxidation [61] and has also been demonstrated to increase the catabolism of BCAA [62], suggesting an effect of PPARα activation on availability of MMA precursors.

A key step in the intracellular processing of cobalamin is the liberation of free cobalamin within the cell cytosol, a reaction involving by the MMACHC protein, and partitioning to the two cobalamin dependent proteins, facilitated by the MMADHC protein. MMACHC is a flavoprotein dependent on glutathione (GSH) for its function [63], and the availability of both GSH and FAD may be limited under conditions of increased PPARα activity. GSH production is directly related to the level of oxidative stress, and as much as half of the cysteine utilized for GSH production is derived from homocysteine through the transsulfuration pathway [64]. Anti-oxidative properties of PPARα agonists [17], combined with down regulation of both enzymes of the transsulfuration pathway [18, 19], may reduce GSH availability following PPARα activation. Further, mmachc and mmadhc are predicted PPAR target genes [65]. Hence, PPARα induced interference with intracellular processing of vitamin B12 and its availability as co-factor of methylmalonyl-CoA mutase, may contribute to increased MMA.

Strengths and limitations

The main strength of this study is the use of specific PPARα and PPARγ agonists, allowing for evaluation of the specific effects of PPAR subtypes. As animals residing in the same cage belonged to the same experimental group, the possibility of cage effects could not be completely excluded, although the animals were individually treated outside the cages. However, by plotting cage mean values instead of individual measurements, the same patterns emerged and within-group cage means were similar (S2 Fig) to the results obtained by using the individual animals. Hence, bias due to cage effects is not likely to have influenced our main conclusions. It has to be noted that the effect of PPAR agonists on one-carbon and B-vitamin metabolome was a secondary aim of this experiment. However, maximizing the information gained from the animals contributes to reducing the number of animals sacrificed, which is in line with the 3 R’s of animal research [66]. We did not measure PPARα and PPARγ activity or protein expression in this study, which may be considered a limitation. Measuring protein expression of PPARs would not necessarily add any information regarding their activity, since this involves several factors. However, activation of the PPARs with the agonists administered in this study has been thoroughly demonstrated in the literature, and increased expression of known PPARα and PPARγ target genes were observed in the current experiment [36]. Further, the discussion on potential mechanisms would benefit from information regarding the expression of genes along the pathways discussed. Unfortunately, as this information could not be obtained from the current experiment, the mechanistic discussion relies on effects previously reported in the literature. However, as previous publications have not provided complete information regarding effects on the metabolite level, the current data should be interpreted as complimentary to the existing literature.

Conclusion

In this study, short-term treatment with a specific PPARα, but not PPARγ, agonist influenced plasma concentrations of several one-carbon metabolites and markers of B-vitamin status, with the most pronounced findings being higher DMG, glycine, serine, NAM, mNAM, PL and MMA, and lower FMN. This targeted metabolomics approach adds to the current literature suggesting the involvement of PPARα in the regulation of these metabolic pathways, as well as the status of closely related B-vitamins.

Supporting information

S1 Arrive Checklist [pdf]

S1 Fig [tif]
Individual metabolite concentrations with overlaying box plots.

S2 Fig [tif]
Cage mean metabolite concentrations with overlaying box plots.

S1 Dataset [xlsx]
Raw data on metabolite concentrations.

Zdroje

1. Finkelstein JD. Methionine metabolism in mammals. J Nutr Biochem. 1990;1(5):228–37. doi: 10.1016/0955-2863(90)90070-2 15539209

2. Selhub J. Homocysteine metabolism. Annu Rev Nutr. 1999;19:217–46. doi: 10.1146/annurev.nutr.19.1.217 10448523

3. Svingen GF, Schartum-Hansen H, Pedersen ER, Ueland PM, Tell GS, Mellgren G, et al. Prospective Associations of Systemic and Urinary Choline Metabolites with Incident Type 2 Diabetes. Clin Chem. 2016;62(5):755–65. doi: 10.1373/clinchem.2015.250761 26980210

