The innate inflammatory response contributes to secondary injury in brain trauma and other disorders. Metabolic factors such as caloric restriction, ketogenic diet, and hyperglycemia influence the inflammatory response, but how this occurs is unclear. Here, we show that glucose metabolism regulates pro-inflammatory NF-κB transcriptional activity through effects on the cytosolic NADH:NAD+ ratio and the NAD(H) sensitive transcriptional co-repressor CtBP. Reduced glucose availability reduces the NADH:NAD+ ratio, NF-κB transcriptional activity, and pro-inflammatory gene expression in macrophages and microglia. These effects are inhibited by forced elevation of NADH, reduced expression of CtBP, or transfection with an NAD(H) insensitive CtBP, and are replicated by a synthetic peptide that inhibits CtBP dimerization. Changes in the NADH:NAD+ ratio regulate CtBP binding to the acetyltransferase p300, and regulate binding of p300 and the transcription factor NF-κB to pro-inflammatory gene promoters. These findings identify a mechanism by which alterations in cellular glucose metabolism can influence cellular inflammatory responses.
Microglia and macrophages are innate immune responders to infection, tissue damage, and other stressors. The early phase of this response involves release of pro-inflammatory cytokines, nitric oxide, and metalloproteinases, along with alterations in cell morphology and surface protein expression1, 2. Although these responses are adaptive in the setting of infection, they can be deleterious in non-infectious injuries such as stroke and head trauma. Accordingly, factors that suppress the acute inflammatory reaction also reduce tissue loss and improve functional outcomes in animal models of non-infectious brain injury3, 4.
Inflammatory responses are influenced at the transcriptional level by factors that affect cellular bioenergetic state, such as caloric restriction, ketogenic diet, and the glycolytic inhibitor 2-deoxyglucose (2DG)5, 6. Caloric restriction, ketogenic diet, and 2DG each produce a ketogenic state in which glucose utilization is suppressed, and these conditions also reduce brain inflammation, tissue loss, and functional impairment after brain injury7,8,9,10,11,12. Conversely, hypoxia and hyperglycemia promote glucose utilization, exacerbate inflammation, and worsen outcomes after brain injury13, 14.
How inflammation affects cell metabolism is well established15, but less is known about how energy metabolism affects inflammatory responses. One potential mechanism is through the cytosolic NADH:NAD+ ratio, which is thermodynamically coupled to glycolysis. The cytosolic NADH:NAD+ ratio is decreased by ketogenic factors such as dietary restriction and 2DG, which decrease flux through glycolysis, and increased by conditions such as hypoxia and hyperglycemia, which increase flux through glycolysis. Cytosolic NADH and NAD+ are physically separated from the mitochondrial metabolite pools, but can move freely across the nuclear membrane to influence transcriptional events.
Despite the fundamental roles of NAD+ and NADH in cell metabolism, only a limited number of NADH-sensitive proteins are known to affect gene transcription16. Among these are the C-terminal binding proteins (CtBP), which function as transcriptional corepressors. Mammals express two CtBP proteins, CtBP1 and CtBP2, that exhibit overlapping actions17, 18. CtBP forms repressor complexes with histone deacetylases, histone methyl transferases, E3 ligases, and other transcriptional regulators19, 20. Some of these complexes include CtBP homodimers or heterodimers, while others require CtBP in its monomeric form21,22,23,24. CtBP in its monomeric form suppresses the activity of the acetyltransferase p300/CBP20, which acetylates both histones and the pro-inflammatory transcription factor, NF-κB25. Increased NADH levels promote the formation of CtBP dimers and higher order oligomers, and thereby modulate CtBP association with its binding partners26.
Here, we investigate whether anti-inflammatory effects of ketogenic metabolism may be mediated through an NADH/CtBP signaling mechanism. We show that changes in cytosolic NADH:NAD+ ratio influence inflammatory responses by regulating NF-κB transcriptional activity through a mechanism requiring CtBP dimerization. This process involves dissociation of p300 from CtBP and acetylation of the NF-κB p65 subunit.
Microglial and macrophage activation is suppressed by 2DG
The reduced glycolytic flux resulting from caloric restriction and ketogenic diet can be mimicked by the glycolytic inhibitor 2DG27, 28. To determine whether 2DG can replicate the effect of ketogenic diet on brain inflammatory responses, we treated rats with intraperitoneal injections of lipopolysaccharide (LPS) or with LPS + 2DG. The systemic LPS injection induced a robust activation of brain microglia, and this was strikingly reduced by co-administration of 2DG (Fig. 1a). In organotypic brain slice cultures (Fig. 1b), 2DG likewise suppressed the effect of LPS on microglial activation and on the expression of inducible nitric oxide synthase (iNOS), a hallmark of inflammatory activation in microglia and macrophages29. Primary microglial cultures similarly showed an attenuated response to LPS in the presence of 2DG (Fig. 1c), thus confirming that the effects of LPS and 2DG on microglia are not dependent upon indirect, systemic effects of these agents. This same pattern of responses was observed in the RAW264.7 macrophage cell line. RAW264.7 cells treated with LPS showed increased iNOS mRNA expression, iNOS protein expression, and nitric oxide production, all of which were attenuated by co-incubation with 2DG (Fig. 1d, e). RAW264.7 cells were used because, unlike primary microglia, they can be efficiently transfected and are not readily activated by transfection procedures. Glutamine was provided as an alternative energy substrate in all of the in vitro studies, as glutamine is taken up by cells and metabolized to the keto acid, α-ketoglutarate. ATP measurements confirmed no significant effect of 2DG or glucose-free medium on ATP levels in the glutamine-supplemented cell cultures (Fig. 1f).
Glycolytic inhibition reduces cytosolic NADH:NAD+ ratio
We assessed the free cytosolic NADH:NAD+ ratio by measuring the cellular lactate:pyruvate ratio30. This indirect approach has advantages over direct biochemical measurements in that it is not influenced by protein bound or mitochondrial NAD+ and NADH30, 31. 2DG and glucose-free medium are predicted to lower the cytosolic (i.e., non-mitochondrial) NADH:NAD+ ratio by decreasing glucose flux through glycolysis, while impaired respiration should increase glycolytic flux and elevate the cytosolic NADH:NAD+ ratio (Fig. 2a). As expected, both 2DG and glucose-free medium reduced the lactate:pyruvate ratio (indicating a reduced free cytosolic NADH:NAD+ ratio), while the respiratory inhibitors antimycin A and cobalt chloride (CoCl2)27, 32 increased it (Fig. 2b). We then evaluated these treatments on LPS-induced iNOS expression. Glucose-free medium suppressed LPS-induced iNOS expression to an extent comparable to that seen with 2DG, while CoCl2 had the opposite effect (Fig. 2c). These findings identify a correlation between changes in the inflammatory response and changes in the NADH:NAD+ ratio in response to metabolic factors.
