Choline Supplementation Does Not Promote Atherosclerosis in CETP-Expressing Male Apolipoprotein E Knockout Mice

Over the last 60 years, the association of lipid abnormalities with cardiovascular disease (CVD) has assumed a bedrock status in the medical, scientific and even lay understanding of the pathogenesis underlying atherosclerosis. Atherosclerosis, one of the leading causes of CVD, has proved to be complex and can be affected by not only dyslipidemia but many other factors, such as smoking, diabetes, physical activity, nutrition, genetic background, inflammatory status, physical activity and hypertension.

The intestinal microbiome has received an increasing amount of attention as a contributor to the progression and/or increased risk of diseases such as obesity and type II diabetes, so it would not be surprising if the microbiome was found to be a contributor to CVD. An emerging theory suggests a pivotal role for the gastrointestinal microbiome in transforming carnitine and metabolites of phosphatidylcholine into TMA (trimethylamine). TMA is absorbed and then converted by hepatic flavin mono-oxidase 3 (FMO3) to trimethylamine oxide (TMAO), which is regarded as proatherogenic independent of dyslipidemia, environmental factors, diabetes and hypertension [1,2]. The fact that trimethylamine compounds are found in the highest concentrations in foods that have long been associated with cardiovascular risk (liver, eggs and red meat) would seem to support this hypothesis.

Choline, an essential nutrient, is found mainly in animal products but can also be found in plants, especially cruciferous vegetables and certain legumes [3]. Choline can also be produced via de novo synthesis in the liver; however, de novo synthesis of choline is not adequate to meet human requirements [4]. The recommended daily intake (RDI) of choline is 425 mg/day for women and 550 mg/day for men [4]. Once choline is made or consumed via dietary sources, it is converted to phosphatidylcholine (PC), which is one of the most abundant phospholipids found in mammalian cell membranes [5,6]. Choline serves as the major source of methyl groups through the synthesis of S-adenosylmethionine [7]. These methyl reactions are critical in the biosynthesis of lipids, maintenance of liver health [8], facilitation of metabolic pathways [6,9] and reduction in plasma homocysteine [10].

Previous studies supporting the metabolomic association of the choline metabolite, TMAO, with CVD used the Apoe^−/− atherosclerosis mouse model fed either a normal rodent chow (0.09% total choline, w/w), an intermediate dose (0.5% total choline), a high-choline dose (1.0%) or TMAO (0.12%) at the time of weaning [1,2]. In these studies, researchers fed high amounts of choline to elevate plasma TMAO levels. It is worth noting that the lowest choline dose supplemented in the normal mouse chow corresponds to an equivalent human dose of 900 mg/day, and the highest dose supplemented is equivalent to a human dose of 10,000 mg/day (20X greater than the Recommended Daily Intake). In early studies, Wang [2] found increased TMAO plasma concentrations correlated to an increase in total aortic root atherosclerotic plaque area in mice supplemented with either increased choline or TMAO for 16 weeks. However, these results have not been consistently reproduced when supplementing choline in such high amounts [11,12,13].

Although the Apoe^−/− mouse model is employed frequently, it is notable for the absence of a key protein involved in human reverse cholesterol transport: cholesterol ester transfer protein (CETP). Collins et al. used male Apoe^−/− mice transfected with hCETP and supplement-fed L-carnitine on a Western diet and were not able to reproduce earlier findings of increased atherosclerosis with increased plasma TMAO concentrations [12]. In fact, they found that increased plasma TMAO was associated with reduced progression of aortic lesions. Therefore, the experiment performed by Wang and colleagues [2] was repeated in the present study using the same background diets and two dose levels of choline in male Apoe^−/− mice with and without CETP expression on a normal diet. The data presented herein do not support a relationship between increased plasma TMAO and aortic lesion progression when supplementing with high doses of choline for 16 weeks.

In the first metabolomics study linking choline and TMAO in the pathogenesis of CVD, Wang [2] suggested atherosclerosis in both the Apoe^−/− female and male mice was associated with choline intake and plasma TMAO levels. After 16 weeks on either a normal chow, 0.5% or 1% choline, or 0.12% TMAO diet, aortic roots were examined and described as demonstrating a dose–response enhancement of atherosclerosis. We aimed to repeat this study in male Apoe^−/− mice using the same treatment diets but in the presence of CETP. We included a 1% choline group without CETP as a comparison to the original study.

