Phospholipase D1 Signaling: Essential Roles in Neural Stem Cell Differentiation
- 202 Downloads
Phospholipase D1 (PLD1) is generally accepted as playing an important role in the regulation of multiple cell functions, such as cell growth, survival, differentiation, membrane trafficking, and cytoskeletal organization. Recent findings suggest that PLD1 also plays an important role in the regulation of neuronal differentiation of neuronal cells. Moreover, PLD1-mediated signaling molecules dynamically regulate the neuronal differentiation of neural stem cells (NSCs). Rho family GTPases and Ca2+-dependent signaling, in particular, are closely involved in PLD1-mediated neuronal differentiation of NSCs. Moreover, PLD1 has a significant effect on the neurogenesis of NSCs via the regulation of SHP-1/STAT3 activation. Therefore, PLD1 has now attracted significant attention as an essential neuronal signaling molecule in the nervous system. In the current review, we summarize recent findings on the regulation of PLD1 in neuronal differentiation and discuss the potential role of PLD1 in the neurogenesis of NSCs.
KeywordsPhospholipase D1 (PLD1) Neural stem cells (NSCs) Neuronal differentiation Neurogenesis
Overview of NSCs
Numerous reports suggest that PLD1 contributes to various cellular mechanisms, including inflammation, tumor cell invasion and metastasis, lipid metabolism, and neural development (Bae et al. 2014; Brown et al. 2017; Bruntz et al. 2014). Therefore, PLD1 have emerged as drug targets for many diseases such as infectious diseases, cancer, cardio-vascular diseases, and neurodegenerative diseases (Brown et al. 2017; Eftekharian et al. 2017). PLD1 is found throughout the cell, particularly, in the perinuclear region, Golgi complex, and early endosomes in non-stimulated cells. Further, it is relocated to the plasma membrane upon stimulation. Increased expression of PLD1, its subcellular localization and altered catalytic activity have essential roles in cell proliferation, differentiation, vesicle trafficking, and cytoskeleton rearrangement in neuron (Brito de Souza et al. 2014; Luo et al. 2017). PLD1 is expressed in many functionally diverse brain areas, including the cerebral cortex, hippocampus, brain stem, spinal cord, and olfactory bulb (Lee et al. 2000). Recent studies have reported that the signal-dependent activation of PLD1 is important for neuronal differentiation in NSCs (Park et al. 2015, 2017; Yoon et al. 2005, 2006). PLD2 is almost exclusively found in the light membrane “lipid raft” fraction of the plasma membrane (Gomez-Cambronero and Keire 1998). PLD2 can be activated in intact cells by a variety of agonists and tyrosine kinases. Further, it can be regulated by small GTPases and certain PKC family members (Gomez-Cambronero 2014). PLD2 promotes neurite outgrowth in PC12 cells and functions as a downstream signaling effector of extracellular signal-regulated kinases in the nerve growth factor (NGF) signaling pathway. In PC12 cells and cerebellar granule neurons, this pathway is activated by NGF and neuronal cell adhesion molecule L1 (Watanabe et al. 2004; Yun et al. 2006). Therefore, both PLD1 and PLD2 appear to influence neurite outgrowth. However, the role of PLD2 in neuronal differentiation of NSCs has not yet been elucidated. Therefore, this review focused on the role of PLD1 in neuronal differentiation and described its potential role in the neurogenesis of NSCs.
Role of PLD1 in Neuronal Differentiation of NSCs
In HiB5 cells, the activation of PLD contributes to neuronal differentiation via neurogenic platelet-derived growth factor (PDGF) (Sung et al. 2001). Further, NGF-induced PLD1 expression mediates neuronal differentiation of PC12 cells (Ammar et al. 2013; Min et al. 2001). PLD1 is also implicated in the bFGF-induced neurite outgrowth of H19-7 cells (Klein 2005; Yoon et al. 2012). In addition, PLD1 corrected the impaired neurite outgrowth capacity of familial Alzheimer’s disease mutant neurons (Cai et al. 2006). Thus, PLD1 is a key molecule in neuronal differentiation, especially neurite outgrowth. Yoon et al. (Yoon et al. 2005) reported for the first time that PLD1 is required for neurite outgrowth during neuronal differentiation of NSCs. Since then, PLD1-mediated signaling pathways have been identified in neuronal differentiation of NSCs. Herein, we summarize the PLD1-mediated signaling molecules involved in the neuronal differentiation of NSCs.