Elevated NADH reverses the anti-inflammatory effect of 2DG
We next asked whether the metabolic influences on the inflammatory responses are blocked when changes in the NADH:NAD+ ratio are negated. Lactate added to culture medium passes readily into cultured cells33 and drives the NADH:NAD+ equilibrium toward NADH (Fig. 2a), thus providing a means of countering the effect of glycolytic inhibition on the cytosolic NADH:NAD+ ratio. The addition of sodium lactate (20 mM, pH 7.4) reversed the effects of glycolytic inhibition on LPS-induced iNOS expression in the cell cultures (Fig. 3a, b). Evaluation of iNOS gene transcription in cells transfected with an iNOS luciferase reporter gene confirmed an effect at the level of iNOS gene transcription (Fig. 3c).
The lactate:pyruvate ratio cannot be reliably measured in cells treated with lactate, so for these studies we instead evaluated changes in cytosolic NADH by measuring changes in intrinsic NAD(P)H fluorescence. This approach does not distinguish NADH from NADPH, but cellular NADPH levels are insensitive to acute changes in glycolysis or lactate34, 35. Signal from mitochondrial NAD(P)H was avoided by sampling only from nuclei, which do not contain mitochondria (Fig. 3d). 2DG reduced the cytosolic NAD(P)H signal, in agreement with the lactate:pyruvate ratio determinations; and as expected 2DG had no effect on the mitochondrial NAD(P)H fluorescence (Fig. 3e). Glucose-free medium had comparable effects (Fig. 3f). The effects of both 2DG and glucose-free medium on NAD(P)H levels were reversed by sodium lactate (20 mM, pH 7.4; Fig. 3f). Although lactate did not produce a significant increase in NAD(P)H signal when administered in the absence of 2DG (Fig. 3f), the mitochondrial inhibitors cobalt and antimycin likewise failed to increase the NAD(P)H signal. NADH fluorescence measurements may be less sensitive to increases than to decreases in NADH because increased NADH is disproportionately protein-unbound, and NADH that is not protein bound has weaker intrinsic fluorescence36.
2DG suppresses NF-κB activated pro-inflammatory genes
To evaluate the broader effects of 2DG on LPS-induced gene expression, we prepared microarrays from RAW264.7 cells after incubation under control, LPS, or LPS + 2DG conditions. Expression levels of 994 genes were significantly affected by LPS and 781 by LPS + 2DG, with 579 genes responding to both conditions (Fig. 4a). An analysis of transcription factor binding sites on these genes showed that conserved NF-κB family binding sites (Rel and RelA/p65) were over-represented in the LPS + 2DG condition (Supplementary Table 1; Supplementary Data 1 and 2), as would be expected given the dominant role of NF-κB in pro-inflammatory transcriptional responses. RT-PCR quantifications of specific NF-κB—driven pro-inflammatory gene transcripts, IL1B, IL6, and iNOS, confirmed that they were upregulated by LPS, and that 2DG suppressed their upregulation (Figs. 1d, 4b).
The anti-inflammatory effect of 2DG is mediated by CtBP
We next evaluated whether the NAD(H)-sensitive transcriptional co-repressor, CtBP, is involved in the process by which energy metabolism influences inflammation. We generated a stable CtBP knockdown RAW264.7 cell line using lentivirus that expressed shRNA targeting a sequence that, in mice, is present only in CtBP1 and CtBP2. The CtBP knockdown cell line displayed a 98.9 ± 0.2 % reduction in CtBP1 and 80.8 ± 4% reduction in CtBP2 transcripts, and a 64 ± 10% reduction in CtBP1/2 protein expression (Fig. 5a). Like wild-type cells, CtBP knockdown cells responded to LPS with increased iNOS expression and NO production (though to a lesser extent); however, unlike wild-type cells, CtBP knockdown cells showed no suppression of this response when treated with 2DG or glucose-free medium (Fig. 5b, c). Similarly, the effect of 2DG on LPS-induced NF-κB transcriptional activity was not observed in the CtBP knockdown cells (Fig. 5d), nor was the effect of 2DG on LPS-induced iNOS, IL-1b, and IL-6 gene expression (Fig. 5e; compare to Figs. 1d, 4b).
If transcriptional effects of cytoplasmic NADH:NAD+ ratio are mediated by CtBP, then they should be diminished in cells expressing an NAD(H)—insensitive CtBP. The G189A mutation in CtBP2 disrupts its binding to NAD(H) while preserving its co-repressor activity27. We therefore determined whether the G189A mutation would negate the effect of NADH elevations on NF-κB–mediated transcriptional responses. Studies were performed in CtBP1−/−/CtBP2−/− MEF cells in order to eliminate effects of endogenous CtBP1/2 (Fig. 6a), and because the shRNA expressed by the stable CtBP knockdown RAW264.7 cell line precludes expression of the mutant CtBP in those cells. The MEF cells were transfected with either wild-type (WT) CtBP1, WT CtBP2, or mutant G189A CtBP2 (Fig. 6a). Since the MEF cells responded only weakly to LPS (not shown), an NF-κB transcriptional response was induced by co-transfection with the p65 subunit of NF-κB. All three of the CtBP constructs suppressed NF-κB transcriptional activity, consistent with the potent co-repressor activity of CtBP (Fig. 6b–d). Treatment with 2DG produced no further reduction in this already suppressed NF-κB activity; however, treatment with CoCl2, which elevates the NADH:NAD+ ratio, increased NF-κB activity in cells expressing WT CtBP2, but not in cells expressing G189A mutant CtBP2 (Fig. 6e). This pattern was also observed in primary microglia:CoCl2 augmented LPS-induced iNOS expression in microglia overexpressing wild-type CtBP, but not in microglia overexpressing G189A CtBP2 (Fig. 6f).
Given that CtBP overexpression suppresses NF-κB transcriptional activity (Fig. 6c, d) we also evaluated the possibility that 2DG effects on LPS-induced responses might be caused by upregulated CtBP expression, independent of the CtBP responses to cytosolic NADH:NAD+ ratio. However, measures of CtBP mRNA levels in primary microglia showed that 2DG did not increase expression of either CtBP1 or CtBP2, with or without LPS co-treatment (Supplemantary Fig. 1a, b).
