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Scientific Reports volume 12, Article number: 18551 (2022)
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Digestion of dietary fibers by gut bacteria has been shown to stimulate intestinal mineral absorption [e.g., calcium (Ca2+) and magnesium (Mg2+)]. Although it has been suggested that local pH and short-chain fatty acid (SCFA) concentrations determine divalent cation absorption, the exact molecular mechanisms are still unknown. Therefore, this study aimed to determine the effects of SCFAs on intestinal Mg2+ absorption. We show that the butyrate concentration in the colon negatively correlates with serum Mg2+ levels in wildtype mice. Moreover, Na-butyrate significantly inhibited Mg2+ uptake in Caco-2 cells, while Ca2+ uptake was unaffected. Although Na-butyrate significantly lowered total ATP production rate, and resulted in increased phosphorylation of AMP-activated protein kinase (AMPK), inhibition of Mg2+ uptake by butyrate preceded these consequences. Importantly, electrophysiological examinations demonstrated that intracellular butyrate directly reduced the activity of the heteromeric Mg2+ channel complex, transient receptor potential melastatin (TRPM)6/7. Blocking cellular butyrate uptake prevented its inhibitory effect on Mg2+ uptake, demonstrating that butyrate acts intracellularly. Our work identified butyrate as novel regulator of intestinal Mg2+ uptake that works independently from metabolic regulation. This finding further highlights the role of microbial fermentation in the regulation of mineral absorption.
The absorption of magnesium (Mg2+) in the intestines is facilitated by different absorption pathways1. Passive, paracellular transport occurs in the small intestine, whereas active transport in the colon is facilitated by channels of the transient receptor potential melastatin (TRPM) cation channel family, TRPM6 and TRPM7, on the apical side2,3, and cyclin M4 (CNNM4) on the basolateral side of enterocytes4. So far, little is known about factors regulating intestinal Mg2+ absorption.
Oral Mg2+ supplementation is often insufficient to restore blood Mg2+ levels in diseases with increased prevalence of Mg2+ deficiency such as type 2 diabetes mellitus (T2DM), hypertension, cardiovascular disease and proton pump inhibitor (PPI)-induced hypomagnesemia5,6,7. Hence, there is an urgent need for alternative treatment options that stimulate intestinal Mg2+ absorption. Targeting the gut microbiota using dietary fibers is a promising strategy, as the fermentation of dietary fibers by gut bacteria was shown to improve intestinal Mg2+ absorption8,9. However, the underlying molecular mechanisms are still unknown.
One possible mechanism is that short-chain fatty acids (SCFAs; acetate, propionate and butyrate), derived from bacterial fermentation of complex dietary carbohydrates, are involved in the increased Mg2+ absorption10. There is increasing amount of evidence that SCFAs act as key signaling molecules between the gut microbiota and the host10,11,12. Indeed, SCFAs strengthen the mucosal barrier integrity, modulate immune cell responses and affect cholesterol, lipid and glucose metabolism in various tissues12. In the context of intestinal physiology, butyrate has been studied most intensively for its role as primary energy source for colonocytes and its protective effects against inflammation and colorectal cancer13,14,15.
Prebiotic fibers (e.g., oligofructose, inulin) increase the production of SCFAs and lower the intraluminal pH of the colon. These factors were shown to be beneficial for the solubility and absorption of Mg2+ in different experimental models8,16,17. As such, the gut microbiota-stimulatory effects on Mg2+ absorption are hypothesized to be dependent on SCFAs, either by acidification of the intestinal lumen or by affecting active transport mechanisms. Although these concepts have been widely adopted in current scientific literature, the direct effects of SCFAs on intestinal Mg2+ absorption have never been clarified.
This study investigated the physiological role of SCFAs on intestinal Mg2+ absorption by elucidating the molecular mechanisms by which SCFAs modulate Mg2+ uptake in the human colon cell line Caco-2, and by correlating serum Mg2+ levels to colonic SCFA concentrations in wildtype C57BL/6J mice.
To assess whether microbiota-derived SCFAs influence Mg2+ homeostasis, correlation analyses were performed between colonic SCFAs concentrations and serum Mg2+ levels in wildtype C57BL/6J mice (Fig. 1). We measured the relative concentration of SCFAs in colon samples that were collected during a previous study18. Linear regression analysis showed a significant inverse correlation of colonic butyrate concentrations with serum Mg2+ levels (P < 0.05, r2 = 0.22) (Fig. 1A). No correlations were found between serum Mg2+ levels and colonic acetate or propionate concentrations (Fig. 1B,C). No correlations were found between colonic SCFAs concentrations and serum Ca2+ levels (Supplementary Fig. S1).
Butyrate concentrations in the colon negatively correlate with serum Mg2+ levels in mice. (A–C) Simple linear regression analyses were performed on colonic SCFAs concentrations, obtained from a previously published dataset18, and serum Mg2+ levels of 25 wildtype male C57BL/6J mice. Simple linear regression analysis between colonic concentrations of butyrate (y = −2.24x + 1.52, r2 = 0.22, P < 0.05) (A), acetate (y = −0.05x + 1.22, r2 = 0.006) (B), propionate (y = 0.15x + 1.15, r2 = 0.003) (C), and serum Mg2+ levels. Data is plotted as individual data points with the linear line indicating the relationship. P < 0.05 is considered significant.
To explain the underlying mechanism of the inverse correlation between colonic butyrate concentrations and serum Mg2+ levels, we investigated whether butyrate affects Mg2+ uptake in the human colon cell line Caco-2 using the heavy 25Mg isotope. Cells incubated for 20 min with 2, 4, or 8 mmol/L Na-butyrate had a significantly reduced 25Mg2+ uptake compared to control (100% vs. 88% ± 2 vs. 86% ± 4 vs. 72% ± 3, respectively, P < 0.05) (Fig. 2A). Of note, a dose–response effect was also observed within the physiological concentration range (8–40 mmol/L) (Supplementary Fig. S2)15. A similar reduction of 25Mg2+ uptake was observed in cells incubated with Na-propionate and Na-acetate (Supplementary Fig. S2). Further experiments were performed using the low-physiological concentration of 8 mmol/L. The inhibitory effect of Na-butyrate was time-dependent, as 8 mmol/L Na-butyrate resulted in a significantly lowered 25Mg2+ uptake between 10- and 30 min compared to control-treated cells (P < 0.05) (Fig. 2B). 45Ca2+ uptake was not inhibited by Na-butyrate treatment in Caco-2 cells (Supplementary Fig. S2). Next, Na-butyrate (0–20 mmol/L) was added to a magnesium green and MgCl2 containing buffer, in order to test if Na-butyrate would be able to bind Mg2+ sufficiently to decrease Mg2+-magnesium green binding-mediated fluorescence. None of the tested concentrations of Na-butyrate resulted in lower fluorescent intensity (Fig. 2C). As a control for our assay, addition of 1 mmol/L ATP to the magnesium green and MgCl2 containing buffer reduced the magnesium green fluorescence by twofold (98% ± 10 vs. 46% ± 18, P < 0.05) and 2 mmol/L ATP abolished the fluorescence completely (Fig. 2D). To determine whether the effects of butyrate were dependent on intracellular actions, butyrate uptake via the monocarboxylate transporter 1 (MCT1) was blocked by the known MCT1 inhibitor phloretin19. Similar to previous experiments, 20 min incubation with 8 mmol/L Na-butyrate significantly reduced 25Mg2+ uptake (100% vs. 65% ± 5, P < 0.05) and this effect was abrogated by addition of 1 mmol/L phloretin (65% ± 5 vs. 101% ± 10, P < 0.05) (Fig. 2E).