PLD1 and Rho Family GTPases in Neuronal Differentiation of NSCs
During brain development, each neuron develops into a single axon and multiple neurites, which then eventually form synapses (Elston and Fujita 2014; Huang et al. 2017). To ensure precise neuronal connectivity, neurons are derived from the coordination of multiple developmental steps, including axon growth, branching, guidance, and synapse formation (Huang et al. 2017). Cytoskeleton rearrangement is required for the dynamics of neuronal morphology formation. The Rho family GTPases, of which RhoA, Cdc42, and Rac1 are best characterized, act as significant modulators of cytoskeleton rearrangement (Threadgill et al. 1997). The Rho family GTPases serves as a molecular switch by converting from an inactive GDP-bound state to an active GTP-bound state. Once activated, they can interact with their specific effectors. Recent reports suggest that RhoA, Rac1, and Cdc42 play a central role in dendritic development. Further, the differential activation of Rho-related GTPases contributes to the generation of morphological diversity in the developing cortex (Threadgill et al. 1997). Rac1 and Cdc42 promote neurite initiation and outgrowth (Daniels et al. 1998). Conversely, RhoA activation antagonizes neurite formation and causes neurite retraction. Thus, the regulation of Rho family GTPases is crucial for guiding downstream biological reactions, such as axon growth or retraction, and synapse maturation during neuronal development.
The Rho family GTPases are important regulators of PLD activity (Powner and Wakelam 2002). PLD1 activity is regulated particularly by interactions with small GTPases that belong to the ARF and Rho families (Powner and Wakelam 2002; Rudge and Wakelam 2009). The transfection of RhoA, Cdc42, or Rac1 can activate PLD1 (Powner and Wakelam 2002; Yoon et al. 2006), which has been implicated in the regulation of the actin cytoskeleton (Rudge and Wakelam 2009). PLD1 controls many physiological functions, such as cell migration and neuronal axon formation, via this regulatory action. In NSCs, the expression levels of Cdc42 and RhoA were increased during neuronal differentiation, and PLD1 and Cdc42 were co-localized in neurites, while RhoA was localized in the cytosol (Yoon et al. 2006). Further, Cdc42 was bound to PLD1 during differentiation, and dominant-negative Cdc42 (Cdc42N17) decreased PLD activity and neurite outgrowth. Conversely, constitutively active Cdc42 (Cdc42V12) increased both PLD activity and neurite outgrowth, suggesting that the association between Cdc42 and PLD1 is important for the activation of PLD1 and neurite outgrowth in NSCs. Moreover, a dominant-negative Rac1 (Rac N17) mutant inhibited PLD1-induced Bcl-2 expression. Bcl-2 expression, however, was not altered by DN-Cdc42 (Cdc42 N17) or DN-Rho (Rho V19) during neuronal differentiation of NSCs (Park et al. 2015). Therefore, the interplay between PLD1 and Rho family GTPases has an important role in the neuronal differentiation of NSCs.
PLD1 and Bcl-2 Expression in Neuronal Differentiation of NSCs
Bcl-2 is a well-known anti-apoptotic protein that prevents the release of apoptogenic factors, such as cytochrome c and second mitochondrial-derived activator of caspase, which was originally found to be overexpressed in B cell lymphoma (Gross et al. 1999). Bcl-2 serves as a critical regulator of pathways involved in apoptosis and inhibits cell death (Liu et al. 2013). Proteins of the Bcl-2 family influence neuronal apoptosis and cell differentiation and a reduction in the ability of neurons to extend neurites in Bcl-2-deficient embryos (Chen et al. 1997; Yoon et al. 2012). Bcl-2 is critical for the neuronal commitment of mouse embryonic stem cells (Trouillas et al. 2008). Moreover, the anti-apoptotic role of Bcl-2 has been well identified in previous studies, in which anti-apoptotic gene modifications have had beneficial effects on the neural differentiation of neural progenitors and NSCs (Esdar et al. 2001; Lee et al. 2009). In vivo studies also indicated that the overexpression of Bcl-2 enhanced retinal axon regeneration after optic-tract transaction (Chen et al. 1997) and increased axonal growth of transplanted fetal dopaminergic neurons in the rat striatum (Holm et al. 2001).