The aortic root lesion size in the male mice on normal chow and on a 0.5% choline diet in the Wang study was approximately 19,000 μm² and 25,000 μm² (p = 0.2), respectively, but lesion size, when fed 1% of the diet (10X the normal chow choline dose), which corresponds to a human dose of 10,000 mg choline per day, was approximately 37,000 μm² (p = 0.045). After correcting the present study to average lesion area, for the control mice with CETP and 1% choline-fed mice with CETP, the average lesion area was 13,713 ± 7543 μm² and 21,212 ± 11,308 μm², respectively, similar to what Wang et al. reported [2]. Although the previous study just met statistical significance in the 1% choline supplemented group and given that the present study reported the same amount of lesion development as previously seen, we failed to see a statistically significant difference in lesion development in any of our groups supplemented with choline when compared to control.

In the present study, we found that TMAO concentrations in mice without CETP on a 1% choline diet were similar to those previous published (average concentration of ~20 μM). We also found a significant dose response for plasma TMAO after 8 weeks in the CETP-transfected mice, although at 16 weeks, TMAO levels were only significantly different between chow and 0.5% but not between 0.5% and 1% choline. An unexpected finding is that mice without CETP fed 1% choline had significantly higher TMAO levels than mice expressing CETP fed 0.5% and 1% choline (Figure 1B). Although in the current study, we achieved similar TMAO levels when compared to those reported by Wang et al., as well as a similar amount of aortic root lesion development, we saw no association of plasma TMAO concentration with lesion development in the presence or absence of CETP in male Apoe^−/− mice when fed high doses of choline on a normal diet. The TMAO lesion area association that Wang et al. saw [2] represents 13 mice with TMAO concentrations greater than 20 μM. More than half of those mice had lesion areas similar to that of animals with TMAO concentrations near the lowest detectable limits.

Both Wang [2] and Koeth [1] cite the lack of change in various lipid and other inflammatory markers as supportive of a role for TMAO in the pathogenesis of atherosclerosis. In our study, we were also unable to demonstrate any difference in these markers between the treatment groups, as well as other changes in markers of inflammation, such as MPO, HDL inflammatory index or proatherogenic oxidized phospholipids.

To date, the results from Wang [2] have not been consistently duplicated when feeding high doses of choline or TMAO. Two additional independent groups have recently explored the connection between dietary choline in murine models of atherosclerosis [11,13]. Lindskog Jonsson [13] compared conventionally raised and germ-free Apoe^−/− mice fed either a normal chow or a Western diet with or without choline supplement (chow plus 1.2% choline and Western diet plus 1% choline, respectively, which are equivalent to the highest dose used by Wang) [2]. After 12 weeks on the diets, the animals were sacrificed, and aortic roots were examined for lesion development. TMAO levels were elevated in the conventionally raised (CONV-R) choline cohort but not in the CONV-R control (no extra choline) chow group or either of the germ-free (GF) groups. This confirms that a 10-fold dose of choline raises TMAO levels only in CONV-R mice (which have a microbiota load of approximately 10¹¹ vs. 100 for GF). Atherosclerotic lesions in the aortic roots were observed in both GF and CONV-R on conventional chow or Western diets, and if anything, the lesions were smaller in the CONV-R chow groups (with or without extra choline) and comparable in all Western diet groups. Moreover, there was no correlation between plasma TMAO concentration and lesion size development.

Aldana-Hernandez [11] examined the relationship in two atherogenic models. When no association between choline intake and atherosclerosis was found in the LDL receptor knockout model (Ldl-r^−/−), it was assumed that the modest increase in TMAO was insufficient to induce cardiovascular changes, and higher doses of TMAO were given and feeding time was doubled. TMAO levels were elevated more in this group, but the mice still did not demonstrate a higher incidence of atherosclerotic plaque after 16 weeks. They repeated this in the Apoe^−/− model and fed either normal chow (0.09% choline), high-dose (1% choline) or TMAO (0.12%). In contrast to the Wang [2] study, no increase in TMAO or atherosclerosis was observed after 12 weeks. Again, the working hypothesis was that there was insufficient time allowed for TMAO elevation or plaque development. Aldana-Hernandez [11] performed an additional feeding trial with the same dietary interventions, which was continued for 28 weeks, and although TMAO levels were shown to increase significantly, these mice did not demonstrate an increase in atherosclerotic plaque development as compared to control mice.

Lindskog Jonsson [13] found no difference in the effects of choline on atherosclerosis in male or female mice. Aldana-Hernandez [11] performed their experiments in male mice only. In an attempt to understand the differences between these two studies, the Getz and Reardon [18] posited that Wang [2] supplemented the diet starting at 4 weeks, compared to 8 weeks by Lindskog Jonsson [13], by which time the flavin-containing monooxygenase 3 protein enzyme (FMO3) is no longer expressed in male mice. However, this explanation however unlikely, as TMAO levels were elevated in both studies in much older mice, indicating the presence and adequacy of FMO3 in converting TMA to TMAO. In our study, we used only male Apoe^−/− mice and administered the same amounts of choline as those described in the Wang [2] paper, and we were also able to demonstrate a comparable dose-response elevation of TMAO in mice when choline supplementation was started at 9–10 weeks of age.

