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Panx1 regulates neural stem and progenitor cell behaviours associated with cytoskeletal dynamics and interacts with multiple cytoskeletal elements
Cell Communication and Signaling volume 11, Article number: 62 (2013)
Abstract
Background
Pannexins (Panxs) are relatively newly discovered large-pore ion and metabolite permeable channels. Although no proteomics-based interactome has yet been published, Panx1 has been demonstrated to interact with actin in an ectopic expression system. This interaction affects both Panx1 plasma membrane stability as well as cytoskeletal remodelling. The current study builds on our recent discovery of Panx1 expression in ventricular zone (VZ) neural stem and progenitor cells (NSC/NPCs), and on the demonstrated interaction of Panx1 with the cytoskeleton.
Findings
Here we demonstrate that Panx1 also plays roles in two additional cell behaviours associated with neurogenesis, including cell migration and neurite extension. Furthermore, we confirm an endogenous interaction between actin and Panx1, and identify a new interaction with actin-related protein 3, an actin cytoskeleton-modulating protein.
Conclusions
This study further establishes the importance of Panx1 in the cell biology of NSC/NPCs and strengthens and expands our knowledge of Panx1 interactions with the cytoskeleton.
Findings
Panxs are four-pass transmembrane proteins that oligomerize to form large-pore mechanosensitive channels permeable to ions and metabolites of up to 1 kDa in size, such as adenosine triphosphate (ATP) [1, 2]. We recently detected Panx1 expression in the Neuro-2a (N2a) cell line as well as in post-natal ventricular zone (VZ) neural stem and progenitor cells (NSC/NPCs), where it positively regulates cell proliferation in part through release of ATP that results in activation of purinergic receptors. This built on earlier work demonstrating an important role of constitutively released episodic bursts of ATP in the proliferation of VZ NSC/NPCs, which in turn activates metabotropic purinergic receptors in an autocrine and paracrine manner [3–5]. Perhaps not surprisingly, as a mechanosensitive channel, recent work has shown that Panx1 is actually physically linked to the cytoskeleton. In an ectopic expression system, Panx1 was reported to physically interact directly with actin [6]. A recent study in glioma cells further supported a role for Panx1 in the dynamic regulation of actin cytoskeleton remodeling [7]. Here we extend on our previous discovery of Panx1 expression in VZ NSC/NPCs by further defining the cell-type demographics of Panx1 over the course of VZ neurogenesis, by demonstrating that Panx1 plays a role in additional cell behaviours associated with neurogenesis, including cell migration and neurite outgrowth, and by uncovering additional interactions with cytoskeletal elements, further establishing the relationship of Panx1 with the cytoskeleton.
In our previous study [8] we observed marked Panx1 expression in Nestin-positive/glial fibrillary acidic protein (Gfap)-positive and Nestin-positive/Gfap-negative NSC/NPCs, but detected little to no Panx1 expression in doublecortin (Dcx) positive neuroblasts in cultures of differentiating VZ neurospheres, and in Dcx-positive neuroblasts migrating from the dorsolateral corner of the lateral ventricle in coronal sections from immature mice (postnatal day 15; P15). To extend on these findings we investigated the expression of Panx1 in Dcx-positive cells in the adult mouse brain (P60). For a complete description of the methods used in this report, please see Additional file 1. Interestingly, we observed robust Panx1 expression in Dcx-positive cells in rostral coronal sections through the lateral ventricles, but relatively minimal Panx1 in Dcx-positive cells in more caudal coronal sections through the lateral ventricles (Figure 1C-E). The high level of Panx1 expression in rostral Dcx-positive migrating migratory neuroblasts suggested that Panx1 might play a role in modulating the process of cell migration from the VZ. To directly investigate the involvement of Panx1 in cell migration, we employed a scratch wound closure assay [9] monitored in real time (Figure 2A-C), in parallel sets of Panx1 siRNA and control siRNA treated cells. Over time, cell migration into the scratch wound leads to a decrease in width (wound closure), and thus differences in the rate of wound closure can be attributed to differences in cell migration [9]. With a knockdown in Panx1 expression of approximately 60% in Panx1 siRNA-treated cells compared with control siRNA-treated cells (Figure 2D,E), we observed a significant impairment in wound closure. In the corresponding Western blot, the expected Panx1 band is present at ~50 kDa corresponding to the full length, fully glycosylated species [10, 11]. The observed lower band was not always present on Western blots of N2a lysates (For example see Figure 3); however when present, it was specifically knocked down by the siRNA. This suggests that it is indeed a form of Panx1 and likely represents one of the lower, less glycosylated species. While we could not track Panx1 knockdown to specific cells, the levels of knockdown we obtained in the overall population provided a significant reduction in cell migration. Together these data suggest that Panx1 plays a role in regulating cell migration.
