Abstract
The ketogenic diet is an emerging therapeutic approach for refractory epilepsy, as well as certain rare and neurodegenerative disorders. The main ketone body, β-hydroxybutyrate (BHB), is the primary energy substrate endogenously produced in a ketogenic diet, however, mechanisms of its therapeutic actions remain unknown. Here, we studied the effects of BHB on mitochondrial energetics, both in non-stimulated conditions and during glutamate-mediated hyperexcitation. We found that glutamate-induced hyperexcitation stimulated mitochondrial respiration in cultured cortical neurons, and that this response was greater in cultures supplemented with BHB than with glucose. BHB enabled a stronger and more sustained maximal uncoupled respiration, indicating that BHB enables neurons to respond more efficiently to increased energy demands such as induced during hyperexcitation. We found that cytosolic Ca2+ was required for BHB-mediated enhancement of mitochondrial function, and that this enhancement was independent of the mitochondrial glutamate-aspartate carrier, Aralar/AGC1. Our results suggest that BHB exerts its protective effects against hyperexcitation by enhancing mitochondrial function through a Ca2+-dependent, but Aralar/AGC1-independent stimulation of mitochondrial respiration.
Similar content being viewed by others
Introduction
Up to 65% of individuals with epilepsy will have their seizures controlled with antiepileptic drugs or enter spontaneous remission during their lifetime1. However, this leaves a large percentage of patients who are refractory to drug therapy2. Ketogenic diet (KD) has been shown to be beneficial for the treatment of refractory epilepsy3,4,5,6. This therapeutic approach has also been proposed for the treatment of other neurological diseases such as Alzheimer’s disease7, amyotrophic lateral sclerosis8, Huntington’s disease9, autism10, Parkinson’s disease11 and ARALAR/AGC1 deficiency12. Many clinical studies have confirmed the beneficial effect of a KD, however, the mechanisms13 through which a KD confers its seizure-reducing, protective effects remain unknown.
KD has a high fat content (80–90%), with little but sufficient protein and a drastic reduction in carbohydrate content. The KD is mainly composed of triglycerides. Long-chain fatty acids (LCFA) and medium-chain fatty acids (MCFA), which are metabolised mainly in the liver, give rise to ketone bodies (acetone, acetoacetate and 3-beta-hydroxybutyrate). 3-beta-hydroxybutyrate (BHB) is the most abundant ketone body in mammals14. Emerging evidence shows that BHB is not only a passive carrier of energy but also has a variety of signalling functions, both at an intracellular and cell surface level, that can affect gene expression, lipid metabolism, neuronal function, and metabolic rate14.
A prime function of mitochondria is to reduce oxygen to water during oxidative phosphorylation (OXPHOS) in order to produce energy. In excitable cells like neurons, calcium (Ca2+) regulates this process15,16,17. ARALAR/AGC1, the regulatory component of the malate–aspartate NADH shuttle (MAS), operates in neurons18, is activated by cytosolic Ca2+ within the nanomolar range18,19,20,21 and is essential for OXPHOS regulation by Ca2+22,23,24. The aim of this study was to investigate the mechanisms underlying the bioenergetic effects of BHB in neurons cultured in physiological oxygen conditions (5%), and to explore the protective effects of BHB during glutamate-induced Ca2+ signalling, and its dependence on Aralar/AGC1 activity.
Material and methods
Materials and reagents
Fetal bovine serum (FBS), horse serum (HS), B27 supplement, minimal essential medium (MEM), Neurobasal medium, Neurobasal medium-A, Opti-MEM medium, Lipofectamine 3000, tetramethylrhodamine methyl ester (TMRM), Fluo-4 AM, and 1,2-bis-(o-aminophenoxy)-ethane-N,N,N′,N′-tetraacetic acid, tetraacetoxymethyl ester (BAPTA-AM) were from Invitrogen (Bio Sciences). D-glucose, (±)-Sodium 3-hydroxybutyrate (BHB), L-Glutamic acid monosodium salt monohydrate (Glu), poly-D-lysine hydrobromide and cytosine arabinofuranoside (Ara-C) were from Sigma-Aldrich (Dublin, Ireland). Aminooxy acetic acid, hemihydrochloride (AOAA) were from Calbiochem. Seahorse XFe96 sensor cartridges, microplates, calibrant and DMEM medium were from Agilent. Bioenergetics reagents: oligomycin (Oli), Carbonyl cyanide-4-(trifluoromethoxy)phenylhydrazone (FCCP), antimycin (A) and rotenone (R) were from Sigma-Aldrich (Dublin, Ireland).