Peptide inhibition of CtBP dimerization
To further evaluate the mechanism by which CtBP regulates inflammatory responses, we generated a synthetic peptide that blocks CtBP dimeriziation. Examination of the crystal structure of a rat CtBP dimer complexed with NAD(H)37 suggested that a peptide near the center of the dimerization region, if stably folded, could bind to the CtBP monomer and interfere with dimer formation. This dimerization region contains two alpha helical domains that are structurally conserved in CtBP family members, and contains four residues that, when mutated, prevent dimerization of drosophila CtBP22. A peptide spanning this region, corresponding to amino acids 114−142 of the long form of mouse CtBP1 (Fig. 7a), and a control peptide lacking any known effects on cell function were generated and fused to N-terminal Tat sequences (CPC Scientific (Sunnyvale, CA). The CtBP peptide sequence was GRKKRRQRRRC VEETADSTLCHILNLYRRTTWLHQALREG (with the Tat sequence underlined), and the control peptide sequence was GRKKRRQRRRC CSFNSYELGSLCYGRKKRRQRR. To determine if the CtBP peptide could block CtBP dimerization in vitro, we co-expressed CtBP1-HA and CtBP1-Flag tagged constructs in COS7 cells and performed immunoprecipitation with antibody to Flag. Very little HA-tagged CtBP was immunoprecipitated with anti-Flag antibody in untreated control samples (Fig. 7b), suggesting that the majority of the CtBP-tagged protein is monomeric. In contrast, in vitro treatment of lysate with 10 mM lactate plus 10 µm NADH for 20 min prior to immunoprecipitation (to force an increase in the NADH:NAD+ ratio in the lysates) greatly increased the amount of CtBP1-HA associated with CtBP1-Flag. This association was disrupted by co-incubation with 50 µm of the CtBP peptide (Fig. 7b).
We next tested whether the CtBP peptide could inhibit LPS-induced inflammatory gene expression, as observed in the 2DG—induced ketogenic state. Primary microglia were treated with LPS, alone or in combination with 5 µm CtBP peptide or control peptide. The CtBP peptide reduced LPS-induced iNOS, IL-1b, and IL-6 transcript expression, while the control peptide had no effect (Fig. 7c). We then evaluated whether the CtBP peptide could block inflammatory gene expression in vivo. In initial experiments, we treated mice intraperitoneally with 2DG (100 mg/kg) 10 min prior to stereotactic injection of 8 µg LPS into the left striatum. Three hours of post-surgery, brains were removed and microglia were isolated from the striatum for gene expression studies. These studies confirmed that LPS robustly induces iNOS expression in microglia in vivo, and that this effect is attenuated by 2DG (Fig. 7d). We then co-injected LPS (8 µg) along with the CtBP peptide or control peptide into the striatum 3 h prior to microglial isolation. The LPS-induced increase in iNOS gene expression was reduced by the CtBP peptide, but not by the control peptide. In contrast, LPS-induced expression of the M2-type anti-inflammatory gene, Socs3 (Suppressor of cytokine signaling 3)38, was unaffected by CtBP peptide, demonstrating that the peptide does not exert a global or nonspecific effect on transcription (Fig. 7e, f).
p300 binding to CtBP and pro-inflammatory gene promoters
One way that CtBP regulates gene transcription is through interactions with the histone acetyltransferase HDAC119. We therefore performed chromatin immunoprecipitation (ChIP) targeting the IL-6 promoter to evaluate the effects of ketogenic state on HDAC1 binding and histone H3 acetylation. Both HDAC1 binding and H3 acetylation were increased in cells treated with LPS, but neither was reversed by 2DG (Fig. 8a). A second way that CtBP regulates gene transcription is by repressing the activity of p30020, 39, which acetylates and thereby promotes the activity of transcription factors such as the p65 subunit of NF-κB25. The ChIP studies showed that LPS-induced p65 binding to the IL-6 promotor, and that this was completely reversed in the presence of 2DG (Fig. 8a). This effect of 2DG was accompanied by parallel changes in p65 acetylation status, as assessed by western blots from cells treated with LPS or LPS + 2DG (Fig. 8b). Additional ChIP studies showed that LPS-induced p300 binding to the IL-6, IL-1b, and iNOS promoter regions, and that 2DG markedly attenuated each of these effects (Fig. 8c). These results parallel the effects of LPS and 2DG on iNOS, IL-1b, and IL-6 mRNA and protein expression (Figs. 1, 4). We then performed co-immunoprecipitation of p300 with CtBP in cells transfected with either wild-type CtBP2 or G189A CtBP2 to confirm that p300 binding to CtBP is similarly sensitive to NADH. 2DG—induced reductions in the cytosolic NADH:NAD+ ratio did not increase the binding of p300 to either wild-type CtBP2 or G189A CtBP2, presumably because binding was already saturated by CtBP overexpression; however, CoCl2—induced elevations in the NADH:NAD+ ratio reduced the binding of p300 to wild-type CtBP, but not G189A CtBP2 (Fig. 8d, e).
CtBP has previously been shown to mediate effects of cellular metabolic state on transcriptional events contributing to cancer and epilepsy27, 40. Our present findings demonstrate that CtBP similarly couples metabolic state to the innate inflammatory response. We show that the pro-inflammatory gene expression and NF-κB transcriptional activity induced by LPS are coupled to glucose metabolism by the cytosolic NADH:NAD+ ratio, and that this coupling is attenuated by CtBP downregulation, by forced elevation of NADH, by transfection with an NADH—insensitive CtBP, and by a synthetic peptide that blocks NADH-induced CtBP dimerization. We additionally show that metabolic state influences CtBP binding to the acetyltransferase p300, p300 binding at pro-inflammatory gene promoter sites, and acetylation state of NF-κB. The observations suggest a mechanism by which the liberation of CtBP from its dimerized form by lowered cytosolic NADH levels can suppress pro-inflammatory gene transcription.
The initial observation by Zhang et al.26 that NADH binding promotes CtBP dimerization suggested that CtBP could regulate transcription in response to metabolic changes. Subsequent studies confirmed that CtBP mediates effects of 2-deoxyglucose, hypoxia, pyruvate, and other metabolic influences on gene expression27, 41. Since NAD+ and NADH recognize the same binding site on CtBP, changes in the concentration of either nucleotide could, in principle, regulate CtBP interactions with its binding partners. However, the relative changes in NADH caused by shifts in the cytosolic NADH:NAD+ ratio are several hundred-fold greater than the reciprocal changes in NAD+ because the cytosolic NADH:NAD+ ratio is normally in the range of 1:70035. The sensitivity of CtBP to changes in NADH thus makes it particularly responsive to changes in energy metabolism42. Inflammatory responses can also be modulated by NAD+—dependent deacetylases of the sirtuin family, notably Sirt143, but unlike CtBP sirtuins are not responsive to changes in NADH concentrations, and it remains uncertain whether their activity is significantly affected by the relatively small changes in NAD+ concentrations that result from changes in energy metabolism44.
