Effects of Choline on DNA Methylation and Macronutrient Metabolic Gene Expression in in Vitro Models of Hyperglycemia

Cell culture and treatments

The human hepatocellular carcinoma cell line HepG2 was kindly provided by Dr. Jean Grassman (Brooklyn College), and the human choriocarcinoma cell line BeWo was retrieved from the American Type Culture Collection (ATCC). The BeWo cells retain important characteristics, such as hormone synthesis and morphology of first-trimester trophoblasts. ¹⁵

HepG2 cells were maintained in Eagle's minimum essential medium (MEM) with 2 mM L-glutamine and 10% fetal bovine serum (FBS). BeWo cells were maintained in Kaighn's modification of Ham's F-12 medium (ATCC^® 30-2004^™) with 10% FBS. All cells were incubated in 5% CO₂-95% air at 37^°C. For the experiments, both HepG2 and BeWo cells were cultured in six-well cell culture plates and grown in MEM containing 2.5% FBS. MEM contained 7 µM of choline as was specified by the manufacturer (Corning), and the 2.5% FBS contained 16 µM of choline as was reported previously. ¹⁶ As such, total choline provided by the MEM and 2.5% FBS was 23 µM. Glucose concentration of the medium was 5 mM as was specified by the manufacturer. To examine the effects of glucose and choline supplementation, the low-glucose, low-choline (LG-LC) group was not provided with additional glucose or choline, the low-glucose, high-choline (LG-HC) group was supplemented with 1 mM of choline chloride, the high-glucose, low-choline (HG-LC) group was supplemented with 30 mM of glucose in addition to the 5 mM glucose in the MEM, and the high-glucose, high-choline (HG-HC) group was supplemented with both 30 mM of glucose and 1 mM of choline chloride. Cells were seeded at a starting amount of 2 X 10 ⁵ cells (passages 5-15) per well and cultured for 72 hours for HepG2 cells and 96 hours for BeWo cells before harvest. The length of cell culture was determined based on previous studies^16,17 and preliminary experiments, which suggest that the cells reached 70% confluence at those time points and the effect of choline and glucose on biomarkers of interest can be detected. Each experiment was repeated three times.

Cell count and viability

After 72 hours of cell culture for HepG2 and 96 hours of cell culture for BeWo, culture medium was removed, and the attached cells were trypsinized, centrifuged, and resuspended in phosphate-buffered saline. Cell counts were measured using a hemocytometer, and cell viability was assessed using the Trypan blue dye exclusion.

RNA extraction, reverse transcription, and quantitative real-time polymerase chain reaction (PCR)

Total RNA was extracted from HepG2 and BeWo cells using TRIzol^® (Life Technologies) and chloroform. RNA concentration and integrity were checked using a NanoDrop2000 instrument (Thermo Fisher Scientific). Reverse transcription was conducted using the high-capacity cDNA reverse transcription kit (Life Technologies) as per the manufacturer's instructions. Quantitative real-time PCR was conducted using SYBR-green detection in a MiniOpticon real-time PCR system (Bio-Rad). Expression of the following genes was analyzed: antigen identified by monoclonal antibody Ki-67 (MKI67), BHMT, caspase 3 (CASP3), choline dehydrogenase (CHDH), DNA methyltransferase 1 (DNMT1), DNA methyltransferase 3A (DNMT3A), fatty acid synthase (FAS), glucose transporter 2 (SLC2A2 or GLUT2), GLUT1 (SLC2A1), glucose-6-phosphate dehydrogenase (G6PD); glycerol-3-phosphate acyltransferase 2 (GPAT2), peroxisomal acyl-coenzyme A oxidase 1 (ACOX1), proliferating cell nuclear antigen (PCNA), and phosphoenolpyruvate carboxykinase (PEPCK). All primers were designed using GeneRunner Version 3.01 (http://www.softpedia.com) (Supplementary Table 1). The efficiency of each pair of primers was between 90% and 100%. Data were expressed as the fold changes in mRNA concentrations of the above genes relative to the housekeeping gene (β-glucuronidase, GUSB) using the ΔΔCt method. ¹⁸

Global DNA methylation

DNA was extracted from HepG2 and BeWo cells using the GeneJET Genomic DNA Purification Kit (Thermo Fisher Scientific) as per the manufacturer's instructions. DNA was treated with nuclease P1, alkaline phosphatase, and phosphodiesterase (Sigma-Aldrich). ¹⁹ CpG methylation of the samples was quantified using a DNA methylation enzyme-linked immunosorbent assay (ELISA) kit (Cayman Chemical) as per the manufacturer's instructions.

