Gangliosides of the nuclear membrane: a crucial locus of cytoprotective modulation

The original concept of gangliosides as localized components of the plasma membrane has broadened in recent years with recognition of their presence in various intracellular pools as well. The nuclear envelope (NE), consisting of two unique membranes, is one such structure shown to contain members of the gangliotetraose family and possibly other sialoglycolipids. GM1 situated in the inner membrane of the NE is tightly associated with a Na+/Ca2+ exchanger whose activity it potentiates in the transfer of Ca2+ from nucleoplasm to the NE lumen. This is in contrast to Na+/Ca2+ exchangers of the plasma membrane which bind GM1 less avidly or not at all. This is believed due to different isoforms of exchanger, and a difference in topology of the exchanger relative to GM1. Cultured neurons from mice genetically engineered to lack gangliotetraose gangliosides such as GM1 were highly vulnerable to Ca2+-induced apoptosis. They were rescued to some extent by GM1 but more effectively by LIGA-20, a membrane-permeant derivative of GM1 that traverses the plasma membrane more effectively than GM1 and inserts into the NE. As further indication of Ca2+ dysregulation, the mutant mice were highly susceptible to kainite-induced seizures which were attenuated by LIGA-20. This correlated with the ability of LIGA-20 to cross the blood-brain barrier, enter brain cells, insert into the NE, and potentiate the nuclear exchanger. GM1 in the NE, in association with nuclear Na+/Ca2+ exchanger, is thus seen as contributing to Ca2+ regulation within the nucleus and in the process exerting a cytoprotective role.     

GM1 ganglioside: another nuclear lipid that modulates nuclear calcium. GM1 potentiates the nuclear sodium-calcium exchanger

The nuclear envelope (NE) enclosing the cell nucleus, although morphologically and chemically distinct from the plasma membrane, has certain features in common with the latter including the presence of GM1 as an important modulatory molecule. This ganglioside influences Ca(2+) flux across both membranes, but by quite different mechanisms. GM1 in the NE contributes to regulation of nuclear Ca(2+) through potentiation of a Na(+)/Ca(2+) exchanger in the inner nuclear membrane, whereas in the cell membrane, it regulates cytosolic Ca(2+) through modulation of a nonvoltage-gated Ca(2+) channel. Studies with neuroblastoma cells suggest GM1 concentration becomes elevated in the NE with onset of axonogenesis. However, the nuclear GM1/exchanger complex is not limited to neuronal cells but also occurs in NE of astrocytes, C6 cells, and certain non-neural cells. Immunoprecipitation and immunoblot experiments have shown high affinity association of the nuclear Na(+)/Ca(2+) exchanger with GM1, in contrast to Na(+)/Ca(2+) exchangers of the plasma membrane, which bind GM1 less avidly or not at all. This is believed to be due to different isoforms of the exchanger and a difference in topology of GM1 relative to the large inner loop of the exchanger in the 2 membranes. Cultured neurons from mice genetically engineered to lack GM1 suffered Ca(2+) dysregulation as seen in their high vulnerability to Ca(2+)-induced apoptosis. They were rescued by GM1 and more effectively by LIGA20, a membrane-permeant derivative of GM1. The mutant animals were highly susceptible to kainate-induced seizures, which are also a reflection of Ca(2+) dysregulation. The seizures were effectively attenuated by LIGA20 in parallel with the ability of this agent to enter brain cells, insert into the NE, and potentiate Na(+)/Ca(2+) exchange activity in the nucleus. The Na(+)/Ca(2+) exchanger of the NE, in association with nuclear GM1, is thus seen contributing to independent regulation of Ca(2+) by the nucleus in a manner that provides cytoprotection against Ca(2+)-induced apoptosis.     

Sphingolipids of the nucleus and their role in nuclear signaling

Sphingolipids have important signaling and regulatory roles in the nuclei of all vertebrate cells examined to date. Sphingomyelin (SM) is the most abundant of this group and occurs in the nuclear envelope (NE) as well as intranuclear sites. The primary product of SM metabolism is ceramide, whose release by nuclear sphingomyelinase triggers apoptosis and other metabolic changes in the nucleus. Further catabolism results in free fatty acid and sphingosine formation, the latter being capable of conversion to sphingosine phosphate by action of a specific nuclear kinase. Finally, glycosphingolipids such as gangliosides occur in the NE where GM1, one member of the gangliotetraose family, influences Ca(2+) flux by activation of a Na(+)/Ca(2+) exchanger located in the inner membrane of the NE. The tightly associated GM1/exchanger complex was shown to exert a cytoprotective role in neurons and other cell types, as absence of this nuclear complex rendered cells vulnerable to apoptosis. A striking example of this mode of Ca(2+) regulation is the greatly enhanced seizure activity in knockout mice lacking gangliotetraose gangliosides, involving programmed cell death in the CA3 region of the hippocampus. In this model, Ca(2+) homeostasis was restored most effectively with LIGA-20, a membrane-permeant derivative of GM1 that entered the NE and activated the nuclear Na(+)/Ca(2+) exchanger.     