Butyrate treatment results in reduced 25Mg2+ uptake in Caco-2 cells. (A) 25Mg2+ uptake by Caco-2 cells after 20 min of treatment with increasing concentrations of Na-butyrate (2–8 mmol/L). Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells using One-Way ANOVA with Dunnett’s correction for multiple testing. (B) Time course of 25Mg2+ uptake by Caco-2 cells treated with 8 mmol/L Na-butyrate (dashed line) or control (solid line) for 30 min. Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells at the same timepoint using Student’s t-test. (C, D) Fluorescence intensity of 2 µmol/L magnesium green in a 1 mmol/L MgCl2 buffer with increasing concentrations of Na-butyrate (0–20 mmol/L) (C), and ATP (0–2 mmol/L) (D). Data represent mean ± SEM (n = 4 (C) and n = 3 (D), each experiment consisted of duplicates). (E) 25Mg2+ uptake by Caco-2 cells after 20 min of treatment with 8 mmol/L Na-butyrate, or 8 mmol/L Na-butyrate and 1 mmol/L phloretin. Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells using One-Way ANOVA with Sidak’s correction for multiple testing.
Since butyrate is the primary energy source for colonocytes20,21, we hypothesized that butyrate treatment results in lower 25Mg2+ uptake by modulating cellular metabolism (Fig. 3). To investigate this in more detail, the effects of butyrate treatment on mitochondrial oxidative phosphorylation (OXPHOS) and glycolysis, the two main metabolic pathways responsible for ATP production, were examined using the Seahorse Xfe96 analyzer. Treatment of cells with 8 mmol/L Na-butyrate decreased the extracellular acidification rate (ECAR) (Fig. 3A) and increased oxygen consumption rate (OCR) (Fig. 3B). Quantification of the ATP production rates demonstrated that butyrate treatment resulted in a significantly decreased glycolytic ATP production (52.71 ± 2.55 vs. 42.95 ± 2.13 pmol ATP/min/µg protein, P < 0.05) (Fig. 3C) and increased mitochondrial ATP production (23.70 ± 3.35 vs. 29.84 ± 3.17 pmol ATP/min/µg protein, P < 0.05) (Fig. 3D). Together, butyrate treatment resulted in a significantly decreased total ATP production (76.41 ± 2.06 vs. 72.79 ± 2.78 pmol ATP/min/µg protein, P < 0.05) (Fig. 3E). In contrast, treatment of cells with either 8 mmol/L acetate or propionate did not affect total ATP production rates, but did result in decreased glycolytic and increased mitochondrial ATP production (Supplementary Fig. S3).
Butyrate treatment results in lower ATP production rates by modulating cellular metabolism. (A, B) Extracellular Acidification Rates (ECAR) (A) and Oxygen Consumption Rates (OCR) (B) of Caco-2 cells treated with control (solid line) or 8 mmol/L Na-butyrate (dashed line) (first arrow), followed by 2 µmol/L oligomycin (blocks OXPHOS as inhibitor of ATP synthase; second arrow) and a mixture of 0.5 µmol/L rotenone and antimycin A (blocks OXPHOS as inhibitor of mitochondrial complex I and III, respectively; third arrow), as measured with the Seahorse Xfe96 analyzer and normalized to control cells. Results of one representative experiment are shown, experiments were repeated in triplicate. Data represent mean ± SEM with 12 replicates per condition. (C–E) Glycolytic (C), mitochondrial (D) and total (C) ATP production rate of cells before (basal) and after (induced) treatment with 8 mmol/L Na-butyrate. Data depicted in (C–E) represent mean ± SEM, and is computed from individual traces from three independent experiments, of which representative traces of one experiment are depicted in (A, B). *P < 0.05 is considered statistically significant compared to basal using paired Student’s t-test.
In order to further understand the butyrate-induced reduction in total ATP levels, we analyzed the phosphorylation levels of AMP-activated protein kinase (AMPK). AMPK is the master energy sensor of the cell and is phosphorylated under conditions of low intracellular ATP22. Caco-2 cells were treated with 8 mmol/L Na-butyrate, 25 mmol/L glucose (to stimulate ATP production), or 2 µmol/L oligomycin (to inhibit ATP production) for 5, 10, and 20 min.
Compared to control, butyrate treatment tended to result in a 1.2 fold higher AMPK phosphorylation after 5 min (not statistically significant), while oligomycin treatment resulted in a nearly twofold higher AMPK phosphorylation (Fig. 4A,D). Yet, butyrate treatment resulted in a significantly higher AMPK phosphorylation of almost 1.5-fold after 10 min (Fig. 4B,E) and twofold after 20 min (Fig. 4C,F). Similarly, oligomycin treatment resulted in a consistently higher AMPK phosphorylation at 10 (Fig. 4B,E) and 20 min (Fig. 4C,F). Vice versa, glucose treatment, known to increase the ATP production, resulted in lower AMPK phosphorylation, which was only significantly after 10 min (Fig. 4A–F). One of the major downstream signaling pathways regulated by AMPK is the mammalian target-of-rapamycin (mTOR) pathway, involving S6K as direct downstream target23. As activated AMPK inhibits the mTOR pathway, the phosphorylation levels of S6K were investigated at the same timepoints. No effects of treatment with butyrate, glucose, or oligomycin, were observed on S6K phosphorylation after 5 min (Fig. 4G,J). However, butyrate treatment resulted in a significantly lower S6K phosphorylation of twofold after 10 min (Fig. 4H,K) and 2.5-fold after 20 min (Fig. 4I,L). At this latter timepoint, glucose treatment resulted in a significantly higher S6K phosphorylation with of 1.5-fold (Fig. 4I,L). All original raw western blot data is depicted in the supplementary information (Supplementary Figs. S4–S5).
Butyrate treatment affects AMPK signaling. (A–C) Representative immunoblot images of pAMPK (62 kDa) and total AMPK (62 kDa) of Caco-2 cell lysates after treatment with 8 mmol/L Na-butyrate, 25 mmol/L glucose, or 2 µmol/L oligomycin for 5 min (A), 10 min (B), and 20 min (C). (D–F) Densitometry analysis of pAMPK expression corrected for total AMPK expression levels after 5 min (D), 10 min (E), and 20 min (F) of treatment with 8 mmol/L Na-butyrate, 25 mmol/L glucose, or 2 µmol/L oligomycin. (G–I) Representative immunoblot images of pS6K (70 kDa) and total S6K (70 kDa) of Caco-2 cell lysates after treatment with 8 mmol/L Na-butyrate, 25 mmol/L glucose, or 2 µmol/L oligomycin for 5 min (G), 10 min (H), and 20 min (I). (J–L) Densitometry analysis of pS6K expression corrected for total S6K expression after 5 min (J), 10 min (K), and 20 min (L) of treatment with 8 mmol/L Na-butyrate, 25 mmol/L glucose, or 2 µmol/L oligomycin. Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells using One-Way ANOVA with Dunnett’s correction for multiple testing. All original immunoblots are presented in Supplementary Figs. S4–S5.