4. Schartum-Hansen H, Pedersen ER, Svingen GF, Ueland PM, Seifert R, Ebbing M, et al. Plasma choline, smoking, and long-term prognosis in patients with stable angina pectoris. European journal of preventive cardiology. 2014;22(5):606–14. doi: 10.1177/2047487314524867 24595862

5. Ueland PM. Choline and betaine in health and disease. J Inherit Metab Dis. 2011;34(1):3–15. doi: 10.1007/s10545-010-9088-4 20446114

6. Schartum-Hansen H, Ueland PM, Pedersen ER, Meyer K, Ebbing M, Bleie O, et al. Assessment of urinary betaine as a marker of diabetes mellitus in cardiovascular patients. PLoS One. 2013;8(8):e69454. doi: 10.1371/journal.pone.0069454 23936331

7. Lever M, George PM, Elmslie JL, Atkinson W, Slow S, Molyneux SL, et al. Betaine and secondary events in an acute coronary syndrome cohort. PLoS One. 2012;7(5):e37883. doi: 10.1371/journal.pone.0037883 22649561

8. Svingen GF, Schartum-Hansen H, Ueland PM, Pedersen ER, Seifert R, Ebbing M, et al. Elevated plasma dimethylglycine is a risk marker of mortality in patients with coronary heart disease. European journal of preventive cardiology. 2014;22(6):743–52. doi: 10.1177/2047487314529351 24671904

9. Oyen J, Svingen GF, Gjesdal CG, Tell GS, Ueland PM, Lysne V, et al. Plasma dimethylglycine, nicotine exposure and risk of low bone mineral density and hip fracture: the Hordaland Health Study. Osteoporos Int. 2015;26(5):1573–83. doi: 10.1007/s00198-015-3030-4 25616506

10. Svingen GF, Ueland PM, Pedersen EK, Schartum-Hansen H, Seifert R, Ebbing M, et al. Plasma dimethylglycine and risk of incident acute myocardial infarction in patients with stable angina pectoris. Arterioscler Thromb Vasc Biol. 2013;33(8):2041–8. doi: 10.1161/ATVBAHA.113.301714 23723367

11. Koutros S, Meyer TE, Fox SD, Issaq HJ, Veenstra TD, Huang WY, et al. Prospective evaluation of serum sarcosine and risk of prostate cancer in the Prostate, Lung, Colorectal and Ovarian Cancer Screening Trial. Carcinogenesis. 2013;34(10):2281–5. doi: 10.1093/carcin/bgt176 23698636

12. de Vogel S, Ulvik A, Meyer K, Ueland PM, Nygard O, Vollset SE, et al. Sarcosine and other metabolites along the choline oxidation pathway in relation to prostate cancer—a large nested case-control study within the JANUS cohort in Norway. Int J Cancer. 2014;134(1):197–206. doi: 10.1002/ijc.28347 23797698

13. Ding Y, Svingen GF, Pedersen ER, Gregory JF, Ueland PM, Tell GS, et al. Plasma Glycine and Risk of Acute Myocardial Infarction in Patients With Suspected Stable Angina Pectoris. J Am Heart Assoc. 2015;5(1):e002621. doi: 10.1161/JAHA.115.002621 26722126

14. Locasale JW. Serine, glycine and one-carbon units: cancer metabolism in full circle. Nat Rev Cancer. 2013;13(8):572–83. doi: 10.1038/nrc3557 23822983

15. Amelio I, Cutruzzola F, Antonov A, Agostini M, Melino G. Serine and glycine metabolism in cancer. Trends Biochem Sci. 2014;39(4):191–8. doi: 10.1016/j.tibs.2014.02.004 24657017

16. Rakhshandehroo M, Knoch B, Muller M, Kersten S. Peroxisome proliferator-activated receptor alpha target genes. PPAR Res. 2010.