Statistical analysis

Analysis of variance tests followed by post hoc Bonferroni's correction were conducted to assess the differences among the treatment groups. Data not meeting the normality assumption were log transformed. All analyses were performed using SPSS (release 22; IBM). Differences were considered as significant at P < 0.05. Values are presented as mean ± standard error.

Differential effects of choline and glucose on HepG2 and BeWo cell growth

At 72 hours of culture, HepG2 cell counts did not differ between the HG or LG groups. However, choline supplementation significantly increased (P < 0.01) the cell counts regardless of glucose treatment (Fig. 1A). At 96 hours of culture, BeWo cell counts tended to increase (P = 0.07) moderately in the HG-LC (high-glucose control) group compared to the LG-LC (low-glucose control) group. However, choline supplementation in the HG-HC group seemed to alleviate the growth-promoting effect of glucose and normalize cell counts to the level of the LG-LC group (Fig. 1B).

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Figure 1

Cell numbers (A and B) and expression of cellular proliferative and apoptotic markers (C and D) of HepG2 and BeWo cells after 72 or 96 hours of cultivation in different choline and glucose concentrations. LG-LC (black bars): low-glucose, low-choline; LG-HC (hatched bars): low-glucose, high-choline; HG-LC (gray bars): high-glucose, low-choline; HG-HC (open bars): high-glucose, high-choline. Different letters indicate significant difference, P < 0.05; (b) P < 0.1.

In HepG2 cells, mRNA expression of the cellular proliferative marker KI67 was increased (P < 0.05) by high-glucose treatment. Choline supplementation further increased (P < 0.05) KI67 expression in both low- and high-glucose groups (Fig. 1C). In BeWo cells, KI67 expression was suppressed (P < 0.01) by high glucose despite the increased cell counts at 96 hours of culture, yet its expression was not altered by choline supplementation (Fig. 1D). The expression of another cellular proliferative marker, PCNA, and the cellular apoptotic marker, CASP3, was not altered by glucose or choline supplementation in BeWo cells.

Choline supplementation increased DNA methylation of HepG2 cells

Expression of the DNMT1, which maintains existing DNA methylation marks, and DNMT3A, which mediates de novo DNA methylation, was examined. In HepG2, neither methyltransferases were altered by glucose treatment. However, choline supplementation significantly increased (P < 0.05) DNMT1 expression, and further, the HG-HC group had a higher (P < 0.01 for DNMT1 and P = 0.09 for DNMT3A) expression of those methyltransferases than the LG-HC group, suggesting that choline-mediated increase in methyltransferase expression was more pronounced in a high-glucose environment (Fig. 2A). Consistent with the higher DNMT expression, choline supplementation increased (P < 0.05) global CpG methylation (Fig. 2B). However, DNA methylation was not modified by glucose treatment in HepG2 cells. In BeWo cells, methyltransferase expression was not altered by glucose or choline treatment (Fig. 2C), and their global CpG methylation levels were below the reliable detection limit of the assay kit (data not shown).

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Figure 2

Methylation-related gene expression (A and C) and global CpG DNA methylation (B) in HepG2 and BeWo cells after 72 or 96 hours of cultivation in different choline and glucose concentrations. LG-LC (black bars): low-glucose, low-choline; LG-HC (hatched bars): low-glucose, high-choline; HG-LC (gray bars): high-glucose, low-choline; HG-HC (open bars): high-glucose, high-choline. Different letters indicate significant difference, P < 0.05.

In order for choline to be used as a methyl donor, it is first oxidized to betaine, which is mediated by the rate-limiting enzyme CHDH. Betaine then donates its labile methyl group to homocysteine for its remethylation to methionine. After methionine is converted to the universal methyl donor S-adenosylmethionine, the choline- or betaine-derived methyl groups can be used in various methylation reactions. The methyl group transfer of betaine is mediated by the enzyme BHMT1, which is predominantly expressed in the liver. Glucose and choline treatments interact to affect CHDH and BHMT1 expression in HepG2 cells. Choline supplementation increases CHDH (LG-LC vs LG-HC, P = 0.01) and BHMT1 (LG-LC vs LG-HC, P < 0.01) expression in the low-glucose condition but not in the high-glucose condition (Fig. 2A).

BeWo cells did not express BHMT1 (data not shown), and CHDH expression was not altered by choline or glucose treatment (Fig. 2C). The lack of BHMT in BeWo may explain the ineffectiveness of choline serving as a methyl donor or influencing methyltransferase expression in these cells.

