Mass spectrometry analyses of normal and polyglutamine expanded ataxin-3 reveal novel interaction partners involved in mitochondrial function.

Deubiquitinating enzymes (DUBs) play important roles in a variety of cellular processes, including regulation of protein homeostasis. The DUB ataxin-3 is an enzyme implicated in protein quality control mechanisms. In the neurodegenerative disease spinocerebellar ataxia type 3 (SCA3), ataxin-3 contains an expanded polyglutamine (polyQ) stretch that leads to aggregation of the protein and neuronal dysfunction. Increasing the understanding of ataxin-3 protein interaction partners could help to elucidate disease mechanisms. Hence, we analyzed the repertoire of proteins interacting with normal and polyQ expanded ataxin-3 by mass spectrometry. This showed that both normal and polyQ expanded ataxin-3 interacted with components of the protein quality control system and mitochondria. Five proteins showed increased interaction with polyQ expanded ataxin-3 relative to normal and three of these were mitochondrial proteins. The analyses underline the role of ataxin-3 in ubiquitin biology and point towards a role in mitochondrial biology.

Polyglutamine expansion of ataxin-3 alters its degree of ubiquitination and phosphorylation at specific sites.

Ubiquitination and phosphorylation of proteins represent post translational modifications (PTMs) capable of regulating a variety of cellular processes. In the neurodegenerative disorder spinocerebellar ataxia type 3 (SCA3), the disease causing protein ataxin-3 carries an expanded polyglutamine (polyQ) stretch causing it to aggregate in nuclear inclusions. These inclusions are decorated with ubiquitin suggestive of a malfunction in the clearance of the mutant protein. Differences in ubiquitin chain topology between normal and polyQ expanded ataxin-3 could be involved in the differential clearance of the two proteins and play a role in SCA3 pathogenesis. Likewise, changes in phosphorylation patterns between the two variants could contribute to pathogenic processes involved in SCA3. We therefore determined the ubiquitination and phosphorylation patterns, together with the ubiquitin-linkage types associated with normal and polyQ expanded ataxin-3 by mass spectrometry (MS). This analysis revealed a similar ubiquitin linkage pattern on normal and expanded ataxin-3. However, the distribution of ubiquitinated lysine residues was altered in polyQ expanded ataxin-3, with increased ubiquitination at the new identified ubiquitination site lysine-8. MS analysis of phosphorylation also revealed novel phosphorylation sites in ataxin-3, and an increase in phosphorylation of expanded ataxin-3 at several positions. The study suggests that differences in clearance of normal and expanded ataxin-3 are not attributed to differences in ubiquitin-linkage pattern. However, the observed differences between the normal and polyQ expanded ataxin-3 with respect to the degree of ubiquitination and phosphorylation on specific sites may have an impact on ataxin-3 function and SCA3 pathogenesis.

GPR119, a Major Enteroendocrine Sensor of Dietary Triglyceride Metabolites Coacting in Synergy With FFA1 (GPR40).

Triglycerides (TGs) are among the most efficacious stimulators of incretin secretion; however, the relative importance of FFA1 (G Protein-coupled Receptor [GPR] 40), FFA4 (GPR120), and GPR119, which all recognize TG metabolites, ie, long-chain fatty acid and 2-monoacylglycerol, respectively, is still unclear. Here, we find all 3 receptors to be highly expressed and highly enriched in fluorescence-activated cell sorting-purified GLP-1 and GIP cells isolated from transgenic reporter mice. In vivo, the TG-induced increase in plasma GIP was significantly reduced in FFA1-deficient mice (to 34%, mean of 4 experiments each with 8-10 animals), in GPR119-deficient mice (to 24%) and in FFA1/FFA4 double deficient mice (to 15%) but not in FFA4-deficient mice. The TG-induced increase in plasma GLP-1 was only significantly reduced in the GPR119-deficient and the FFA1/FFA4 double deficient mice, but not in the FFA1, and FFA4-deficient mice. In mouse colonic crypt cultures the synthetic FFA1 agonists, TAK-875 stimulated GLP-1 secretion to a similar extent as the prototype GLP-1 secretagogue neuromedin C; this, however, only corresponded to approximately half the maximal efficiency of the GPR119 agonist AR231453, whereas the GPR120 agonist Metabolex-209 had no effect. Importantly, when the FFA1 agonist was administered on top of appropriately low doses of the GPR119 agonist, a clear synergistic, ie, more than additive, effect was observed. It is concluded that the 2-monoacylglycerol receptor GPR119 is at least as important as the long-chain fatty acid receptor FFA1 in mediating the TG-induced secretion of incretins and that the 2 receptors act in synergy, whereas FFA4 plays a minor if any role.

Seven transmembrane G protein-coupled receptor repertoire of gastric ghrelin cells.