17. Contreras AV, Torres N, Tovar AR. PPAR-alpha as a key nutritional and environmental sensor for metabolic adaptation. Adv Nutr. 2013;4(4):439–52. doi: 10.3945/an.113.003798 23858092

18. Sheikh K, Camejo G, Lanne B, Halvarsson T, Landergren MR, Oakes ND. Beyond lipids, pharmacological PPARalpha activation has important effects on amino acid metabolism as studied in the rat. American journal of physiology Endocrinology and metabolism. 2007;292(4):E1157–65. doi: 10.1152/ajpendo.00254.2006 17164430

19. Rogue A, Renaud MP, Claude N, Guillouzo A, Spire C. Comparative gene expression profiles induced by PPARgamma and PPARalpha/gamma agonists in rat hepatocytes. Toxicol Appl Pharmacol. 2011;254(1):18–31. doi: 10.1016/j.taap.2011.04.005 21515302

20. Wrzesinski K, I RL, Kulej K, Sprenger RR, Bjorndal B, Christensen BJ, et al. Proteomics identifies molecular networks affected by tetradecylthioacetic acid and fish oil supplemented diets. J Proteomics. 2013;84:61–77. doi: 10.1016/j.jprot.2013.03.027 23568020

21. Chu R, Lim H, Brumfield L, Liu H, Herring C, Ulintz P, et al. Protein profiling of mouse livers with peroxisome proliferator-activated receptor alpha activation. Mol Cell Biol. 2004;24(14):6288–97. doi: 10.1128/MCB.24.14.6288-6297.2004 15226431

22. Ntaios G, Savopoulos C, Chatzopoulos S, Mikhailidis D, Hatzitolios A. Iatrogenic hyperhomocysteinemia in patients with metabolic syndrome: a systematic review and metaanalysis. Atherosclerosis. 2011;214(1):11–9. doi: 10.1016/j.atherosclerosis.2010.08.045 20846651

23. Dierkes J, Westphal S. Effect of drugs on homocysteine concentrations. Semin Vasc Med. 2005;5(2):124–39. doi: 10.1055/s-2005-872398 16047265

24. Lever M, McEntyre CJ, George PM, Slow S, Chambers ST, Foucher C. Fenofibrate causes elevation of betaine excretion but not excretion of other osmolytes by healthy adults. J Clin Lipidol. 2014;8(4):433–40. doi: 10.1016/j.jacl.2014.04.001 25110225

25. Lever M, McEntyre CJ, George PM, Slow S, Elmslie JL, Lunt H, et al. Extreme urinary betaine losses in type 2 diabetes combined with bezafibrate treatment are associated with losses of dimethylglycine and choline but not with increased losses of other osmolytes. Cardiovasc Drugs Ther. 2014;28(5):459–68. doi: 10.1007/s10557-014-6542-9 25060556

26. Lever M, George PM, Slow S, Elmslie JL, Scott RS, Richards AM, et al. Fibrates may cause an abnormal urinary betaine loss which is associated with elevations in plasma homocysteine. Cardiovasc Drugs Ther. 2009;23(5):395–401. doi: 10.1007/s10557-009-6188-1 19653086

27. Lever M, George PM, Atkinson W, Molyneux SL, Elmslie JL, Slow S, et al. Plasma lipids and betaine are related in an acute coronary syndrome cohort. PLoS One. 2011;6(7):e21666. doi: 10.1371/journal.pone.0021666 21747945

28. Lysne V, Strand E, Svingen GF, Bjorndal B, Pedersen ER, Midttun O, et al. Peroxisome Proliferator-Activated Receptor Activation is Associated with Altered Plasma One-Carbon Metabolites and B-Vitamin Status in Rats. Nutrients. 2016;8(1).