Koeth [1] used a model identical to that of Wang [2] but fed the Apoe^−/− mice carnitine (another trimethylamine compound found in meat and capable of being transformed by some microbial strains in the gastrointestinal tract into TMAO). This group concluded that dietary L-carnitine altered caecal microbial composition, increased TMA synthesis which resulted in TMAO production and increased atherosclerosis. Collins [12] replicated this experiment in male Apoe^−/− mice transfected with CETP and failed to show any difference between low-dose and high-dose carnitine in the production of aortic atherogenic lesions or even a dose-response rise in plasma TMAO in response to a human-equivalent dose of 500 mg and 2000 mg per day.

In a separate in vitro experiment, Collins et al. exposed J774 mouse macrophages to a very high TMAO gradient and were not able to demonstrate foam cell development [12]—an essential component of the atherogenesis model. Not only was there no change in cholesterol uptake by macrophages, but no impact on cholesterol efflux from the macrophage could be detected, which is consistent with findings from Lindskog Jonsson [13]. TMAO elevations with administration of carnitine or choline were found by Collins [12], Lindskog Jonsson [13] and again in this current study. Although Aldana-Hernandez et al. [11] did not find elevated TMAO after feeding high-dose choline (1%), the Apoe^−/− mice were also fed 0.12% TMAO, and this did not produce a higher incidence of atherosclerosis.

There are few groups independent of Wang and Koeth that have shown associations of plasma TMAO concentrations with atherosclerotic lesion size when administering choline or TMAO in the diet. Ding [19] fed 0.3% TMAO to 9-week-old male Apoe^−/− mice for 8 weeks in a casein-based semi-purified diet. The diets used in the present study and the Wang and Koeth diets are certified diets made with plant-based protein, and they are not semi-purified. Ding et al. saw a significant increase in percent lesion area for TMAO-treated animals when compared to control animals. Chen [20] treated 8-week-old female Apoe^−/− mice with a 1% choline diet for 4 months on a normal chow but gave limited information about the composition of the diets. Their study showed more advanced lesions. Thoracic aortas had approximately 30% lesion coverage in the control animals and upwards of 70% in the 1% choline-fed group. When compared to the present study for the same amount of time on chow, we saw less than 1.5% lesion coverage of the thoracic area in our control and choline-treated animals. In their study, aortic root lesions were also more advanced, more indicative to those seen in a Western-diet-fed animal when looking at the representative micrographs. The measures reported for aortic root lesion area were percent of total vessel, not total area, so there is further difficulty in interpreting and comparing results to those of the current study.

With these differences seen between study groups, the intestinal microbiome has been shown to be influenced by dietary components, such as protein source [21,22] and fat [23,24], and microbiome diversity (a measure of gut health) has been shown to change with dietary patterns [25]. These differences make it difficult to reproduce animal studies that distillate on metabolites generated by the gut microbiome that are not well controlled or if semi-purified diets are not used. Other factors, including animal background, source or procurement, housing conditions (single- or multi-housed, caging types, etc.) and facility containment levels also play a role in influencing the gut microbiome and atherosclerosis outcome [26,27].

In conclusion, our study failed to corroborate any association between TMAO and aortic atherosclerosis when feeding large doses of choline to non-CETP-expressing male Apoe^−/− mice for 16 weeks. Enhancing reverse cholesterol transport in CETP-transfected male Apoe^−/− mice also failed to show any difference in atherosclerosis despite a dose-responsive elevation of TMAO after 8 and 16 weeks. Taken together, these data from male Apoe^−/− mice with or without expression of CETP do not support increased plasma TMAO as a causative agent of atherosclerosis.

Conceptualization, H.L.C., S.J.A. and J.D.B.; methodology, H.L.C. and S.J.A.; formal analysis, H.L.C. and D.N.B.; investigation, H.L.C. and S.J.A.; writing—original draft preparation, D.N.B.; writing—review and editing, H.L.C., S.J.A. and J.D.B. All authors have read and agreed to the published version of the manuscript.

This work was funded by Balchem Corporation.

The animal study protocol under which this work was conducted was approved by the Institutional Animal Care and Use Committee of VascularStrategies (protocol A18-0002 was approved on 1 June 2018).

The datasets used and/or analyzed during the current study are available from the corresponding author upon reasonable request.

H.L.C. and S.J.A. are employees of VascularStrategies and were funded by Balchem Corporation to perform this study/work. J.D.B. and D.N.B. are employees of Balchem Corporation. Balchem Corporation funded VascularStrategies to perform this study/work.