Neuronal cell culture
Primary cultures of cortical or hippocampal neurons were prepared at embryonic day 16–18, as described previously25. First, the pregnant female C57BL/6 J wild‐type mice, embryonic gestation day 16–19 (E16-E18) were sacrificed by cervical dislocation and a hysterectomy of the uterus was performed. Rapid decapitation of the 5–6 embryos was carried out and the cerebral cortices and/or hippocampi were isolated and pooled in a dissection buffer on ice (1 × PBS with 0.25% glucose and 0.3% BSA). All animal work was performed with ethics approval (REC202002001) and under licenses granted by the Health Products Regulatory Authority in accordance with European Communities Council Directive (86/609/EEC), and procedures were reviewed and approved by the RCSI Research Ethics Committee. For the data presented in this study a total of 24 animals were required. All methods were carried out in accordance with relevant guidelines and regulations. The study is reported in accordance with ARRIVE guidelines. Then the tissue was incubated with 0.25% trypsin–EDTA at 37 °C for 15 min. After the incubation period, the trypsinisation was ceased by the addition of plating media (PM). The PM is comprised of MEM with 5% FBS, 5% HS, 100 U mL−1 penicillin/streptomycin, 0.5 mM L-glutamine and 0.45% (w/v) D-glucose. The neurons were gently dissociated using a Pasteur pipette and after centrifugation at 1500 rpm for 3 min, the medium containing trypsin was aspirated. The remaining cell pellet was re-suspended in fresh PM, seeded on poly-D-lysine-coated plates (final concentration of 50 μg/mL or 10 μg/mL on glass or plastic surface, respectively) and then incubated at 37 °C and 5% CO2 in ambient O2. Plating neuronal density varied from 1.2 to 1.5 × 106 cells per sterile WillCo dish (WillCo Wells B.V.) of 35 mm diameter and 5.0 × 104 cells/well in Seahorse XF96 well plates. After 24 h, PM was exchanged with 50% feeding medium (Neurobasal containing 100 U mL−1 penicillin/streptomycin, 2% B27, and 2 mM L-glutamine) and 50% fresh PM, with addition of the mitotic inhibitor, cytosine arabinofuranoside (Ara-C) (480–500 nM). At this point, cells used to study the effect of physiological O2 concentration were transferred to a BioSpherix Xvivo × 3 hypoxia chamber at 37 °C and 5% CO2 in 5% O2, while matched cell cultures were placed in a standard incubator at 37ºC, 5% CO2 and ambient O2 as a control. At days in vitro (DIV) 2, the medium was exchanged for complete feeding medium and experiments were performed on cultures at 9–11 DIV.
Measurement of cellular oxygen consumption
Cellular oxygen consumption rate (OCR) and Extracellular Acidification rate (ECAR) were measured using a Seahorse XFe96 Extracellular Flux Analyzer (Seahorse Bioscience26) as previously described16. Primary cortical neurons were plated in XFe96 cell culture plates and maintained for 9–11 DIV at 37 °C, 5% CO2 and either in ambient (21%) or in 5% O2.
Prior to experimentation, the cells were equilibrated with XF Base Medium, bicarbonate-free DMEM-based medium (without pyruvate, lactate, glucose or glutamine) supplemented with L-lysine (0.136 mM) and L-arginine (0.574 mM) and pH 7.4, for 1 h. After baseline measurements, cells were either stimulated with glucose (15 mM or 2.5 mM, gluc) or with 3-beta hydroxybutyrate (5 mM, BHB) as solo substrates or in combination with glutamate (100 μM).
Substrates and glutamate, prepared in the same medium in which the experiment was conducted, were automatically injected from the first port, A, to the wells at the times indicated. Calibration of the respiration took place after the injection from port A. Mitochondrial function in neurons was determined through sequential addition of 3 μM oligomycin (Oli), 0.5 μM Carbonyl cyanide-4-(trifluoromethoxy)phenylhydrazone (FCCP), and 1 μM antimycin A / 1 μM rotenone (A/R). This allowed the determination of basal oxygen consumption, oxygen consumption linked to ATP synthesis (ATP), non-ATP linked oxygen consumption (proton leak), mitochondrial uncoupled respiration (MUR), and non-mitochondrial oxygen consumption (NM)26,27,28. Basal respiration was calculated by subtracting non-mitochondrial respiration from OCR after the initial stabilization (third measurement), and was considered 100%. Glycolytic capacity was measured as the ECAR rate reached by a given cell after the addition of the substrate with or without glutamate stimulation. Basal acidification state was considered as 100% and calculated after ECAR stabilization (third measurement).
BAPTA-AM (50 μM) was loaded into the cells using Ca2+-free Krebs buffer (140 mM NaCl, 5.9 mM KCl, 1.2 mM MgCl2, 15 mM HEPES, with 15 mM glucose and 1% B27) for 60 min. Afterwards, the cells were washed and equilibrated in experimental XF Base Medium (with no carbon sources and 1.8 mM CaCl2) for 15 min before starting the experiment.
Cortical neurons were treated with 0.5 mM aminooxyacetic acid (AOAA) for 1 h in feeding medium prior to experimentation. Afterwards, the cells were washed and equilibrated in experimental XF Base Medium (with no carbon sources and 1.8 mM CaCl2) for 15 min before starting the experiment. It is important to note that, in spite of the fact that neurons were grown at 5% O2 for 9–10 days, the bioenergetic experiments were performed in ambient conditions since the Seahorse XFe96 Extracellular Flux Analyzer could not be placed inside the BioSpherix Xvivo × 3 hypoxia chamber.
Imaging of spontaneous cytosolic calcium oscillations in primary hippocampal neurons
At DIV 9–10, primary hippocampal neurons were loaded with Fluo-4 AM (6 μM) in fresh pre-warmed Krebs buffer (140 mM NaCl, 5.9 mM KCl, 1.2 mM MgCl2, 15 mM HEPES and 2.5 mM CaCl2, with 15 mM glucose or 5 mM BHB, pH 7.4), for 30 min. Neurons were then washed in fresh, pre-warmed buffer and placed on the stage of an LSM 5 Live confocal microscope in a thermostatically-regulated stage incubator set at 37 °C, 5% CO2 and an O2 concentration controller set to concentrations as indicated (Carl Zeiss and Pecon, both Germany). Single-cell imaging was performed using a 40 × , 1.3 NA oil-immersion objective (Carl Zeiss) run with ZEN software (Carl Zeiss, UK).