Recent studies have demonstrated that Bcl-2 is implicated in PLD1-mediated neuronal differentiation. PLD1 is known to regulate Bcl-2 expression in various cells (Cho et al. 2008, 2011; Choi and Han 2012). For instance, PLD1 regulates Bcl-2 expression via the JNK/STAT3 pathway, which leads to neuronal cell differentiation of H19-7 cells (Yoon et al. 2012). A recent study also demonstrated that PLD1 increased Bcl-2 expression and promoted Bcl-2-mediated signaling in NSCs (Park et al. 2015). More specifically, PLD1 is regulated by PLCγ/PKCα activation and promotes Bcl-2 expression, via the PA/AA/PGE2/EP4/PKA/p38 MAPK pathway during neuronal differentiation. These results suggest that PLD1-mediated Bcl-2 expression affects the neuronal differentiation of NSCs.
PLD1 and Ca2+-Dependent Signaling in Neuronal Differentiation of NSCs
The development of the nervous system occurs through a series of well-organized steps in the proliferation of NSCs, its migration over considerable distances from the germinal centers to their destinations, and ultimately their differentiation into billions of neurons and glia, which populate the brain (Toth et al. 2016). In these processes, Ca2+ signaling is essential for the developing brain (Zheng and Poo 2007). Increased Ca2+ levels regulate PKCα activation and translocation to the membrane from the cytosol in various processes (Boncoeur et al. 2013; Champion and Kass 2004). PKCα regulates Ca2+-dependent differentiation in several cell lines and primary cells and plays an essential role in synaptic plasticity by raising intracellular Ca2+ levels (Kopach et al. 2013; Park et al. 2015). PLD catalyzes the hydrolysis of PC to PA and choline (Exton 2002). PA itself acts as a cellular messenger or is further transformed by PA phosphohydrolase into DAG, which is essential for the activation of PKC (Zhao et al. 2007). The activation and phosphorylation of PLD1 is regulated by PKCα, with a similar interrelationship between PLD and PKC isoforms seen in a variety of cell types (Kim et al. 2005; Park et al. 2015). Recent studies revealed that increased intracellular Ca2+ affects PKCα activation and neurite outgrowth in NSCs (Park et al. 2015, 2017). In addition, a PKCα specific inhibitor, RO320432, reduced the activation of PLD1 and affected PLD1 signaling during differentiation in NSCs (Park et al. 2015, 2017). Moreover, intracellular Ca2+ promotes neurogenesis by translocating PKCα to the membrane through making complex with hippocalcin (HPCA). And then PKCα is activated by direct binding to phosphoinositide-dependent protein kinase 1 (PDK1) in NSCs. PDK1 signals upstream of PKCα trigger neurite outgrowth leading to increased expressions of Nt3, Nt45, Bdnf, and Neuro D in NSCs (Park et al. 2017).
Another important Ca2+ signaling factor, phospholipase C (PLCγ), also affects PLD1 signaling in several cells (Park et al. 2009, 2015; Yoon et al. 2012). When treated with some growth factors, PLCγ is phosphorylated and generates DAG and inositol 1,4,5-triphosphate (IP3), which in turn activates PKCα, consequently increasing intracellular Ca2+ (Hall et al. 1996; Oh et al. 2008). Recent studies demonstrated that PLCγ signaling elevates the intracellular Ca2+ concentration and regulates neocortical neuronal progenitor migration and neuronal differentiation (Lundgren et al. 2012; Park et al. 2015). Moreover, the inhibition of PLCγ using a specific inhibitor, U73122, or blocking intracellular [Ca2+]i with BAPTA-AM, reduced the phosphorylation and activation of PKCα during neuronal differentiation of NSCs (Park et al. 2015). Furthermore, U73122 or BAPTA-AM inhibited PLD1 activity and neuronal differentiation in NSCs (Park et al. 2015). Taken together, these results suggest that intracellular Ca2+ signal molecules, including PLCγ, PKCα, and PDK1, regulate PLD1-mediated neuronal differentiation in NSCs.