Presence of Sodium–Calcium Exchanger/GM1 Complex in the Nuclear Envelope of Non-neural Cells: Nature of Exchanger-GM1 Interaction

Previous studies have revealed the presence of Na⁺Ca²⁺ exchanger (NCX) activity associated with GM1 ganglioside in the nuclear envelope (NE) of neurons and glia as well as various neural cell lines. The nuclear NCX1 exchanger, unlike that in the plasma membrane, was shown to be tightly associated with GM1 and potentiated by the latter. One non-neural cell line, Jurkat, was found to contain no Na⁺Ca²⁺ exchanger of the NCX1, NCX2, or NCX3 types in either nuclear or plasma membrane. To determine whether such absence in the NE is generally characteristic of non-neural cells we have examined two more such cell lines in addition to human lymphocytes. RT-PCR showed NCX1 expression in both HeLa and NCTC cell lines and also NCX2 in the latter; NCX3, a subtype previously observed in NG108-15 cells, was not expressed in either. Immunocytochemical and immunoblot studies indicated NCX1 on the cell surface and nuclear envelope of both cell types. Some alternatively spliced isoforms of NCX1 in the nuclear envelope of both cell types were tightly associated with ganglioside GM1. Human lymphocytes, a mixed population of T and B cells, showed similar evidence for plasma membrane and nuclear expression in some but not all cells. The high affinity association between NCX1 and GM1, explored by reaction with base, acid, and proteases, was found to involve charge–charge interaction with a requirement for a positively charged moiety in NCX.Special issue dedicated to Lawrence F. Eng.     

Nuclear sphingolipids: metabolism and signaling

Sphingolipids are most prominently expressed in the plasma membrane, but recent studies have pointed to important signaling and regulatory roles in the nucleus. The most abundant nuclear sphingolipid is sphingomyelin (SM), which occurs in the nuclear envelope (NE) as well as intranuclear sites. The major metabolic product of SM is ceramide, which is generated by nuclear sphingomyelinase and triggers apoptosis and other metabolic changes. Ceramide is further hydrolyzed to free fatty acid and sphingosine, the latter undergoing conversion to sphingosine phosphate by action of a specific nuclear kinase. Gangliosides are another type of sphingolipid found in the nucleus, members of the a-series of gangliotetraose gangliosides (GM1, GD1a) occurring in the NE and endonuclear compartments. GM1 in the inner membrane of the NE is tightly associated with a Na(+)/Ca(2+) exchanger whose activity it potentiates, thereby contributing to regulation of Ca(2+) homeostasis in the nucleus. This was shown to exert a cytoprotective role as absence or inactivation of this nuclear complex rendered cells vulnerable to apoptosis. This was demonstrated in the greatly enhanced kainite-induced seizure activity in knockout mice lacking gangliotetraose gangliosides. The pathology included apoptotic destruction of neurons in the CA3 region of the hippocampus. Ca(2+) homeostasis was restored in these animals with LIGA-20, a membrane-permeant derivative of GM1 that entered the NE and activated the nuclear Na(+)/Ca(2+) exchanger. Some evidence suggests the presence of uncharged glycosphingolipids in the nucleus.     

NAADP mobilizes Ca2+ from a thapsigargin-sensitive store in the nuclear envelope by activating ryanodine receptors

Ca2+ release from the envelope of isolated pancreatic acinar nuclei could be activated by nicotinic acid adenine dinucleotide phosphate (NAADP) as well as by inositol 1,4,5-trisphosphate (IP3) and cyclic ADP-ribose (cADPR). Each of these agents reduced the Ca2+ concentration inside the nuclear envelope, and this was associated with a transient rise in the nucleoplasmic Ca2+ concentration. NAADP released Ca2+ from the same thapsigargin-sensitive pool as IP3. The NAADP action was specific because, for example, nicotineamide adenine dinucleotide phosphate was ineffective. The Ca2+ release was unaffected by procedures interfering with acidic organelles (bafilomycin, brefeldin, and nigericin). Ryanodine blocked the Ca2+-releasing effects of NAADP, cADPR, and caffeine, but not IP3. Ruthenium red also blocked the NAADP-elicited Ca2+ release. IP3 receptor blockade did not inhibit the Ca2+ release elicited by NAADP or cADPR. The nuclear envelope contains ryanodine and IP3 receptors that can be activated separately and independently; the ryanodine receptors by either NAADP or cADPR, and the IP3 receptors by IP3.     