Fluo-4 was excited at 488 nm and the emission was collected through a 505–550 nm barrier filter. All microscope settings including laser intensity, scan time and image rate (300 frames/min) were kept constant for the whole set of experiments. After 2 min baseline recording of spontaneous neuronal activity (600 cycles), the buffer was exchanged for pre-warmed magnesium-free Krebs buffer (140 mM NaCl, 5.9 mM KCl, 15 mM HEPES and 2.5 mM CaCl2) with the corresponding substrate (15 mM glucose or 5 mM BHB) and equilibrated with the previously used O2 concentration. Then, the cells were imaged for a further 2 min (cycle 600–1200), before bolus addition of MgCl2 (1.2 mM final concentration) and recording for another two minutes. All images were processed and analysed using ImageJ 1.51 k Software (Wayne Rasband, NIH, USA). The single cell, intracellular Fluo-4 kinetics were analysed for spike frequency, total number of spikes and area under the curve. All single cell kinetics presented are normalized to their respective baseline values.
Imaging of cytosolic calcium and mitochondrial membrane potential
Primary cortical neurons were loaded with Fluo-4 AM (6 μM) for 30 min in feeding medium. The neurons were then washed in fresh pre-warmed experimental Krebs buffer (as above) and subsequently incubated with TMRM (10 nM) in experimental Krebs buffer for 30 min prior to experimentation. The cortical neurons were placed on the stage of an LSM 710 confocal microscope equipped with a 40 × , 1.3 NA oil-immersion objective, a thermostatically regulated chamber set at 37 °C, 5% CO2, and an O2 concentration controller (Carl Zeiss and Pecon). TMRM was excited at 561 nm, and emission was detected in the range of 562—710 nm. Fluo-4 was excited at 488 nm, and the emission was detected in the range of 489–552 nm. All microscope settings including laser intensity and scan time were kept constant for the whole set of experiments, taking images every 60 s. After a baseline equilibration time, glutamate (100 μM final concentration) was added to the medium. All images were processed and analyzed using ImageJ 1.51 k Software, and the data presented were normalized to the baseline.
Statistical analysis
Data are given as means ± SEM. Data were analysed using one-way ANOVA, followed by Tukey's post hoc test or Student's t test for two-group comparison. p values < 0.05 were considered to be statistically significant. All statistical analyses were performed using GraphPad Prism 5.
Results
BHB reduces spontaneous neuronal activity in neurons cultured in physiological oxygen levels
We started our investigation by comparing neuronal Ca2+ signalling in primary neuron cultures maintained either at physiological O2 (5%) or ambient O2 (21%). Cytosolic Ca2+ oscillations are important characteristics of intact neuronal and network activity (see review written by Kar et al.29). We studied spontaneous Ca2+ oscillations at physiological and atmospheric O2 levels in Fluo-4 loaded primary hippocampal neurons in live time-course experiments and maintained in glucose. After 9–10 days of culture, axons and dendrites of the hippocampal neurons had developed into a sparse network that primarily formed an in vitro neural network. The hippocampal neurons were randomly selected for cytoplasmic Ca2+ analysis and the number of Ca2+ peaks and normalised fluorescence intensity were calculated. We observed typical Ca2+ oscillations in neurons cultured in both 21% and 5% O2 concentrations, and a similar normalized F/F0 Fluo-4 fluorescence intensity at baseline (Fig. 1A,C,E,G). The increase in fluorescence intensity after removal of Mg2+ from the media (MgCl2 free), which precludes Mg2+ ions from binding NMDA receptor pores thus facilitating intracellular Ca2+ entry, was significantly higher in neurons at physiological O2 concentration (Fig. 1B, Table 1) but not in BHB (Fig. 1F). Fluo-4 fluorescence recovered after Mg2+ re-addition both in ambient and in 5% O2 (Fig. 1A,C,E,G). The frequency in spontaneous synchronous cytosolic Ca2+ oscillations was determined by automatically counting cytosolic Ca2+ peaks (Fig. 1D,H)30,31. Interestingly, this revealed a significantly reduced basal frequency in neurons cultured in 5% O2 (22.13 ± 1.36 vs. 14.18 ± 0.99, p = 3.81 × 10−6) and a higher frequency during Mg2+ withdrawal (28.45 ± 1.41 vs. 33.95 ± 1.42, p = 0.0063) (Fig. 1D).
Interestingly, in the presence of BHB, the OCR involved in ATP synthesis was significantly higher in cortical neurons grown in physiological O2 than in ambient conditions (63.11 ± 4.11% vs. 73.48 ± 2.80% in 5 mM BHB at ambient and 5% O2 respectively, p = 0.046, Fig. 2I). This was also similar to that observed in the presence of glucose as substrate (Fig. 2G,H). The mitochondrial respiratory control ratio was defined as state 3 respiration during highest ATP consumption divided by state 4 respiration with ATP synthase inhibited by Oligomycin27. This is calculated as the ratio of the respiration supporting ATP synthesis (OXPHOS, defined by the difference induced through inhibition of ATP synthase with Oligomycin, μATP) to the respiration ‘wasted’ to offset the proton leak (proton H+ leak) defined with baseline consumption subtracted by the remaining OCR after block of the respiratory chain with Antimycin and Rotenone. In cortical neurons the mitochondrial respiratory control ratio was lower (p = 0.0103, Table 2) in 5 mM BHB at ambient and 5% O2 respectively (Table 2), indicating highly coupled and efficient mitochondria in physiological conditions. Moreover, the MUR was significantly enhanced at physiological O2 concentration in unchallenged neurons in 5 mM BHB (Fig. 2K), which suggests an increased intrinsic respiratory capacity at 5% O2 using BHB as substrate.