HPCA is a high-affinity Ca2+-binding protein, which is restricted to the CNS and most abundant in pyramidal cells of the CA1 region in the hippocampus (Kobayashi et al. 2005). During brain development the expression of HPCA sharply increases concurrently with synapse formation (Saitoh et al. 1994). HPCA belongs to the family of EF-hand-containing neuronal Ca2+ sensor proteins, which possess a Ca2+/myristoyl switch that allows its translocation to the membrane, in response to increased cytosolic Ca2+ concentrations (Oh et al. 2008; Park et al. 2017). HPCA exerts a neuroprotective action by blocking the formation of Ca2+-induced cell death stimuli (Masuo et al. 2007). Further, infusion of mutant Hpca lacking Ca2+-binding sites prevents long-term depression in hippocampal neurons (Jo et al. 2010). Since HPCA has a crucial role in Ca2+-mediated neuronal activity in the brain, it is possible that HPCA is implicated in neuronal differentiation of NSCs. HPCA is also regulated by a Ca2+-mediated PLD1 signaling pathway (Oh et al. 2008; Park et al. 2017). It also induces the expression of neuro-D, leading to neurite outgrowth during differentiation in H19-7 cells (Oh et al. 2008). A recent study demonstrated that the expression of nerve growth factors, such as NT-3, NT-45, and BDNF, depended on Ca2+ binding and the myristoylation of HPCA during the neuronal differentiation of NSCs (Park et al. 2017). Interestingly, HPCA directly binds to PKCα, which facilitates the PKCα-regulated kinase cascade; PKCα-dependent PLD1 activation is required for neurite outgrowth. Moreover, PLD1 and HPCA were even co-localized on embryonic day 14 (E14) in the rat cerebral neocortex, and HPCA-dependent PLD1 activation was required for neuronal differentiation of NSCs. Finally, their collaboration greatly influenced the neurogenesis of NSCs (Park et al. 2017).
PLD1 as an Accelerator in Neurogenesis of NSCs
Neurogenesis is the transition of proliferative and multipotent NSCs to fully differentiated neurons. It occurs in multiple brain areas, including the neocortex, piriform cortex, amygdala, substantia nigra, striatum, and hypothalamus (Iannitelli et al. 2017). Neurogenesis is the process by which neurons are generated from neural stem cells and progenitor cells. It precedes gliogenesis throughout the nervous system, and a single progenitor can give rise to both neurons and astrocytes (Bayer et al. 1991). Neurogenesis is tightly controlled owing to its critical importance in proper physiological function, and the multiple signals controlling the growth and directionality of the relevant cell fate decision (Sun et al. 2001). To promote neurogenesis, proneural basic helix-loop-helix (bHLH) transcription factors, such as neurogenin-1 and Mash-1, not only drive neurogenesis by activating the expression of a cascade of neuronal genes (Frohman et al. 1999) but also through inhibiting glial gene expression (Urban and Guillemot 2014). However, some neurogenic factors can regulate both these processes, depending on the concentration of proneural genes. For example, although bone morphogenetic proteins promote neurogenesis in progenitor cells that express high levels of neurogenin-1, it promotes gliogenesis in progenitor cells that have a low level of neurogenin-1 expression (Morrison 2001). Thus, embryonic neurogenesis is tightly linked to cell fate specification. Moreover, according to recent studies, the molecular and genetic factors influencing neurogenesis notably include the Notch pathway; many genes have been linked to Notch pathway regulation (Kageyama et al. 2008; Rash et al. 2011).
How Does PLD1 Promote Neurogenesis in NSCs?