心肌细胞核Ca^2＋库特点及其调节的离体研究

To investigate the regulation of Ca2+ in the isolated cardiac nuclei from rats which may illuminated the mechanism of nuclear calcium transport system. Elocity and isopyknic gradient centrifugation were employed to fractionate rat cardiac nuclei. Then fluo-4 confocal microscopy techniques was used to verify the changes of nuclear Ca2+. There are calcium-dependent Ca2+ uptake in the cardiac nuclear obtained from normal rats. The accumulation Ca2+ of cardiac nuclei in vitro from the incubating medium were not consistent with free [Ca2+] in incubating medium. The nuclear envelope was initially loaded with Ca2+ (1 mmol/L ATP and approximately 100 nmol/L Ca2+), Adequate Ca2+ loading was next confirmed by imaging the nuclear envelope and nucleoplasm. Exposure of Ca2+ -loaded nuclei to IP3, ryanodine or ryanodine + thapsigargin, respectively, resulted in a rapid and transient elevation of nucleoplasmic Ca2+ free concentration, this effects were abolished by pretreatment of cardiac nuclei with Ca2+ -ATPase inhibitor thapsigargin. Thapsigargin and IP3 receptor antagonist heparin induced nucleoplasmic Ca2+ free concentration decrease. Fluorescence experiments indicated that both ryanodine receptors and Ca2+ -ATPase were distributed in the outer layer of nuclear envelope, and inositol 1,4,5-trisphosphate receptors mainly dispersively localized at inner layer of nuclear envelope. The present study demonstrates that nuclear calcium were regulated by free Ca2+, IP3 and ryanodine. The results suggested calcium transport system might be present in the myocardial nuclei, the myocardial nuclei might served as one of calcium pools in myocardial cell.     

Activation of metabotropic glutamate receptor mGlu5 on nuclear membranes mediates intranuclear Ca2+ changes in heterologous cell types and neurons

Nuclear Ca2+ plays a critical role in many cellular functions although its mode (s) of regulation is unclear. This study shows that the metabotropic glutamate receptor, mGlu5, mobilizes nuclear Ca2+ independent of cytosolic Ca2+ regulation. Immunocytochemical, ultrastructural, and subcellular fractionation techniques revealed that the metabotropic glutamate receptor, mGlu5, can be localized to nuclear membranes in heterologous cells as well as midbrain and cortical neurons. Nuclear mGlu5 receptors derived from HEK cells or cortical cell types bound [3H]quisqualate. When loaded with Oregon Green BAPTA, nuclei isolated from mGlu5-expressing HEK cells responded to the addition of glutamate with rapid, oscillatory [Ca2+] elevations that were blocked by antagonist or EGTA. In contrast, carbachol-activation of endogenous muscarinic receptors led to cytoplasmic but not nuclear Ca2+ responses. Similarly, activation of mGlu5 receptors expressed on neuronal nuclei led to sustained Ca2+ oscillatory responses. These results suggest mGlu5 may mediate intranuclear signaling pathways.     

Spontaneously active ion channels of membranes of the nuclear envelope of hippocampal pyramidal neurons

The genetic apparatus of an eukaryotic cell is surrounded by two membranes of the nuclear envelope that forms a half-permeable barrier for the movement of molecules and ions. Using a patch-clamp technique in experiments on isolated nuclei of pyramidal neurons from the hippocampal CA1 area, we describe the biophysical properties of spontaneously active ion channels in the nuclear membranes of these cells. In the external nuclear membrane, we found anion channels with a unitary conductance of 156 pS and with very rapid kinetics of fluctuation, while in the inner membrane we recorded cationic channels with a unitary conductance of 248 pS and very slow kinetics. Channels of both types demonstrated clear voltage dependences. We hypothesize that the physiological importance of these channels is related to the function of the intermembrane space of the nuclear envelope of these cells forming a considerable calcium store. It seems possible that such channels in the nuclear membranes are necessary for the maintenance of the ion balance between the cytoplasm and perinuclear space and between the latter and karyoplasm, and also for neutralization of voltage shifts in the course of Ca²⁺ release. Neirofiziologiya/Neurophysiology, Vol. 39, No. 1, pp. 3–8, January–February, 2007.     