Effect of BHB on glutamate-induced Ca2+ overloading
Having shown that in neurons using 2.5 mM or 15 mM glucose or 5 mM BHB, basal respiration was not limited by substrate supply, we next studied the control of respiration by agents able to increase neuronal workload at physiological O2 concentration. Oxygen consumption is controlled by the mitochondrial proton electrochemical gradient (∆μH+32). In most cell types, ∆μH+ is mainly used in ATP synthesis. Increases in cell workload will consume ATP and lead to increased ATP production in mitochondria, through the utilization of ∆μH+, which is expected to increase OCR. In particular, we studied the effects of glutamate-induced workload increase.
Glutamate (Glu) is the main excitatory neurotransmitter of the central nervous system. In the presence of 15 mM glucose, glutamate addition induced a pronounced and sustained increase in cytosolic Ca2+ in neurons cultured in 21% O2, which was reduced in neurons cultured in physiological O2 (black dashed lines) (Fig. 3A). NMDA receptor activation induced early mitochondrial depolarization, shown by a decrease in tetramethylrhodamine methyl ester (TMRM) fluorescence (Fig. 3A), as previously described33. Interestingly, the lower cytosolic Ca2+ levels observed at 5% O2 were associated with a more pronounced decrease in mitochondrial membrane potential, which might reflect increased mitochondrial Ca2+ buffering capacity (Fig. 3A,C,D,E).
Similar effects were observed in the presence of BHB (Fig. 3B,F,G,H), although the glutamate-mediated peak in cytosolic Ca2+ in ambient conditions was significantly higher than that observed in neurons using glucose (578.64 ± 9.08 vs. 721.86 ± 14.39 normalized F/F0 fluorescence, with 15 mM glucose or 5 mM BHB in 21% O2 respectively, p = 1.135 × 10−5, Fig. 3C,F). Interestingly however, an even stronger attenuation of the cytosolic Fluo-4 fluorescence was registered at physiological O2 concentration in the presence of BHB (Fig. 3B,F) compared to glucose (Fig. 3A,C) (517.19 ± 10.47 vs. 438.95 ± 10.42 normalized F/F0 fluorescence, with 15 mM glucose or 5 mM BHB at 5% O2 respectively, p = 0.025).
BHB increases glutamate-mediated stimulation of respiration and mitochondrial ATP production, and preserves maximal respiratory capacity
As dictated by the principles of chemiosmotic coupling, changes in workload after glutamate stimulation promoted increased mitochondrial ATP production (Fig. 2G–I) coupled to increased O2 consumption by the respiratory chain and increased substrate supply to mitochondria (Fig. 2A–C). The magnitude of the glutamate-mediated stimulation of OCR (Fig. 2J) was similar in neuronal cultures grown in ambient and at 5% O2, using 15 mM or 2.5 mM glucose. Interestingly, BHB was a more effective substrate, allowing significantly higher stimulation of mitochondrial respiration regardless of the O2 concentration in which primary neurons had grown (Fig. 2J).
Moreover, the measure of mitochondrial efficiency, the respiratory control ratio, was higher after glutamate stimulation than in control unchallenged conditions for all substrates and O2 conditions (Fig. 2G–I, Table 2). Importantly, the respiratory control ratio after glutamate injection was significantly larger in neurons cultured in 5% O2, showing a higher capability to increase ATP production compared to neurons cultured in ambient conditions, only in the presence of BHB ( p = 0.0315, Fig. 2I, Table 2).
Interestingly, the inability of mitochondria to sustain glutamate-stimulated respiration in neurons cultured in ambient O2, reflected by the large decrease in maximal uncoupled respiration (MUR) regardless of the substrate present, strikingly contrasted with the effect observed at physiological O2 levels (Fig. 2K). At 5% O2 MUR was significantly preserved (Fig. 2K, Table 2). Thus, neurons grown at physiological O2 concentration might be protected from mitochondrial dysfunction induced by glutamate stimulation.
The glutamate-induced increase in workload promoted an increase in mitochondrial respiration and a limited rise in the glycolytic flux (Fig. 2D–F). Moreover, the glutamate-mediated stimulation of glycolysis was jeopardized at physiological O2 concentration, reaching lower values compared to ambient condition in the presence of either glucose or BHB as substrates (Fig. 2L).
BHB’s effect on mitochondrial responses to glutamate stimulation is Aralar-MAS independent
We next studied the influence of Aralar/AGC1, the regulatory component of the malate-aspartate NADH shuttle (MAS), on glutamate excitotoxicity. We determined the effects of aminooxyacetic acid (0.5 mM AOAA), the inhibitor of aspartate aminotransferase (AST) which is a widely used inhibitor of the MAS34, on primary cortical neurons grown in 5% O2 (Fig. 4A–L) and in ambient conditions (Supplementary Fig. 1), with glucose or BHB as substrates. We found that the glutamate-induced increase in OCR observed with glucose as substrate was completely abolished by AOAA (Fig. 4A,B,J) indicating that Aralar-MAS has an essential role in this response. Interestingly, AOAA incubation did not abolish the glutamate-induced increase in respiration in neurons with BHB as substrate (Fig. 4C,J).
The Aralar-MAS transfers the reducing equivalents of cytosolic NADH into mitochondria, thus increasing mitochondrial ATP production35,36. Consistently, an increase in the glycolytic flux was observed in neurons cultured in 5% O2 and treated with AOAA in the presence of glucose, potentially indicating a compensatory mechanism to overcome the inefficient respiration upon glutamate stimulation to match the increased ATP demand (Fig. 4D,E,L). Interestingly, this significant increase in glycolysis was also observed in neurons treated with AOAA in the presence of BHB (Fig. 4F,L), although these neurons were able to promote an Aralar-independent stimulation of OXPHOS (Fig. 4F,L). Moreover, the described effects on glycolysis were only observed in neurons cultured at 5% O2, but not in cortical neurons grown in ambient conditions, in which the glutamate-mediated stimulation of glycolysis was not observed (see Supplementary Fig. 1D–F,L).
