Methylosome protein 50 associates with the purinergic receptor P2X5 and is involved in osteoclast maturation.

Purinergic signaling plays important roles in bone. P2X5, a member of ligand-gated ion channel receptors, has been demonstrated to regulate osteoclast maturation. However, the molecular mechanism of P2X5-mediated osteoclast regulation remains unclear. Here, we identified methylosome protein 50 (MEP50), a critical cofactor of the protein arginine methyltransferase 5 (PRMT5), as a P2X5-associating molecule. RNAi-mediated knockdown of MEP50 results in decreased formation of mature osteoclasts. MEP50 associates with P2X5, and this association requires the C-terminal intracellular region of P2X5. Additionally, impaired maturation of P2X5-deficient osteoclasts could be restored by transduction of full-length P2X5, but not a C-terminal deletion mutant of P2X5. These results indicate that P2X5 associates with MEP50 and suggest a link between the PRMT5 complex and P2X5 signaling in osteoclast maturation.

Altered allostery of the left flipper domain underlies the weak ATP response of rat P2X5 receptors.

Although the extracellular ATP-gated cation channel purinergic receptor P2X5 is widely expressed in heart, skeletal muscle, and immune and nervous systems in mammals, little is known about its functions and channel-gating activities. This lack of knowledge is due to P2X5's weak ATP responses in several mammalian species, such as humans, rats, and mice. WT human P2X5 (hP2X5Δ328-349) does not respond to ATP, whereas a full-length variant, hP2X5 (hP2X5-FL), containing exon 10 encoding the second hP2X5 transmembrane domain (TM2), does. However, although rat P2X5 (rP2X5) has a full-length TM2, ATP induces only weak currents in rP2X5, which prompted us to investigate the mechanism underlying this small ATP response. Here, we show that single replacements of specific rP2X5 residues with the corresponding residues in hP2X5 (S191F or F195H) significantly enhance the current amplitude of rP2X5. Using a combination of engineered disulfide cross-linking, single-channel recording, and molecular modeling, we interrogated the effects of S191F and F195H substitutions on the allostery of the left flipper (LF) domain. On the basis of our findings, we propose that the bound ATP-induced distinct allostery of the LF domain with that of other functional subtypes has caused the weak ATP response of rP2X5 receptors. The findings of our study provide the prerequisite for future transgenic studies on the physiological and pathological functions of P2X5 receptors.

Functional characterization of P2Y1 and P2X4 receptors in human neuroblastoma SK-N-MC cells / Caracterización funcional de receptores P2Y1 y P2X4 en células SK-N-MC de neuroblastoma humano

Nucleotides are important signalling molecules in both the peripheral and central nervous system. However, the in vitro study of their receptors can be hampered by the heterogeneity of primary neuronal cultures. The use of clonal neuroblastoma cell lines allows to circumvent this difficulty, so these lines are often used as a model to analyze the properties, regulation and physiological role of nucleotide receptors in neural tissues. Expression studies indicated the presence of P2Y1, P2Y6, P2Y11, P2Y13, P2X1, P2X4, P2X5, P2X6 and P2X7 proteins in SK-N-MC cells. Functional analyses showed transient [Ca2+]i increases upon application of ADP, 2-MeSADP or ADPβS. Responses to these agonists seem to be mediated by a P2Y1 receptor, as demonstrated by the almost complete blockade exerted by the P2Y1-selective antagonist MRS2179. ATP was also able to induce [Ca2+]i increases in SK-N-MC cells. Responses to ATP were partially blocked by MRS2179 and the P2X antagonist TNP-ATP, thus suggesting that ATP can interact with two different P2 receptors: a P2Y1 receptor, inhibited by MRS2179, and a TNP-ATP sensitive P2X receptor. To characterize the P2X receptor responsible for the MRS2179-resistant component of the ATP response, we analyze the effect of several P2X agonists on [Ca2+]i. Cells did not show responses to either α,β-meATP or BzATP, although [Ca2+]i increases could be observed when cells were challenged with CTP. Both the response to CTP and the MRS2179-resistant component of ATP response were potentiated by ivermectin. Such pharmacological profile is consistent with the presence of a functional P2X4 receptor in SK-N-MC cell line

Los nucleótidos son importantes moléculas señalizadoras en el sistema nervioso. El estudio in vitro de sus receptores puede verse obstaculizado por la heterogeneidad de los cultivos neuronales. El uso de líneas celulares de neuroblastoma permite eludir esta dificultad y dichas líneas se utilizan frecuentemente como un modelo con el que analizar las propiedades, regulación y función de los receptores de nucleótidos en tejidos neurales. Estudios de expresión indicaron la presencia de proteínas P2Y1, P2Y6, P2Y11, P2Y13, P2X1, P2X4, P2X5, P2X6 y P2X7 en las células SK-N-MC. Análisis funcionales mostraron incrementos transitorios de [Ca2+]i tras la aplicación de ADP, 2- MeSADP o ADPβS, respuestas que parecen estar mediadas a través un receptor P2Y1, como se pone de manifiesto por el bloqueo casi total ejercido por el antagonista selectivo P2Y1, MRS2179. El ATP también indujo incrementos de [Ca2+]i en las células SK-N-MC, siendo su respuesta parcialmente bloqueada por MRS2179 y por el antagonista P2X TNP-ATP, lo que sugiere que el ATP puede interactuar con dos receptores P2 diferentes: un receptor P2Y1, inhibido por MRS2179, y un receptor P2X sensible a TNP-ATP. Se caracterizó el receptor P2X analizando el efecto de varios agonistas en la [Ca2+]i. Ninguna célula mostró respuestas a α,β- meATP o BzATP, aunque se observaron incrementos de [Ca2+]i cuando las células fueron estimuladas con CTP. Tanto la respuesta a CTP como el componente de la respuesta a ATP resistente a MRS2179, se potenciaron en presencia de ivermectina. Todos estos datos sugieren la presencia de un receptor P2X4 funcional en las células SK-N-MC

A dual polybasic motif determines phosphoinositide binding and regulation in the P2X channel family.

Phosphoinositides modulate the function of several ion channels, including most ATP-gated P2X receptor channels in neurons and glia, but little is known about the underlying molecular mechanism. We identified a phosphoinositide-binding motif formed of two clusters of positively charged amino acids located on the P2X cytosolic C-terminal domain, proximal to the second transmembrane domain. For all known P2X subtypes, the specific arrangement of basic residues in these semi-conserved clusters determines their sensitivity to membrane phospholipids. Neutralization of these positive charges disrupts the functional properties of the prototypical phosphoinositide-binding P2X4 subtype, mimicking wortmannin-induced phosphoinositide depletion, whereas adding basic residues at homologous positions to the natively insensitive P2X5 subtype establishes de novo phosphoinositide-mediated regulation. Moreover, biochemical evidence of in vitro P2X subunit-phospholipid interaction and functional intracellular phosphoinositide-binding assays demonstrate that the dual polybasic cluster is necessary and sufficient for regulation of P2X signaling by phospholipids.