Sialidase occurs in both membranes of the nuclear envelope and hydrolyzes endogenous GD1a

Previous reports indicated the presence of both gangliosides and sialidase in the nuclear envelope (NE) of primary neurons and the NG108-15 neural cell line. GM1, one of the major gangliosides of this membrane, was shown to be tightly associated with a sodium-calcium exchanger in the inner membrane of the NE and to potentiate exchanger activity. GD1a was the other major ganglioside detected in the NE and, like GM1, occurs in both inner and outer membranes. A subsequent report indicated the presence of sialidase activity in the NE without specification as to which of the two membranes express it. The present study was undertaken to determine the nature and locus of this activity within the NE of two cell lines: NG108-15 and SH-SY5Y. Western blot analysis of the separated membranes revealed occurrence of Neu3 in the inner membrane and Neu1 in the outer membrane of the NE. Moreover, sialidase activity at both sites was shown capable of catalyzing conversion of endogenous GD1a to GM1.     

心肌细胞核Ca2+库特点及其调节的离体研究

研究核外Ca~(2+)浓度对核Ca~(2+)的影响,及细胞核Ca~(2+)摄取和释放的关系,以探讨核Ca~(2+)转运的调节机制。采用差速离心和密度梯度离心法分离纯化心肌细胞核,以Fluo-4/AM荧光指示剂负载心肌细胞核,应用激光共聚焦扫描显微镜和荧光分光光度计进行观察和测定。结果显示,分离纯化的成年大鼠心肌细胞核内自由[Ca~(2+)]随着核外[Ca~(2+)]的增加而逐渐增加,孵育液[Ca~(2+)]为1000 nmol/L达高峰,但二者增加的程度并不一致,之后随核外[Ca~(2+)]浓度的增加而呈降低趋势。ATP和100—600nmol/L的核外游离Ca~(2+),使心肌细胞核显示核被膜腔Ca~(2+)荧光,ATP和1000nmol/L的核外游离Ca~(2+)则进一步引起核浆内的Ca~(2+)荧光强度升高。荧光染色观察可见IP_3受体染色主要位于核内膜,而钙泵和ryanodine受体染色主要位于核外膜。IP_3和Ryancodine使核Ca~(2+)短暂升高1.68倍和1.93倍(P<0.001),而钙泵抑制剂Thapsigargin和IP_3受体抑制剂Heparin则分别使核Ca~(2+)降低64%和35.6%(p<0.05)。ryanodine使IP_3升高的核Ca~(2+)显著回落至正常水平以下(p<0.001)。Thapsigargin不能阻断IP_3和Ryanodine所致的核Ca~(2+)释放增加(p<0.05),但事先采用钙泵抑制剂Thapsigargin预处理心肌细胞核,则能显著的阻断IP_3和Ryanodine所致的核Ca~(2+)升高作用(Ca~(2+)释放作用)(p<0.05)。结果提示大鼠心肌细胞核可能也是细胞内的钙库之一,心肌细胞核上存在Ca~(2+)-ATPase、ryanodine受体和IP_3受体等Ca~(2+)转运系统,可能参与核Ca~(2+)摄取和释放的调节。     

GM1 Ganglioside in the Nuclear Membrane Modulates Nuclear Calcium Homeostasis During Neurite Outgrowth

Abstract: GM1 in the nuclear membrane, previously shown to be up-regulated during neurite outgrowth, has been found to influence nuclear Ca²⁺ flux during differentiation of Neuro-2a cells. Nuclei were isolated from cultured Neuro-2a cells before and after neuraminidase-induced neuritogenesis and incubated with ⁴⁵Ca²⁺ for varying periods to determine uptake/efflux of Ca²⁺. At 5, 10, and 15 min ⁴⁵Ca²⁺ levels in nuclei from differentiated cells were significantly lower than those in nuclei from untreated cells. The same result was obtained when the GM1 level was elevated artificially by preincubation of the nuclei in 10 µ M GM1. In experiments designed to measure efflux specifically, isolated nuclei preincubated in GM1 released ⁴⁵Ca²⁺ more rapidly than untreated nuclei. We conclude that one role of GM1 in the nuclear membrane is to alter Ca²⁺ regulatory mechanisms in the nucleus following onset of neuronal process outgrowth.     