29. Ericsson A, Turner N, Hansson GI, Wallenius K, Oakes ND. Pharmacological PPARalpha activation markedly alters plasma turnover of the amino acids glycine, serine and arginine in the rat. PLoS One. 2014;9(12):e113328. doi: 10.1371/journal.pone.0113328 25486018

30. Lu Y, Boekschoten MV, Wopereis S, Muller M, Kersten S. Comparative transcriptomic and metabolomic analysis of fenofibrate and fish oil treatments in mice. Physiol Genomics. 2011;43(23):1307–18. doi: 10.1152/physiolgenomics.00100.2011 21954454

31. Ohta T, Masutomi N, Tsutsui N, Sakairi T, Mitchell M, Milburn MV, et al. Untargeted metabolomic profiling as an evaluative tool of fenofibrate-induced toxicology in Fischer 344 male rats. Toxicol Pathol. 2009;37(4):521–35. doi: 10.1177/0192623309336152 19458390

32. Mayer O Jr., Simon J, Holubec L, Pikner R, Subrt I. Fenofibrate-induced hyperhomocysteinemia may be prevented by folate co-administration. Eur J Clin Pharmacol. 2003;59(5–6):367–71. doi: 10.1007/s00228-003-0616-0 12845504

33. Dierkes J, Westphal S, Luley C. Serum homocysteine increases after therapy with fenofibrate or bezafibrate. Lancet. 1999;354(9174):219–20. doi: 10.1016/S0140-6736(99)02153-4 10421307

34. Zhen Y, Krausz KW, Chen C, Idle JR, Gonzalez FJ. Metabolomic and genetic analysis of biomarkers for peroxisome proliferator-activated receptor alpha expression and activation. Mol Endocrinol. 2007;21(9):2136–51. doi: 10.1210/me.2007-0150 17550978

35. Delaney J, Hodson MP, Thakkar H, Connor SC, Sweatman BC, Kenny SP, et al. Tryptophan-NAD+ pathway metabolites as putative biomarkers and predictors of peroxisome proliferation. Arch Toxicol. 2005;79(4):208–23. doi: 10.1007/s00204-004-0625-5 15838709

36. Strand E, Lysne V, Grinna ML, Bohov P, Svardal A, #xf8, et al. Short-Term Activation of Peroxisome Proliferator-Activated Receptors and Induces Tissue-Specific Effects on Lipid Metabolism and Fatty Acid Composition in Male Wistar Rats. PPAR Research. 2019;2019:12.

37. Midttun O, Hustad S, Ueland PM. Quantitative profiling of biomarkers related to B-vitamin status, tryptophan metabolism and inflammation in human plasma by liquid chromatography/tandem mass spectrometry. Rapid Commun Mass Spectrom. 2009;23(9):1371–9. doi: 10.1002/rcm.4013 19337982

38. Midttun O, Kvalheim G, Ueland PM. High-throughput, low-volume, multianalyte quantification of plasma metabolites related to one-carbon metabolism using HPLC-MS/MS. Anal Bioanal Chem. 2013;405(6):2009–17. doi: 10.1007/s00216-012-6602-6 23232958

39. Kelleher BP, Broin SD. Microbiological assay for vitamin B12 performed in 96-well microtitre plates. J Clin Pathol. 1991;44(7):592–5. doi: 10.1136/jcp.44.7.592 1856292

40. Midttun O, McCann A, Aarseth O, Krokeide M, Kvalheim G, Meyer K, et al. Combined Measurement of 6 Fat-Soluble Vitamins and 26 Water-Soluble Functional Vitamin Markers and Amino Acids in 50 muL of Serum or Plasma by High-Throughput Mass Spectrometry. Anal Chem. 2016;88(21):10427–36. doi: 10.1021/acs.analchem.6b02325 27715010

