BackgroundOur original demonstration of immunomodulatory effects of erythropoietin in multiple myeloma led us to the search for the cells in the immune system that are direct targets for erythropoietin. The finding that lymphocytes do not express erythropoietin receptors led to the hypothesis that other cells act as direct targets and thus mediate the effects of erythropoietin. The finding that erythropoietin has effects on dendritic cells thus led to the question of whether macrophages act as target cells for erythropoietin. Design and MethodsThe effects of erythropoietin on macrophages were investigated both in-vivo and in-vitro. The in-vivo studies were performed on splenic macrophages and inflammatory peritoneal macrophages, comparing recombinant human erythropoietin-treated and untreated mice, as well as transgenic mice over-expressing human erythropoietin (tg6) and their control wild-type counterparts. The in-vitro effects of erythropoietin on macrophage surface markers and function were investigated in murine bone marrow-derived macrophages treated with recombinant human erythropoietin. ResultsErythropoietin was found to have effects on macrophages in both the in-vivo and in-vitro experiments. In-vivo treatment led to increased numbers of splenic macrophages, and of the splenic macrophages expressing CD11b, CD80 and major histocompatibility complex class II. The peritoneal inflammatory macrophages obtained from erythropoietin-treated mice displayed increased expression of F4/80, CD11b, CD80 and major histocompatibility complex class II, and augmented phagocytic activity. The macrophages derived in-vitro from bone marrow cells expressed erythropoietin receptor transcripts, and in-vitro stimulation with erythropoietin activated multiple signaling pathways, including signal transducer and activator of transcription (STAT)1 and 5, mitogen-activated protein kinase, phosphatidylinositol 3-kinase and nuclear factor kappa B. In-vitro erythropoietin treatment of these cells up-regulated their surface expression of CD11b, F4/80 and CD80, enhanced their phagocytic activity and nitric oxide secretion, and also led to augmented interleukin 12 secretion and decreased interleukin 10 secretion in response to lipopolysaccharide. ConclusionsOur results show that macrophages are direct targets of erythropoietin and that erythropoietin treatment enhances the pro-inflammatory activity and function of these cells. These findings point to a multifunctional role of erythropoietin and its potential clinical applications as an immunomodulating agent.Key words: erythropoietin receptor, pro-inflammation, macrophages, signal transducer and activator of transcription (STAT).Citation: Lifshitz L, Tabak G, Gassmann M, Mittelman M, and Neumann D. Macrophages as novel target cells for erythropoietin. Haematologica 2010;95(11):1823-1831. doi:10.3324/haematol.2010 This is an open-access paper. Macrophages as novel target cells for erythropoietin
Key pointsr The G-protein coupled inwardly rectifying potassium (GIRK) channel is an important mediator of neurotransmission via Gβγ subunit of the heterotrimeric G i/o protein released by G-protein coupled receptor (GPCR) activation.r Channels containing the GIRK1 subunit exhibit high basal currents, whereas channels that are formed by the GIRK2 subunit have very low basal currents.r GIRK1-containing channels, but not channels consisting of GIRK2 only, recruit Gβγ to the plasma membrane. The Gα subunit of the G protein is not recruited by either GIRK1/2 or GIRK2.r The unique distal C terminus of GIRK1 (G1-dCT) endows the channel with strong interaction with Gβγ, and deletion of G1-dCT abolishes the Gβγ recruitment and reduces the basal currents.r These findings suggest that the basal activity of GIRK channels depends on channel-induced recruitment of Gβγ. The unique C terminus of GIRK1 subunit plays an important role in Gβγ recruitment.Abstract The G-protein coupled inwardly rectifying potassium (GIRK, or Kir3) channels are important mediators of inhibitory neurotransmission via activation of G-protein coupled receptors (GPCRs). GIRK channels are tetramers comprising combinations of subunits (GIRK1-4), activated by direct binding of the Gβγ subunit of G i/o proteins. Heterologously expressed GIRK1/2 exhibit high, Gβγ-dependent basal currents (I basal ) and a modest activation by GPCR or coexpressed Gβγ. Inversely, the GIRK2 homotetramers exhibit low I basal and strong activation by Gβγ. The high I basal of GIRK1 seems to be associated with its unique distal C terminus (G1-dCT), which is not present in the other subunits. We investigated the role of G1-dCT using electrophysiological and fluorescence assays in Xenopus laevis oocytes and protein interaction assays. We show that expression of GIRK1/2 increases the plasma membrane level of coexpressed Gβγ (a phenomenon we term 'Gβγ recruitment') but not of coexpressed Gα i3 . All GIRK1-containing channels, but not GIRK2 homomers, recruited Gβγ to the plasma membrane. In biochemical assays, truncation of G1-dCT reduces the binding between the cytosolic parts of GIRK1 and Gβγ, but not Gα i3 . Nevertheless, the truncation of G1-dCT does not impair activation by Gβγ. In fluorescently labelled homotetrameric GIRK1 channels and in the heterotetrameric GIRK1/2 channel, the truncation of G1-dCT abolishes Gβγ recruitment and decreases I basal . Thus, we conclude that G1-dCT carries an essential role in Gβγ recruitment by GIRK1 and, consequently, in determining its high basal activity. Our results indicate that G1-dCT is a crucial part of a Gβγ anchoring site of GIRK1-containing channels, spatially and functionally distinct from the site of channel activation by Gβγ.