AOAA treatment compromises NADH supply to the respiratory chain, and this led to a reduction in mitochondrial efficiency particularly observed with glucose, determined by the decrease of the O2 consumption linked to ATP synthesis and an increase in proton leak compared to control (Fig. 4G–H). Thus, the mitochondrial respiratory control ratio (ATP synthesis/proton leak) in neurons with 15 mM glucose was: control 4.38 ± 0.17 versus glutamate + AOAA 3.34 ± 0.25 (p = 0.005), and in neurons with 2.5 mM glucose was: control 3.88 ± 0.33 versus glutamate + AOAA 2.49 ± 0.23 (p = 0.002, Table 2). Maximal uncoupled respiration (MUR) was also substantially affected by AOAA in neurons using glucose as a substrate, reaching even lower values compared to glutamate stimulation in the absence of AOAA (Fig. 4K). Neurons using 15 mM glucose exhibited MUR values of: with glutamate 56.27 ± 3.50% versus glutamate + AOAA 46.29 ± 2.28% (p = 0.025); and in the presence of 2.5 mM glucose MUR values were: with glutamate 53.99 ± 5.22% versus glutamate + AOAA 33.84 ± 3.76% (p = 0.004, Table 2).
No significant effects in the respiratory control ratio (control 3.41 ± 0.31 vs. glutamate + AOAA 3.53 ± 0.22, p = 0.760) or in MUR (with glutamate 63.28 ± 6.31% vs. glutamate + AOAA 50.37 ± 5.81%, p = 0.140) were found in the presence of BHB (Fig. 4I,K, Table 2). Taken together, these data suggest that, contrary to what was observed with glucose, BHB modulates mitochondrial respiration independently of Aralar-MAS activity in physiological O2 conditions.
BHB effect on mitochondrial function upon glutamate stimulation relies on cytosolic calcium signalling
Glutamate-mediated NMDA receptor activation causes Na+ and Ca2+ entry into the neuronal cytosol, which induces the activation of plasma membrane and endoplasmic reticulum ATPase pumps to restore the intracellular ionic balance while consuming a vast amount of ATP37. BAPTA-AM is a rapid intracellular Ca2+-chelator38. To investigate whether cytosolic Ca2+ signalling may mediate BHB effects on mitochondrial function during glutamate stimulation, primary cortical neurons were incubated with BAPTA-AM and then challenged with glutamate.
In BAPTA-AM loaded neurons, glutamate-mediated Ca2+ signals in the cytosol were significantly reduced both at 5% and 21% O2 concentrations using glucose (Fig. 5A–D) or BHB (Fig. 5E–H) as substrates, without affecting basal respiration (not shown). With glucose as the substrate, glutamate–induced stimulation of OCR was severely decreased by BAPTA incubation in neurons cultured at either 5% or 21% O2 (Fig. 6A,B,D,E), while the glutamate-mediated decrease in MUR was unaffected by BAPTA-AM incubation (Fig. 6C,F). These results indicated that Ca2+-signalling is required for the glutamate-induced stimulation of respiration in neurons utilising glucose as substrate, and that the O2 concentration in which neurons are grown does not modulate this effect.
Interestingly, BAPTA-AM reduced, but did not eliminate, glutamate-mediated stimulation of OCR (glutamate 45.44 ± 3.75% vs. glutamate + BAPTA 24.69 ± 2.43%, p = 3.00 × 10−5) in neurons grown in ambient O2 and with BHB as substrate (Fig. 7A,B). This BAPTA-mediated effect was stronger in neurons grown at physiological O2 concentration, however, with a decrease in glutamate-induced stimulation up to 78.98% (with 5 mM BHB: glutamate 47.67 ± 6.49% vs. glutamate + BAPTA 10.02 ± 4.72%, p = 1.20 × 10−4 Fig. 7D,E) reaching levels comparable to OCR in control conditions (9.36 ± 1.53% at 5% O2). Moreover, MUR in BAPTA-AM preloaded neurons was preserved even after glutamate stimulation at 5% O2 (Fig. 7F), but not in ambient conditions (Fig. 7C), reaching levels similar to control with BHB.
These results suggest that primary cortical neurons rely on cytosolic Ca2+ signalling to induce glutamate-mediated OCR stimulation in the presence of glucose. However, with BHB as substrate, this cytosolic Ca2+ signalling pathway is only partially involved in the regulation of mitochondrial respiration in ambient conditions, and it is completely absent at 5% O2.
BHB-mediated intracellular stored calcium mobilization upon glutamate is significantly reduced in cultures maintained in physiological oxygen concentration
Finally, we studied the source of Ca2+ which contributed to the glutamate-mediated increase in cytosolic Ca2+. Cytosolic Ca2+ levels were measured in neurons loaded with the fluorescent probe Fluo-4 in four different conditions in ambient (Fig. 8A) or at physiological O2 concentration (Fig. 8B): (i) 5 mM BHB with 100 μM glutamate in the presence of 2.5 mM CaCl2 (Glu + BHB, black traces), (ii) 5 mM BHB without glutamate in the presence of 2.5 mM CaCl2 (BHB, green traces), (iii) 5 mM BHB without glutamate in the absence of CaCl2 plus 100 μM EGTA (BHB, red dashed traces) and (iv) 15 mM glucose without glutamate in the absence of CaCl2 plus 100 μM EGTA (Gluc, blue dashed traces) used as negative control.