41. Cohen J. A power primer. Psychol Bull. 1992;112(1):155–9. doi: 10.1037//0033-2909.112.1.155 19565683

42. Team RC. R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria; 2018.

43. Bjorndal B, Brattelid T, Strand E, Vigerust NF, Svingen GF, Svardal A, et al. Fish oil and the pan-PPAR agonist tetradecylthioacetic acid affect the amino acid and carnitine metabolism in rats. PLoS One. 2013;8(6):e66926. doi: 10.1371/journal.pone.0066926 23826175

44. Bremer J. Carnitine—metabolism and functions. Physiol Rev. 1983;63(4):1420–80. doi: 10.1152/physrev.1983.63.4.1420 6361812

45. Wang W, Wu Z, Dai Z, Yang Y, Wang J, Wu G. Glycine metabolism in animals and humans: implications for nutrition and health. J Amino Acids. 2013;45(3):463–77.

46. van Vlies N, Ferdinandusse S, Turkenburg M, Wanders RJ, Vaz FM. PPAR alpha-activation results in enhanced carnitine biosynthesis and OCTN2-mediated hepatic carnitine accumulation. Biochim Biophys Acta. 2007;1767(9):1134–42. doi: 10.1016/j.bbabio.2007.07.001 17692817

47. Peeters A, Baes M. Role of PPARalpha in Hepatic Carbohydrate Metabolism. PPAR Res. 2010.

48. Kim HI, Ahn YH. Role of peroxisome proliferator-activated receptor-gamma in the glucose-sensing apparatus of liver and beta-cells. Diabetes. 2004;53 Suppl 1:S60–5.

49. McCormick DB. Riboflavin. In: Erdman JW, Macdonald IA, Zeisel SH, editors. Present Knowledge in Nutrition. 10 ed: Wiley-Blackwell; 2012. doi: 10.1016/j.nut.2011.07.010

50. Loo Y, Shin M, Yamashita Y, Ishigami M, Sasaki M, Sano K, et al. Effect of feeding clofibrate-containing diet on the hepatic NAD+ level in rats. J Nutr Sci Vitaminol (Tokyo). 1995;41(3):341–7. doi: 10.3177/jnsv.41.341 7472678

51. Ringeissen S, Connor SC, Brown HR, Sweatman BC, Hodson MP, Kenny SP, et al. Potential urinary and plasma biomarkers of peroxisome proliferation in the rat: identification of N-methylnicotinamide and N-methyl-4-pyridone-3-carboxamide by 1H nuclear magnetic resonance and high performance liquid chromatography. Biomarkers. 2003;8(3–4):240–71. doi: 10.1080/1354750031000149124 12944176

52. Stavrum AK, Heiland I, Schuster S, Puntervoll P, Ziegler M. Model of tryptophan metabolism, readily scalable using tissue-specific gene expression data. J Biol Chem. 2013;288(48):34555–66. doi: 10.1074/jbc.M113.474908 24129579

53. Shin M, Ohnishi M, Iguchi S, Sano K, Umezawa C. Peroxisome-proliferator regulates key enzymes of the tryptophan-NAD+ pathway. Toxicol Appl Pharmacol. 1999;158(1):71–80. doi: 10.1006/taap.1999.8683 10387934

54. Shin M, Kim I, Inoue Y, Kimura S, Gonzalez FJ. Regulation of mouse hepatic alpha-amino-beta-carboxymuconate-epsilon-semialdehyde decarboxylase, a key enzyme in the tryptophan-nicotinamide adenine dinucleotide pathway, by hepatocyte nuclear factor 4alpha and peroxisome proliferator-activated receptor alpha. Mol Pharmacol. 2006;70(4):1281–90. doi: 10.1124/mol.106.026294 16807375

55. Ueland PM, McCann A, Midttun O, Ulvik A. Inflammation, vitamin B6 and related pathways. Mol Aspects Med. 2017;53:10–27. doi: 10.1016/j.mam.2016.08.001 27593095

56. Ueland PM, Ulvik A, Rios-Avila L, Midttun O, Gregory JF. Direct and functional biomarkers of vitamin B6 status. Annu Rev Nutr. 2015;35:33–70. doi: 10.1146/annurev-nutr-071714-034330 25974692

57. Syversen U, Stunes AK, Gustafsson BI, Obrant KJ, Nordsletten L, Berge R, et al. Different skeletal effects of the peroxisome proliferator activated receptor (PPAR)alpha agonist fenofibrate and the PPARgamma agonist pioglitazone. BMC Endocr Disord. 2009;9(10).