Dcx-positive neuroblasts overall appeared to express less Panx1 than NSC/NPCs immediately proximal to the ventricle, suggesting that Panx1 expression decreases with differentiation. This was confirmed in vitro in retinoic acid and low serum differentiated N2a cells and differentiating VZ NSC/NPC cultures (Figure 3A,B). Interestingly, immunostaining of endogenous Panx1 in neuronally differentiated VZ cells and N2a cells revealed strong Panx1 expression within the developing neurites (Figure 3A,B). Since differentiation of N2a cells and VZ NSC/NPCs in vitro is associated with such marked neurite outgrowth, we examined whether blocking or knocking down Panx1 can, on its own, induce neurite extension in the absence of additional differentiation stimuli. Indeed, blocking Panx1 with probenecid [12–14] induced marked neurite extension in both N2a cells and VZ NSC/NPCs (Figure 3C-I). Similarly, Panx1 siRNA knockdown in N2a cells caused increased neurite outgrowth without additional stimuli (Figure 3J), while Panx1EGFP overexpression inhibited neurite extension in N2a cells induced to differentiate (Figure 3K).
Current knowledge points to close links between Panx1 and cytoskeletal dynamics, and the cell behaviours in which Panx1 appears to be involved in the context of neurogenesis (proliferation, migration, neurite outgrowth) are all tightly linked to the cytoskeleton. To better understand the interface between Panx1 and the cytoskeleton and to determine whether this underlies Panx1 regulation of VZ NSC/NPCs we set out to uncover novel Panx1 interactors using an unbiased proteomics strategy; we are the first group, to our knowledge, to do so. We therefore performed immunoprecipitations from N2a cells overexpressing Panx1-EGFP or EGFP as control (Figure 4A). The EGFP tag does not affect the trafficking or functioning of the Panx1 [6, 15, 16] and therefore was deemed suitable for use in identification of interactors. The identification of interactors was performed by high-performance liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS). All proteins precipitated by the EGFP tag alone were excluded from further analysis.
We discovered several novel interactions, including several cytoskeleton-related proteins. Gene ontology (GO) analysis (http://www.broadinstitute.org/gsea/msigdb/index.jsp) of hits revealed that 10% of the putative Panx1-interacting proteins amenable to GO analysis could be classified by the generic GO term GO:0005856 aka ‘CYTOSKELETON’ (Additional file 2: Table S1). This GO term refers to ‘Any of the various filamentous elements that form the internal framework of cells, and typically remain after treatment of the cells with mild detergent to remove membrane constituents and soluble components of the cytoplasm. The term embraces intermediate filaments, microfilaments, microtubules, the microtrabecular lattice, and other structures characterized by a polymeric filamentous nature and long-range order within the cell. The various elements of the cytoskeleton not only serve in the maintenance of cellular shape but also have roles in other cellular functions, including cellular movement, cell division, endocytosis, and movement of organelles.’
A large number of these newly identified cytoskeleton-associated proteins (14/26) were associated with the GO term collectively known as ‘ACTIN_CYTOSKELETON’ (GO:0015629). Among these, we observed significant overlap of actin-related protein 3 (Arp3; Figure 4B,C) and actin (Figure 4D) with Panx1EGFP by confocal microscopy. Interestingly, as with endogenous Panx1, we also observed high levels of Panx1EGFP localized to neurites and other cellular protrusions resembling filopodia (Figure 4C,D). Finally, endogenous Panx1, actin and Arp3 co-precipitated from N2a cells (Figure 4E). Actin was previously identified as a Panx1 interactor in cells ectopically expressing Panx1 [6]; this confirms that an interaction occurs between the two endogenously expressed proteins.