Lower cytosolic Fluo-4 fluorescence peaks (normalised F/F0) were registered at 5% O2 (Fig. 8C) compared to ambient O2 (Fig. 8D), as previously observed in an independent set of experiments (Fig. 5). Interestingly, we observed that BHB by itself stimulated an increase in cytosolic Ca2+ (green trace, Fig. 8A,B). Considering the first condition, Glu + BHB, as the reference value we calculated the percentage of cytosolic Ca2+ mobilized only by BHB in the presence of extracellular Ca2+. Thus, no statistical differences were found in BHB-mediated increase in cytosolic Ca2+ (in 21% O2 32.15 ± 1.87% vs. 5% O2 36.90 ± 3.53%, p = 0.237, graphical insert in C and in D in green).
Moreover, to analyse the source of Ca2+ in the BHB-mediated mobilization process we utilized media with 2.5 mM CaCl2 or Ca2+-free media in the presence of EGTA (100 μM), and the second condition (BHB in green) was used as the reference value to calculate the next percentages. We identified a significantly reduced contribution of Ca2+ from intracellular stores to promote the cytosolic Ca2+ rise in physiological O2 concentration (in 21% O2 63.52 ± 3.02% vs. 5% O2 48.26 ± 6.80%, p = 0.042). These results indicate that in our experimental conditions BHB-mediated intracellular stored Ca2+ mobilization upon glutamate was significantly reduced at physiological O2 concentration, a Ca2+ signalling mechanism apparently essential to promote mitochondrial respiration.
Discussion
We here addressed how β-hydroxybutyrate (BHB), the main ketone body and energy substrate endogenously produced in a KD, affects mitochondrial bioenergetics during glutamate-mediated Ca2+ signalling in primary cultured neurons grown at in vivo O2 levels, and 2) which Ca2+-mediated mechanisms are involved in this process. BHB increased glutamate-mediated stimulation of respiration compared to glucose, and enabled stronger and more sustained maximal uncoupled respiration. Finally, these effects were independent of the malate-aspartate NADH shuttle activity, but relied on cytosolic Ca2+-dependent mechanisms.
BHB improves mitochondrial energetics
In the present study, we aimed to assess the therapeutic effectiveness of BHB, the most abundant ketone body in mammals, in non-stimulated cortical neurons at physiological O2 concentration, and under glutamate-mediated excitotoxicity conditions relevant to epileptic seizures. BHB was mainly consumed by OXPHOS, since the injection of the ketone body was accompanied by a rise in respiration (Fig. 2C,J). At 5% O2 BHB increased MUR (Fig. 2C,K), an effect not observed with glucose, indicating the possibility that the ketone body is a more efficient substrate since MUR is mainly controlled by substrate supply, together with the intrinsic respiratory capacity of mitochondria27.
We also studied the contribution of Aralar-MAS activity on the glutamate-mediated increase in OCR in the presence of aminooxyacetic acid (0.5 mM AOAA), the inhibitor of AST, which is a widely used inhibitor of MAS34. Glutamate stimulation promoted an increase in cytosolic Ca2+ concentration which results in a net increase in ATP consumption in order to restore the cytosolic ionic balance15. Importantly, we identified BHB as a much more effective substrate than glucose in conditions of glutamate stimulation, allowing significantly higher and sustained stimulation of mitochondrial respiration (Fig. 4C,J) with a significant increase in O2 consumption linked to ATP synthesis observed at 5% O2 compared to 21% O2 (Fig. 4I). This indicates that varying substrates may enable mitochondria to face hyperexcitation more efficiently. Moreover, culturing in 5% O2 enabled the neurons to maintain their MUR in the presence of glutamate regardless of the substrate present, unlike those cultured in ambient conditions (Fig. 4K).
Previous work revealed that the lack of ARALAR-MAS prevented adequate glucose-derived pyruvate supply to the mitochondria, inducing a metabolic limitation16. Moreover, BHB was found to promote efficient recovery from deficits in both basal and glutamate-stimulated respiration in aralar-deficient neurons39. Here, our analysis performed in physiological O2 concentration reinforces the concept that ARALAR-MAS plays an essential role in the response to glutamate-induced increases in neuronal workload, and is a key mechanism for upregulating respiration in the presence of glucose, facilitating adequate pyruvate supply to the mitochondria (Fig. 4A,B,J). Moreover, BHB constitutes an effective substrate enabling primary cortical neurons to bypass energetic limitations imposed by ARALAR-MAS inhibition (Fig. 4C,J).
Interestingly, BHB-mediated Ca2+ mobilization (Fig. 8) and the effects on mitochondrial respiration upon glutamate stimulation seem to be significantly altered in cortical neurons in physiological O2 concentration (Fig. 7). In our experimental conditions, primary cortical neurons rely on cytosolic Ca2+ signalling to induce glutamate-mediated OCR stimulation in the presence of BHB (Fig. 7D,E). In ambient conditions, however, the presence of BAPTA-AM, a rapid intracellular Ca2+-chelator, only halved OCR stimulation (Fig. 7A,B). This effect might be mediated by BHB-induced ER Ca2+ release in the mitochondria-associated membranes (MAMs) points of contact between the ER and mitochondria, the signal which stimulates OXPHOS. Furthermore, BHB-mediated mobilisation of intracellular stored Ca2+ upon glutamate was significantly reduced at physiological O2 concentration (Fig. 8). One limitation of this work was that we evaluated short-term BHB-mediated signalling mechanisms induced by acute administration of the ketone body, relevant to the seizure setting. However, these short-term effects may need to be dissected from long-term effects that involve modulation in gene expression in physiological O2 concentrations.