De novo mutations in GNB1, encoding the Gβ1 subunit of G proteins, cause a neurodevelopmental disorder with global developmental delay and epilepsy. Mice carrying a pathogenic mutation, K78R, recapitulate aspects of the disorder, including developmental delay and frequent spike-wave discharges (SWD). Cultured mutant cortical neurons display aberrant bursting activity on multi-electrode arrays. Strikingly, the antiepileptic drug ethosuximide (ETX) restores normal neuronal network behavior in vitro and suppresses SWD in vivo. In contrast, while valproic acid suppresses SWD, it does not restore normal network behavior, suggesting that ETX has mechanistic specificity for the effects of aberrant Gβ1 signaling. Consistent with this, we show that K78R is a gain-of-function of G protein-coupled potassium channel (GIRK) activation that is potently inhibited by ETX. This work suggests that altered Gβ1 signaling causes disease in part through effects on GIRK channels, illustrates the utility of cultured neuronal networks in pharmacological screening, and establishes effective pre-clinical models for GNB1 Encephalopathy.
Summary Mutations in the GNB1 gene, encoding the Gβ 1 subunit of heterotrimeric G proteins, cause GNB1 Encephalopathy. Patients experience seizures, pointing to abnormal activity of ion channels or neurotransmitter receptors. We studied three Gβ 1 mutations (K78R, I80N and I80T) using computational and functional approaches. In heterologous expression models, these mutations did not alter the coupling between G protein-coupled receptors to G i/o , or the Gβγ regulation of the neuronal voltage-gated Ca 2+ channel Ca V 2.2. However, the mutations profoundly affected the Gβγ regulation of the G protein-gated inwardly rectifying potassium channels (GIRK, or Kir3). Changes were observed in Gβ 1 protein expression levels, Gβγ binding to cytosolic segments of GIRK subunits, and in Gβγ function, and included gain-of-function for K78R or loss-of-function for I80T/N, which were GIRK subunit-specific. Our findings offer new insights into subunit-dependent gating of GIRKs by Gβγ, and indicate diverse etiology of GNB1 Encephalopathy cases, bearing a potential for personalized treatment.
The tetrameric G protein-gated K+ channels (GIRKs) mediate inhibitory effects of neurotransmitters that activate Gi/o-coupled receptors. GIRKs are activated by binding of the Gβγ dimer, via contacts with Gβ. Gγ underlies membrane targeting of Gβγ, but has not been implicated in channel gating. We observed that, in Xenopus oocytes, expression of Gγ alone activated homotetrameric GIRK1* and heterotetrameric GIRK1/3 channels, without affecting the surface expression of GIRK or Gβ. Gγ and Gβ acted interdependently: the effect of Gγ required the presence of ambient Gβ and was enhanced by low doses of coexpressed Gβ, whereas excess of either Gβ or Gγ imparted suboptimal activation, possibly by sequestering the other subunit “away” from the channel. The unique distal C-terminus of GIRK1, G1-dCT, was important but insufficient for Gγ action. Notably, GIRK2 and GIRK1/2 were not activated by Gγ. Our results suggest that Gγ regulates GIRK1* and GIRK1/3 channel’s gating, aiding Gβ to trigger the channel’s opening. We hypothesize that Gγ helps to relax the inhibitory effect of a gating element (“lock”) encompassed, in part, by the G1-dCT; GIRK2 acts to occlude the effect of Gγ, either by setting in motion the same mechanism as Gγ, or by triggering an opposing gating effect.
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