To investigate whether the butyrate treatment-induced inhibition of Mg2+ uptake was dependent on AMPK signaling (Fig. 5), Caco-2 cells were treated for 5, 10, and 20 min with 8 mmol/L Na-butyrate and/or 2 mmol/L AICAR, a well-known AMPK-activating compound24. As observed in previous experiments, butyrate treatment resulted in a significantly lower 25Mg2+ uptake at all timepoints (Fig. 5A–C). However, AICAR treatment, that resulted in activation of AMPK, did not affect 25Mg2+ uptake after 5 min (Fig. 5A), and resulted in higher 25Mg2+ uptake after 10 min (Fig. 5B). Yet, combined AICAR and butyrate treatment resulted in a significantly lower 25Mg2+ uptake compared to treatment with AICAR only (Fig. 5A–C). Subsequently, we analyzed whether low intracellular ATP levels directly inhibited 25Mg2+ uptake by treating cells with oligomycin for 5, 10, and 20 min. While 5 min of butyrate treatment resulted in a significantly lower 25Mg2+ uptake of almost 1.5-fold, there were no effects of 5 min of oligomycin treatment (Fig. 5D). After 10 and 20 min, butyrate and oligomycin treatment both resulted in a significantly lower 25Mg2+ uptake (Fig. 5E).
Butyrate treatment reduces 25Mg2+ uptake independent of ATP. (A–C) 25Mg2+ uptake by Caco-2 cells after treatment with 8 mmol/L Na-butyrate and/or 2 mmol/L AICAR for 5 min (A), 10 min (B), and 20 min (C). Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells using One-Way ANOVA with Sidak’s correction for multiple testing. (D–E) 25Mg2+ uptake by Caco-2 cells after treatment with 8 mmol/L Na-butyrate or 2 µmol/L oligomycin after 5 min (D). Time course of 25Mg2+ uptake by Caco-2 cells after treatment with 8 mmol/L Na-butyrate or 2 µmol/L oligomycin at 5, 10, and 20 min (E). Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). *P < 0.05 is considered statistically significant compared to control cells at the same timepoint using One-Way ANOVA with Dunnett’s correction for multiple testing.
Subsequently, the potential direct effects of butyrate on Mg2+ uptake were investigated (Fig. 6). Over the last decade, heteromeric TRPM6/7 channels have been established as the main regulators of Mg2+ absorption in the colon2,3. In order to explore whether TRPM6/7 is involved in the butyrate treatment-inhibited Mg2+ uptake, Caco-2 cells were treated with 8 mmol/L Na-butyrate and the TRPM6/7 inhibitor NS8593 (30 µmol/L) for 10 minutes3. Importantly, treatment of Caco-2 cells with butyrate and NS8593 resulted in a fourfold lower 25Mg2+ uptake (100% vs. 24% ± 2, P < 0.05), similar to the effect of NS8593 alone. This suggests that butyrate treatment is exerting its effect via TRPM6/7 (Fig. 6A). Therefore, we investigated whether butyrate could directly affect TRPM6/7 channel activity. Human Embryonic Kidney (HEK293) cells transiently transfected with TRPM6/7, were subjected to whole-cell patch clamp using 8 mmol/L Na-butyrate in the patch pipette solution. Cells exposed to intracellular Na-butyrate presented significantly lower current densities over time at + 80 mV and – 80 mV, compared to control (759 ± 159 vs. 433 ± 53 pA/pF, P < 0.05 and − 45 ± 10 vs. − 18 ± 4 pA/pF, P < 0.05, respectively) (Fig. 6B,C). Of note, the effects of intracellular Na-butyrate specifically resulted in lower current densities of TRPM7, as current densities of TRPM6 were not affected (Supplementary Fig. S6). All original traces of electrophysiological recordings are depicted in the supplementary information (Supplementary Figs. S7–S9).
Intracellular butyrate results in lower TRPM6/7 channel activity. (A) 25Mg2+ uptake by Caco-2 cells after treatment with 8 mmol/L Na-butyrate and/or 30 µmol/L NS8593 after 10 min. Data represent mean ± SEM (n = 3, each experiment consisted of triplicates). * P < 0.05 is considered statistically significant compared to control cells using One-Way ANOVA with Sidak’s correction for multiple testing. (B, C) Whole-cell currents measured at − 80 mV and + 80 mV over time in TRPM6/7-transfected (HA-mTRPM7 pCINeo IRES GFP and HA-hTRPM6 pCINeo IRES GFP) HEK293 cells without (circles, n = 9) or with 8 mmol/L Na-butyrate (squares, n = 11) in the intracellular pipette solution (B). Bar graphs of current amplitudes without (Control) or with 8 mmol/L Na-butyrate (Na-butyrate) in the intracellular pipette solution (C). Data represent mean ± SEM. *P < 0.05 is considered statistically significant compared to control cells using Student’s t-test.
Our study demonstrates that butyrate, a short-chain fatty acid derived from bacterial fermentation, reduces intestinal TRPM6/7-mediated Mg2+ uptake preceding changes in metabolic regulation. This conclusion is based on the following results: (i) colonic butyrate concentrations negatively correlate with serum Mg2+ levels in wildtype mice; (ii) butyrate treatment results in lower 25Mg2+ uptake in the human colon cell line Caco-2; (iii) combined treatment of Caco-2 cells with butyrate and phloretin, a specific inhibitor of the butyrate transporter MCT1, prevents this lower 25Mg2+ uptake; (iv) treatment of Caco-2 cells with butyrate and NS8593, a TRPM6/7 blocker, results in a fourfold lower 25Mg2+ uptake, similar to treatment of Caco-2 cells with NS8593 alone; (v) intracellular butyrate results in significantly lower TRPM6/7 channel activity.
Fermentation of dietary carbohydrates by the gut microbiota is associated with enhanced mineral absorption25. In the human colon, acetate, propionate and butyrate are produced at a molar ratio of approximately 60:20:20 with concentrations ranging between 20 and 140 mmol/L10,26. Acetate and propionate are important modulators of lipid, glucose, and cholesterol metabolism in various tissues, whereas butyrate exerts limited systemic functions but is an important modulator of colonic homeostasis10,15,25. Here, we report that only colonic butyrate concentrations, but not acetate and propionate, correlated with serum Mg2+ levels in wildtype C57BL/6J mice. In the colon, butyrate is the primary energy source for enterocytes and acts as a histone deacetylase (HDAC) inhibitor15. These functions are dependent on butyrate absorption by monocarboxylate transporters (e.g., MCT1)26,27. We now demonstrate that butyrate results in a reduced 25Mg2+ uptake via intracellular mechanisms, as phloretin, a specific inhibitor of the butyrate transporter MCT1, abolishes the inhibitory effect of butyrate on 25Mg2+ uptake. Specifically, our results suggest that intracellular butyrate initiates a negative feedback mechanism for 25Mg2+ uptake by inhibition of TRPM6/7 channels.