Na,K-ATPase in the nuclear envelope regulates Na+: K+ gradients in hepatocyte nuclei

Evidence is emerging that the nuclear envelope itself is responsible for transport and signaling activities quite distinct from those associated with the nuclear pore. For example, the envelope has a Ca2+-signaling pathway that, among other things, regulates meiosis in oocytes. The nuclear envelope's outer membrane also contains K+ channels. Here we show that Na+/K+ gradients exist between the nuclear envelope lumen and both cytoplasm and nucleoplasm in hepatocyte nuclei. The gradients are formed by Na,K-ATPases in the envelope's inner membrane, oriented with the ATP hydrolysis site in the nucleoplasm. We further demonstrate nucleoplasm/cytoplasm Na+ and K+ gradients, of which only the Na+ gradient is dissipated directly by Na,K-ATPase inhibition with ouabain. Finally, our results demonstrate that nuclear pores are not freely permeable to sodium and potassium. Based on these results and numerous in vitro studies, nuclear monovalent cation transporters and channels are likely to play a role in modulation of chromatin structure and gene expression.     

Mutant NG108-15 cells (NG-CR72) deficient in GM1 synthase respond aberrantly to axonogenic stimuli and are vulnerable to calcium-induced apoptosis: they are rescued with LIGA-20

The neuroblastoma x glioma NG108-15 hybrid cell line, a widely used model for the study of neuronal differentiation, contains a variety of gangliosides including GM1 and its sialosylated derivative, GD1a. To investigate the role of these a-series gangliotetraose gangliosides in neuritogenesis, we have obtained a mutated subclone of NG108-15 that is deficient in that family of gangliosides. NG108-15 cells were grown in the presence of cholera toxin, which killed the large majority of cells, and from the cholera-resistant survivors we isolated a clone, NG-CR72, that lacks GM1 and GD1a in the plasma and nuclear membranes. GM2 concentration was significantly higher in the plasma membrane. Enzyme assay indicated deficiency of UDP-Gal:GM2 galactosyltransferase (GM1 synthase), which was confirmed by incorporation studies with [3H]sphingosine. These cells resembled wild-type NG108-15 in extending dendritic processes in response to dendritogenic agents (retinoic acid, dibutyryl cAMP) but responded aberrantly to axonogenic stimuli (KCl, ionomycin) by extending unstable neurites that showed the cytoskeletal staining characteristic of dendrites. Moreover, mutant cells treated with the Ca2+ elevating axonogenic agents underwent apoptosis over time, attributed to dysfunction of Ca2+ regulatory mechanisms normally mediated by GM1. Such agents caused dramatic and sustained elevation of intracellular Ca2+ in mutant cells, in contrast to modest and temporary elevation in wild-type cells. Exogenous GM1, inserted into the plasma membrane, had no discernable protective effect on NG-CR72 cells whereas LIGA-20, a membrane-permeant derivative of GM1 that entered both plasma and nuclear membranes, blocked apoptosis, permitted extension of stable neurites, and attenuated the abnormal elevation of intracellular Ca2+.     

Calcium sensing receptor regulates cardiomyocyte function through nuclear calcium

Nuclear Ca2+ plays a pivotal role in the regulation of gene expression. IP3 (inositol-1,4,5-trisphosphate) is an important regulator of nuclear Ca2+. We hypothesized that the CaR (calcium sensing receptor) stimulates nuclear Ca2+ release through IICR (IP3-induced calcium release) from perinuclear stores. Spontaneous Ca2+ oscillations and the spark frequency of nuclear Ca2+ were measured simultaneously in NRVMs (neonatal rat ventricular myocytes) using confocal imaging. CaR-induced nuclear Ca2+ release through IICR was abolished by inhibition of CaR and IP3Rs (IP3 receptors). However, no effect on the inhibition of RyRs (ryanodine receptors) was detected. The results suggest that CaR specifically modulates nuclear Ca2+ signalling through the IP3R pathway. Interestingly, nuclear Ca2+ was released from perinuclear stores by CaR activator-induced cardiomyocyte hypertrophy through the Ca2+-dependent phosphatase CaN (calcineurin)/NFAT (nuclear factor of activated T-cells) pathway. We have also demonstrated that the activation of the CaR increased the NRVM protein content, enlarged cell size and stimulated CaN expression and NFAT nuclear translocation in NRVMs. Thus, CaR enhances the nuclear Ca2+ transient in NRVMs by increasing fractional Ca2+ release from perinuclear stores, which is involved in cardiac hypertrophy through the CaN/NFAT pathway.     