Choline supplementation altered lipid and glucose metabolic genes in HepG2 cells

In HepG2 cells, both choline and glucose supplementation increased (P < 0.05) the expression of ACOX1, a gene that encodes the ACOX1 protein, which mediates fatty acid β-oxidation in the peroxisome (Fig. 3A). ²⁰ The HG-HC group had the highest expression compared to the other three groups. However, neither FAS, which mediates de novo fatty acid synthesis, nor GPAT2, which mediates triglyceride synthesis, was affected by glucose or choline treatment. PEPCK, the rate-limiting enzyme in the process of gluconeogenesis, was increased (P < 0.05) in the HG-LC group compared to the LG-LC group. However, choline supplementation in the HG-HC group seemed to normalize the elevation of PEPCK due to high glucose (Fig. 3A). G6PD, the first enzyme in the pentose phosphate pathway, was upregulated in the LG-HC group compared to the LG-LC group, but this effect of choline was not seen in the high-glucose groups. The glucose transporter GLUT2, which mediates hepatic glucose uptake, was upregulated (P < 0.05) by high glucose regardless of choline supplementation.

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Figure 3

Glucose and fatty acid metabolic gene expression in HepG2 (A) and BeWo (B) cells after 72 or 96 hours of cultivation in different choline and glucose concentrations. LG-LC (black bars): low-glucose, low-choline; LG-HC (hatched bars): low-glucose, high-choline; HG-LC (gray bars): high-glucose, low-choline; HG-HC (open bars): high-glucose, high-choline. Different letters indicate significant difference, P < 0.05.

No alterations in fatty acid or glucose metabolic gene expression as a result of choline supplementation were observed in BeWo cells (Fig. 3B). High glucose decreased (P < 0.01) the expression of the glucose transporter GLUT1 but increased (P < 0.05) the expression of GPAT2 regardless of choline supplementation. PEPCK was not expressed in the placenta (data not shown).

Effects of choline and glucose on cell growth differed between cell lines

In HepG2 cells, choline appeared to be a stronger promoting factor for cell growth and proliferation than glucose, as both cell counts and the expression of the cellular proliferative marker KI67 were increased by choline supplementation. In contrast, in vitro hyperglycemia did not alter HepG2 cell counts, which was consistent with the observation by Iyer et al. ²¹ However, another study by Chandrasekaran et al ²² suggests that when HepG2 cells were supplemented with 50 mM glucose, they demonstrated abnormal morphology, detachment from culture plates, and apoptosis, which were not observed in this study. The differed results may be due to the lower dose (35 mM) of glucose used in our experiment, which seems to be well tolerated by HepG2 cells. High glucose upregulated KI67, which was further amplified by choline cosupplementation. Previous studies suggest that hyperglycemia enhances liver stellate cell proliferation and exacerbates collagen production and connective tissue overgrowth, which is a potential mechanism of liver fibrosis.^23,24 It is unclear whether the growth and proliferation promoting effect of choline also applies to other liver cell types and plays a role in liver damage. In vivo studies in animals and humans, however, generally suggest choline as a lipotrope that prevents the formation of fatty liver and normalizes liver enzymes.^8,25

High-glucose treatment tended to increase BeWo cell counts modestly in the current study setting, although Weiss et al ²⁶ and Masumoto et al ²⁷ both reported that trophoblast growth was inhibited by in vitro hyperglycemia. Interestingly, expression of the cellular proliferative marker KI67 was significantly dampened in high glucose, whereas another proliferative marker PCNA was unchanged, despite the modest increase in cell counts. These results may indicate that after prolonged culture (96 hours) in high glucose, there was a larger proportion of cells in the high-glucose groups that were not proliferating compared to the low-glucose groups, since neither KI67 nor PCNA was expressed in resting (G0) cells. Choline supplementation seemed to partially normalize the overgrowth triggered by in vitro hyperglycemia, although it did not affect KI67 expression. Taken together, both glucose and choline have complicated roles in the growth and proliferation of BeWo cells.