We showed by whole-cell patch clamp experiments that intracellular butyrate resulted in 1.5-fold lower TRPM6/7 currents compared to untreated cells. Fatty acids have been previously reported as intracellular modulators of ion channel activity and are able to act as (anta)agonists on transient receptor potential (TRP) channels28,29,30,31. Poly-unsaturated fatty acids, including arachidonic acid, eicosapentaenoic acid (EPA) and docosahexaenoic acid, have been shown to inhibit TRPM8 currents in Chinese hamster ovary cells32. Moreover, 40 µmol/L linoleic acid (LA) significantly reduced currents at both negative and positive membrane potentials of TRPM8 and TRPV1 channels in Drosophila S2 cells33. Similarly, 10 µmol/L LA and EPA inhibited capsaicin-evoked currents of TRPV1 by 82% and 48% in HEK293 cells, respectively34. These fatty acids competitively inhibited TRPV1 currents evoked by ligands (e.g. capsaicin), suggesting a common binding site34. Although these studies have investigated long-chain fatty acids, our data suggest a similar mechanism for the SCFA butyrate.
Generally, two mechanisms are considered to explain effects of butyrate on TRPM6/7 activity: the SCFA may directly bind to the channel or affect the lipid bilayer28,35. Butyrate acts as a ligand for G-protein coupled receptors (GPCRs), such as GPR43 (FFAR2), on intestinal epithelial cells10,13. Activation of GPR43 by butyrate stimulates phospholipase C (PLC) activity, which in turn converts phosphatidylinositol 4,5-bisphosphate (PIP2) to diacylglycerol (DAG) and inositol triphosphate (IP3)36. Since TRPM7 activity is negatively regulated by hydrolysis of PIP237,38,39, it could be hypothesized that butyrate indirectly inhibits TRPM7 activity by the hydrolysis of PIP2 via activation of GPR43 at the cell surface membrane. However, this mechanism is unlikely, since the inhibitory effect of butyrate on the TRPM6/7 channel was specific for intracellular butyrate application. The negative regulation of TRPM6/7 activity by butyrate could be caused by direct interaction with the channel, or via indirect regulation through inhibitory pathways like the PKC/RACk1 pathway40. Therefore, structural studies are necessary to identify if there are interaction sites of butyrate within TRPM6/7 channels.
Although we show that butyrate-mediated reduced Mg2+ uptake is preceding effects of butyrate treatment on metabolic regulation, we cannot exclude that reduced ATP levels contribute to the long-term inhibitory effect of butyrate treatment on 25Mg2+ uptake. Although butyrate-dependent inhibition of 25Mg2+ uptake preceded effects of butyrate treatment on ATP production, blocking ATP production by oligomycin treatment also resulted in significantly lower 25Mg2+ uptake after 10 and 20 min. At these timepoints, butyrate and oligomycin treatment both resulted in a significantly higher phosphorylation of AMPK, confirming an intracellular state of low ATP. This inhibition is similar to what is observed with AMPK activating drugs, such as metformin41. A 24 h pre-incubation with metformin or AICAR significantly reduced 25Mg2+ uptake in Caco-2 cells and in the renal cell line mDCT1541. Our results demonstrate that low intracellular ATP levels are accompanied by reduced Mg2+ uptake. Thus, butyrate may play a dual role in reduced Mg2+ uptake by affecting TRPM6/7 activity acutely, and by reducing intracellular ATP levels in a delayed response.
Our results suggest that butyrate provides a negative feedback mechanism for colonic Mg2+ absorption upon dietary fiber intake. Dietary fibers are known to acidify the intestinal lumen and thereby increase the solubility of Mg2+ in the colon8,9,16,17,42. When the luminal ionized Mg2+ concentration is higher, the permeability for Mg2+ in the colon should be reduced to keep Mg2+ absorption stable. Given that dietary fibers also increase the microbial diversity and subsequently the production of butyrate43,44, butyrate provides an excellent signaling molecule to reduce Mg2+ channel activity. Since there is oscillation of butyrate concentrations upon dietary fiber fermentation45,46, TRPM6/7 channels will not be constantly inhibited. Considering the fact that Mg2+ absorption via TRPM6/7 channels is high in the proximal colon, and this intestinal segment is dominated by butyrate-producing bacteria10,47,48, butyrate could act as negative regulator of Mg2+ absorption in this segment. Although butyrate supplementation did not result in differences in serum Mg2+ concentration or fecal Mg2+ extrusion between butyrate and control-treated mice after 1 and 14 days of treatment in a previous study49, our correlation analyses demonstrated that the colonic butyrate content is inversely associated with the serum Mg2+ levels in a physiologically relevant setting.
Our study is the first that sheds molecular insights on how SCFAs influence intestinal Mg2+ uptake. We show that butyrate treatment results in decreased 25Mg2+ uptake by fast inhibition of TRPM6/7 channels, preceding metabolic consequences. In particular patients with Mg2+ deficiency may benefit from a low molar ratio of butyrate to optimally enhance Mg2+ absorption.
Serum electrolyte concentrations, and organic acid concentrations from the colonic content (fermentation broth) were determined in wildtype male C57BL/6J mice described in detail by Gommers et al.18. This study was approved by the animal ethics board of the Radboud University Nijmegen (RU DEC 2015-0112) and by the Dutch Central Commission for Animal Experiments (CCD, AVD103002016382). This study was performed in accordance with relevant guidelines and regulations. This study was performed in compliance with the ARRIVE guidelines.
The organic acids concentrations were determined in the colonic content (fermentation broth) of mice. In short, the colonic content was diluted four times with 1 mol/L perchloric acid (HClO4, Sigma-Aldrich, USA) to release the organic acids. Proteins and fat in the fermentation broth were precipitated by ultrasonication and removed by centrifugation for 10 min at 20,000×g. Organic acids, including the SCFAs, were determined by high performance anion exchange chromatography (HPAEC) with UV and refractive index (RI) detection. 25 µL of the supernatant was injected on a guard column in series with two Rezex ROA Organic acids H+ analytical columns (Phenomenex, USA). The organic acids were eluted isocratic with 5 mmol/L sulfuric acid (H2SO4), with a flow rate of 0.60 mL/min. The column oven was held at a temperature of 60 °C. Data analysis was done with Chromeleon software version 7.2 (Thermo Scientific). Quantitative analyses were performed by using standards of the organic acids (Sigma-Aldrich, USA).