58. di Salvo ML, Contestabile R, Safo MK. Vitamin B(6) salvage enzymes: mechanism, structure and regulation. Biochim Biophys Acta. 2011;1814(11):1597–608. doi: 10.1016/j.bbapap.2010.12.006 21182989

59. Hannibal L, Lysne V, Bjorke-Monsen AL, Behringer S, Grunert SC, Spiekerkoetter U, et al. Biomarkers and Algorithms for the Diagnosis of Vitamin B12 Deficiency. Front Mol Biosci. 2016;3:27. doi: 10.3389/fmolb.2016.00027 27446930

60. Molloy AM, Pangilinan F, Mills JL, Shane B, O'Neill MB, McGaughey DM, et al. A Common Polymorphism in HIBCH Influences Methylmalonic Acid Concentrations in Blood Independently of Cobalamin. Am J Hum Genet. 2016;98(5):869–82. doi: 10.1016/j.ajhg.2016.03.005 27132595

61. Pyper SR, Viswakarma N, Yu S, Reddy JK. PPARalpha: energy combustion, hypolipidemia, inflammation and cancer. Nucl Recept Signal. 2010;8:e002. doi: 10.1621/nrs.08002 20414453

62. Kobayashi R, Murakami T, Obayashi M, Nakai N, Jaskiewicz J, Fujiwara Y, et al. Clofibric acid stimulates branched-chain amino acid catabolism by three mechanisms. Arch Biochem Biophys. 2002;407(2):231–40. doi: 10.1016/s0003-9861(02)00472-1 12413496

63. Hannibal L, DiBello PM, Jacobsen DW. Proteomics of vitamin B12 processing. Clin Chem Lab Med. 2013;51(3):477–88. doi: 10.1515/cclm-2012-0568 23241609

64. Mosharov E, Cranford MR, Banerjee R. The quantitatively important relationship between homocysteine metabolism and glutathione synthesis by the transsulfuration pathway and its regulation by redox changes. Biochemistry. 2000;39(42):13005–11. doi: 10.1021/bi001088w 11041866

65. Fang L, Zhang M, Li Y, Liu Y, Cui Q, Wang N. PPARgene: A Database of Experimentally Verified and Computationally Predicted PPAR Target Genes. PPAR Res. 2016;2016:6042162. doi: 10.1155/2016/6042162 27148361

66. Kilkenny C, Browne WJ, Cuthill IC, Emerson M, Altman DG. Improving bioscience research reporting: the ARRIVE guidelines for reporting animal research. PLoS Biol. 2010;8(6):e1000412. doi: 10.1371/journal.pbio.1000412 20613859

Short-term treatment with a peroxisome proliferator-activated receptor α agonist influences plasma one-carbon metabolites and B-vitamin status in rats

Summary

Introduction

Methods

Results

Conclusion

Keywords:

Introduction

Materials and methods

Animals and study design

Ethics statement

Biochemical analyses

Statistical analyses and presentation of data

Results

Discussion

Strengths and limitations

Conclusion

Supporting information

Zdroje

PLOS One

Svět praktické medicíny 1/2024 (znalostní test z časopisu)

Koncepce osteologické péče pro gynekology a praktické lékaře

Sekvenční léčba schizofrenie

Hypertenze a hypercholesterolémie – synergický efekt léčby

Význam metforminu pro „udržitelnou“ terapii diabetu