The novel Panx1 interactor, Arp3, is a major component of the Arp2/3 complex, a seven-subunit protein that plays a major role in the regulation of the actin cytoskeleton (reviewed in Firat-Karalar and Welch, 2011 [17]). A link between Panx1 and actin cytoskeleton rearrangements has previously been described [7]. Arp3 closely resemble the structure of monomeric actin, and one of its functions is to serve as a nucleation site for new actin filaments. Actin and actin-associated proteins, including the Arp2/3 complex, have been shown to be integral in both migration [18, 19] and neurite outgrowth [19, 20]. Actin polymerization in lamellipodia and filopodia of migrating cells provides the necessary driving force for leading edge protrusion. Furthermore, Arp2/3 complex regulates the actin filaments present in these cellular processes. In fact, Arp2/3 depletion has been shown to significantly reduce filopodia formation in both primary neurons and neuroblastoma cells [21], while alterations to Arp2/3 function cause dysregulation of lamellipodia dynamics [22]. Furthermore, Arp2/3-mediated actin polymerization regulates growth cone mobility and neuritogenesis [23], as loss of Arp2/3 activity causes erratic neurite numbers and extension, as well as increased focal adhesions [21]. Moreover, in agreement with our previously published work illustrating a role for Panx1 in the positive regulation of VZ NSC/NPC proliferation, the actin cytoskeleton has been shown to be indispensable for cell division (reviewed in Firat-Karalar and Welch, 2011 [17]). This includes roles in contractile ring formation, centrosome separation, and spindle positioning. As Panx1 interactors, actin and Arp3 have illustrated a direct connection between Panx1 and the actin cytoskeleton. This further supports the observed role for Panx1 in the actin-associated behaviours of cell migration and neurite outgrowth, as well as that previously published linking Panx1 to cell proliferation.
Altogether, our data expand on our previous findings by demonstrating that Panx1 is expressed in Dcx-positive migrating neuroblasts in adult brain, and is also involved in additional cell behaviours associated with neurogenesis, including migration and neurite outgrowth. Further, our analysis of protein interactions uncovered a novel Panx1 interacting protein, Arp3, a major part of the Arp2/3 complex, which is an important regulator of actin cytoskeletal dynamics in cell proliferation, neuritogenesis and cell migration [17]. We also established that endogenously expressed Panx1 interacts with actin, and discovered that a large proportion of Panx1 interacting proteins are associated with the cytoskeleton. Overall, this study provides novel evidence reinforcing the link between Panx1 and the cytoskeleton, and suggests that this relationship underlies the regulation and function of Panx1 in VZ NSC/NPCs.
References
Macvicar BA, Thompson RJ: Non-junction functions of pannexin-1 channels. Trends Neurosci. 2009, 33: 93-102.
Penuela S, Gehi R, Laird DW: The biochemistry and function of pannexin channels. Biochimica Et Biophysica Acta. 2012, 1828: 15-22.
Mishra SK, et al: Extracellular nucleotide signaling in adult neural stem cells: synergism with growth factor-mediated cellular proliferation. Development. 2006, 133: 675-684. 10.1242/dev.02233.
Lin JH, et al: Purinergic signaling regulates neural progenitor cell expansion and neurogenesis. Dev Biol. 2007, 302: 356-366. 10.1016/j.ydbio.2006.09.017.
Suyama S, et al: Purinergic signaling promotes proliferation of adult mouse subventricular zone cells. J Neurosci. 2012, 32: 9238-9247. 10.1523/JNEUROSCI.4001-11.2012.
Bhalla-Gehi R, Penuela S, Churko JM, Shao Q, Laird DW: Pannexin1 and Pannexin3 delivery, cell surface dynamics, and cytoskeletal interactions. J Biol Chem. 2010, 285: 9147-9160. 10.1074/jbc.M109.082008.
Bao BA, Lai CP, Naus CC, Morgan JR: Pannexin1 drives multicellular aggregate compaction via a signaling cascade that remodels the actin cytoskeleton. J Biol Chem. 2012, 287: 8407-8416. 10.1074/jbc.M111.306522.
Wicki-Stordeur LE, Dzugalo AD, Swansburg RM, Suits JM, Swayne LA: Pannexin 1 regulates postnatal neural stem and progenitor cell proliferation. Neural Dev. 2012, 7: 11-10.1186/1749-8104-7-11.
Liang CC, Park AY, Guan JL: In vitro scratch assay: a convenient and inexpensive method for analysis of cell migration in vitro. Nat Protoc. 2007, 2: 329-333.
Penuela S, et al: Pannexin 1 and Pannexin 3 are glycoproteins that exhibit many distinct characteristics from the connexin family of gap junction proteins. J Cell Sci. 2007, 120: 3772-3783. 10.1242/jcs.009514.