Serum Mg2+ concentrations were determined using a colometric xylidyl-IL blue assay kit, according to the manufacturer’s protocol (Roche/Hitachi, Tokyo, Japan) and measured at 600 nm on a Bio-Rad Benchmark Plus microplate spectrophotometer (BioRad, Hercules, California, USA). Serum Ca2+ levels were measured using the o-cresolphthalein complexone method50. Briefly, o-cresolphthalein color reagent (Sigma, Zwijndrecht, the Netherlands) was incubated with the samples and standards and the absorbance was measured immediately at 570 nm. Both Mg2+ and Ca2+ measurements were performed using Precinorm U (Roche, Basel, Switzerland) as control.
The human carcinoma cell line Caco-2 (ATCC® HTB-37™, passage number 4–21) was maintained in Dulbecco’s Modified Eagle’s Medium with 25 mmol/L HEPES and 4.5 g/L glucose (DMEM, Lonza, Belgium), supplemented with 4 mmol/L l-Glutamine (Sigma-Aldrich, Saint Louis, USA), 5% (v/v) fetal bovine serum (FBS, HyClone, GE Healthcare Life Sciences, Illinois, USA), 1% (v/v) non-essential amino acids (Biowest, MO, USA), and 1% (v/v) Penicillin–Streptomycin (Gibco, New York, USA). Cells were maintained in a 37 °C incubator with 5% (v/v) CO2 and were cultured for 21 days or otherwise stated. Culture medium was changed every other day and cells were passed once a week when a confluency of approximately 80% was reached. Cells were seeded at a density of 0.5 × 105 cells per cm2. Human Embryonic Kidney cells (HEK293; ATCC®-1573™, passage number 11–18) were grown in DMEM supplemented with 10% (v/v) FBS, 10 µL/mL non-essential amino acids, and 2 mmol/L l-Glutamine.
The effect of Na-butyrate on Mg2+ binding was investigated using the cell-impermeant magnesium green pentapotassium salt (Life Technologies, Oregon, USA). 100 µmol/L stock solutions of magnesium green were prepared in MQ. The working buffer contained 2 µmol/L magnesium green dye, 115 mmol/L KCl, 20 mmol/L NaCl, 0.1 mmol/L EGTA and 10 mmol/L Tris–HCL, pH 7.2. Dye affinities for Mg2+ were first tested in the absence of Na-butyrate in the concentration range of 0–10 mmol/L MgCl2 yielding a Kd ~ 1.0 mmol/L (standard curve, data not shown). Subsequently, Na-butyrate, in the range of 0–20 mmol/L, was added to the working buffer (adjusted osmolarity with NaCl). Fluorescence was measured on a Tecan I-control Infinite200 pro (Thermo Fisher Scientific) at an absorption of 500 nm and an emission of 535 nm.
Mg2+ uptake by Caco-2 cells was determined using the stable 25Mg isotope (Cortecnet, Voisins Le Brettoneux, France). We used the non-radioactive stable isotope 25Mg (natural abundance 10%), which can be distinguished from 24Mg (natural abundance 80%) and 26Mg (natural abundance 10%). To this end, cells were depleted from Mg2+ and serum overnight. At the start of the experiment, cells were washed once with a pre-warmed basic uptake buffer (in mmol/L): 125 NaCl, 5.0 KCl, 0.5 CaCl2, 0.5 Na2HPO4, 0.5 Na2SO4, 15 HEPES, pH 7.5 adjusted with NaOH. Then, 500 µL of basic uptake buffer containing 1.0 mmol/L 25MgO was added to the cells. At each time point, cells were washed three times with ice-cold phosphate-buffered saline (PBS) and lysed in HNO3 (≥ 65%; Sigma-Aldrich, Steinheim, Germany) at 65 °C for 15 min. 25Mg2+ uptake by the cells was determined by inductively coupled plasma mass spectrometry (ICP-MS) analysis (Faculty of Science, Radboud University, Nijmegen). Calculations were performed based on the normalized ratio between 25Mg and total Mg (24Mg + 25Mg + 26Mg) (an increase of intracellular 25Mg will change the isotopic ratio compared to its normal abundance).
Caco-2 cells were pre-treated with 25 µmol/L BAPTA-AM (1,2-bis(o-aminophenoxy) ethane-N,N,Nʹ,Nʹ-tetraacetic acid acetoxymethyl ester) (Invitrogen, Eugene, USA) for 30 min at 37 °C. Then, cells were washed once with warm Krebs–Henseleit bicarbonate (KHB) buffer (in mmol/L): 110 NaCl, 5 KCl, 1.2 MgCl2, 0.1 CaCl2, 10 Na-acetate, 2 NaHPO4, and 20 HEPES, pH 7.4 (NaOH), followed by 10 min incubation with KHB buffer supplemented with inhibitors of voltage-gated calcium channels, 10 μmol/L felodipine and 10 μmol/L verapamil, and 1 μCi/mL 45Ca (lot: 17M431A, Perkin Elmer, MA, USA) at 37 °C. Subsequently, the assay was stopped by washing the cells three times with ice-cold KHB buffer supplemented with 0.5 mmol/L CaCl2 and 1.5 mmol/L LaCl3. Cells were harvested in 0.05% (v/v) SDS solution, mixed with Opti-Flour O (Perkin Elmer, MA, USA). 45Ca uptake was then quantified by a liquid scintillation counter (Hidex SL 600, Hidex).
Extracellular Acidification Rates (ECAR) and Oxygen Consumption Rate (OCR) were measured using the Seahorse XFe96 Extracellular Flux analyzer (Agilent Technologies, Texas, USA). Seahorse V3 culture plates were coated with 50 µg/mL fibronectin. Subsequently, Caco-2 cells were seeded at a density of 0.5 × 105 cells per cm2 and cultured for two days. Cells were serum starved overnight before the measurement. One hour before the run, cells were washed once with PBS, and incubated with Agilent Seahorse XF DMEM Medium pH 7.4 (103575-100; with 5 mmol/L HEPES, without phenol red and sodium pyruvate, Agilent Technologies, Texas, USA) supplemented with 10 mmol/L glucose at 37 °C, without CO2. After basal measurements, cells received an acute injection of 8 mmol/L Na-butyrate, Na-acetate or Na-propionate, followed by 2 μmol/L oligomycin A, and a mixture of 0.5 μmol/L rotenone and 0.5 μmol/L antimycin A. One measurement cycle consisted of 3 min incubation time and 3 min measurement time. OCR and ECAR values were normalized to total protein content. ATP production rates were calculated as described by White et al.51.