CtBP1 and CtBP2 have nearly identical amino acid sequences and share the same NAD(H) binding site. CtBP1 lacks a putative nuclear localization signal, but may enter the nucleus as heterodimer with CtBP2 or other proteins22, 45 and may also interact in the extra-nuclear cytosol with binding partners such as p300 and HDAC1. CtBP2−/− mice are nonviable, but CtBP1−/− mice are viable and fertile. Mice with combinations of CtBP1 and CtBP2 mutant alleles exhibit gene dosage-sensitive defects in several developmental processes17. Specific defects in immune function were not reported in these mutants, but CtBP has elsewhere been shown to modulate the role of estrogen receptors on inflammatory responses mediated by the AP-1 transcription factor, independent of metabolic changes46.
CtBP regulates gene transcription in multiple ways, including interactions with histone deacetylases, histone methyl transferases, E3 ligases, and the p300 acetyltransferase. We did not find changes in histone acetylation or HDAC1 binding at pro-inflammatory gene promoters in response to a ketogenic state, but did find decreased binding of p300 and decreased acetylation of p65, which is a substrate for p30025. Since p65 acetylation increases NF-κB transcriptional activity, these findings identify a mechanism by which metabolic effects on CtBP can modulate gene transcription. However, both monomer and dimer forms of CtBP can affect gene transcription21,22,23,24, and our findings do not establish that p300/CtBP binding is essential for the observed effects of CtBP on pro-inflammatory gene transcription. CtBP2 could alternatively directly associate with p65 and suppress its acetylation by a mechanism independent of dimer/monomer transition or p300 inhibition47. Recent studies have also identified alternative ways that glucose metabolism can influence inflammatory responses, including effects on HDAC4 protein levels, NLRP3 inflammasome formation, and the activation of RAGE receptors48,49,50.
Cell cultures were used in our studies to facilitate manipulation of CtBP expression and cellular cytosolic NADH:NAD+ ratios. A limitation cell cultures, and cell lines in particular, is a shift from respiratory ATP production toward more glycolytic ATP production (the Warburg effect51). Moreover, the glucose concentration in standard culture media is saturating for glucose uptake and metabolism. As a consequence, basal glycolytic flux is typically much higher in culture preparations than in vivo. This may explain why relatively larger shifts in the cytosolic NADH:NAD+ ratio were observed with glycolytic inhibition than with respiratory inhibitors. However, the anti-inflammatory effects of 2DG in the cell culture preparations were also observed in vivo, as initially reported several decades ago6. Importantly, these results were also mimicked, both in vitro and in vivo, by the use of a novel synthetic peptide that inhibits NADH-induced CtBP dimerization. This result agrees with the prior observation that native CtBP1 requires NADH to suppress p300 activity, whereas a mutant form of CtBP1 that cannot dimerize suppresses p300 independent of NADH20 It may be surprising that reduced CtBP expression did not itself lead to a super-induction of iNOS and related genes, given co-repressor actions of CtBP. However, a reduction in total CtBP does not necessarily produce a comparable reduction in nuclear monomeric CtBP.
Taken together, our findings indicate that metabolic influences that alter the cytosolic NADH:NAD+ ratio regulate NF-κB transcriptional activity through an NADH-dependent effect on CtBP dimerization. Conditions that reduce glycolytic flux, such as ketogenic diet and caloric restriction, can thereby suppress NF-κB activity, while conditions that increase glycolytic flux may increase it. These interactions provide a mechanism for the suppressive effects of ketogenic diet and caloric restriction on brain inflammation after brain injury. By extension, these interactions may also contribute to the pro-inflammatory states associated with diabetes mellitus and metabolic syndrome15, 52, 53.
The MEF cell lines (CtBP1 −/− /CtBP2 −/− and CtBP1 −/+ /CtBP2 −/+) were a kind gift from Dr. A. Roopra (University of Wisconsin, Madison). HEK293 cells and the macrophage-derived RAW264.7 cell line were obtained from the ATCC. The pNF-κB-RE-firefly and pRL-CMV renilla luciferase reporter were obtained from Promega, and the control pTA-luciferase reporter was obtained from Panomics. Full length cDNAs of mouse CtBP1 and CtBP2 were cloned into pIRES-hrGFP-1a (Agilent) from adult mouse brain cDNA by reverse transcriptase PCR. The CtBP2 G189A mutant was a gift from Dr. J. Blaydes (University of Southampton, UK) and was cloned into pIRES-hrGFP-1a. The iNOS promoter-luciferase reporter was a gift from Dr. C. Lowenstein (University of Rochester, Addgene plasmid 19,296)54, the p300 plasmid was a gift from Dr. W. Sellers (Dana-Farber Cancer Institute, Addgene plasmid 10,717), the p65 plasmid was a gift from Dr. W. Greene (UCSF, Addgene plasmid 21,966), and the flag-tagged CtBP2 plasmid was a gift from Dr. A. Roopra (University of Wisconsin, Madison). GIPZ-puro vector-based lentiviral vectors containing CtBP1/2 shRNA were purchased from Open Biosystem (Thermol Scientific), and purified lentivirus transduction particles were generated by the UCSF ViraCore Laboratory. All constructs were sequence verified. All other reagents were obtained from Sigma-Aldrich except where noted.
Surgical procedures and microglial isolation
Studies were approved by the San Francisco Veterans Affairs Medical Center animal studies committee. Male Sprague Dawley rats, age 4–6 months (Charles River Laboratories), were given intraperitoneal injections of LPS (10 mg/kg) or saline vehicle, with or without 2-deoxyglucose (2DG; 100 mg/kg)55. Twenty-four hours later the rats were anesthetized and perfused with saline followed by 4% formaldehyde. Coronal 40 μm cryostat sections were prepared and immunostained56 for CD11b (Serotec, clone OX-42, 1:100 dilution). Images were acquired using fluorescence confocal microscope and quantified as described57.