Activation of sarcolemma and nuclear membranes ET-1 receptors regulates transcellular calcium levels in heart and vascular smooth muscle cells

The use of an ET-1 fluorescent probe in human heart and vascular smooth muscle cells showed that ET-1 receptors are present at both the sarcolemma and nuclear envelope membranes. The use of immunofluorescence studies showed that the ETA receptor was mainly present at the sarcolemma and cytosolic levels. However, the ETB receptor was present at the sarcolemma and the cytosol, as well as the nuclear envelope membranes and the nucleoplasm. In addition, ET-1 immunoreactivity was seen in the cytosol and the nucleus. Using Ca2+ fluorescent probes such as Fluo-3, Indo 1, and yellow cameleon, as well as confocal microscopy three-dimensional image measurement technique, stimulation of ET-1 receptors at the sarcolemma membranes induced an increase of cytosolic and nuclear free Ca2+ levels. This effect of extracellular ET-1 was blocked by removal of extracellular calcium. Direct stimulation of ET-1 receptors at the nuclear envelope membranes also induced an increase of intranuclear free Ca2+ level. Our results suggest that the stimulation of sarcolemmal Ca2+ influx by ET-1 seems to be due to the activation of ETA and ETB receptors. However, the increase of nucleoplasmic Ca2+ levels by cytosolic ET-1 seems to be mediated via the activation of ETB receptors. Activation of nuclear membranes ETB receptors seems to prevent nuclear Ca2+ overload and may protect the cell from apoptosis.     

Activated nuclear metabotropic glutamate receptor mGlu5 couples to nuclear Gq/11 proteins to generate inositol 1,4,5-trisphosphate-mediated nuclear Ca2+ release

Recently we have shown that the metabotropic glutamate 5 (mGlu5) receptor can be expressed on nuclear membranes of heterologous cells or endogenously on striatal neurons where it can mediate nuclear Ca2+ changes. Here, pharmacological, optical, and genetic techniques were used to show that upon activation, nuclear mGlu5 receptors generate nuclear inositol 1,4,5-trisphosphate (IP3) in situ. Specifically, expression of an mGlu5 F767S mutant in HEK293 cells that blocks Gq/11 coupling or introduction of a dominant negative Galphaq construct in striatal neurons prevented nuclear Ca2+ changes following receptor activation. These data indicate that nuclear mGlu5 receptors couple to Gq/11 to mobilize nuclear Ca2+. Nuclear mGlu5-mediated Ca2+ responses could also be blocked by the phospholipase C (PLC) inhibitor, U73122, the phosphatidylinositol (PI) PLC inhibitor 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphorylcholine (ET-18-OCH3), or by using small interfering RNA targeted against PLCbeta1 demonstrating that PI-PLC is involved. Direct assessment of inositol phosphate production using a PIP2/IP3 "biosensor" revealed for the first time that IP3 can be generated in the nucleus following activation of nuclear mGlu5 receptors. Finally, both IP3 and ryanodine receptor blockers prevented nuclear mGlu5-mediated increases in intranuclear Ca2+. Collectively, this study shows that like plasma membrane receptors, activated nuclear mGlu5 receptors couple to Gq/11 and PLC to generate IP3-mediated release of Ca2+ from Ca2+-release channels in the nucleus. Thus the nucleus can function as an autonomous organelle independent of signals originating in the cytoplasm, and nuclear mGlu5 receptors play a dynamic role in mobilizing Ca2+ in a specific, localized fashion.     

3T3 cells have nuclear invaginations containing F-actin

Nuclear envelope invaginations occur in many kinds of cell. Double-labeling of 3T3 cells with Hoechst 33342 strain for DNA and phalloidin-rhodamine for F-actin, show that some nuclei appear to contain tangled knots of F-actin. Concanavalin A-fluorescein staining for membranes shows that the knots are continuations of the nuclear envelope. Although they contain F-actin, the knots appear by electron microscopy to be cytoplasmic invaginations lacking microfilaments. Since we have shown previously that nuclear-membrane associated actin forms perinuclear shells in 3T3 cells, we propose that nuclear knots also are composed of actin associated with the nuclear membrane. 3T3 nuclei also contain nuclear invaginations of a second kind. These invaginations lie perpendicular to the first type and lack F-actin.