Cells were lysed in ice-cold lysis buffer containing (in mmol/L): 50 Tris–HCl, 1 EGTA, 1 EDTA, 10 sodium glycerophosphate, 1 sodium orthovanadate, 10 sodium fluoride, 10 sodium pyrophosphate, 270 sucrose, and 150 NaCl with 1% (v/v) Triton X-100 and a cocktail of the following protease inhibitors: PMSF (1 mmol/L), aprotinin (1 µg/mL), leupeptin (5 µg/mL), pepstatin (1 µg/mL). Protein concentrations were determined using Bradford according to the manufacturer’s protocol (Sigma Aldrich, St. Louis, MO, USA). Samples were denaturated in laemmli buffer containing 100 mmol/L dithiothreitol (DTT) for 30 min at 37 °C, subjected to SDS-PAGE (20 µg) and transferred to polyvinylidene (PVDF) membranes. Membranes were blocked in 5% (w/v) non-fat dry milk (NFDM) dissolved in 1 × Tris-buffered saline (TBS)-T (TBS with 0.1% (v/v) Tween-20) for 45–60 min at room temperature. Subsequently, membranes were immunoblotted overnight at 4 °C with primary antibody (rabbit pAMPKα (Thr172) (1:1000, Cell Signaling Technologies, Danvers, USA, #2535), rabbit AMPKα (1:1000, Cell Signaling Technologies, Danvers, USA, #5831), rabbit pS6K(Thr389) (1:1000, Cell Signaling Technologies, Danvers, USA, #2708), rabbit S6K (1:1000, Cell Signaling Technologies, Danvers, USA, #9234). Because these antibodies have been extensively characterized and are among the most widely-used in the field, membranes were cut prior to hybridisation with antibodies to save materials. This was performed in such a manner that the edges were approximately 20 kDa from the expected size of the protein of interest. The next day, the blots were washed three times in TBS-T to remove unbound primary antibody and incubated with horseradish peroxidase (HRP) conjugated secondary antibody (PO α-rabbit 1:10,000, Sigma Aldrich, St. Louis, MO, USA) for 1 h at room temperature. After washing three times with TBS-T, the proteins were visualized with chemiluminescent reagent (SuperSignal West femto/pico, Thermo Scientific, Waltham, USA) and processed with Bio-Rad Chemidoc XRS. Optimal exposure time was determined and applied to each blot specifically to prevent under- or overexposure. Band densities were quantified with densitometric analysis using Image J software (version 2.0).
HEK293 cells were transfected with 0.5 μg of mouse TRPM7 (HA-mTRPM7 pCINeo IRES GFP) plasmid and 0.5 μg of human TRPM6 (HA-hTRPM6 pCINeo IRES GFP) plasmid using Lipofectamine 2000 (Invitrogen) at 1:2 DNA:Lipofectamine ratio for 36–48 h. For single transfections, HEK293 cells were transfected with 1 μg of human TRPM6 (HA-hTRPM6 pCINeo IRES GFP) or 1 μg mouse TRPM7 (HA-mTRPM7 pCINeo IRES GFP) using Lipofectamine 2000 (Invitrogen) at 1:2 DNA:Lipofectamine ratio for 36–48 h. Prior to the start of the experiments, cells were seeded on glass coverslips coated with 50 μg/mL fibronectin (Roche, Mannheim, Germany). Cells were placed in the recording chamber at room temperature and selected based on the intensity of the fluorescent reporter (GFP). All experiments were undertaken and analysed using an EPC-10 amplifier and the Patchmaster software (HEKA ElectroniK GmbH, Lambrecht, Germany). The sampling interval was set to 200 ms and data was low-pass filtered at 2.9 kHz. Patch clamp pipettes were pulled from thin-walled borosilicate glass (Harvard Apparatus, March-Hugstetten, Germany) and had resistance between 1 and 3 MΩ when filled with the pipette solution containing 150 mmol/L NaCl, 10 mmol/L Na2EDTA, and 10 mmol/L HEPES, pH 7.3 adjusted with NaOH. The extracellular solution contained 150 mmol/L NaCl, 10 mmol/L HEPES and 1 mmol/L CaCl2, pH 7.4 adjusted with NaOH. 400 mmol/L stock solutions of Na-butyrate were prepared in MilliQ (MQ), with a final concentration of 8 mmol/L Na-butyrate in the pipette solution. Series resistance compensation was set to 75–95% in all experiments. From a holding potential of 0 mV, a linear 500 ms voltage ramp from − 100 to + 100 mV was applied every 2 s. Current densities were obtained by normalizing the current amplitude to the cell capacitance using Igor Pro software (Wavemetrics, Oregon, USA). Bar graphs show the current densities obtained at + 80 and − 80 mV 200 s after break in to the cell.
Results are presented as mean ± standard error of the mean (SEM). Unless otherwise indicated, comparisons between two groups were analyzed by unpaired Student’s t-test, after testing for normal distribution using the Shapiro–Wilk test. Due to the repeated measurement-nature of the Seahorse analyzer, these were specifically tested with a paired Student’s t-test. Comparisons of more than two groups were analyzed by One-Way ANOVA followed by Dunnett’s or Sidak’s post-hoc test to correct for multiple comparisons. Correlations analyses were performed using simple linear regression. GraphPad Prism (version 8) was used to perform the statistical analyses.
The raw data that support the findings of this study are available from the corresponding author upon reasonable request.
de Baaij, J. H., Hoenderop, J. G. & Bindels, R. J. Magnesium in man: Implications for health and disease. Physiol. Rev. 95, 1–46. https://doi.org/10.1152/physrev.00012.2014 (2015).
Article CAS PubMed Google Scholar
Chubanov, V. et al. Epithelial magnesium transport by TRPM6 is essential for prenatal development and adult survival. Elife https://doi.org/10.7554/eLife.20914 (2016).
Article PubMed PubMed Central Google Scholar
Ferioli, S. et al. TRPM6 and TRPM7 differentially contribute to the relief of heteromeric TRPM6/7 channels from inhibition by cytosolic Mg(2+) and Mg·ATP. Sci. Rep. 7, 8806. https://doi.org/10.1038/s41598-017-08144-1 (2017).
Article ADS CAS PubMed PubMed Central Google Scholar
de Baaij, J. H., Hoenderop, J. G. & Bindels, R. J. Regulation of magnesium balance: lessons learned from human genetic disease. Clin. Kidney J. 5, i15–i24. https://doi.org/10.1093/ndtplus/sfr164 (2012).
Article CAS PubMed PubMed Central Google Scholar
Dousdampanis, P., Trigka, K. & Fourtounas, C. Hypomagnesemia, chronic kidney disease and cardiovascular mortality: Pronounced association but unproven causation. Hemodial. Int. 18, 730–739. https://doi.org/10.1111/hdi.12159 (2014).
Article PubMed Google Scholar
Gommers, L. M., Hoenderop, J. G., Bindels, R. J. & de Baaij, J. H. Hypomagnesemia in type 2 diabetes: A vicious circle?. Diabetes 65, 3–13. https://doi.org/10.2337/db15-1028 (2016).
Article CAS PubMed Google Scholar
Ter Braake, A. D., Shanahan, C. M. & de Baaij, J. H. F. Magnesium counteracts vascular calcification: Passive interference or active modulation?. Arterioscler. Thromb. Vasc. Biol. 37, 1431–1445. https://doi.org/10.1161/atvbaha.117.309182 (2017).
Article PubMed Google Scholar
Coudray, C., Demigne, C. & Rayssiguier, Y. Effects of dietary fibers on magnesium absorption in animals and humans. J. Nutr. 133, 1–4. https://doi.org/10.1093/jn/133.1.1 (2003).