Stereotaxic LPS injections were performed in adult male C57BL/6 J mice that were anesthetized with 2% isoflurane. The left striatum (A 1.3, ML 1.9, DV 3.5 mm from Bregma and the cortical surface) was injected with 8 µg LPS and 5 pmole CtBP peptide or control peptide in a volume of 5 µl sterile saline over 25 min (0.2 µl/min). Three hours later the mice were transcardially perfused with saline to remove circulating macrophages. After perfusion, brains were quickly removed and the left anterior quadrant containing the infusion site (approximately 100 mg tissue) was dissected and placed in ice-cold Hank’s Balanced Salt Solution (HBSS) without Ca2+ and Mg2+. Tissue was briefly minced with a sterile razor blade and cells were dissociated using Neural Tissue Dissociation Kit (P) and Octo Dissociator (Miltenyi Biotec, San Diego, CA). Microglia were isolated using CD11b MicroBeads (Miltenyi Biotec). Accuracy of cell separation was validated by expression profiling of cellular fractions using quantitative PCR primers specific to microglia (Iba1 forward: 5′-GAAGCGAATGCTGGAGAAAC, reverse: 5′-GACCAGTTGGCCTCTTGTGT), neurons (NeuN forward: 5′-GGAACAGTCTATGGGCCTGA, reverse: 5′-ACAAGAGAGTGGTGGGAACG) and astrocytes (GFAP forward: 5′-AGAAAGGTTGAATCGCTGGG, reverse: 5′-CGGCGATAGTCGTTAGCTTC) (Supplementary Fig. 2).
Hippocampal organotypic slice cultures
Slice cultures were prepared as described58, with minor modifications. Brains were removed from 4-day-old male mice C57BL/6 mice, and 350 µm sagittal sections were prepared with a vibratome in ice-cold dissecting media. The hippocampi were placed on Millicell inserts in 6 well culture plates, and maintained for 2 weeks at 37 ˚C in 5% CO2/ 95% air incubator. Experiments were initiated by adding 10 μg/ml LPS ± 1 mM 2DG. After 24 h the slices were fixed with 4% formaldehyde. Slices were immunostained using rabbit polyclonal antibody to Iba1 (Wako #019-19,741; 1:200 dilution) and rabbit polyclonal antibody to iNOS (Millipore, # 06-573; 1:250 dilution).
Mouse primary microglia cells were isolated and cultured as described56 and used after 10 days in vitro. Cell lines were seeded at a density of 1 × 104 cells/well in 24-well plates 1 day prior to the experiments. For protein expression and luciferase assays, MEF cells, RAW264.7 cells and HEK293 cells were seeded in 12-well or 24-well plates overnight, and transfected with plasmids using Lipofectamine2000 (Invitrogen) when they reached 80% confluence. A stable CtBP1/2 knockdown cell line was generated from RAW264.7 cells by incubating the cells with CtBP1/2 shRNA lentiviral stocks for 3 h. Puromycin was added after 48 h, and infected cells were selected over 10 passages. Stable clones were pooled for propagation and experiments.
Studies were initiated by washing cells into serum-free Dulbecco’s minimal essential medium containing 6 mM glutamine and 2 mM glucose (or no glucose, where indicated). Lipopolysaccharide (LPS), lactate, and metabolic inhibitors were added to this medium from concentrated stocks that were pre-adjusted to pH 7.4, and the cultures were replaced in a 37 °C, 5% CO2 incubator. The final LPS concentration was 10 ng/ml in the cell cultures. All experiments were repeated at least three times, using triplicate wells in each experiment.
Cells were washed with ice-cold phosphate-buffered saline and extracted with ice-cold 0.5% trichloroacetic acid. The cell lysate pH was adjusted to 7.8 with 1 M Tris-base. ATP concentration was determined by a luciferase-linked method (Promega Enlighten ATP kit) using ATP standards. Values were normalized to protein concentrations as determined by the Bradford assay (Bio-Rad) in sister culture wells.
Lactate and pyruvate assays
RAW264.7 cells were rinsed with ice-cold phosphate-buffered saline, lysed in 0.2 N NaOH, and aliquots were taken for protein assay. Lactate and pyruvate were measured in pH-neutralized lysates by enzyme-linked assays as described12 using standards treated identically.
Real-time changes in cellular (cytoplasmic) NADH content were estimated by measuring endogenous NADH fluorescence with 360 nm excitation and > 410 nm emission59. Fluorescence images were acquired at 1 min intervals after 5 min of baseline recording. Regions of interest were selected from the nucleus to eliminate signal from mitochondria, and cytochalasin D (1 µm) was included to prevent cell movement. Images acquired from each cell were used to calculate change in fluorescence intensity / average of pre-treatment fluorescence intensity (ΔF/F o). In a subset of experiments cells were pre-incubated with 200 nm Mitotracker Red-FM (Molecular Probes) to verify that the NADH fluorescence measurements were not contaminated by mitochondrial NADH fluorescence. Mitochondrial and NADH signals were imaged by interleaving NADH fluorescence excitation and Mitotraker (excitation 550 nm; emission > 610 nm).
Nitric oxide measurements
Production of nitric oxide was assessed by analyzing nitrite concentrations in the culture medium collected after 24 h incubation under the designated conditions. Aliquots of culture medium or nitrite standards prepared in culture medium were mixed with equal volumes of Griess reagent and light absorbance was measured at 540 nm56. Values were normalized to the protein content of each culture well.
Luciferase reporter gene assays
Cells were transfected with 300 ng of 5xNF-κB or iNOS firefly luciferase constructs using Lipofectamine2000 (Life Technologies), and co-transfected with 100 ng of GL3-Renilla luciferase construct (Promega) as an internal control of transfection efficiency. In some experiments cells were also transfected with a CtBP constructs (200 ng) or CtBP empty control vector. Renilla luciferase and firefly luciferase activity were measured in cell lysates using a dual luciferase assay kit (Promega) on a Modulus Microplate Reader (Turner Biosystems). Reporter luciferase activity was normalized to Renilla luciferase activity in each assay.
Microarray and differential expression analysis
Cells were collected after 24 h incubation under the designated conditions. RNA was extracted and arrayed in triplicates using Mouse OneArray chip (Phalanx Biotech). Data analysis was performed using Bioconductor packages in R (www.bioconductor.org). Raw reads from microarrays were first normalized across the samples using the ‘vsn’ package from Bioconductor60. The normalized expression levels of the samples (with technical and experimental duplicates) were then fitted with a mixed linear model using the ‘limma’ package from Bioconductor61. Differential expression between pairs of treatment factors were also calculated using the ‘limma’ package, and the resulting p-values were adjusted for multiple tests using the Benjamin-Hochberg procedure. A Venn diagram was also generated to visualize the overlap of differentially expressed genes between pairs of factors among three factors, using R codes adapted from the ‘limma’ package. Shared transcription factor binding sites were identified by blast differentially expressed genes in the oPOSSUM server (http://opossum.cisreg.ca/oPOSSUM3/) with a filter setting of Z-score above 15.