Conclusion
Together these results underscore the role of BHB as a more efficient substrate to sustain mitochondrial respiration upon glutamate-mediated stimulation at physiological O2 concentrations compared to glucose. Moreover, BHB-mediated cytosolic calcium signalling is required to fully stimulate mitochondrial respiration. Collectively, the experimental evidence provided suggests that ketone administration alone might afford anti-seizure benefits for patients with epilepsy by enhancing mitochondrial function.
Data availability
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
References
Kwan, P., Schachter, S. C. & Brodie, M. J. Drug-resistant epilepsy. N. Engl. J. Med. 365, 919–926. https://doi.org/10.1056/NEJMra1004418 (2011).
Kwan, P. & Brodie, M. J. Epilepsy after the first drug fails: Substitution or add-on?. Seizure 9, 464–468. https://doi.org/10.1053/seiz.2000.0442 (2000).
Kessler, S. K., Neal, E. G., Camfield, C. S. & Kossoff, E. H. Dietary therapies for epilepsy: Future research. Epilepsy Behav. 22, 17–22. https://doi.org/10.1016/j.yebeh.2011.02.018 (2011).
Klepper, J., Engelbrecht, V., Scheffer, H., van der Knaap, M. S. & Fiedler, A. GLUT1 deficiency with delayed myelination responding to ketogenic diet. Pediatr. Neurol. 37, 130–133. https://doi.org/10.1016/j.pediatrneurol.2007.03.009 (2007).
Kossoff, E. H., Zupec-Kania, B. A. & Rho, J. M. Ketogenic diets: an update for child neurologists. J. Child Neurol. 24, 979–988. https://doi.org/10.1177/0883073809337162 (2009).
Villeneuve, N. et al. The ketogenic diet improves recently worsened focal epilepsy. Dev. Med. Child Neurol. 51, 276–281. https://doi.org/10.1111/j.1469-8749.2008.03216.x (2009).
Van der Auwera, I., Wera, S., Van Leuven, F. & Henderson, S. T. A ketogenic diet reduces amyloid beta 40 and 42 in a mouse model of Alzheimer’s disease. Nutr. Metab. (Lond.) 2, 28. https://doi.org/10.1186/1743-7075-2-28 (2005).
Zhao, Z. et al. A ketogenic diet as a potential novel therapeutic intervention in amyotrophic lateral sclerosis. BMC Neurosci. 7, 29. https://doi.org/10.1186/1471-2202-7-29 (2006).
Ruskin, D. N. et al. A ketogenic diet delays weight loss and does not impair working memory or motor function in the R6/2 1J mouse model of Huntington’s disease. Physiol. Behav. 103, 501–507. https://doi.org/10.1016/j.physbeh.2011.04.001 (2011).
Ruskin, D. N. et al. Ketogenic diet improves core symptoms of autism in BTBR mice. PLoS One 8, e65021. https://doi.org/10.1371/journal.pone.0065021 (2013).
Vanitallie, T. B. et al. Treatment of Parkinson disease with diet-induced hyperketonemia: A feasibility study. Neurology 64, 728–730. https://doi.org/10.1212/01.WNL.0000152046.11390.45 (2005).
Dahlin, M. et al. The ketogenic diet compensates for AGC1 deficiency and improves myelination. Epilepsia 56, e176-181. https://doi.org/10.1111/epi.13193 (2015).
Zilberter, Y. & Zilberter, T. Glucose-sparing action of ketones boosts functions exclusive to glucose in the brain. eNeuro https://doi.org/10.1523/ENEURO.0303-20.2020 (2020).
Newman, J. C. & Verdin, E. Beta-hydroxybutyrate: A signaling metabolite. Annu. Rev. Nutr. 37, 51–76. https://doi.org/10.1146/annurev-nutr-071816-064916 (2017).
Glancy, B. & Balaban, R. S. Role of mitochondrial Ca2+ in the regulation of cellular energetics. Biochemistry 51, 2959–2973. https://doi.org/10.1021/bi2018909 (2012).
Llorente-Folch, I. et al. Calcium-regulation of mitochondrial respiration maintains ATP homeostasis and requires ARALAR/AGC1-malate aspartate shuttle in intact cortical neurons. J. Neurosci. 33, 13957–13971. https://doi.org/10.1523/JNEUROSCI.0929-13.2013 (2013).
McCormack, J. G., Halestrap, A. P. & Denton, R. M. Role of calcium ions in regulation of mammalian intramitochondrial metabolism. Physiol. Rev. 70, 391–425. https://doi.org/10.1152/physrev.1990.70.2.391 (1990).
Pardo, B. et al. Essential role of aralar in the transduction of small Ca2+ signals to neuronal mitochondria. J. Biol. Chem. 281, 1039–1047. https://doi.org/10.1074/jbc.M507270200 (2006).
Contreras, L. et al. Ca2+ Activation kinetics of the two aspartate-glutamate mitochondrial carriers, aralar and citrin: Role in the heart malate-aspartate NADH shuttle. J. Biol. Chem. 282, 7098–7106. https://doi.org/10.1074/jbc.M610491200 (2007).
Palmieri, L. et al. Citrin and aralar1 are Ca(2+)-stimulated aspartate/glutamate transporters in mitochondria. EMBO J. 20, 5060–5069. https://doi.org/10.1093/emboj/20.18.5060 (2001).
Satrustegui, J., Pardo, B. & Del Arco, A. Mitochondrial transporters as novel targets for intracellular calcium signaling. Physiol Rev 87, 29–67. https://doi.org/10.1152/physrev.00005.2006 (2007).
Gellerich, F. N. et al. The control of brain mitochondrial energization by cytosolic calcium: the mitochondrial gas pedal. IUBMB Life 65, 180–190. https://doi.org/10.1002/iub.1131 (2013).