Over the past year several regulatory mechanisms, including the promotion of neurogenesis by proneural bHLH genes and the instruction of gliogenesis by signal transducers and activators of transcription 3 (STAT3) in a neurogenic capacity of NSCs in culture, have been identified (Kang et al. 2016; Park et al. 2017). STAT3 is an important transcription factor that regulates glial fibrillary acidic protein (GFAP) expression. Further, the DNA binding of STAT3 was affected by the phosphorylation of the Ser727 or/and Tyr 705 site (Yokogami et al. 2000). STAT3 binds to different domains of CBP/p300 and the STAT/p300/Smad complex, acting at the STAT-binding element in the astrocyte-specific GFAP promoter, which is particularly effective at inducing astrocyte differentiation in NSCs (Nakashima et al. 1999). SH2-domain-containing tyrosine phosphatase-1 (SHP-1) negatively regulates STAT3 signaling through the direct de-phosphorylation of STAT3 (Tyr 705). Importantly, this SHP-1-dependent STAT3-inhibitory mechanism is closely involved in PLD1-directed neurogenesis in NSCs. PLD-derived PA interacts with and inhibits SHP-1 activity (Frank et al. 1999). Exogenously added PA induced phosphorylation of SHP-1 and de-phosphorylation of STAT3 (Tyr 705) in a dose-dependent manner in NSCs. Moreover, PLD1 knockdown inhibited SHP-1 activity and affected the de-phosphorylation of STAT3 (Tyr 705). Thus, PLD1 promotes neurogenesis and suppresses gliogenesis by controlling the activation of SHP-1/STAT3 in NSCs. Therefore, PLD1/PA/SHP-1/STAT3 signaling is an important pathway in embryonic brain neurogenesis.
This work was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF), funded by the Ministry of Science, ICT, & Future Planning (NRF-2015R1C1A1A02037376), and partly supported by the Korea government (MSIP) (NRF-2016R1A2B4015358).
Compliance with Ethical Standards
Conflict of Interest
The authors declare that they have no conflict of interest.
- Ammar MR, Humeau Y, Hanauer A, Nieswandt B, Bader MF, Vitale N (2013) The Coffin-Lowry syndrome-associated protein RSK2 regulates neurite outgrowth through phosphorylation of phospholipase D1 (PLD1) and synthesis of phosphatidic acid. J Neurosci 33:19470–19479. https://doi.org/10.1523/JNEUROSCI.2283-13.2013 CrossRefPubMedGoogle Scholar
- Boncoeur E, Bouvet GF, Migneault F, Tardif V, Ferraro P, Radzioch D, de Sanctis JB, Eidelman D, Govindaraju K, Dagenais A, Berthiaume Y (2013) Induction of nitric oxide synthase expression by lipopolysaccharide is mediated by calcium-dependent PKCalpha-beta1 in alveolar epithelial cells. Am J Physiol Lung Cell Mol Physiol 305:L175–L184. https://doi.org/10.1152/ajplung.00295.2012 CrossRefPubMedGoogle Scholar
- Cai D, Zhong M, Wang R, Netzer WJ, Shields D, Zheng H, Sisodia SS, Foster DA, Gorelick FS, Xu H, Greengard P (2006) Phospholipase D1 corrects impaired betaAPP trafficking and neurite outgrowth in familial Alzheimer’s disease-linked presenilin-1 mutant neurons. Proc Natl Acad Sci U S A 103:1936–1940. https://doi.org/10.1073/pnas.0510710103 CrossRefPubMedCentralPubMedGoogle Scholar
- Cho JH, Oh DY, Kim HJ, Park SY, Choi HJ, Kwon SJ, Lee KS, Han JS (2011) The TSP motif in AP180 inhibits phospholipase D1 activity resulting in increased efficacy of anticancer drug via its direct binding to carboxyl terminal of phospholipase D1. Cancer Lett 302:144–154. https://doi.org/10.1016/j.canlet.2011.01.005 CrossRefPubMedGoogle Scholar