Quantitative real-time PCR analysis
RNA was extracted from freshly harvested cells (Qiagen), treated with DNAse I (Promega) and first-strand cDNA was synthesized from 2 μg total RNA with Oligo (dT) primers (Life Technologies). Real-time PCR with SYBR green detection (Applied Biosystems) was performed as described previously62 using an ABI 7900HT FAST Real-Time PCR System. Dilution series and standard curves of β-actin were amplified on each plate for all experiments. Transcript levels of all genes from each sample were normalized to its ß-Actin mRNA level using the 2−ΔΔCT method62.
Co-immunoprecipitation and western blots
Cells were lysed with M-PER reagent (Pierce) supplemented with benzonase nuclease (Novagen) and protease inhibitors (Roche). Soluble lysate was centrifuged for 10 min at 4 °C and the supernatant was incubated with anti-Flag M2 agarose (Sigma) overnight. The M2 agarose was washed five times with 0.25% Triton X-100 / phosphate-buffered saline and three times with 0.5% Triton X-100/phosphate-buffered saline. Bound protein was eluted using 1X Sample Loading Buffer (Invitrogen) and heated to 100 °C for 5 min. Lysate and eluate were resolved on 10% SDS-PAGE gels, and transferred to PVDF membranes (Millipore)62. The blots were probed with mouse polyclonal anti iNOS (Upstate, #06-573; 1:1000), rabbit polyclonal anti ß-actin (Sigma-Aldrich, #A2066; 1:1000), and mouse monoclonal anti-CtBP (AbNova, # H1487-MO1, 1:1000).
Cells were treated with 1% formaldehyde for 10 min at 37 °C and rinsed twice with ice-cold phosphate-buffered saline supplemented with phenylmethanesulfonyl fluoride and protease inhibitors (Roche). Cells were then lysed, sonicated on ice, and centrifuged. Aliquots of the supernatants were heated to reverse crosslinks and recover genomic DNA for an input control. A ChIP assay kit (Millipore) was used with mouse antibody to CtBP (AbNova, # H1487-MO1, 1:250 dilution) and rabbit antibodies to p300, HDAC1, and p65 (Santa Cruz Biotechnology; sc-585, sc-7872, sc-372) or acetyl H3 (Cell Signaling, #8173), each at 1:250 dilutions, and with mouse and rabbit IgG controls (Cell Signaling). Precipitated material was eluted by two 15 min incubations at room temperature with 250 μl of 1% SDS / 0.1 M NaHCO3. Chromatin was crosslink-reversed and submitted to RNAse and proteinase K digestion. DNA was extracted by phenol-chloroform and the DNA from both the ChIP and the input controls were analyzed by quantitative real-time PCR analysis. Primers targeting the iNOS, Il-1b, and Il6 promoter regions were as published63, 64.
Peptide design and synthesis
The crystal structure of a rat CtBP dimer complexed with NAD(H) (PDB 1HKU)37 using Accelrys DS Viewer 1.7 suggested that a peptide near the center of the dimerization region, if stably folded, might interfere with dimer formation. This dimerization region contains two alpha helical domains that are structurally conserved in CtBP family members and also contains residues that, when mutated, prevent dimerization of drosophila CtBP22. A corresponding CtBP peptide along with a control peptide lacking any known cell function were generated and fused to an N-terminal Tat sequence by CPC Scientific (Sunnyvale, CA). The CtBP peptide sequence was GRKKRRQRRRC VEETADSTLCHILNLYRRTTWLHQALREG (with the Tat sequence underlined), and the control peptide sequence was GRKKRRQRRRC CSFNSYELGSLCYGRKKRRQRR.
CtBP dimerization assay
CtBP1-HA and CtBP1-Flag expression constructs were generated by PCR amplification of full length CtBP1 coding sequence from mouse brain-derived cDNA, followed by cloning in-frame into pSelect-CHA-zeo (Invivogen, San Diego, CA) and pCMV-(DYKDDDDK)-C (Clontech, Mountain View, CA) vectors, respectively. Clone identity and integrity were verified by sequence analysis. COS7 cells were grown to 75% confluence in 6-well plates in Dulbecco’s minimal essential medium containing fetal bovine serum and 230 µm sodium pyruvate. Five micrograms of each plasmid per plate was transfected using Lipofectamine2000 (Life Technologies, Inc., Grand Island, NY). 24 h post transfection, cells were washed once in 1X PBS and lysed in NP-40 buffer (20 mM Tris-HCl pH 8.0, 137 mM NaCl, 10% glycerol, 1% Nonidet P-40, 2 mM EDTA) containing Complete Mini protease inhibitor cocktail (Roche, Indianapolis, IN). Lysates were cleared of cellular debris by brief centrifugation and concentration determined by Pierce BCA Protein Assay (Thermo Scientific, Rockford, IL). Forty micrograms of protein from each sample lysate was incubated at 37 °C for 20 min either with or without the addition of 50 µm CtBP peptide. In some studies incubation solution also contained 10 mM sodium lactate and 10 µm NADH to promote CtBP dimerization. Co-immunoprecipitation was performed by overnight incubation of samples with 2 µg mouse monoclonal ANTI-FLAG M2 antibody (Sigma-Aldrich, # F3165), 3 h incubation with 40 µl prewashed protein A/G-Sepharose beads (Biovision Inc., Milpitas, CA) and serially washed with NP-40 buffer per manufacturer’s instructions. Bound protein was eluted from Sepharose beads by addition of NuPAGE LDS Sample buffer (Life Technologies, Inc.) and analyzed by standard SDS-PAGE gel electrophoresis using polyclonal rabbit anti-HA antibody (Thermo Scientific, # PA1-985, 1:500 dilution).
In all cell culture or slice culture studies the ‘n’ values denote the number of independent experiments, each using neurons prepared from different mice. Each independent experiment contained triplicate culture wells. Data other than the microarray results are expressed as means ± SEM and assessed using one-way ANOVA followed by either the Tukey–Kramer test where multiple groups are compared against one another, or Dunnett’s test where multiple groups are compared against a common control group. All data analyses were performed while blinded to the treatment conditions.
The microarray data that support the findings of this study are available in FigShare with the identifier https://doi.org/10.6084/m9.figshare.c.3828235.v1. The authors declare that all other relevant data supporting the findings of the study are available in this article and its Supplementary Information files, or from the corresponding author upon request.
Brown, G. C. & Neher, J. J. Inflammatory neurodegeneration and mechanisms of microglial killing of neurons. Mol. Neurobiol. 41, 242–247 (2010).