Article CAS PubMed Google Scholar
Hess, M. W. et al. Inulin significantly improves serum magnesium levels in proton pump inhibitor-induced hypomagnesaemia. Aliment. Pharmacol. Ther. 43, 1178–1185. https://doi.org/10.1111/apt.13619 (2016).
Article CAS PubMed Google Scholar
den Besten, G. et al. The role of short-chain fatty acids in the interplay between diet, gut microbiota, and host energy metabolism. J. Lipid Res. 54, 2325–2340. https://doi.org/10.1194/jlr.R036012 (2013).
Article CAS Google Scholar
Diether, N. E. & Willing, B. P. Microbial fermentation of dietary protein: An important factor in diet(-)microbe(-)host interaction. Microorganisms https://doi.org/10.3390/microorganisms7010019 (2019).
Article PubMed PubMed Central Google Scholar
Koh, A., De Vadder, F., Kovatcheva-Datchary, P. & Backhed, F. From dietary fiber to host physiology: Short-chain fatty acids as key bacterial metabolites. Cell 165, 1332–1345. https://doi.org/10.1016/j.cell.2016.05.041 (2016).
Article CAS PubMed Google Scholar
Kim, M. H., Kang, S. G., Park, J. H., Yanagisawa, M. & Kim, C. H. Short-chain fatty acids activate GPR41 and GPR43 on intestinal epithelial cells to promote inflammatory responses in mice. Gastroenterology 145, 396–406. https://doi.org/10.1053/j.gastro.2013.04.056 (2013).
Article CAS PubMed Google Scholar
Li, Z. et al. Butyrate reduces appetite and activates brown adipose tissue via the gut-brain neural circuit. Gut 67, 1269–1279. https://doi.org/10.1136/gutjnl-2017-314050 (2018).
Article CAS PubMed Google Scholar
Liu, H. et al. Butyrate: A double-edged sword for health?. Adv. Nutr. 9, 21–29. https://doi.org/10.1093/advances/nmx009 (2018).
Article CAS PubMed PubMed Central Google Scholar
Coudray, C. et al. Stimulatory effect of inulin on intestinal absorption of calcium and magnesium in rats is modulated by dietary calcium intakes short- and long-term balance studies. Eur. J. Nutr. 44, 293–302. https://doi.org/10.1007/s00394-004-0526-7 (2005).
Article CAS PubMed Google Scholar
Coudray, C., Tressol, J. C., Gueux, E. & Rayssiguier, Y. Effects of inulin-type fructans of different chain length and type of branching on intestinal absorption and balance of calcium and magnesium in rats. Eur. J. Nutr. 42, 91–98. https://doi.org/10.1007/s00394-003-0390-x (2003).
Article CAS PubMed Google Scholar
Gommers, L. M. M. et al. Low gut microbiota diversity and dietary magnesium intake are associated with the development of PPI-induced hypomagnesemia. FASEB J. 33, 11235–11246. https://doi.org/10.1096/fj.201900839R (2019).
Article CAS PubMed Google Scholar
Stein, J., Zores, M. & Schröder, O. Short-chain fatty acid (SCFA) uptake into Caco-2 cells by a pH-dependent and carrier mediated transport mechanism. Eur. J. Nutr. 39, 121–125. https://doi.org/10.1007/s003940070028 (2000).
Article CAS PubMed Google Scholar
Donohoe, D. R. et al. The microbiome and butyrate regulate energy metabolism and autophagy in the mammalian colon. Cell Metab. 13, 517–526 (2011).
Article CAS PubMed PubMed Central Google Scholar
Ahmad, M. S. et al. Butyrate and glucose metabolism by colonocytes in experimental colitis in mice. Gut 46, 493–499 (2000).
Article CAS PubMed PubMed Central Google Scholar
González, A., Hall, M. N., Lin, S. C. & Hardie, D. G. AMPK and TOR: The Yin and yang of cellular nutrient sensing and growth control. Cell Metab. 31, 472–492. https://doi.org/10.1016/j.cmet.2020.01.015 (2020).
Article CAS PubMed Google Scholar
Xu, J., Ji, J. & Yan, X. H. Cross-talk between AMPK and mTOR in regulating energy balance. Crit. Rev. Food Sci. Nutr. 52, 373–381. https://doi.org/10.1080/10408398.2010.500245 (2012).
Article CAS PubMed Google Scholar
Kim, J., Yang, G., Kim, Y., Kim, J. & Ha, J. AMPK activators: Mechanisms of action and physiological activities. Exp. Mol. Med. 48, e224 (2016).
Article CAS PubMed PubMed Central Google Scholar
Alexander, C., Swanson, K. S., Fahey, G. C. & Garleb, K. A. Perspective: Physiologic importance of short-chain fatty acids from nondigestible carbohydrate fermentation. Adv. Nutr. 10, 576–589. https://doi.org/10.1093/advances/nmz004 (2019).
Article PubMed PubMed Central Google Scholar
Parada Venegas, D. et al. Short chain fatty acids (SCFAs)-mediated gut epithelial and immune regulation and its relevance for inflammatory bowel diseases. Front. Immunol. 10, 277 (2019).
Article PubMed PubMed Central Google Scholar
Sivaprakasam, S., Bhutia, Y. D., Yang, S. & Ganapathy, V. Short-chain fatty acid transporters: Role in colonic homeostasis. Compr. Physiol. 8, 299–314. https://doi.org/10.1002/cphy.c170014 (2017).
Article PubMed PubMed Central Google Scholar
Elinder, F. & Liin, S. I. Actions and mechanisms of polyunsaturated fatty acids on voltage-gated ion channels. Front. Physiol. 8, 43 (2017).
Article PubMed PubMed Central Google Scholar
Bang, S., Yoo, S., Oh, U. & Hwang, S. W. Endogenous lipid-derived ligands for sensory TRP ion channels and their pain modulation. Arch. Pharm. Res. 33, 1509–1520. https://doi.org/10.1007/s12272-010-1004-9 (2010).
Article CAS PubMed Google Scholar
Ciardo, M. G. & Ferrer-Montiel, A. Lipids as central modulators of sensory TRP channels. Biochim. Biophys. Acta Biomembr. 1859, 1615–1628. https://doi.org/10.1016/j.bbamem.2017.04.012 (2017).
Article CAS PubMed Google Scholar
Zhang, H. et al. A mechanism underlying the effects of polyunsaturated fatty acids on breast cancer. Int. J. Mol. Med. 30, 487–494 (2012).
Article CAS PubMed PubMed Central Google Scholar
Andersson, D. A., Nash M Fau-Bevan, S. & Bevan, S. Modulation of the cold-activated channel TRPM8 by lysophospholipids and polyunsaturated fatty acids. J. Neurosci. 27, 3347–3355. https://doi.org/10.1523/JNEUROSCI.4846-06.2007 (2007).
Article CAS PubMed PubMed Central Google Scholar
Parnas, M., Peters, M. & Minke, B. Linoleic acid inhibits TRP channels with intrinsic voltage sensitivity: Implications on the mechanism of linoleic acid action. Channels 3, 164–166 (2009).