- Eftekharian MM, Azimi T, Ghafouri-Fard S, Sayad A, Omrani MD, Sarrafzadeh S, Abbasalipourkabir R, Mazdeh M, Taheri M (2017) Phospholipase D1 expression analysis in relapsing-remitting multiple sclerosis patients. Neurol Sci 38:865–872. https://doi.org/10.1007/s10072-017-2857-1 CrossRefPubMedGoogle Scholar
- Gage FH, Ray J, Fisher LJ (1995) Isolation, characterization, and use of stem cells from the CNS. Annu Rev Neurosci 18:159–192. https://doi.org/10.1146/annurev.ne.18.030195.001111 CrossRefPubMedGoogle Scholar
- Jo J, Son GH, Winters BL, Kim MJ, Whitcomb DJ, Dickinson BA, Lee YB, Futai K, Amici M, Sheng M, Collingridge GL, Cho K (2010) Muscarinic receptors induce LTD of NMDAR EPSCs via a mechanism involving hippocalcin, AP2 and PSD-95. Nat Neurosci 13:1216–1224. https://doi.org/10.1038/nn.2636 CrossRefPubMedGoogle Scholar
- Kobayashi M, Masaki T, Hori K, Masuo Y, Miyamoto M, Tsubokawa H, Noguchi H, Nomura M, Takamatsu K (2005) Hippocalcin-deficient mice display a defect in cAMP response element-binding protein activation associated with impaired spatial and associative memory. Neuroscience 133:471–484. https://doi.org/10.1016/j.neuroscience.2005.02.034 CrossRefPubMedGoogle Scholar
- Kopach O, Viatchenko-Karpinski V, Atianjoh FE, Belan P, Tao YX, Voitenko N (2013) PKCalpha is required for inflammation-induced trafficking of extrasynaptic AMPA receptors in tonically firing lamina II dorsal horn neurons during the maintenance of persistent inflammatory pain. J Pain 14:182–192. https://doi.org/10.1016/j.jpain.2012.10.015 CrossRefPubMedCentralPubMedGoogle Scholar
- Masuo Y, Ogura A, Kobayashi M, Masaki T, Furuta Y, Ono T, Takamatsu K (2007) Hippocalcin protects hippocampal neurons against excitotoxin damage by enhancing calcium extrusion. Neuroscience 145:495–504. https://doi.org/10.1016/j.neuroscience.2006.12.011 CrossRefPubMedGoogle Scholar
- Park SY, Cho JH, Oh DY, Park JW, Ahn MJ, Han JS, Oh JW (2009) House dust mite allergen Der f 2-induced phospholipase D1 activation is critical for the production of interleukin-13 through activating transcription factor-2 activation in human bronchial epithelial cells. J Biol Chem 284:20099–20110. https://doi.org/10.1074/jbc.M109.010017 CrossRefPubMedCentralPubMedGoogle Scholar
- Sung TC, Roper RL, Zhang Y, Rudge SA, Temel R, Hammond SM, Morris AJ, Moss B, Engebrecht J, Frohman MA (1997) Mutagenesis of phospholipase D defines a superfamily including a trans-Golgi viral protein required for poxvirus pathogenicity. EMBO J 16:4519–4530. https://doi.org/10.1093/emboj/16.15.4519 CrossRefPubMedCentralPubMedGoogle Scholar
- Trouillas M, Saucourt C, Duval D, Gauthereau X, Thibault C, Dembele D, Feraud O, Menager J, Rallu M, Pradier L, Boeuf H (2008) Bcl2, a transcriptional target of p38alpha, is critical for neuronal commitment of mouse embryonic stem cells. Cell Death Differ 15:1450–1459. https://doi.org/10.1038/cdd.2008.63 CrossRefPubMedGoogle Scholar
- Watanabe H, Yokozeki T, Yamazaki M, Miyazaki H, Sasaki T, Maehama T, Itoh K, Frohman MA, Kanaho Y (2004) Essential role for phospholipase D2 activation downstream of ERK MAP kinase in nerve growth factor-stimulated neurite outgrowth from PC12 cells. J Biol Chem 279:37870–37877. https://doi.org/10.1074/jbc.M402610200 CrossRefPubMedGoogle Scholar
- Zheng JQ, Poo MM (2007) Calcium signaling in neuronal motility. Annu Rev Cell Dev Biol 23:375–404. https://doi.org/10.1146/annurev.cellbio.23.090506.123221 CrossRefPubMedGoogle Scholar
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.