Chen, Y., Won, S. J., Xu, Y. & Swanson, R. A. Targeting microglial activation in stroke therapy: pharmacological tools and gender effects. Curr. Med. Chem. 21, 2146–2155 (2014).
An, C. et al. Molecular dialogs between the ischemic brain and the peripheral immune system: dualistic roles in injury and repair. Prog. Neurobiol. 115, 6–24 (2014).
Loane, D. J. & Byrnes, K. R. Role of microglia in neurotrauma. Neurotherapeutics 7, 366–377 (2010).
Longo, V. D. & Mattson, M. P. Fasting: molecular mechanisms and clinical applications. Cell Metab. 19, 181–192 (2014).
Goth, A. Inhibition of anaphylactoid edema in the rat by 2-deoxyglucose. Am. J. Physiol. 197, 1056–1058 (1959).
Gasior, M., Rogawski, M. A. & Hartman, A. L. Neuroprotective and disease-modifying effects of the ketogenic diet. Behav. Pharmacol. 17, 431–439 (2006).
Yu, Z. F. & Mattson, M. P. Dietary restriction and 2-deoxyglucose administration reduce focal ischemic brain damage and improve behavioral outcome: evidence for a preconditioning mechanism. J. Neurosci. Res. 57, 830–839 (1999).
Loncarevic-Vasiljkovic, N. et al. Caloric restriction suppresses microglial activation and prevents neuroapoptosis following cortical injury in rats. PLoS ONE 7, e37215 (2012).
Tu, Y. F., Lu, P. J., Huang, C. C., Ho, C. J. & Chou, Y. P. Moderate dietary restriction reduces p53-mediated neurovascular damage and microglia activation after hypoxic ischemia in neonatal brain. Stroke 43, 491–498 (2012).
Appelberg, K. S., Hovda, D. A. & Prins, M. L. The effects of a ketogenic diet on behavioral outcome after controlled cortical impact injury in the juvenile and adult rat. J. Neurotrauma 26, 497–506 (2009).
Wang, Q. et al. Pyruvate protects against experimental stroke via an anti-inflammatory mechanism. Neurobiol. Dis. 36, 223–231 (2009).
Kaur, C., Rathnasamy, G. & Ling, E. A. Roles of activated microglia in hypoxia induced neuroinflammation in the developing brain and the retina. J. Neuroimmune Pharmacol. 8, 66–78 (2012).
Robbins, N. M. & Swanson, R. A. Opposing effects of glucose on stroke and reperfusion injury: acidosis, oxidative stress, and energy metabolism. Stroke 45, 1881–1886 (2014).
Hotamisligil, G. S. Inflammation and metabolic disorders. Nature 444, 860–867 (2006).
Ghosh, S., George, S., Roy, U., Ramachandran, D. & Kolthur-Seetharam, U. NAD: a master regulator of transcription. Biochim. Biophys. Acta 1799, 681–693 (2010).
Hildebrand, J. D. & Soriano, P. Overlapping and unique roles for C-terminal binding protein 1 (CtBP1) and CtBP2 during mouse development. Mol. Cell Biol. 22, 5296–5307 (2002).
Chinnadurai, G. Transcriptional regulation by C-terminal binding proteins. Int. J. Biochem. Cell Biol. 39, 1593–1607 (2007).
Kuppuswamy, M. et al. Role of the PLDLS-binding cleft region of CtBP1 in recruitment of core and auxiliary components of the corepressor complex. Mol. Cell Biol. 28, 269–281 (2008).
Kim, J. H., Cho, E. J., Kim, S. T. & Youn, H. D. CtBP represses p300-mediated transcriptional activation by direct association with its bromodomain. Nat. Struct. Mol. Biol. 12, 423–428 (2005).
Birts, C. N. et al. A cyclic peptide inhibitor of C-terminal binding protein dimerization links metabolism with mitotic fidelity in breast cancer cells. Chem. Sci. 4, 3046–3057 (2013).
Bhambhani, C., Chang, J. L., Akey, D. L. & Cadigan, K. M. The oligomeric state of CtBP determines its role as a transcriptional co-activator and co-repressor of Wingless targets. EMBO J. 30, 2031–2043 (2011).
Verger, A. et al. Mechanisms directing the nuclear localization of the CtBP family proteins. Mol. Cell Biol. 26, 4882–4894 (2006).
Quinlan, K. G. et al. Role of the C-terminal binding protein PXDLS motif binding cleft in protein interactions and transcriptional repression. Mol. Cell Biol. 26, 8202–8213 (2006).
Chen, L. F., Mu, Y. & Greene, W. C. Acetylation of RelA at discrete sites regulates distinct nuclear functions of NF-kappaB. EMBO J. 21, 6539–6548 (2002).
Zhang, Q., Piston, D. W. & Goodman, R. H. Regulation of corepressor function by nuclear NADH. Science 295, 1895–1897 (2002).
Garriga-Canut, M. et al. 2-Deoxy-D-glucose reduces epilepsy progression by NRSF-CtBP-dependent metabolic regulation of chromatin structure. Nat. Neurosci. 9, 1382–1387 (2006).
Yao, J., Chen, S., Mao, Z., Cadenas, E. & Brinton, R. D. 2-Deoxy-D-glucose treatment induces ketogenesis, sustains mitochondrial function, and reduces pathology in female mouse model of Alzheimer’s disease. PLoS ONE 6, e21788 (2011).
Forstermann, U. & Kleinert, H. Nitric oxide synthase: expression and expressional control of the three isoforms. Naunyn Schmiedebergs Arch. Pharmacol. 352, 351–364 (1995).
Williamson, D. H., Lund, P. & Krebs, H. A. The redox state of free nicotinamide-adenine dinucleotide in the cytoplasm and mitochondria of rat liver. Biochem. J. 103, 514–527 (1967).
Alano, C. C. et al. Differences among cell types in NAD(+) compartmentalization: A comparison of neurons, astrocytes, and cardiac myocytes. J. Neurosci. Res. 85, 3378–3385 (2007).
Karovic, O. et al. Toxic effects of cobalt in primary cultures of mouse astrocytes. Similarities with hypoxia and role of HIF-1alpha. Biochem. Pharmacol. 73, 694–708 (2007).
Poole, R. C. & Halestrap, A. P. Transport of lactate and other monocarboxylates across mammalian plasma membranes. Am. J. Physiol. 264, C761–782 (1993).
Reiss, P. D., Zuurendonk, P. F. & Veech, R. L. Measurement of tissue purine, pyrimidine, and other nucleotides by radial compression high-performance liquid chromatography. Anal. Biochem. 140, 162–171 (1984).