The molecular mechanisms regulating secretion of the orexigenic-glucoregulatory hormone ghrelin remain unclear. Based on qPCR analysis of FACS-purified gastric ghrelin cells, highly expressed and enriched 7TM receptors were comprehensively identified and functionally characterized using in vitro, ex vivo and in vivo methods. Five Gαs-coupled receptors efficiently stimulated ghrelin secretion: as expected the ß1-adrenergic, the GIP and the secretin receptors but surprisingly also the composite receptor for the sensory neuropeptide CGRP and the melanocortin 4 receptor. A number of Gαi/o-coupled receptors inhibited ghrelin secretion including somatostatin receptors SSTR1, SSTR2 and SSTR3 and unexpectedly the highly enriched lactate receptor, GPR81. Three other metabolite receptors known to be both Gαi/o- and Gαq/11-coupled all inhibited ghrelin secretion through a pertussis toxin-sensitive Gαi/o pathway: FFAR2 (short chain fatty acid receptor; GPR43), FFAR4 (long chain fatty acid receptor; GPR120) and CasR (calcium sensing receptor). In addition to the common Gα subunits three non-common Gαi/o subunits were highly enriched in ghrelin cells: GαoA, GαoB and Gαz. Inhibition of Gαi/o signaling via ghrelin cell-selective pertussis toxin expression markedly enhanced circulating ghrelin. These 7TM receptors and associated Gα subunits constitute a major part of the molecular machinery directly mediating neuronal and endocrine stimulation versus metabolite and somatostatin inhibition of ghrelin secretion including a series of novel receptor targets not previously identified on the ghrelin cell.

K(v) 7 (KCNQ) channel openers normalize central 2-deoxyglucose uptake in a mouse model of mania and increase prefrontal cortical and hippocampal serine-9 phosphorylation levels of GSK3ß.

Several metabolic neuroimaging studies have indicated that bipolar patients with mania exhibit alterations in metabolic activity, suggesting that perturbations in corticolimbic function contribute to the functional deficits associated with the disease. Because pharmacological stimulation of K(v)7 channel function has shown anti-manic like efficacy in the D-amphetamine and chlordiazepoxide (AMPH+CDP) induced hyperactivity mouse model of mania, we addressed whether this effect of K(v)7 channels could be associated with changes in cerebral [¹4C]2-deoxyglucose (2-DG) uptake, a surrogate marker of brain metabolic activity. Acute administration of the Kv7 channel modulators, retigabine (pan K(v)7.2-K(v)7.5 channel opener) and ICA-27243 (K(v)7.2/K(v)7.3 channel-preferring opener) reduced 2-DG uptake in several mouse forebrain structures with a brain regional signature similar to the mood stabilizers, lithium and valproate. Combined administration of AMPH+CDP enhanced 2-DG uptake in the striatum, cortex and thalamus, and both retigabine and ICA-27243 fully prevented this stimulatory effect of AMPH+CDP. In addition, both K(v)7 channel openers dose-dependently increased phospho-serine-9 levels of GSK3ß in the prefrontal cortex and hippocampus, a common molecular mechanism shared by anti-manic drugs. In combination, these data emphasize the potential of K(v)7 channel openers in the treatment of bipolar disorder, and suggest that heteromeric K(v)7.2/K(v)7.3 channels may present a novel anti-manic therapeutic target.

Kv7 (KCNQ) channel openers induce hypothermia in the mouse.

Kv7 channels, encoded by corresponding kcnq genes, are expressed both centrally and peripherally where they serve to dampen neuronal activity. While Kv7 channel openers have shown efficacy in neurological and neuropsychiatric disease models, the impact of Kv7 channel activation on physiological endpoint markers have not been addressed in detail. In this study we assessed the effect of a range of Kv7 channel openers with different affinity for neuronal Kv7.2-5 channel subunits on body temperature regulation in mice. Female NMRI mice were acutely exposed to vehicle (10% Tween-80, i.p.), retigabine (3-30 mg/kg, i.p., pan-Kv7 channel opener), (S)BMS-204352 (60-240 mg/kg, i.p., Kv7.4/5 channel-preferring opener), ICA-27243 (1-10mg/kg, i.p., Kv7.2/3 channel-preferring opener), or S-(1) (10-60 mg/kg, i.p., Kv7.2/3 channel-preferring opener), and rectal body temperature was measured 15-120 min post-injection. Retigabine (>10mg/kg), ICA-27243 (≥ 10 mg/kg), and S-(1) (≥ 30 mg/kg) dose-dependently lowered rectal body temperature with maximal doses of each Kv7 channel opener inducing a marked drop (>4°C) in rectal temperature. The Kv7 channel openers showed differential temporal pharmacodynamics, which likely reflects their different pharmacokinetic profiles. Pretreatment with the pan-Kv7 channel blocker XE-991 (1.0mg/kg, i.p.) completely reversed the hypothermic effect of the pan-Kv7 opener, retigabine (15 mg/kg), whereas ICA-27243-induced hypothermia (10mg/kg) could only be partially prevented by XE-991. Because ICA-27743 and S-(1) are Kv7.2/3 channel subunit-preferring compounds, this suggests that the Kv7.2/3 channel isoform is the predominant substrate for Kv7 channel opener-evoked hypothermia. These data indicate the physiological relevance of Kv7 channel function on body temperature regulation which may potentially reside from central inhibitory Kv7 channel activity.