Choline but not glucose treatment promoted DNA methylation in HepG2 cells

CpG methylation of DNA is a major epigenetic event that alters gene expression without changing the genetic sequence. There is mounting evidence suggesting that both global and site-specific CpG methylation levels are altered in patients with metabolic diseases, such as diabetes. Zhao et al ¹⁰ reported that leukocyte global CpG methylation was positively associated with insulin resistance. Pancreatic and duodenal homeobox 1 (PDX1), a critical gene that promotes pancreatic cell maturation and islet function, was hypermethylated in pancreatic islet cells isolated from patients with type 2 diabetes. ¹¹ These findings highlight the potential role of epigenetics in regulating the pathogenesis and progression of diabetes. In a HepG2 cell culture model, Chiang et al. ²⁸ demonstrated that in vitro hyperglycemia increased DNMT3A expression and global CpG methylation, suggesting activation of the transmethylation cycle. Supplying additional methyl donors, such as choline, under the condition of hyperglycemia may exacerbate the already active transmethylation cycle. In this study, choline supplementation increased DNMT expression and global CpG methylation in HepG2 cells. However, in contrast to that reported by Chiang et al, ²⁸ global CpG methylation was not altered by glucose treatment. Cosupplementation of choline and glucose seems to have an additive effect on promoting DNMT expression but not on global CpG methylation levels. It should be noted that both CHDH and BHMT expression were decreased in the HG-HC group. This may serve as a feedback mechanism to prevent excess amounts of choline-derived methyl groups from entering the transmethylation cycle when both glucose and choline are in surplus, thereby maintaining CpG methylation levels despite the upregulation of DNMTs. Taken together, supplementing choline in HepG2 cell culture did not seem to exacerbate CpG hypermethylation under the condition of hyperglycemia.

In BeWo cells, DNMT expression was not altered by either choline or glucose. The lack of BHMT expression in these cells may explain the null effect of choline. However, in an in vivo system, choline-derived methyl groups can be transferred from the maternal compartment (eg, liver) to the placenta. A previous human study has shown that higher maternal choline intake increases both global and site-specific CpG methylation of the placenta. ⁵ As such, in vivo studies are needed to further discern the interaction of glucose and choline on trophoblast CpG methylation in an integral whole-body system.

Choline supplementation was not associated with unfavorable alterations in fatty acid or glucose metabolism

Although fatty liver is associated with a higher risk of insulin resistance, ²⁹ recent studies suggest that fat accumulation in the liver itself does not always result in insulin resistance.^8,30–32 While choline deficiency results in fatty liver, it improves insulin resistance and glucose tolerance in male animals.^7,8 The dissociation between fatty liver and insulin resistance is proposed to be related to choline's effect on promoting the triglyceride breakdown and efflux of free fatty acids from the liver to circulation. ⁸ Circulating free fatty acids exacerbate peripheral insulin resistance. In this study, we found that choline supplementation enhanced the transcription of ACOX1 in HepG2 cells, especially in a high-glucose environment. ACOX1 mediates the first step of long-chain fatty acid β-oxidation in the peroxisome, and its increase may upregulate fatty acid catabolism. ²⁰ However, genes that mediate de novo fatty acid synthesis (eg, FAS) or triglyceride synthesis (eg, GPAT2) were not differentially expressed in the high- or low-choline groups. These findings do not support the role of choline in promoting triglyceride breakdown and fatty acid output but rather indicate its effect on reducing fatty acid content by enhancing β-oxidation.

Choline supplementation ameliorated the elevation in PEPCK expression under the condition of high glucose. Although glucose normally inhibits PEPCK expression and reduces gluconeogenesis, chronic hyperglycemia blunts its inhibitory effect,^33,34 leading to PEPCK overexpression and an increased rate of gluconeogenesis, which is observed in patients with type 2 diabetes. Our HepG2 cell model suggests that choline supplementation may rectify PEPCK expression when hepatocytes are exposed to high glucose, which may in turn mitigate gluconeogenesis and hepatic glucose output. Choline supplementation did not change glucose or fatty acid metabolic gene expression in BeWo cells, likely due to the lack of PEPCK expression and gluconeogenesis in these cells.

Glucose treatment triggered differential responses in HepG2 and BeWo cells. While increased expression of GLUT2 in HepG2 cells may enhance glucose uptake, there was a decrease in GLUT1 expression in the high-glucose-treated BeWo cells, which may be a mechanism of the trophoblasts to prevent excessive glucose transfer under hyperglycemic stress. The elevation of GPAT2 in BeWo cells in the high-glucose groups may be an additional regulating mechanism to promote triglyceride or phospholipid synthesis and trap free fatty acids in the placenta, thereby preventing their transport to the fetus.

Taken together, these results suggest that choline supplementation do not adversely affect hepatic glucose and fatty acid metabolism in either HepG2 cells or BeWo cells. Choline may be used as a lipotropic supplementation to prevent or improve hepatic steatosis by improving fatty acid β-oxidation and may lower the risk of hyperglycemia by dampening gluconeogenesis. The neutral effect of choline on placental-derived BeWo cells discerns the concerns about its potential negative impacts on the metabolic balance of pregnant women and their fetuses. Nevertheless, clinical studies are needed to confirm the efficacy and safety of choline supplementation in modulating macronutrient homeostasis in humans.

Supplementary table 1.

Real-time PCR primers.