Gellerich, F. N. et al. Cytosolic Ca2+ regulates the energization of isolated brain mitochondria by formation of pyruvate through the malate-aspartate shuttle. Biochem. J. 443, 747–755. https://doi.org/10.1042/BJ20110765 (2012).
Llorente-Folch, I. et al. The regulation of neuronal mitochondrial metabolism by calcium. J. Physiol. 593, 3447–3462. https://doi.org/10.1113/JP270254 (2015).
Concannon, C. G. et al. AMP kinase-mediated activation of the BH3-only protein Bim couples energy depletion to stress-induced apoptosis. J. Cell Biol. 189, 83–94. https://doi.org/10.1083/jcb.200909166 (2010).
Qian, W. & Van Houten, B. Alterations in bioenergetics due to changes in mitochondrial DNA copy number. Methods 51, 452–457. https://doi.org/10.1016/j.ymeth.2010.03.006 (2010).
Brand, M. D. & Nicholls, D. G. Assessing mitochondrial dysfunction in cells. Biochem. J. 435, 297–312. https://doi.org/10.1042/BJ20110162 (2011).
Mookerjee, S. A., Gerencser, A. A., Nicholls, D. G. & Brand, M. D. Quantifying intracellular rates of glycolytic and oxidative ATP production and consumption using extracellular flux measurements. J. Biol. Chem. 292, 7189–7207. https://doi.org/10.1074/jbc.M116.774471 (2017).
Kar, P., Samanta, K. & Parekh, A. B. Cytosolic and intra-organellar Ca2+ oscillations: Mechanisms and function. Curr. Opin. Physiol. 17, 175–186. https://doi.org/10.1016/j.cophys.2020.08.011 (2020).
Maravall, M., Mainen, Z. F., Sabatini, B. L. & Svoboda, K. Estimating intracellular calcium concentrations and buffering without wavelength ratioing. Biophys. J. 78, 2655–2667. https://doi.org/10.1016/S0006-3495(00)76809-3 (2000).
Weisova, P. et al. Latrepirdine is a potent activator of AMP-activated protein kinase and reduces neuronal excitability. Transl. Psychiatry 3, e317. https://doi.org/10.1038/tp.2013.92 (2013).
Mitchell, P. & Moyle, J. Estimation of membrane potential and pH difference across the cristae membrane of rat liver mitochondria. Eur. J. Biochem. 7, 471–484. https://doi.org/10.1111/j.1432-1033.1969.tb19633.x (1969).
Davidson, S. M., Yellon, D. & Duchen, M. R. Assessing mitochondrial potential, calcium, and redox state in isolated mammalian cells using confocal microscopy. Methods Mol. Biol. 372, 421–430. https://doi.org/10.1007/978-1-59745-365-3_30 (2007).
Ying, W. NAD+/NADH and NADP+/NADPH in cellular functions and cell death: regulation and biological consequences. Antioxid. Redox Signal. 10, 179–206. https://doi.org/10.1089/ars.2007.1672 (2008).
Chen, Y. B. et al. Bcl-xL regulates mitochondrial energetics by stabilizing the inner membrane potential. J. Cell Biol. 195, 263–276. https://doi.org/10.1083/jcb.201108059 (2011).
Ma, Y. et al. NAD(+)/NADH metabolism and NAD(+)-dependent enzymes in cell death and ischemic brain injury: Current advances and therapeutic implications. Curr. Med. Chem. 22, 1239–1247. https://doi.org/10.2174/0929867322666150209154420 (2015).
Harris, J. J., Jolivet, R. & Attwell, D. Synaptic energy use and supply. Neuron 75, 762–777. https://doi.org/10.1016/j.neuron.2012.08.019 (2012).
Abramov, A. Y. & Duchen, M. R. Mechanisms underlying the loss of mitochondrial membrane potential in glutamate excitotoxicity. Biochim. Biophys. Acta 1777, 953–964. https://doi.org/10.1016/j.bbabio.2008.04.017 (2008).
Perez-Liebana, I. et al. betaOHB protective pathways in aralar-KO neurons and brain: An alternative to ketogenic diet. J. Neurosci. 40, 9293–9305. https://doi.org/10.1523/JNEUROSCI.0711-20.2020 (2020).
Acknowledgements
This publication has emanated from research supported by a postdoctoral fellowship and research Grants from the Irish Research Council (IRC) (GOIPD/2017/1418) co-funded by the Royal College of Surgeons in Ireland, and by Grants from Science Foundation Ireland (SFI) (08/IN.1/B1949, 14/JPND/B3077 and 16/RC/3948, the latter of which is co-funded under the European Regional Development Fund and by FutureNeuro industry partners). The authors thank Dr. Manuela Salvucci and Dr. Andreas U. Lindner for technical advice.
Author information
Authors and Affiliations
Contributions
Conception and design: I.L.F., H.D., J.H.M.P.; Acquisition, analysis, interpretation of data: I.L.F., H.D., O.W., N.M.C.C., J.H.M.P.; Draft and revision of work: I.L.F., H.D., J.H.M.P.; Wrote manuscript: I.L.F.,H.D., J.H.M.P.; Prepared figures: I.L.F., H.D.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Llorente-Folch, I., Düssmann, H., Watters, O. et al. Ketone body β-hydroxybutyrate (BHB) preserves mitochondrial bioenergetics. Sci Rep 13, 19664 (2023). https://doi.org/10.1038/s41598-023-46776-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-023-46776-8
- Springer Nature Limited
This article is cited by
-
Nutritional Strategies in Major Depression Disorder: From Ketogenic Diet to Modulation of the Microbiota-Gut-Brain Axis
Molecular Neurobiology (2024)