Ying, W. NAD+/NADH and NADP+/NADPH in cellular functions and cell death: regulation and biological consequences. Antioxid. Redox Signal 10, 179–206 (2008).
Palero, J. A. et al. In vivo monitoring of protein-bound and free NADH during ischemia by nonlinear spectral imaging microscopy. Biomed. Opt. Express 2, 1030–1039 (2011).
Nardini, M. et al. CtBP/BARS: a dual-function protein involved in transcription co-repression and Golgi membrane fission. EMBO J. 22, 3122–3130 (2003).
Qin, H. et al. Signal transducer and activator of transcription-3/suppressor of cytokine signaling-3 (STAT3/SOCS3) axis in myeloid cells regulates neuroinflammation. Proc. Natl Acad. Sci. USA 109, 5004–5009 (2012).
Meloni, A. R., Lai, C. H., Yao, T. P. & Nevins, J. R. A mechanism of COOH-terminal binding protein-mediated repression. Mol. Cancer Res. 3, 575–583 (2005).
Di, L. J., Fernandez, A. G., De Siervi, A., Longo, D. L. & Gardner, K. Transcriptional regulation of BRCA1 expression by a metabolic switch. Nat. Struct. Mol. Biol. 17, 1406–1413 (2011).
Zhang, Q. et al. Redox sensor CtBP mediates hypoxia-induced tumor cell migration. Proc. Natl Acad. Sci. USA 103, 9029–9033 (2006).
Fjeld, C. C., Birdsong, W. T. & Goodman, R. H. Differential binding of NAD+ and NADH allows the transcriptional corepressor carboxyl-terminal binding protein to serve as a metabolic sensor. Proc. Natl Acad. Sci. USA 100, 9202–9207 (2003).
McGettrick, A. F. & O’Neill, L. A. How metabolism generates signals during innate immunity and inflammation. J. Biol. Chem. 288, 22893–22898 (2013).
Feldman, J. L., Dittenhafer-Reed, K. E. & Denu, J. M. Sirtuin catalysis and regulation. J. Biol. Chem. 287, 42419–42427 (2012).
Bergman, L. M. et al. Role of the unique N-terminal domain of CtBP2 in determining the subcellular localisation of CtBP family proteins. BMC Cell Biol. 7, 35 (2006).
Saijo, K., Collier, J. G., Li, A. C., Katzenellenbogen, J. A. & Glass, C. K. An ADIOL-ERbeta-CtBP transrepression pathway negatively regulates microglia-mediated inflammation. Cell 145, 584–595 (2011).
Xu, X. et al. EVI1 acts as an inducible negative-feedback regulator of NF-kappaB by inhibiting p65 acetylation. J. Immunol. 188, 6371–6380 (2012).
Moon, J. S. et al. mTORC1-Induced HK1-dependent glycolysis regulates NLRP3 inflammasome activation. Cell Rep. 12, 102–115 (2015).
Wang, B. et al. Glycolysis-dependent histone deacetylase 4 degradation regulates inflammatory cytokine production. Mol. Biol. Cell 25, 3300–3307 (2015).
Manigrasso, M. B., Juranek, J., Ramasamy, R. & Schmidt, A. M. Unlocking the biology of RAGE in diabetic microvascular complications. Trends Endocrinol. Metab. 25, 15–22 (2014).
Warburg, O. On respiratory impairment in cancer cells. Science 124, 269–270 (1956).
Calle, M. C. & Fernandez, M. L. Inflammation and type 2 diabetes. Diabetes Metab. 38, 183–191 (2012).
Horvath, P. et al. Fasting glucose level modulates cell surface expression of CD11b and CD66b in granulocytes and monocytes of patients with type 2 diabetes. J. Investig. Med. 61, 972–977 (2013).
Lowenstein, C. J. et al. Macrophage nitric oxide synthase gene: two upstream regions mediate induction by interferon gamma and lipopolysaccharide. Proc. Natl Acad. Sci. USA 90, 9730–9734 (1993).
Suh, S. W. et al. Glucose and NADPH oxidase drive neuronal superoxide formation in stroke. Ann. Neurol. 64, 654–663 (2008).
Kauppinen, T. M. et al. Zinc triggers microglial activation. J. Neurosci. 28, 5827–5835 (2008).
d’Avila, J. C. et al. Microglial activation induced by brain trauma is suppressed by post-injury treatment with a PARP inhibitor. J. Neuroinflammation 9, 31 (2012).
del Rio, J. A. & Soriano, E. Regenerating cortical connections in a dish: the entorhino-hippocampal organotypic slice co-culture as tool for pharmacological screening of molecules promoting axon regeneration. Nat. Protoc. 5, 217–226 (2010).
Brennan, A. M., Connor, J. A. & Shuttleworth, C. W. NAD(P)H fluorescence transients after synaptic activity in brain slices: predominant role of mitochondrial function. J. Cereb. Blood Flow Metab. 26, 1389–1406 (2006).
Huber, W., von Heydebreck, A., Sultmann, H., Poustka, A. & Vingron, M. Variance stabilization applied to microarray data calibration and to the quantification of differential expression. Bioinformatics 18(Suppl 1): S96–104 (2002).
Smyth, G. K. Linear models and empirical bayes methods for assessing differential expression in microarray experiments. Stat. Appl. Genet. Mol. Biol. 3, Article3 (2004).
Shen, Y. et al. Mutations in PNKD causing paroxysmal dyskinesia alters protein cleavage and stability. Hum. Mol. Genet. 20, 2322–2332 (2011).
Saijo, K. et al. A Nurr1/CoREST pathway in microglia and astrocytes protects dopaminergic neurons from inflammation-induced death. Cell 137, 47–59 (2009).
Zschiedrich, I. et al. Coactivator function of RIP140 for NFkappaB/RelA-dependent cytokine gene expression. Blood 112, 264–276 (2008).
We thank J. Blaydes for the CtBP2 G189A plasmid, C. Lowenstein for the iNOS promoter-luciferase reporter, W. Sellers for the p300 plasmid, W. Greene for the p65 plasmid, and A. Roopra for the FLAG-tagged CtBP2 plasmid, the CtBP1,2 −/− MEF cell lines, and constructive discussions. This work was supported by the NIH (NS041421) and the Dept. of Veterans Affairs.
The authors declare no competing financial interests.
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Shen, Y., Kapfhamer, D., Minnella, A.M. et al. Bioenergetic state regulates innate inflammatory responses through the transcriptional co-repressor CtBP. Nat Commun 8, 624 (2017). https://doi.org/10.1038/s41467-017-00707-0
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