Penuela S, Bhalla R, Nag K, Laird DW: Glycosylation regulates Pannexin intermixing and cellular localization. Mol Biol Cell. 2009, 20: 4313-4323. 10.1091/mbc.E09-01-0067.
Silverman W, Locovei S, Dahl G: Probenecid, a gout remedy, inhibits Pannexin 1 channels. Am J Physiol Cell Physiol. 2008, 295: C761-C767. 10.1152/ajpcell.00227.2008.
Silverman WR, et al: The Pannexin 1 channel activates the inflammasome in neurons and astrocytes. J Biol Chem. 2009, 284: 18143-18151. 10.1074/jbc.M109.004804.
Weilinger NL, Tang PL, Thompson RJ: Anoxia-induced Nmda receptor activation opens Pannexin channels via Src family kinases. J Neurosci Nurs. 2012, 32: 12579-12588. 10.1523/JNEUROSCI.1267-12.2012.
Wicki-Stordeur LE, Boyce AK, Swayne LA: Analysis of a Pannexin 2-Pannexin 1 chimeric protein supports divergent roles for Pannexin C-termini in cellular localization. Cell Commun Adhes. 2013, 20: 73-79. 10.3109/15419061.2013.791681.
Lai CP, et al: Tumor-suppressive effects of Pannexin 1 in C6 glioma cells. Cancer Res. 2007, 67: 1545-1554. 10.1158/0008-5472.CAN-06-1396.
Firat-Karalar EN, Welch MD: New mechanisms and functions of actin nucleation. Curr Opin Cell Biol. 2011, 23: 4-13. 10.1016/j.ceb.2010.10.007.
Sawa M, et al: Essential role of the C. elegans Arp2/3 complex in cell migration during ventral enclosure. J Cell Sci. 2003, 116: 1505-1518. 10.1242/jcs.00362.
Schaefer AW, et al: Coordination of actin filament and microtubule dynamics during neurite outgrowth. Dev Cell. 2008, 15: 146-162. 10.1016/j.devcel.2008.05.003.
Firat-Karalar EN, Hsiue PP, Welch MD: The actin nucleation factor Jmy is a negative regulator of neuritogenesis. Mol Biol Cell. 2011, 22: 4563-4574. 10.1091/mbc.E11-06-0585.
Korobova F, Svitkina T: Arp2/3 complex is important for filopodia formation, growth cone motility, and neuritogenesis in neuronal cells. Mol Biol Cell. 2008, 19: 1561-1574. 10.1091/mbc.E07-09-0964.
Ingerman E, Hsiao JY, Mullins RD: Arp2/3 complex atp hydrolysis promotes lamellipodial actin network disassembly but is dispensable for assembly. J Cell Biol. 2013, 200: 619-633. 10.1083/jcb.201211069.
Gupton SL, Gertler FB: Integrin signaling switches the cytoskeletal and exocytic machinery that drives neuritogenesis. Dev Cell. 2010, 18: 725-736. 10.1016/j.devcel.2010.02.017.
Acknowledgements
Operating support for this work came from a Natural Sciences and Engineering Research Council of Canada (NSERC) Discovery Grant, a Victoria Foundation Willard and Elva Dawson fund grant, and a University of Victoria laboratory start-up grant awarded to LAS. We also thank the Canadian Foundation for Innovation Leaders Opportunity Fund, and the British Columbia Knowledge and Development Fund for supporting the purchase of a confocal microscope that was essential to this work. LWS is supported by an NSERC Vanier Canada Graduate Scholarship, a Howard E. Petch Research Scholarship and an Edythe Hembroff-Schleicher Graduate Scholarship. Finally, we thank Ross Prager for assistance with data analysis, and Jen Graham for assistance with animal work.
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LAS and LWS devised the study. LWS performed the experiments and data analysis. LAS and LWS wrote and revised the manuscript. Both authors read and approved the final manuscript.
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Additional file 2: Table S1: GO analysis of Panx1 interactors - gene sets associated with the cytoskeleton. (XLSX 12 KB)
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Wicki-Stordeur, L.E., Swayne, L.A. Panx1 regulates neural stem and progenitor cell behaviours associated with cytoskeletal dynamics and interacts with multiple cytoskeletal elements. Cell Commun Signal 11, 62 (2013). https://doi.org/10.1186/1478-811X-11-62
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DOI: https://doi.org/10.1186/1478-811X-11-62