Article CAS PubMed Google Scholar
Matta, J. A., MiyaresRlFau-Ahern, G. P. & Ahern, G. P. TRPV1 is a novel target for omega-3 polyunsaturated fatty acids. J. Physiol. 578, 397–411 (2007).
Article CAS PubMed Google Scholar
Ordway, R. W., Singer JjFau-Walsh, J. V. Jr. & Walsh, J. V. Jr. Direct regulation of ion channels by fatty acids. Trends Neurosci. 14, 96–100 (1991).
Article CAS PubMed Google Scholar
Priyadarshini, M., Kotlo, K. U., Dudeja, P. K. & Layden, B. T. Role of short chain fatty acid receptors in intestinal physiology and pathophysiology. Compr. Physiol. 8, 1091–1115 (2018).
Article PubMed PubMed Central Google Scholar
Suzuki, S., Lis, A., Schmitz, C., Penner, R. & Fleig, A. The TRPM7 kinase limits receptor-induced calcium release by regulating heterotrimeric G-proteins. Cell Mol. Life Sci. 75, 3069–3078 (2018).
Article CAS PubMed PubMed Central Google Scholar
Zhelay, T. et al. Depletion of plasma membrane-associated phosphoinositides mimics inhibition of TRPM7 channels by cytosolic Mg(2+), spermine, and pH. J. Biol. Chem. 293, 18151–18167 (2018).
Article CAS PubMed PubMed Central Google Scholar
Runnels, L. W., Yue, L. & Clapham, D. E. The TRPM7 channel is inactivated by PIP(2) hydrolysis. Nat. Cell Biol. 4, 329–336. https://doi.org/10.1038/ncb781 (2002).
Article CAS PubMed Google Scholar
Cao, G. et al. RACK1 inhibits TRPM6 activity via phosphorylation of the fused alpha-kinase domain. Curr. Biol. 18, 168–176. https://doi.org/10.1016/j.cub.2007.12.058 (2008).
Article CAS PubMed Google Scholar
Bouras, H. et al. Metformin regulates TRPM6, a potential explanation for magnesium imbalance in type 2 diabetes patients. Can. J. Physiol. Pharmacol. 98, 400–411. https://doi.org/10.1139/cjpp-2019-0570 (2020).
Article CAS PubMed Google Scholar
Leonhard-Marek, S., Gabel, G. & Martens, H. Effects of short chain fatty acids and carbon dioxide on magnesium transport across sheep rumen epithelium. Exp. Physiol. 83, 155–164. https://doi.org/10.1113/expphysiol.1998.sp004098 (1998).
Article CAS PubMed Google Scholar
Cantu-Jungles, T. M. & Hamaker, B. R. New view on dietary fiber selection for predictable shifts in gut microbiota. MBio 11, 20 (2020).
Google Scholar
Makki, K., Deehan, E. C., Walter, J. & Bäckhed, F. The impact of dietary fiber on gut microbiota in host health and disease. Cell Host Microbe 23, 705–715. https://doi.org/10.1016/j.chom.2018.05.012 (2018).
Article CAS PubMed Google Scholar
Tahara, Y. et al. Gut microbiota-derived short chain fatty acids induce circadian clock entrainment in mouse peripheral tissue. Sci. Rep. 8, 1395 (2018).
Article ADS PubMed PubMed Central Google Scholar
Segers, A. et al. The circadian clock regulates the diurnal levels of microbial short-chain fatty acids and their rhythmic effects on colon contractility in mice. Acta Physiol. 225, e13193. https://doi.org/10.1111/apha.13193 (2019).
Article CAS Google Scholar
Lameris, A. L. et al. Segmental transport of Ca2+ and Mg2+ along the gastrointestinal tract. Am. J. Physiol. Gastrointest. Liver Physiol. 308, G206-216. https://doi.org/10.1152/ajpgi.00093.2014 (2015).
Article CAS PubMed Google Scholar
Rios-Covian, D., Gueimonde, M., Duncan, S. H., Flint, H. J. & de les Reyes-Gavilan, C. G. Enhanced butyrate formation by cross-feeding between Faecalibacterium prausnitzii and Bifidobacterium adolescentis. FEMS Microbiol. Lett. 362, 176. https://doi.org/10.1093/femsle/fnv176 (2015).
Article CAS Google Scholar
Gommers, L. M. M. et al. Colonic expression of calcium transporter TRPV6 is regulated by dietary sodium butyrate. Pflugers Arch. 474, 293–302. https://doi.org/10.1007/s00424-021-02648-6 (2022).
Article CAS PubMed Google Scholar
Dirks, N. F. et al. Determination of human reference values for serum total 1,25-dihydroxyvitamin D using an extensively validated 2D ID-UPLC-MS/MS method. J. Steroid Biochem. Mol. Biol. 164, 127–133 (2016).
Article CAS PubMed Google Scholar
Romero, N., Rogers, G., Neilson, A. & Dranka, B. P. Quantifying Cellular ATP Production Rate Using Agilent Seahorse XF Technology (Agilent Technologies, 2018).
Google Scholar
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We thank Desirée Bos from the department of Radiology and Nuclear Medicine, Radboud university medical center, Nijmegen, the Netherlands and Daan Panneman from the department of Translational Metabolic Laboratory, Radboud university medical center, Nijmegen, the Netherlands for their technical assistance with the magnesium green experiments and Seahorse measurements. This work was supported by grants from the Netherlands Organization for Scientific Research (J. Hoenderop, NWO VICI 016.130.668 and J. de Baaij, NWO VENI 016.186.012).
These authors contributed equally: Jeroen H. F. de Baaij and Joost G. J. Hoenderop.
Department of Physiology, Radboud Institute for Molecular Life Sciences (RIMLS), Radboud University Medical Center (Radboudumc), P.O. Box 9101, 6500 HB, Nijmegen, The Netherlands
Lisanne M. M. Gommers, Pieter A. Leermakers, Jenny van der Wijst, Sara R. Roig, Anastasia Adella, Melissa A. E. van de Wal, René J. M. Bindels, Jeroen H. F. de Baaij & Joost G. J. Hoenderop
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L.M.M.G., J.v.d.W., J.H.F.d.B. and J.G.J.H. designed research; L.M.M.G., J.v.d.W., S.R.R., P.A.L., R.J.M.B., J.H.F.d.B. and J.G.J.H. analyzed and interpreted data; L.M.M.G., J.v.d.W., S.R.R., M.v.d.W. and A.A. performed research; L.M.M.G., J.v.d.W., P.A.L., J.H.F.d.B. and J.G.J.H. wrote the paper; All authors had access to the study data and reviewed and approved the final manuscript.
Correspondence to Joost G. J. Hoenderop.
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Gommers, L.M.M., Leermakers, P.A., van der Wijst, J. et al. Butyrate reduces cellular magnesium absorption independently of metabolic regulation in Caco-2 human colon cells. Sci Rep 12, 18551 (2022). https://doi.org/10.1038/s41598-022-21683-6
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DOI: https://doi.org/10.1038/s41598-022-21683-6
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